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New guidelines for determining brain death released
The consensus practice guideline on brain death, also known as death by neurologic criteria (BD/DNC), was developed by a panel of 20 experts from different specialties, institutions, and medical societies.
As with previous guidelines, the updated version stipulates that brain death should be declared when a patient with a known cause of catastrophic brain injury has permanent loss of function of the brain, including the brain stem, which results in coma, brain stem areflexia, and apnea in the setting of an adequate stimulus.
But the updated version also clarifies questions on neurological examinations and apnea testing and offers new guidance on pre-evaluation targets for blood pressure and body temperature and evaluating brain death in patients who are pregnant, are on extracorporeal membrane oxygenation, or have an injury to the base of the brain.
Also, for the first time, the guidance clarifies that clinicians don’t need to obtain consent before performing a brain death evaluation, unless institutional policy, state laws, or regulations stipulate otherwise.
“The 2023 guidelines will be considered the standard of care in the U.S.,” lead author David M. Greer, MD, chair and chief of neurology, Boston University, and chief of neurology, Boston Medical Center, said in an interview. “Each hospital in the U.S. is responsible for its own policy for BD/DNC determination, and our hope is that they will quickly revise their policies in accordance with this new national standard.”
The guidelines, which are accompanied by a three-page checklist and a free digital app, were published online in Neurology.
Four years in the making
Work on the 85 recommendations in the new report began more than 4 years ago as a collaborative effort by the American Academy of Neurology, the American Academy of Pediatrics, the Child Neurology Society, and the Society of Critical Care Medicine.
A lack of high-quality evidence on brain death determination led panelists to devise an evidence-informed formal consensus process to develop the guidelines, which involved three rounds of anonymous voting on each recommendation and the rationales behind them.
The strength of each recommendation was based on the level of consensus reached through voting, with Level A denoting a recommendation that “must” be followed, Level B one that “should” be followed, and Level C one that “may” be followed.
The majority of recommendations received an A or B rating. Only one recommendation, about whether a second clinical exam is needed in adults, garnered a C rating.
In children, the guidelines recommend that clinicians must perform two clinical examinations and two apnea tests 12 hours apart. In adults, only one exam is required. Both of those recommendations were rated Level A. A recommendation for a second exam in adults received the single Level C rating.
A uniform set of guidelines?
The new guidelines replace adult practice guidance published by AAN in 2010 and guideline for infants and children released in 2011 by AAP, CNS, and SCCM, and for the first time combine brain death guidelines for adult and pediatric patients into one document.
“It is important for clinicians to review the new guideline carefully and ensure their hospital brain death guidelines are updated to be consistent with the new guideline in order to prevent inaccurate determinations of death,” guidelines coauthor Ariane Lewis, MD, NYU Langone Health, New York, said in an interview.
The 1981 Uniform Determination of Death Act (UDDA) is the legal foundation for the declaration of BD/DNC in the United States, but it only stipulates that brain death determination must be made in accordance with accepted medical standards.
There is no single national standard, and states and hospitals are free to adopt their own, which many have done. One goal of the new guidelines was to create a uniform set of guidelines that all institutions follow.
“This is a step toward having a set of guidelines that are accepted by most of the societies and clinical specialties involved in this sort of diagnosis,” that could lead to a national-level policy, Fernando Goldenberg, MD, professor of neurology and director of neuroscience critical care, University of Chicago Medicine, said in an interview.
Dr. Goldenberg was not part of the panel that developed the updated guidelines, but was a coauthor of a consensus statement from the World Brain Death Project in 2020.
Developing a singular global guideline for brain death determination is unlikely, Dr. Goldenberg said. Policies vary widely across the world, and some countries don’t even recognize brain death.
“But this attempts to unify things at the U.S. level, which is very important,” he said.
Permanent vs. irreversible
Dr. Goldenberg said that combining adult and pediatric guidelines into one document will be very helpful for clinicians like him who treat patients from age 16 years and up.
The expanded guidance on apnea testing, recommendations on specific ancillary tests to use or avoid, and inclusion of language stipulating that prior consent is not needed to perform a brain death evaluation are also useful.
He also noted that the section on credentialing and training of clinicians who perform BD/DNC evaluations recognizes advanced practice providers, the first time he recalls seeing these professionals included in brain death guidelines.
However, the panel’s decision to use the term “permanent” to describe loss of brain function instead of “irreversible” gave Dr. Goldenberg pause.
The UDDA provides that an individual is declared legally dead when “circulatory and respiratory functions irreversibly stop; or all functions of the entire brain, including the brain stem, irreversibly stop.”
Earlier in October, the American College of Physicians released a position paper on cardiorespiratory death determination that called for a revision of the UDDA language.
The ACP suggested that “irreversibly” be replaced with “permanently” with regard to the cessation of circulatory and respiratory functions, but that “irreversible” be kept in the description of brain death.
“Permanent means that there is damage that is potentially reversible and irreversible means that the damage is so profound, it cannot be reversed even if an attempt to do so is performed,” Dr. Goldenberg said.
Even though the World Brain Death Project, on which he worked, also used “permanent” to describe brain function loss, Dr. Goldenberg said he aligns with ACP’s position.
“The understanding of brain death is that the damage is so profound, it is irreversible, even if you were to try,” he said. “Therefore, I think that the most appropriate term for brain death should be irreversible as opposed to permanent.”
The report was funded by the American Academy of Neurology. Dr. Greer has received travel funding from Boston University; serves as editor-in-chief for Seminars in Neurology; receives publishing royalties for 50 Studies Every Neurologist Should Know and Successful Leadership in Academic Medicine; has received honoraria from AAN; has received research funding from Becton, Dickinson, and Company; and has served as expert witness in legal proceedings. Dr. Lewis has received honoraria from AAN and Neurodiem, serves as Neurology deputy editor of disputes and debates, and serves as deputy editor of seminars in Neurology. Dr. Goldenberg reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
The consensus practice guideline on brain death, also known as death by neurologic criteria (BD/DNC), was developed by a panel of 20 experts from different specialties, institutions, and medical societies.
As with previous guidelines, the updated version stipulates that brain death should be declared when a patient with a known cause of catastrophic brain injury has permanent loss of function of the brain, including the brain stem, which results in coma, brain stem areflexia, and apnea in the setting of an adequate stimulus.
But the updated version also clarifies questions on neurological examinations and apnea testing and offers new guidance on pre-evaluation targets for blood pressure and body temperature and evaluating brain death in patients who are pregnant, are on extracorporeal membrane oxygenation, or have an injury to the base of the brain.
Also, for the first time, the guidance clarifies that clinicians don’t need to obtain consent before performing a brain death evaluation, unless institutional policy, state laws, or regulations stipulate otherwise.
“The 2023 guidelines will be considered the standard of care in the U.S.,” lead author David M. Greer, MD, chair and chief of neurology, Boston University, and chief of neurology, Boston Medical Center, said in an interview. “Each hospital in the U.S. is responsible for its own policy for BD/DNC determination, and our hope is that they will quickly revise their policies in accordance with this new national standard.”
The guidelines, which are accompanied by a three-page checklist and a free digital app, were published online in Neurology.
Four years in the making
Work on the 85 recommendations in the new report began more than 4 years ago as a collaborative effort by the American Academy of Neurology, the American Academy of Pediatrics, the Child Neurology Society, and the Society of Critical Care Medicine.
A lack of high-quality evidence on brain death determination led panelists to devise an evidence-informed formal consensus process to develop the guidelines, which involved three rounds of anonymous voting on each recommendation and the rationales behind them.
The strength of each recommendation was based on the level of consensus reached through voting, with Level A denoting a recommendation that “must” be followed, Level B one that “should” be followed, and Level C one that “may” be followed.
The majority of recommendations received an A or B rating. Only one recommendation, about whether a second clinical exam is needed in adults, garnered a C rating.
In children, the guidelines recommend that clinicians must perform two clinical examinations and two apnea tests 12 hours apart. In adults, only one exam is required. Both of those recommendations were rated Level A. A recommendation for a second exam in adults received the single Level C rating.
A uniform set of guidelines?
The new guidelines replace adult practice guidance published by AAN in 2010 and guideline for infants and children released in 2011 by AAP, CNS, and SCCM, and for the first time combine brain death guidelines for adult and pediatric patients into one document.
“It is important for clinicians to review the new guideline carefully and ensure their hospital brain death guidelines are updated to be consistent with the new guideline in order to prevent inaccurate determinations of death,” guidelines coauthor Ariane Lewis, MD, NYU Langone Health, New York, said in an interview.
The 1981 Uniform Determination of Death Act (UDDA) is the legal foundation for the declaration of BD/DNC in the United States, but it only stipulates that brain death determination must be made in accordance with accepted medical standards.
There is no single national standard, and states and hospitals are free to adopt their own, which many have done. One goal of the new guidelines was to create a uniform set of guidelines that all institutions follow.
“This is a step toward having a set of guidelines that are accepted by most of the societies and clinical specialties involved in this sort of diagnosis,” that could lead to a national-level policy, Fernando Goldenberg, MD, professor of neurology and director of neuroscience critical care, University of Chicago Medicine, said in an interview.
Dr. Goldenberg was not part of the panel that developed the updated guidelines, but was a coauthor of a consensus statement from the World Brain Death Project in 2020.
Developing a singular global guideline for brain death determination is unlikely, Dr. Goldenberg said. Policies vary widely across the world, and some countries don’t even recognize brain death.
“But this attempts to unify things at the U.S. level, which is very important,” he said.
Permanent vs. irreversible
Dr. Goldenberg said that combining adult and pediatric guidelines into one document will be very helpful for clinicians like him who treat patients from age 16 years and up.
The expanded guidance on apnea testing, recommendations on specific ancillary tests to use or avoid, and inclusion of language stipulating that prior consent is not needed to perform a brain death evaluation are also useful.
He also noted that the section on credentialing and training of clinicians who perform BD/DNC evaluations recognizes advanced practice providers, the first time he recalls seeing these professionals included in brain death guidelines.
However, the panel’s decision to use the term “permanent” to describe loss of brain function instead of “irreversible” gave Dr. Goldenberg pause.
The UDDA provides that an individual is declared legally dead when “circulatory and respiratory functions irreversibly stop; or all functions of the entire brain, including the brain stem, irreversibly stop.”
Earlier in October, the American College of Physicians released a position paper on cardiorespiratory death determination that called for a revision of the UDDA language.
The ACP suggested that “irreversibly” be replaced with “permanently” with regard to the cessation of circulatory and respiratory functions, but that “irreversible” be kept in the description of brain death.
“Permanent means that there is damage that is potentially reversible and irreversible means that the damage is so profound, it cannot be reversed even if an attempt to do so is performed,” Dr. Goldenberg said.
Even though the World Brain Death Project, on which he worked, also used “permanent” to describe brain function loss, Dr. Goldenberg said he aligns with ACP’s position.
“The understanding of brain death is that the damage is so profound, it is irreversible, even if you were to try,” he said. “Therefore, I think that the most appropriate term for brain death should be irreversible as opposed to permanent.”
The report was funded by the American Academy of Neurology. Dr. Greer has received travel funding from Boston University; serves as editor-in-chief for Seminars in Neurology; receives publishing royalties for 50 Studies Every Neurologist Should Know and Successful Leadership in Academic Medicine; has received honoraria from AAN; has received research funding from Becton, Dickinson, and Company; and has served as expert witness in legal proceedings. Dr. Lewis has received honoraria from AAN and Neurodiem, serves as Neurology deputy editor of disputes and debates, and serves as deputy editor of seminars in Neurology. Dr. Goldenberg reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
The consensus practice guideline on brain death, also known as death by neurologic criteria (BD/DNC), was developed by a panel of 20 experts from different specialties, institutions, and medical societies.
As with previous guidelines, the updated version stipulates that brain death should be declared when a patient with a known cause of catastrophic brain injury has permanent loss of function of the brain, including the brain stem, which results in coma, brain stem areflexia, and apnea in the setting of an adequate stimulus.
But the updated version also clarifies questions on neurological examinations and apnea testing and offers new guidance on pre-evaluation targets for blood pressure and body temperature and evaluating brain death in patients who are pregnant, are on extracorporeal membrane oxygenation, or have an injury to the base of the brain.
Also, for the first time, the guidance clarifies that clinicians don’t need to obtain consent before performing a brain death evaluation, unless institutional policy, state laws, or regulations stipulate otherwise.
“The 2023 guidelines will be considered the standard of care in the U.S.,” lead author David M. Greer, MD, chair and chief of neurology, Boston University, and chief of neurology, Boston Medical Center, said in an interview. “Each hospital in the U.S. is responsible for its own policy for BD/DNC determination, and our hope is that they will quickly revise their policies in accordance with this new national standard.”
The guidelines, which are accompanied by a three-page checklist and a free digital app, were published online in Neurology.
Four years in the making
Work on the 85 recommendations in the new report began more than 4 years ago as a collaborative effort by the American Academy of Neurology, the American Academy of Pediatrics, the Child Neurology Society, and the Society of Critical Care Medicine.
A lack of high-quality evidence on brain death determination led panelists to devise an evidence-informed formal consensus process to develop the guidelines, which involved three rounds of anonymous voting on each recommendation and the rationales behind them.
The strength of each recommendation was based on the level of consensus reached through voting, with Level A denoting a recommendation that “must” be followed, Level B one that “should” be followed, and Level C one that “may” be followed.
The majority of recommendations received an A or B rating. Only one recommendation, about whether a second clinical exam is needed in adults, garnered a C rating.
In children, the guidelines recommend that clinicians must perform two clinical examinations and two apnea tests 12 hours apart. In adults, only one exam is required. Both of those recommendations were rated Level A. A recommendation for a second exam in adults received the single Level C rating.
A uniform set of guidelines?
The new guidelines replace adult practice guidance published by AAN in 2010 and guideline for infants and children released in 2011 by AAP, CNS, and SCCM, and for the first time combine brain death guidelines for adult and pediatric patients into one document.
“It is important for clinicians to review the new guideline carefully and ensure their hospital brain death guidelines are updated to be consistent with the new guideline in order to prevent inaccurate determinations of death,” guidelines coauthor Ariane Lewis, MD, NYU Langone Health, New York, said in an interview.
The 1981 Uniform Determination of Death Act (UDDA) is the legal foundation for the declaration of BD/DNC in the United States, but it only stipulates that brain death determination must be made in accordance with accepted medical standards.
There is no single national standard, and states and hospitals are free to adopt their own, which many have done. One goal of the new guidelines was to create a uniform set of guidelines that all institutions follow.
“This is a step toward having a set of guidelines that are accepted by most of the societies and clinical specialties involved in this sort of diagnosis,” that could lead to a national-level policy, Fernando Goldenberg, MD, professor of neurology and director of neuroscience critical care, University of Chicago Medicine, said in an interview.
Dr. Goldenberg was not part of the panel that developed the updated guidelines, but was a coauthor of a consensus statement from the World Brain Death Project in 2020.
Developing a singular global guideline for brain death determination is unlikely, Dr. Goldenberg said. Policies vary widely across the world, and some countries don’t even recognize brain death.
“But this attempts to unify things at the U.S. level, which is very important,” he said.
Permanent vs. irreversible
Dr. Goldenberg said that combining adult and pediatric guidelines into one document will be very helpful for clinicians like him who treat patients from age 16 years and up.
The expanded guidance on apnea testing, recommendations on specific ancillary tests to use or avoid, and inclusion of language stipulating that prior consent is not needed to perform a brain death evaluation are also useful.
He also noted that the section on credentialing and training of clinicians who perform BD/DNC evaluations recognizes advanced practice providers, the first time he recalls seeing these professionals included in brain death guidelines.
However, the panel’s decision to use the term “permanent” to describe loss of brain function instead of “irreversible” gave Dr. Goldenberg pause.
The UDDA provides that an individual is declared legally dead when “circulatory and respiratory functions irreversibly stop; or all functions of the entire brain, including the brain stem, irreversibly stop.”
Earlier in October, the American College of Physicians released a position paper on cardiorespiratory death determination that called for a revision of the UDDA language.
The ACP suggested that “irreversibly” be replaced with “permanently” with regard to the cessation of circulatory and respiratory functions, but that “irreversible” be kept in the description of brain death.
“Permanent means that there is damage that is potentially reversible and irreversible means that the damage is so profound, it cannot be reversed even if an attempt to do so is performed,” Dr. Goldenberg said.
Even though the World Brain Death Project, on which he worked, also used “permanent” to describe brain function loss, Dr. Goldenberg said he aligns with ACP’s position.
“The understanding of brain death is that the damage is so profound, it is irreversible, even if you were to try,” he said. “Therefore, I think that the most appropriate term for brain death should be irreversible as opposed to permanent.”
The report was funded by the American Academy of Neurology. Dr. Greer has received travel funding from Boston University; serves as editor-in-chief for Seminars in Neurology; receives publishing royalties for 50 Studies Every Neurologist Should Know and Successful Leadership in Academic Medicine; has received honoraria from AAN; has received research funding from Becton, Dickinson, and Company; and has served as expert witness in legal proceedings. Dr. Lewis has received honoraria from AAN and Neurodiem, serves as Neurology deputy editor of disputes and debates, and serves as deputy editor of seminars in Neurology. Dr. Goldenberg reported no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FROM NEUROLOGY
Are manual therapies effective at reducing chronic tension headache frequency in adults?
Evidence summary
Small studies offer mixed evidence of benefit
Seven RCTs using manual therapies to treat chronic tension headaches have reported the change in headache frequency (TABLE1-7). Most, but not all, manual therapies significantly improved headache frequency.
Participants ranged in age from 18 to 65 years, with mean age ranges of 33 to 42 years in each study. At baseline, patients had 10 or more tension-type headaches per month. The manual therapies varied in techniques, duration, and the training of the person performing the intervention:
- Twice-weekly chiropractic spinal manipulation for 6 weeks1
- Soft-tissue therapy plus spinal manipulation (8 treatments over 4 weeks)2
- Chiropractic spinal manipulation with or without amitriptyline for 14 weeks3
- Corrective osteopathic manipulation treatment (OMT) techniques tailored for each patient for 1 month4
- High-velocity low-amplitude manipulation (HVLA) plus exercise or myofascial release plus exercise twice weekly for 8 weeks5
- Manual therapy treatment consisting of a combination of mobilizations of the cervical and thoracic spine, exercises, and postural correction for up to 9 sessions of 30 minutes each6
- One hour of direct or indirect myofascial release treatment twice weekly for 12 weeks.7
Three studies involved chiropractic providers.1-3 One study (n = 19) found a positive effect, in which chiropractic manipulation augmented with amitriptyline performed better than chiropractic manipulation alone.3 Another chiropractic study did not find an immediate posttreatment benefit but did report significant headache reduction at the 4-week follow-up interval.1 The third chiropractic study did not show additional benefit from HVLA manipulation.2
One small study involving osteopathic physicians using OMT found reduced headache frequency after 12 weeks but not at 4 weeks.4 Another study, comparing HVLA or myofascial release with exercise to exercise alone, found benefit for the HVLA group but not for myofascial release; interventions in this study were performed by a physician with at least 6 years of unspecified manual therapy experience.5 A small study of manual therapists found improvement at the end of manual therapy but not at 18 months.6 Another small study using providers with 10 months’ experience with myofascial release found reduced headache frequency 4 weeks after a course of direct and indirect myofascial release (compared with sham release).7
Editor’s takeaway
It isn’t hard to imagine why muscle tension headaches might respond to certain forms of manual therapy. However, all available studies of these modalities have been small (< 100 patients) or lacked blinding, introducing the potential for significant bias. Nevertheless, for now it appears reasonable to refer interested patients with tension headache to an osteopathic physician for OMT or myofascial release to reduce headache frequency.
1. Boline PD, Kassak K, Bronfort G, et al. Spinal manipulation vs amitriptyline for the treatment of chronic tension-type headaches—a randomized clinical-trial. J Manipulative Physiol Ther. 1995;18:148-254.
2. Bove G. Spinal manipulation in the treatment of episodic tension-type headache: a randomized controlled trial. JAMA. 1998;280:1576-1579.
3. Vernon H, Jansz G, Goldsmith CH, et al. A randomized, placebo-controlled clinical trial of chiropractic and medical prophylactic treatment of adults with tension-type headache: results from a stopped trial. J Manipulative Physiol Ther. 2009;32:344-351.
4. Rolle G, Tremolizzo L, Somalvico F, et al. Pilot trial of osteopathic manipulative therapy for patients with frequent episodic tension-type headache. J Am Osteopath Assoc. 2014;114:678-685. doi: 10.7556/jaoa.2014.136
5. Corum M, Aydin T, Ceylan CM, et al. The comparative effects of spinal manipulation, myofascial release and exercise in tension-type headache patients with neck pain: a randomized controlled trial. Complement Ther Clin Pract. 2021;43:101319. doi: 0.1016/j.ctcp.2021.101319
6. Castien RF, van der Windt DAWM, Grooten A, et al. Effectiveness of manual therapy compared to usual care by the general practitioner for chronic tension-type headache: a pragmatic, randomised, clinical trial. Cephalalgia. 2009;31:133-143.
7. Ajimsha MS. Effectiveness of direct vs indirect technique myofascial release in the management of tension-type headache. J Bodyw Mov Ther. 2011;15:431-435. doi: 10.1016/j.jbmt.2011.01.021
Evidence summary
Small studies offer mixed evidence of benefit
Seven RCTs using manual therapies to treat chronic tension headaches have reported the change in headache frequency (TABLE1-7). Most, but not all, manual therapies significantly improved headache frequency.
Participants ranged in age from 18 to 65 years, with mean age ranges of 33 to 42 years in each study. At baseline, patients had 10 or more tension-type headaches per month. The manual therapies varied in techniques, duration, and the training of the person performing the intervention:
- Twice-weekly chiropractic spinal manipulation for 6 weeks1
- Soft-tissue therapy plus spinal manipulation (8 treatments over 4 weeks)2
- Chiropractic spinal manipulation with or without amitriptyline for 14 weeks3
- Corrective osteopathic manipulation treatment (OMT) techniques tailored for each patient for 1 month4
- High-velocity low-amplitude manipulation (HVLA) plus exercise or myofascial release plus exercise twice weekly for 8 weeks5
- Manual therapy treatment consisting of a combination of mobilizations of the cervical and thoracic spine, exercises, and postural correction for up to 9 sessions of 30 minutes each6
- One hour of direct or indirect myofascial release treatment twice weekly for 12 weeks.7
Three studies involved chiropractic providers.1-3 One study (n = 19) found a positive effect, in which chiropractic manipulation augmented with amitriptyline performed better than chiropractic manipulation alone.3 Another chiropractic study did not find an immediate posttreatment benefit but did report significant headache reduction at the 4-week follow-up interval.1 The third chiropractic study did not show additional benefit from HVLA manipulation.2
One small study involving osteopathic physicians using OMT found reduced headache frequency after 12 weeks but not at 4 weeks.4 Another study, comparing HVLA or myofascial release with exercise to exercise alone, found benefit for the HVLA group but not for myofascial release; interventions in this study were performed by a physician with at least 6 years of unspecified manual therapy experience.5 A small study of manual therapists found improvement at the end of manual therapy but not at 18 months.6 Another small study using providers with 10 months’ experience with myofascial release found reduced headache frequency 4 weeks after a course of direct and indirect myofascial release (compared with sham release).7
Editor’s takeaway
It isn’t hard to imagine why muscle tension headaches might respond to certain forms of manual therapy. However, all available studies of these modalities have been small (< 100 patients) or lacked blinding, introducing the potential for significant bias. Nevertheless, for now it appears reasonable to refer interested patients with tension headache to an osteopathic physician for OMT or myofascial release to reduce headache frequency.
Evidence summary
Small studies offer mixed evidence of benefit
Seven RCTs using manual therapies to treat chronic tension headaches have reported the change in headache frequency (TABLE1-7). Most, but not all, manual therapies significantly improved headache frequency.
Participants ranged in age from 18 to 65 years, with mean age ranges of 33 to 42 years in each study. At baseline, patients had 10 or more tension-type headaches per month. The manual therapies varied in techniques, duration, and the training of the person performing the intervention:
- Twice-weekly chiropractic spinal manipulation for 6 weeks1
- Soft-tissue therapy plus spinal manipulation (8 treatments over 4 weeks)2
- Chiropractic spinal manipulation with or without amitriptyline for 14 weeks3
- Corrective osteopathic manipulation treatment (OMT) techniques tailored for each patient for 1 month4
- High-velocity low-amplitude manipulation (HVLA) plus exercise or myofascial release plus exercise twice weekly for 8 weeks5
- Manual therapy treatment consisting of a combination of mobilizations of the cervical and thoracic spine, exercises, and postural correction for up to 9 sessions of 30 minutes each6
- One hour of direct or indirect myofascial release treatment twice weekly for 12 weeks.7
Three studies involved chiropractic providers.1-3 One study (n = 19) found a positive effect, in which chiropractic manipulation augmented with amitriptyline performed better than chiropractic manipulation alone.3 Another chiropractic study did not find an immediate posttreatment benefit but did report significant headache reduction at the 4-week follow-up interval.1 The third chiropractic study did not show additional benefit from HVLA manipulation.2
One small study involving osteopathic physicians using OMT found reduced headache frequency after 12 weeks but not at 4 weeks.4 Another study, comparing HVLA or myofascial release with exercise to exercise alone, found benefit for the HVLA group but not for myofascial release; interventions in this study were performed by a physician with at least 6 years of unspecified manual therapy experience.5 A small study of manual therapists found improvement at the end of manual therapy but not at 18 months.6 Another small study using providers with 10 months’ experience with myofascial release found reduced headache frequency 4 weeks after a course of direct and indirect myofascial release (compared with sham release).7
Editor’s takeaway
It isn’t hard to imagine why muscle tension headaches might respond to certain forms of manual therapy. However, all available studies of these modalities have been small (< 100 patients) or lacked blinding, introducing the potential for significant bias. Nevertheless, for now it appears reasonable to refer interested patients with tension headache to an osteopathic physician for OMT or myofascial release to reduce headache frequency.
1. Boline PD, Kassak K, Bronfort G, et al. Spinal manipulation vs amitriptyline for the treatment of chronic tension-type headaches—a randomized clinical-trial. J Manipulative Physiol Ther. 1995;18:148-254.
2. Bove G. Spinal manipulation in the treatment of episodic tension-type headache: a randomized controlled trial. JAMA. 1998;280:1576-1579.
3. Vernon H, Jansz G, Goldsmith CH, et al. A randomized, placebo-controlled clinical trial of chiropractic and medical prophylactic treatment of adults with tension-type headache: results from a stopped trial. J Manipulative Physiol Ther. 2009;32:344-351.
4. Rolle G, Tremolizzo L, Somalvico F, et al. Pilot trial of osteopathic manipulative therapy for patients with frequent episodic tension-type headache. J Am Osteopath Assoc. 2014;114:678-685. doi: 10.7556/jaoa.2014.136
5. Corum M, Aydin T, Ceylan CM, et al. The comparative effects of spinal manipulation, myofascial release and exercise in tension-type headache patients with neck pain: a randomized controlled trial. Complement Ther Clin Pract. 2021;43:101319. doi: 0.1016/j.ctcp.2021.101319
6. Castien RF, van der Windt DAWM, Grooten A, et al. Effectiveness of manual therapy compared to usual care by the general practitioner for chronic tension-type headache: a pragmatic, randomised, clinical trial. Cephalalgia. 2009;31:133-143.
7. Ajimsha MS. Effectiveness of direct vs indirect technique myofascial release in the management of tension-type headache. J Bodyw Mov Ther. 2011;15:431-435. doi: 10.1016/j.jbmt.2011.01.021
1. Boline PD, Kassak K, Bronfort G, et al. Spinal manipulation vs amitriptyline for the treatment of chronic tension-type headaches—a randomized clinical-trial. J Manipulative Physiol Ther. 1995;18:148-254.
2. Bove G. Spinal manipulation in the treatment of episodic tension-type headache: a randomized controlled trial. JAMA. 1998;280:1576-1579.
3. Vernon H, Jansz G, Goldsmith CH, et al. A randomized, placebo-controlled clinical trial of chiropractic and medical prophylactic treatment of adults with tension-type headache: results from a stopped trial. J Manipulative Physiol Ther. 2009;32:344-351.
4. Rolle G, Tremolizzo L, Somalvico F, et al. Pilot trial of osteopathic manipulative therapy for patients with frequent episodic tension-type headache. J Am Osteopath Assoc. 2014;114:678-685. doi: 10.7556/jaoa.2014.136
5. Corum M, Aydin T, Ceylan CM, et al. The comparative effects of spinal manipulation, myofascial release and exercise in tension-type headache patients with neck pain: a randomized controlled trial. Complement Ther Clin Pract. 2021;43:101319. doi: 0.1016/j.ctcp.2021.101319
6. Castien RF, van der Windt DAWM, Grooten A, et al. Effectiveness of manual therapy compared to usual care by the general practitioner for chronic tension-type headache: a pragmatic, randomised, clinical trial. Cephalalgia. 2009;31:133-143.
7. Ajimsha MS. Effectiveness of direct vs indirect technique myofascial release in the management of tension-type headache. J Bodyw Mov Ther. 2011;15:431-435. doi: 10.1016/j.jbmt.2011.01.021
EVIDENCE-BASED ANSWER:
MAYBE. Among patients with chronic tension headaches, manual therapies may reduce headache frequency more than sham manual therapy, usual care, or exercise treatments—by 1.5 to 4.2 headaches or days with headache per week (strength of recommendation, B; preponderance of evidence from primarily small, heterogeneous randomized controlled trials [RCTs]).
Not acne, but what?
AN OTHERWISE HEALTHY
Scattered papules and pustules were present on the forehead, nose, and cheeks, with background erythema and telangiectasias (FIGURE 1). A few pinpoint crusted excoriations were noted. A sample was taken from the papules and pustules using a #15 blade and submitted for examination.
WHAT IS YOUR DIAGNOSIS?
HOW WOULD YOU TREAT THIS PATIENT?
Diagnosis: Rosacea with Demodex mites
Under light microscopy, the scraping revealed Demodex mites (FIGURE 2). It has been proposed that these mites play a role in the inflammatory process seen in rosacea, although studies have yet to determine whether the inflammatory symptoms of rosacea cause the mites to proliferate or if the mites contribute to the initial inflammatory process.1,2
Demodex folliculorum and D brevis are part of normal skin flora; they are found in about 12% of all follicles and most commonly involve the face.3 They often become abundant in the presence of numerous sebaceous glands. Men have more sebaceous glands than women do, and thus run a greater risk for infestation with mites. An abnormal proliferation of Demodex mites can lead to demodicosis.
Demodex mites can be examined microscopically via the skin surface sampling technique known as scraping, which was done in this case. Samples taken from the papules and pustules utilizing a #15 blade are placed in immersion oil on a glass slide, cover-slipped, and examined by light microscopy.
Rosacea is thought to be an inflammatory disease in which the immune system is triggered by a variety of factors, including UV light, heat, stress, alcohol, hormonal influences, and microorganisms.1,4 The disease is found in up to 10% of the population worldwide.1
The diagnosis of rosacea requires at least 1 of the 2 “core features”—persistent central facial erythema or phymatous changes—or 2 of 4 “major features”: papules/pustules, ocular manifestation, flushing, and telangiectasias. There are 3 phenotypes: ocular, papulopustular, and erythematotelangiectatic.5,6
Continue to: The connection
The connection. Papulopustular and erythematotelangiectatic rosacea may be caused by a proliferation of Demodex mites and increased vascular endothelial growth factor production.2 In fact, a proliferation of Demodex is seen in almost all cases of papulopustular rosacea and more than 60% of cases of erythematotelangiectatic rosacea.2
Patient age and distribution of lesions narrowed the differential
Acne vulgaris is an inflammatory disease of the pilosebaceous units caused by increased sebum production, inflammation, and bacterial colonization (Propionibacterium acnes) of hair follicles on the face, neck, chest, and other areas. Both inflammatory and noninflammatory lesions can be present, and in serious cases, scarring can result.7 The case patient’s age and accompanying broad erythema were more consistent with rosacea than acne vulgaris.
Seborrheic dermatitis is a common skin condition usually stemming from an inflammatory reaction to a common yeast. Classic symptoms include scaling and erythema of the scalp and central face, as well as pruritus. Topical antifungals such as ketoconazole 2% cream and 2% shampoo are the mainstay of treatment.8 The broad distribution and papulopustules in this patient argue against the diagnosis of seborrheic dermatitis.
Systemic lupus erythematosus is a systemic inflammatory disease that often has cutaneous manifestations. Acute lupus manifests as an erythematous “butterfly rash” across the face and cheeks. Chronic discoid lupus involves depigmented plaques, erythematous macules, telangiectasias, and scarring with loss of normal hair follicles. These findings classically are photodistributed.9 The classic broad erythema extending from the cheeks over the bridge of the nose was not present in this patient.
Treatment is primarily topical
Mild cases of rosacea often can be managed with topical antibiotic creams. More severe cases may require systemic antibiotics such as tetracycline or doxycycline, although these are used with caution due to the potential for antibiotic resistance.
Ivermectin 1% cream is a US Food and Drug Administration–approved medication that is applied once daily for up to a year to treat the inflammatory pustules associated with Demodex mites. Although it is costly, studies have shown better results with topical ivermectin than with other topical medications (eg, metronidazole 0.75% gel or cream). However, metronidazole 0.75% gel applied twice daily and oral tetracycline 250 mg or doxycycline 100 mg daily or twice daily for at least 2 months often are utilized when the cost of topical ivermectin is prohibitive.10
Our patient was treated with a combination of doxycycline 100 mg daily for 30 days and
1. Forton FMN. Rosacea, an infectious disease: why rosacea with papulopustules should be considered a demodicosis. A narrative review. J Eur Acad Dermatol Venereol. 2022;36:987-1002. doi: 10.1111/jdv.18049
2. Forton FMN. The pathogenic role of demodex mites in rosacea: a potential therapeutic target already in erythematotelangiectatic rosacea? Dermatol Ther (Heidelb). 2020;10:1229-1253. doi: 10.1007/s13555-020-00458-9
3. Elston DM. Demodex mites: facts and controversies. Clin Dermatol. 2010;28:502-504. doi: 10.1016/j.clindermatol.2010.03.006
4. Erbağci Z, OzgöztaŞi O. The significance of demodex folliculorum density in rosacea. Int J Dermatol. 1998;37:421-425. doi: 10.1046/j.1365-4362.1998.00218.x
5. Tan J, Almeida LMC, Criber B, et al. Updating the diagnosis, classification and assessment of rosacea: recommendations from the global ROSacea COnsensus (ROSCO) panel. Br J Dermatol. 2017;176:431-438. doi: 10.1111/bjd.15122
6. Gallo RL, Granstein RD, Kang S, et al. Standard classification and pathophysiology of rosacea: the 2017 update by the National Rosacea Society Expert Committee. J Am Acad Dermatol. 2018;78:148-155. doi: 10.1016/j.jaad.2017.08.037
7. Williams HC, Dellavalle RP, Garner S. Acne vulgaris. Lancet. 2012;379:361-372. doi: 10.1016/S0140-6736(11)60321-8.
8. Clark GW, Pope SM, Jaboori KA. Diagnosis and treatment of seborrheic dermatitis. Am Fam Physician. 2015;91:185-190.
9. Yell JA, Mbuagbaw J, Burge SM. Cutaneous manifestations of systemic lupus erythematosus. Br J Dermatol. 1996;135:355-362.
10. Raedler LA. Soolantra (ivermectin) 1% cream: a novel, antibiotic-free agent approved for the treatment of patients with rosacea. Am Health Drug Benefits. 2015;8(Spec Feature):122-125.
AN OTHERWISE HEALTHY
Scattered papules and pustules were present on the forehead, nose, and cheeks, with background erythema and telangiectasias (FIGURE 1). A few pinpoint crusted excoriations were noted. A sample was taken from the papules and pustules using a #15 blade and submitted for examination.
WHAT IS YOUR DIAGNOSIS?
HOW WOULD YOU TREAT THIS PATIENT?
Diagnosis: Rosacea with Demodex mites
Under light microscopy, the scraping revealed Demodex mites (FIGURE 2). It has been proposed that these mites play a role in the inflammatory process seen in rosacea, although studies have yet to determine whether the inflammatory symptoms of rosacea cause the mites to proliferate or if the mites contribute to the initial inflammatory process.1,2
Demodex folliculorum and D brevis are part of normal skin flora; they are found in about 12% of all follicles and most commonly involve the face.3 They often become abundant in the presence of numerous sebaceous glands. Men have more sebaceous glands than women do, and thus run a greater risk for infestation with mites. An abnormal proliferation of Demodex mites can lead to demodicosis.
Demodex mites can be examined microscopically via the skin surface sampling technique known as scraping, which was done in this case. Samples taken from the papules and pustules utilizing a #15 blade are placed in immersion oil on a glass slide, cover-slipped, and examined by light microscopy.
Rosacea is thought to be an inflammatory disease in which the immune system is triggered by a variety of factors, including UV light, heat, stress, alcohol, hormonal influences, and microorganisms.1,4 The disease is found in up to 10% of the population worldwide.1
The diagnosis of rosacea requires at least 1 of the 2 “core features”—persistent central facial erythema or phymatous changes—or 2 of 4 “major features”: papules/pustules, ocular manifestation, flushing, and telangiectasias. There are 3 phenotypes: ocular, papulopustular, and erythematotelangiectatic.5,6
Continue to: The connection
The connection. Papulopustular and erythematotelangiectatic rosacea may be caused by a proliferation of Demodex mites and increased vascular endothelial growth factor production.2 In fact, a proliferation of Demodex is seen in almost all cases of papulopustular rosacea and more than 60% of cases of erythematotelangiectatic rosacea.2
Patient age and distribution of lesions narrowed the differential
Acne vulgaris is an inflammatory disease of the pilosebaceous units caused by increased sebum production, inflammation, and bacterial colonization (Propionibacterium acnes) of hair follicles on the face, neck, chest, and other areas. Both inflammatory and noninflammatory lesions can be present, and in serious cases, scarring can result.7 The case patient’s age and accompanying broad erythema were more consistent with rosacea than acne vulgaris.
Seborrheic dermatitis is a common skin condition usually stemming from an inflammatory reaction to a common yeast. Classic symptoms include scaling and erythema of the scalp and central face, as well as pruritus. Topical antifungals such as ketoconazole 2% cream and 2% shampoo are the mainstay of treatment.8 The broad distribution and papulopustules in this patient argue against the diagnosis of seborrheic dermatitis.
Systemic lupus erythematosus is a systemic inflammatory disease that often has cutaneous manifestations. Acute lupus manifests as an erythematous “butterfly rash” across the face and cheeks. Chronic discoid lupus involves depigmented plaques, erythematous macules, telangiectasias, and scarring with loss of normal hair follicles. These findings classically are photodistributed.9 The classic broad erythema extending from the cheeks over the bridge of the nose was not present in this patient.
Treatment is primarily topical
Mild cases of rosacea often can be managed with topical antibiotic creams. More severe cases may require systemic antibiotics such as tetracycline or doxycycline, although these are used with caution due to the potential for antibiotic resistance.
Ivermectin 1% cream is a US Food and Drug Administration–approved medication that is applied once daily for up to a year to treat the inflammatory pustules associated with Demodex mites. Although it is costly, studies have shown better results with topical ivermectin than with other topical medications (eg, metronidazole 0.75% gel or cream). However, metronidazole 0.75% gel applied twice daily and oral tetracycline 250 mg or doxycycline 100 mg daily or twice daily for at least 2 months often are utilized when the cost of topical ivermectin is prohibitive.10
Our patient was treated with a combination of doxycycline 100 mg daily for 30 days and
AN OTHERWISE HEALTHY
Scattered papules and pustules were present on the forehead, nose, and cheeks, with background erythema and telangiectasias (FIGURE 1). A few pinpoint crusted excoriations were noted. A sample was taken from the papules and pustules using a #15 blade and submitted for examination.
WHAT IS YOUR DIAGNOSIS?
HOW WOULD YOU TREAT THIS PATIENT?
Diagnosis: Rosacea with Demodex mites
Under light microscopy, the scraping revealed Demodex mites (FIGURE 2). It has been proposed that these mites play a role in the inflammatory process seen in rosacea, although studies have yet to determine whether the inflammatory symptoms of rosacea cause the mites to proliferate or if the mites contribute to the initial inflammatory process.1,2
Demodex folliculorum and D brevis are part of normal skin flora; they are found in about 12% of all follicles and most commonly involve the face.3 They often become abundant in the presence of numerous sebaceous glands. Men have more sebaceous glands than women do, and thus run a greater risk for infestation with mites. An abnormal proliferation of Demodex mites can lead to demodicosis.
Demodex mites can be examined microscopically via the skin surface sampling technique known as scraping, which was done in this case. Samples taken from the papules and pustules utilizing a #15 blade are placed in immersion oil on a glass slide, cover-slipped, and examined by light microscopy.
Rosacea is thought to be an inflammatory disease in which the immune system is triggered by a variety of factors, including UV light, heat, stress, alcohol, hormonal influences, and microorganisms.1,4 The disease is found in up to 10% of the population worldwide.1
The diagnosis of rosacea requires at least 1 of the 2 “core features”—persistent central facial erythema or phymatous changes—or 2 of 4 “major features”: papules/pustules, ocular manifestation, flushing, and telangiectasias. There are 3 phenotypes: ocular, papulopustular, and erythematotelangiectatic.5,6
Continue to: The connection
The connection. Papulopustular and erythematotelangiectatic rosacea may be caused by a proliferation of Demodex mites and increased vascular endothelial growth factor production.2 In fact, a proliferation of Demodex is seen in almost all cases of papulopustular rosacea and more than 60% of cases of erythematotelangiectatic rosacea.2
Patient age and distribution of lesions narrowed the differential
Acne vulgaris is an inflammatory disease of the pilosebaceous units caused by increased sebum production, inflammation, and bacterial colonization (Propionibacterium acnes) of hair follicles on the face, neck, chest, and other areas. Both inflammatory and noninflammatory lesions can be present, and in serious cases, scarring can result.7 The case patient’s age and accompanying broad erythema were more consistent with rosacea than acne vulgaris.
Seborrheic dermatitis is a common skin condition usually stemming from an inflammatory reaction to a common yeast. Classic symptoms include scaling and erythema of the scalp and central face, as well as pruritus. Topical antifungals such as ketoconazole 2% cream and 2% shampoo are the mainstay of treatment.8 The broad distribution and papulopustules in this patient argue against the diagnosis of seborrheic dermatitis.
Systemic lupus erythematosus is a systemic inflammatory disease that often has cutaneous manifestations. Acute lupus manifests as an erythematous “butterfly rash” across the face and cheeks. Chronic discoid lupus involves depigmented plaques, erythematous macules, telangiectasias, and scarring with loss of normal hair follicles. These findings classically are photodistributed.9 The classic broad erythema extending from the cheeks over the bridge of the nose was not present in this patient.
Treatment is primarily topical
Mild cases of rosacea often can be managed with topical antibiotic creams. More severe cases may require systemic antibiotics such as tetracycline or doxycycline, although these are used with caution due to the potential for antibiotic resistance.
Ivermectin 1% cream is a US Food and Drug Administration–approved medication that is applied once daily for up to a year to treat the inflammatory pustules associated with Demodex mites. Although it is costly, studies have shown better results with topical ivermectin than with other topical medications (eg, metronidazole 0.75% gel or cream). However, metronidazole 0.75% gel applied twice daily and oral tetracycline 250 mg or doxycycline 100 mg daily or twice daily for at least 2 months often are utilized when the cost of topical ivermectin is prohibitive.10
Our patient was treated with a combination of doxycycline 100 mg daily for 30 days and
1. Forton FMN. Rosacea, an infectious disease: why rosacea with papulopustules should be considered a demodicosis. A narrative review. J Eur Acad Dermatol Venereol. 2022;36:987-1002. doi: 10.1111/jdv.18049
2. Forton FMN. The pathogenic role of demodex mites in rosacea: a potential therapeutic target already in erythematotelangiectatic rosacea? Dermatol Ther (Heidelb). 2020;10:1229-1253. doi: 10.1007/s13555-020-00458-9
3. Elston DM. Demodex mites: facts and controversies. Clin Dermatol. 2010;28:502-504. doi: 10.1016/j.clindermatol.2010.03.006
4. Erbağci Z, OzgöztaŞi O. The significance of demodex folliculorum density in rosacea. Int J Dermatol. 1998;37:421-425. doi: 10.1046/j.1365-4362.1998.00218.x
5. Tan J, Almeida LMC, Criber B, et al. Updating the diagnosis, classification and assessment of rosacea: recommendations from the global ROSacea COnsensus (ROSCO) panel. Br J Dermatol. 2017;176:431-438. doi: 10.1111/bjd.15122
6. Gallo RL, Granstein RD, Kang S, et al. Standard classification and pathophysiology of rosacea: the 2017 update by the National Rosacea Society Expert Committee. J Am Acad Dermatol. 2018;78:148-155. doi: 10.1016/j.jaad.2017.08.037
7. Williams HC, Dellavalle RP, Garner S. Acne vulgaris. Lancet. 2012;379:361-372. doi: 10.1016/S0140-6736(11)60321-8.
8. Clark GW, Pope SM, Jaboori KA. Diagnosis and treatment of seborrheic dermatitis. Am Fam Physician. 2015;91:185-190.
9. Yell JA, Mbuagbaw J, Burge SM. Cutaneous manifestations of systemic lupus erythematosus. Br J Dermatol. 1996;135:355-362.
10. Raedler LA. Soolantra (ivermectin) 1% cream: a novel, antibiotic-free agent approved for the treatment of patients with rosacea. Am Health Drug Benefits. 2015;8(Spec Feature):122-125.
1. Forton FMN. Rosacea, an infectious disease: why rosacea with papulopustules should be considered a demodicosis. A narrative review. J Eur Acad Dermatol Venereol. 2022;36:987-1002. doi: 10.1111/jdv.18049
2. Forton FMN. The pathogenic role of demodex mites in rosacea: a potential therapeutic target already in erythematotelangiectatic rosacea? Dermatol Ther (Heidelb). 2020;10:1229-1253. doi: 10.1007/s13555-020-00458-9
3. Elston DM. Demodex mites: facts and controversies. Clin Dermatol. 2010;28:502-504. doi: 10.1016/j.clindermatol.2010.03.006
4. Erbağci Z, OzgöztaŞi O. The significance of demodex folliculorum density in rosacea. Int J Dermatol. 1998;37:421-425. doi: 10.1046/j.1365-4362.1998.00218.x
5. Tan J, Almeida LMC, Criber B, et al. Updating the diagnosis, classification and assessment of rosacea: recommendations from the global ROSacea COnsensus (ROSCO) panel. Br J Dermatol. 2017;176:431-438. doi: 10.1111/bjd.15122
6. Gallo RL, Granstein RD, Kang S, et al. Standard classification and pathophysiology of rosacea: the 2017 update by the National Rosacea Society Expert Committee. J Am Acad Dermatol. 2018;78:148-155. doi: 10.1016/j.jaad.2017.08.037
7. Williams HC, Dellavalle RP, Garner S. Acne vulgaris. Lancet. 2012;379:361-372. doi: 10.1016/S0140-6736(11)60321-8.
8. Clark GW, Pope SM, Jaboori KA. Diagnosis and treatment of seborrheic dermatitis. Am Fam Physician. 2015;91:185-190.
9. Yell JA, Mbuagbaw J, Burge SM. Cutaneous manifestations of systemic lupus erythematosus. Br J Dermatol. 1996;135:355-362.
10. Raedler LA. Soolantra (ivermectin) 1% cream: a novel, antibiotic-free agent approved for the treatment of patients with rosacea. Am Health Drug Benefits. 2015;8(Spec Feature):122-125.
How best to diagnose and manage abdominal aortic aneurysms
Ruptured abdominal aortic aneurysms (AAAs) caused about 6000 deaths annually in the United States between 2014 and 20201 and are associated with a pooled mortality rate of 81%.2 They result from a distinct degenerative process of the layers of the aortic wall.2 An AAA is defined as an abdominal aorta whose dilation is > 50% normal (more commonly, a diameter > 3 cm).3,4 The risk for rupture correlates closely with size; most ruptures occur in aneurysms > 5.5 cm3,4 (TABLE 15).
Most AAAs are asymptomatic and often go undetected until rupture, resulting in poor outcomes. Because of a low and declining prevalence of AAA and ruptured AAA in developed countries, screening recommendations target high-risk groups rather than the general population.4,6-8 This review summarizes risk factors, prevalence, and current evidence-based screening and management recommendations for AAA.
Who’s at risk?
Age is the most significant nonmodifiable risk factor, with AAA rupture uncommon in patients younger than 55 years.9 One retrospective study found the odds ratio (OR) for diagnosing AAA was 9.41 in adults ages 65 to 69 years (95% CI, 8.76-10.12; P < .0001) and 14.46 (95% CI, 13.45-15.55; P < .0001) in adults ages 70 to 74 years, compared to adults younger than 55 years.10
Smoking is the most potent modifiable risk factor for AAA. Among patients with AAA, > 90% have a history of smoking.4 The association between smoking and AAA is dose dependent, with an OR of 2.61 (95% CI, 2.47-2.74) in patients with a pack-per-year history < 5 years and 12.13 (95% CI, 11.66-12.61) in patients with a pack-per-year history > 35 years, compared to nonsmokers.10 The risk for AAA increases with smoking duration but decreases with cessation duration.4,10 Smoking cessation remains an important intervention, as active smokers have higher AAA rupture rates.11
Other risk factors for AAA include concomitant cardiovascular disease (CVD) such as coronary artery disease (CAD), cerebrovascular disease, atherosclerosis, dyslipidemia, and hypertension.10 Factors associated with reduced risk for AAA include African American race, Hispanic ethnicity, Asian ethnicity, diabetes, smoking cessation, consuming fruits and vegetables > 3 times per week, and exercising more than once per week.6,10
Prevalence declines but sex-based disparities in outcomes persist
The prevalence of AAA has declined in the United States and Europe in recent decades, correlating with declining rates of smoking.4,12 Reports published between 2011 and 2019 estimate that AAA prevalence in men older than 60 years has declined over time, with a prevalence of 1.2% to 3.3%.6 The prevalence of AAA has also decreased in women,6,13,14 estimated in 1 study to be as low as 0.74%.13 Similarly, deaths from ruptured AAA have declined markedly in the United States—by 70% between 1999 and 2016 according to 1 analysis.9
One striking difference in the male-female data is that although AAAs are more common in men, there is a 2- to 4-fold higher risk for rupture in women, who account for nearly half of all AAA-related deaths.9,10,15-17 The reasons for this heightened risk to women despite lower prevalence are not fully understood but are likely multifactorial and related to a general lack of screening for AAA in women, tendency for AAA to rupture at smaller diameters in women, rupture at an older age in women, and a history of worse surgical outcomes in women than men (though the gap in surgical outcomes appears to be closing).9,10,18
Continue to: While declines in AAA and AAA-related...
While declines in AAA and AAA-related death are largely attributed to lower smoking rates, other likely contributing factors include the implementation of screening programs, incidental detection during cross-sectional imaging, and improved surgical techniques and management of CV risk factors (eg, hypertension, hyperlipidemia).9,10
The benefits of screening older men
Randomized controlled trials (RCTs) have demonstrated the benefits of AAA screening programs. A meta-analysis of 4 populationbased RCTs of AAA screening in men ≥ 65 years demonstrated statistically significant reductions in AAA rupture (OR = 0.62; 95% CI, 0.55-0.70) and death from AAA (OR = 0.65; 95% CI, 0.57-0.74) over 12 to 15 years, with a number needed to screen (NNS) of 305 (95% CI, 248-411) to prevent 1 AAA-related death.18 The study also found screening decreases the rate of emergent surgeries for AAA (OR = 0.57; 95% CI, 0.48-0.68) while increasing the number of elective surgeries (OR = 1.44; 95% CI, 1.34-1.55) over 4 to 15 years.18
Only 1 study has demonstrated an improvement in all-cause mortality with screening programs, with a relatively small benefit (OR = 0.97; 95% CI, 0.94-0.99).19 Only 1 of the studies included women and, while underpowered, showed no difference in AAA-related death or rupture.20 Guidelines and recommendations of various countries and professional societies focus screening on subgroups at highest risk for AAA.4,6-8,18
Screening recommendations from USPSTF and others
The US Preventive Services Task Force (USPSTF) currently recommends one-time ultrasound screening for AAA in men ages 65 to 75 years who have ever smoked (commonly defined as having smoked > 100 cigarettes) in their lifetime.6 This grade “B” recommendation, initially made in 2005 and reaffirmed in the 2014 and 2019 USPSTF updates, recommends screening the highest-risk segment of the population (ie, older male smokers).
In men ages 65 to 75 years with no smoking history, rather than routine screening, the USPSTF recommends selectively offering screening based on the patient’s medical history, family history, risk factors, and personal values (with a “C” grade).6 The USPSTF continues to recommend against screening for AAA in women with no smoking history and no family history of AAA.6 According to the USPSTF, the evidence is insufficient to recommend for or against screening women ages 65 to 75 years who have ever smoked or have a family history of AAA (“I” statement).6
Continue to: One critique of the USPSTF recommendations
One critique of the USPSTF recommendations is that they fail to detect a significant portion of patients with AAA and AAA rupture. For example, in a retrospective analysis of 55,197 patients undergoing AAA repair, only 33% would have been detected by the USPSTF grade “B” recommendation to screen male smokers ages 65 to 75 years, and an analysis of AAA-related fatalities found 43% would be missed by USPSTF criteria.9,21
Screening guidelines from the Society for Vascular Surgery (SVS) are broader than those of the USPSTF, in an attempt to capture a larger percentage of the population at risk for AAA-related disease by extrapolating from epidemiologic data. The SVS guidelines include screening for women ages 65 to 75 years with a smoking history, screening men and women ages 65 to 75 years who have a first-degree relative with AAA, and consideration of screening patients older than 75 years if they are in good health and have a first-degree relative with AAA or a smoking history and have not been previously screened.4 However, these expanded recommendations are not supported by patient-oriented evidence.6
Attempts to broaden screening guidelines must be tempered by potential risks for harm, primarily overdiagnosis (ie, diagnosing AAAs that would not otherwise rise to clinical significance) and overtreatment (ie, resulting in unnecessary imaging, appointments, anxiety, or surgery). Negative psychological effects on quality of life after a diagnosis of AAA have not been shown to cause significant harm.6,18
A recent UK analysis found that screening programs for AAA in women modeled after those in men are not cost effective, with an NNS to prevent 1 death of 3900 in women vs 700 in men.15,18 Another recent trial of ultrasound screening in 5200 high-risk women ages 65 to 74 years found an AAA incidence of 0.29% (95% CI, 0.18%-0.48%) in which only 3 large aneurysms were identified.22
In the United States, rates of screening for AAA remain low.23 One study has shown electronic medical record–based reminders increased screening rates from 48% to 80%.24 Point-of-care bedside ultrasound performed by clinicians also could improve screening rates. Multiple studies have demonstrated that screening and diagnosis of AAA can be performed safely and effectively at the bedside by nonradiologists such as family physicians and emergency physicians.25-28 In 1 study, such exams added < 4 minutes to the patient encounter.26 Follow-up surveillance schedules for those identified as having a AAA are summarized in TABLE 2.4
Continue to: Management options
Management options: Immediate repair or surveillance?
After diagnosing AAA, important decisions must be made regarding management, including indications for surgical repair, appropriate follow-up surveillance, and medications for secondary prevention and cardiovascular risk reduction.
EVAR vs open repair
The 2 main surgical strategies for aneurysm repair are open repair and endovascular repair (EVAR). In the United States, EVAR is becoming the more common approach and was used to repair asymptomatic aneurysms in > 80% of patients and ruptured aneurysms in 50% of patients.6 There have been multiple RCTs assessing EVAR and open repair for large and small aneurysms.29-34 Findings across these studies consistently show EVAR is associated with lower immediate (ie, 30-day) morbidity and mortality but no longer-term survival benefit compared to open repair.
EVAR procedures require ongoing long-term surveillance for endovascular leakage and other complications, resulting in an increased need for re-intervention.31,33,35 For these reasons, the National Institute for Health and Care Excellence (NICE) guidelines suggest open repair as the preferred modality.7 However, SVS and the American College of Cardiology Foundation/American Heart Association guidance support either EVAR or open repair, noting that open repair may be preferable in patients unable to engage in long-term follow-up surveillance.36
Indications for repair. In general, repair is indicated when an aneurysm reaches or exceeds 5.5 cm.4,7 Both SVS and NICE also recommend clinicians consider surgical repair of smaller, rapidly expanding aneurysms (> 1 cm over a 1-year period).4,7 Based on evidence suggesting a higher risk for rupture in women with smaller aneurysms,14,37 SVS recommends clinicians consider surgical repair in women with an AAA ≥ 5.0 cm. Several RCTs evaluating the benefits of immediate repair for smaller-sized aneurysms (4.0-5.5 cm) favored surveillance.38,39 Accepted indications for surgical repair are summarized in TABLE 3.4,7,34Surgical repair recommendations also are based on aneurysm morphology, which can be fusiform or saccular (FIGURE). More than 90% of AAAs are fusiform.40 Although saccular AAAs are less common, some studies suggest they are more prone to rupture than fusiform AAAs, and SVS guidelines suggest surgical repair of saccular aneurysms regardless of size.4,41,42
Perioperative and long-term risks. Both EVAR and open repair of AAA carry a high perioperative and long-term risk for death, as patients often have multiple comorbidities. A 2019 trial comparing EVAR to open repair with 14 years of follow-up reported death in 68% of patients in the EVAR group and 70% in the open repair group. 31 Among these deaths, 2.7% in the EVAR group and 3.7% in the open repair group were aneurysm related.31 The study also found a second surgical intervention was required in 19.8% of patients in the open repair group and 26.7% in the EVAR group.31
Continue to: When assessing perioperative risk...
When assessing perioperative risk, SVS guidelines recommend clinicians employ a shared decision-making approach with patients that incorporates Vascular Quality Initiative (VQI) mortality risk score.4 (VQI risk calculators are available at https://qxmd.com/vascular-study-group-new-england-decision-support-tools.43)
Medication management
Based on the close association of aortic aneurysm with atherosclerotic CVD (ASCVD), professional societies such as the European Society of Cardiology and European Atherosclerosis Society (ESC/EAS) have suggested aortic aneurysm is equivalent to ASCVD and should be managed medically in a similar manner to peripheral arterial disease.44 Indeed, many patients with AAA may have concomitant CAD or other arterial vascular diseases (eg, carotid, lower extremity).
Statins. In its guidelines, the ESC/EAS consider patients with AAA at “very high risk” for adverse CV events and suggest pharmacotherapy with high-intensity statins, adding ezetimibe or proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors if needed, to reduce low-density lipoprotein cholesterol ≥ 50% from baseline, with a goal of < 55 mg/dL.44 Statin therapy additionally lowers all-cause postoperative mortality in patients undergoing AAA repair but does not affect the rate of aneurysm expansion.45
Aspirin and other anticoagulants. Although aspirin therapy may be indicated for the secondary prevention of other cardiovascular events that may coexist with AAA, it does not appear to affect the rate of growth or prevent rupture of aneurysms.46,47 In addition to aspirin, anticoagulants such as clopidogrel, enoxaparin, and warfarin are not recommended when the presence of AAA is the only indication.4
Other medications. Angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, beta-blockers, and antibiotics (eg, doxycycline) have been studied as a treatment for AAA. However, none has shown benefit in reducing aneurysm growth or rupture and they are not recommended for that sole purpose.4,48
Metformin. There is a negative association between diabetes and AAA expansion and rupture. Several cohort studies have indicated that this may be an independent effect driven primarily by exposure to metformin. While it is not unreasonable to consider this another important indication for metformin use in patients with diabetes, RCT evidence has yet to establish a role for metformin in patients without diabetes who have AAA.48,49
ACKNOWLEDGEMENT
The authors thank Gwen Wilson, MLS, AHIP, for her assistance with the literature searches performed in the preparation of this manuscript.
CORRESPONDENCE
Nicholas LeFevre, MD, Family and Community Medicine, University of Missouri–Columbia School of Medicine, One Hospital Drive, M224 Medical Science Building, Columbia, MO 65212; nlefevre@health.missouri.edu
1. CDC. Wide-ranging Online Data for Epidemiologic Research (WONDER) database. Accessed August 30, 2023. https://wonder.cdc.gov/ucd-icd10.html
2. Reimerink JJ, van der Laan MJ, Koelemay MJ, et al. Systematic review and meta-analysis of population-based mortality from ruptured abdominal aortic aneurysm. Br J Surg. 2013;100:1405-1413. doi: 10.1002/bjs.9235
3. Kent KC. Clinical practice. Abdominal aortic aneurysms. N Engl J Med. 2014;371:2101-2108. doi: 10.1056/NEJMcp1401430
4. Chaikof EL, Dalman RL, Eskandari MK, et al. The Society for Vascular Surgery practice guidelines on the care of patients with an abdominal aortic aneurysm. J Vasc Surg. 2018;67:2-77.e2. doi: 10.1016/j.jvs.2017.10.044
5. Moll FL, Powell JT, Fraedrich G, et al. Management of abdominal aortic aneurysms clinical practice guidelines of the European society for vascular surgery. Eur J Vasc Endovasc Surg. 2011;41 suppl 1:S1-S58. doi: 10.1016/j.ejvs.2010.09.011
6. Owens DK, Davidson KW, Krist AH, et al; US Preventive Services Task Force. Screening for abdominal aortic aneurysm: US Preventive Services Task Force recommendation statement. JAMA. 2019;322:2211-2218. doi: 10.1001/jama.2019.18928
7. National Institute for Health and Care Excellence. Abdominal aortic aneurysm: diagnosis and management. NICE guideline [NG156]. March 19, 2020. Accessed June 30, 2023. www.nice.org.uk/guidance/ng156/chapter/recommendations
8. Canadian Task Force on Preventive Health Care. Recommendations on screening for abdominal aortic aneurysm in primary care. CMAJ. 2017;189:E1137-E1145. doi: 10.1503/cmaj.170118
9. Abdulameer H, Al Taii H, Al-Kindi SG, et al. Epidemiology of fatal ruptured aortic aneurysms in the United States (1999-2016). J Vasc Surg. 2019;69:378-384.e2. doi: 10.1016/j.jvs.2018.03.435
10. Kent KC, Zwolak RM, Egorova NN, et al. Analysis of risk factors for abdominal aortic aneurysm in a cohort of more than 3 million individuals. J Vasc Surg. 2010;52:539-548. doi: 10.1016/j.jvs.2010.05.090
11. [No authors listed] Smoking, lung function and the prognosis of abdominal aortic aneurysm. The UK Small Aneurysm Trial Participants. Eur J Vasc Endovasc Surg. 2000;19:636-642. doi: 10.1053/ejvs.2000.1066
12. Oliver-Williams C, Sweeting MJ, Turton G, et al. Lessons learned about prevalence and growth rates of abdominal aortic aneurysms from a 25-year ultrasound population screening programme. Br J Surg. 2018;105:68-74. doi: 10.1002/bjs.10715
13. Ulug P, Powell JT, Sweeting MJ, et al. Meta-analysis of the current prevalence of screen-detected abdominal aortic aneurysm in women. Br J Surg. 2016;103:1097-1104. doi: 10.1002/bjs.10225
14. Chabok M, Nicolaides A, Aslam M, et al. Risk factors associated with increased prevalence of abdominal aortic aneurysm in women. Br J Surg. 2016;103:1132-1138. doi: 10.1002/bjs.10179
15. Sweeting, MJ, Masconi KL, Jones E, et al. Analysis of clinical benefit, harms, and cost-effectiveness of screening women for abdominal aortic aneurysm. Lancet. 2018;392:487-495. doi: 10.1016/S0140-6736(18)31222-4
16. Sweeting MJ, Thompson SG, Brown LC, et al; RESCAN collaborators. Meta-analysis of individual patient data to examine factors affecting growth and rupture of small abdominal aortic aneurysms. Br J Surg. 2012;99:655-665. doi: 10.1002/bjs.8707
17. Skibba AA, Evans JR, Hopkins SP, et al. Reconsidering gender relative to risk of rupture in the contemporary management of abdominal aortic aneurysms. J Vasc Surg. 2015;62:1429-1436. doi: 10.1016/j.jvs.2015.07.079
18. Guirguis-Blake JM, Beil TL, Senger CA, et al. Primary care screening for abdominal aortic aneurysm: updated evidence report and systematic review for the US Preventive Services Task Force. JAMA. 2019;322:2219-2238. doi: 10.1001/jama.2019.17021
19. Thompson SG, Ashton HA, Gao L, et al; Multicentre Aneurysm Screening Study (MASS) Group. Final follow-up of the Multicentre Aneurysm Screening Study (MASS) randomized trial of abdominal aortic aneurysm screening. Br J Surg. 2012;99:1649-1656. doi: 10.1002/bjs.8897
20. Ashton HA, Gao L, Kim LG, et al. Fifteen-year follow-up of a randomized clinical trial of ultrasonographic screening for abdominal aortic aneurysms. Br J Surg. 2007;94:696-701. doi: 10.1002/bjs.5780
21. Carnevale ML, Koleilat I, Lipsitz EC, et al. Extended screening guidelines for the diagnosis of abdominal aortic aneurysm. J Vasc Surg. 2020;72:1917-1926. doi: 10.1016/j.jvs.2020.03.047
22. Duncan A, Maslen C, Gibson C, et al. Ultrasound screening for abdominal aortic aneurysm in high-risk women. Br J Surg. 2021;108:1192-1198. doi: 10.1093/bjs/znab220
23. Shreibati JB, Baker LC, Hlatky MA, et al. Impact of the Screening Abdominal Aortic Aneurysms Very Efficiently (SAAAVE) Act on abdominal ultrasonography use among Medicare beneficiaries. Arch Intern Med. 2012;172:1456-1462. doi: 10.1001/archinternmed.2012.4268
24. Hye RJ, Smith AE, Wong GH, et al. Leveraging the electronic medical record to implement an abdominal aortic aneurysm screening program. J Vasc Surg. 2014;59:1535-1542. doi: 10.1016/j.jvs.2013.12.016
25. Rubano E, Mehta N, Caputo W, et al., Systematic review: emergency department bedside ultrasonography for diagnosing suspected abdominal aortic aneurysm. Acad Emerg Med. 2013. 20:128-138. doi: 10.1111/acem.12080
26. Blois B. Office-based ultrasound screening for abdominal aortic aneurysm. Can Fam Physician. 2012;58:e172-e178.
27. Arnold MJ, Jonas CE, Carter RE. Point-of-care ultrasonography. Am Fam Physician. 2020;101:275-285.
28. Nixon G, Blattner K, Muirhead J, et al. Point-of-care ultrasound for FAST and AAA in rural New Zealand: quality and impact on patient care. Rural Remote Health. 2019;19:5027. doi: 10.22605/RRH5027
29. Lederle FA, Wilson SE, Johnson GR, et al. Immediate repair compared with surveillance of small abdominal aortic aneurysms. N Engl J Med. 2002;346:1437-1444. doi: 10.1056/NEJMoa012573
30. Filardo G, Lederle FA, Ballard DJ, et al. Immediate open repair vs surveillance in patients with small abdominal aortic aneurysms: survival differences by aneurysm size. Mayo Clin Proc. 2013;88:910-919. doi: 10.1016/j.mayocp.2013.05.014
31. Lederle FA, Kyriakides TC, Stroupe KT, et al. Open versus endovascular repair of abdominal aortic aneurysm. N Engl J Med. 2019;380:2126-2135. doi: 10.1056/NEJMoa1715955
32. Patel R, Sweeting MJ, Powell JT, et al., Endovascular versus open repair of abdominal aortic aneurysm in 15-years’ follow-up of the UK endovascular aneurysm repair trial 1 (EVAR trial 1): a randomised controlled trial. Lancet. 2016;388:2366-2374. doi: 10.1016/S0140-6736(16)31135-7
33. van Schaik TG, Yeung KK, Verhagen HJ, et al. Long-term survival and secondary procedures after open or endovascular repair of abdominal aortic aneurysms. J Vasc Surg. 2017;66:1379-1389. doi: 10.1016/j.jvs.2017.05.122
34. Powell JT, Brady AR, Brown, LC, et al; United Kingdom Small Aneurysm Trial Participants. Long-term outcomes of immediate repair compared with surveillance of small abdominal aortic aneurysms. N Engl J Med. 2002;346:1445-1452. doi: 10.1056/NEJMoa013527
35. Paravastu SC, Jayarajasingam R, Cottam R, et al. Endovascular repair of abdominal aortic aneurysm. Cochrane Database Syst Rev. 2014:CD004178. doi: 10.1002/14651858.CD004178.pub2
36. Rooke TW, Hirsch AT, Misra S, et al. 2011 ACCF/AHA focused update of the guideline for the management of patients with peripheral artery disease (updating the 2005 guideline): a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines. J Am Coll Cardiol. 2011;58:2020-2045. doi: 10.1016/j.jacc.2011.08.023
37. Bhak RH, Wininger M, Johnson GR, et al. Factors associated with small abdominal aortic aneurysm expansion rate. JAMA Surg. 2015;150:44-50. doi: 10.1001/jamasurg.2014.2025
38. Ouriel K, Clair DG, Kent KC, et al; Positive Impact of Endovascular Options for treating Aneurysms Early (PIVOTAL) Investigators. Endovascular repair compared with surveillance for patients with small abdominal aortic aneurysms. J Vasc Surg. 2010;51:1081-1087. doi: 10.1016/j.jvs.2009.10.113
39. Cao P, De Rango P, Verzini F, et al. Comparison of surveillance versus aortic endografting for small aneurysm repair (CAESAR): results from a randomised trial. Eur J Vasc Endovasc Surg. 2011;41:13-25. doi: 10.1016/j.ejvs.2010.08.026
40. Karthaus EG, Tong TML, Vahl A, et al; Dutch Society of Vascular Surgery, the Steering Committee of the Dutch Surgical Aneurysm Audit and the Dutch Institute for Clinical Auditing. Saccular abdominal aortic aneurysms: patient characteristics, clinical presentation, treatment, and outcomes in the Netherlands. Ann Surg. 2019;270:852-858. doi: 10.1097/SLA.0000000000003529
41. Nathan DP, Xu C, Pouch AM, et al. Increased wall stress of saccular versus fusiform aneurysms of the descending thoracic aorta. Ann Vasc Surg. 2011;25:1129-2237. doi: 10.1016/j.avsg.2011.07.008
42. Durojaye MS, Adeniyi TO, Alagbe OA. Multiple saccular aneurysms of the abdominal aorta: a case report and short review of risk factors for rupture on CT Scan. Ann Ib Postgrad Med. 2020;18:178-180.
43. Bertges DJ, Neal D, Schanzer A, et al. The Vascular Quality Initiative Cardiac Risk Index for prediction of myocardial infarction after vascular surgery. J Vasc Surg. 2016;64:1411-1421.e4. doi: 10.1016/j.jvs.2016.04.045
44. Mach F, Baigent C, Catapano AL, et al. 2019 ESC/EAS guidelines for the management of dyslipidaemias: lipid modification to reduce cardiovascular risk. Eur Heart J. 2020;41:111-188. doi: 10.1093/eurheartj/ehz455
45. Twine CP, Williams IM. Systematic review and meta-analysis of the effects of statin therapy on abdominal aortic aneurysms. Br J Surg. 2011;98:346-353. doi: 10.1002/bjs.7343
46. Arnett DK, Blumenthal RS, Albert MA, et al. 2019 ACC/AHA guideline on the primary prevention of cardiovascular disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Circulation. 2019;140:e596-e646. doi: 10.1161/CIR.0000000000000678
47. Erbel R, Aboyans V, Boileau C, et al. 2014 ESC guidelines on the diagnosis and treatment of aortic diseases: document covering acute and chronic aortic diseases of the thoracic and abdominal aorta of the adult. The Task Force for the Diagnosis and Treatment of Aortic Diseases of the European Society of Cardiology (ESC). Eur Heart J. 2014;35:2873-2926. doi: 10.1093/eurheartj/ehu281
48. Lederle FA, Noorbaloochi S, Nugent S, et al. Multicentre study of abdominal aortic aneurysm measurement and enlargement. Br J Surg. 2015;102:1480-1487. doi: 10.1002/bjs.9895
49. Itoga NK, Rothenberg KA, Suarez P, et al. Metformin prescription status and abdominal aortic aneurysm disease progression in the U.S. veteran population. J Vasc Surg. 2019;69:710-716.e3. doi: 10.1016/j.jvs.2018.06.19
Ruptured abdominal aortic aneurysms (AAAs) caused about 6000 deaths annually in the United States between 2014 and 20201 and are associated with a pooled mortality rate of 81%.2 They result from a distinct degenerative process of the layers of the aortic wall.2 An AAA is defined as an abdominal aorta whose dilation is > 50% normal (more commonly, a diameter > 3 cm).3,4 The risk for rupture correlates closely with size; most ruptures occur in aneurysms > 5.5 cm3,4 (TABLE 15).
Most AAAs are asymptomatic and often go undetected until rupture, resulting in poor outcomes. Because of a low and declining prevalence of AAA and ruptured AAA in developed countries, screening recommendations target high-risk groups rather than the general population.4,6-8 This review summarizes risk factors, prevalence, and current evidence-based screening and management recommendations for AAA.
Who’s at risk?
Age is the most significant nonmodifiable risk factor, with AAA rupture uncommon in patients younger than 55 years.9 One retrospective study found the odds ratio (OR) for diagnosing AAA was 9.41 in adults ages 65 to 69 years (95% CI, 8.76-10.12; P < .0001) and 14.46 (95% CI, 13.45-15.55; P < .0001) in adults ages 70 to 74 years, compared to adults younger than 55 years.10
Smoking is the most potent modifiable risk factor for AAA. Among patients with AAA, > 90% have a history of smoking.4 The association between smoking and AAA is dose dependent, with an OR of 2.61 (95% CI, 2.47-2.74) in patients with a pack-per-year history < 5 years and 12.13 (95% CI, 11.66-12.61) in patients with a pack-per-year history > 35 years, compared to nonsmokers.10 The risk for AAA increases with smoking duration but decreases with cessation duration.4,10 Smoking cessation remains an important intervention, as active smokers have higher AAA rupture rates.11
Other risk factors for AAA include concomitant cardiovascular disease (CVD) such as coronary artery disease (CAD), cerebrovascular disease, atherosclerosis, dyslipidemia, and hypertension.10 Factors associated with reduced risk for AAA include African American race, Hispanic ethnicity, Asian ethnicity, diabetes, smoking cessation, consuming fruits and vegetables > 3 times per week, and exercising more than once per week.6,10
Prevalence declines but sex-based disparities in outcomes persist
The prevalence of AAA has declined in the United States and Europe in recent decades, correlating with declining rates of smoking.4,12 Reports published between 2011 and 2019 estimate that AAA prevalence in men older than 60 years has declined over time, with a prevalence of 1.2% to 3.3%.6 The prevalence of AAA has also decreased in women,6,13,14 estimated in 1 study to be as low as 0.74%.13 Similarly, deaths from ruptured AAA have declined markedly in the United States—by 70% between 1999 and 2016 according to 1 analysis.9
One striking difference in the male-female data is that although AAAs are more common in men, there is a 2- to 4-fold higher risk for rupture in women, who account for nearly half of all AAA-related deaths.9,10,15-17 The reasons for this heightened risk to women despite lower prevalence are not fully understood but are likely multifactorial and related to a general lack of screening for AAA in women, tendency for AAA to rupture at smaller diameters in women, rupture at an older age in women, and a history of worse surgical outcomes in women than men (though the gap in surgical outcomes appears to be closing).9,10,18
Continue to: While declines in AAA and AAA-related...
While declines in AAA and AAA-related death are largely attributed to lower smoking rates, other likely contributing factors include the implementation of screening programs, incidental detection during cross-sectional imaging, and improved surgical techniques and management of CV risk factors (eg, hypertension, hyperlipidemia).9,10
The benefits of screening older men
Randomized controlled trials (RCTs) have demonstrated the benefits of AAA screening programs. A meta-analysis of 4 populationbased RCTs of AAA screening in men ≥ 65 years demonstrated statistically significant reductions in AAA rupture (OR = 0.62; 95% CI, 0.55-0.70) and death from AAA (OR = 0.65; 95% CI, 0.57-0.74) over 12 to 15 years, with a number needed to screen (NNS) of 305 (95% CI, 248-411) to prevent 1 AAA-related death.18 The study also found screening decreases the rate of emergent surgeries for AAA (OR = 0.57; 95% CI, 0.48-0.68) while increasing the number of elective surgeries (OR = 1.44; 95% CI, 1.34-1.55) over 4 to 15 years.18
Only 1 study has demonstrated an improvement in all-cause mortality with screening programs, with a relatively small benefit (OR = 0.97; 95% CI, 0.94-0.99).19 Only 1 of the studies included women and, while underpowered, showed no difference in AAA-related death or rupture.20 Guidelines and recommendations of various countries and professional societies focus screening on subgroups at highest risk for AAA.4,6-8,18
Screening recommendations from USPSTF and others
The US Preventive Services Task Force (USPSTF) currently recommends one-time ultrasound screening for AAA in men ages 65 to 75 years who have ever smoked (commonly defined as having smoked > 100 cigarettes) in their lifetime.6 This grade “B” recommendation, initially made in 2005 and reaffirmed in the 2014 and 2019 USPSTF updates, recommends screening the highest-risk segment of the population (ie, older male smokers).
In men ages 65 to 75 years with no smoking history, rather than routine screening, the USPSTF recommends selectively offering screening based on the patient’s medical history, family history, risk factors, and personal values (with a “C” grade).6 The USPSTF continues to recommend against screening for AAA in women with no smoking history and no family history of AAA.6 According to the USPSTF, the evidence is insufficient to recommend for or against screening women ages 65 to 75 years who have ever smoked or have a family history of AAA (“I” statement).6
Continue to: One critique of the USPSTF recommendations
One critique of the USPSTF recommendations is that they fail to detect a significant portion of patients with AAA and AAA rupture. For example, in a retrospective analysis of 55,197 patients undergoing AAA repair, only 33% would have been detected by the USPSTF grade “B” recommendation to screen male smokers ages 65 to 75 years, and an analysis of AAA-related fatalities found 43% would be missed by USPSTF criteria.9,21
Screening guidelines from the Society for Vascular Surgery (SVS) are broader than those of the USPSTF, in an attempt to capture a larger percentage of the population at risk for AAA-related disease by extrapolating from epidemiologic data. The SVS guidelines include screening for women ages 65 to 75 years with a smoking history, screening men and women ages 65 to 75 years who have a first-degree relative with AAA, and consideration of screening patients older than 75 years if they are in good health and have a first-degree relative with AAA or a smoking history and have not been previously screened.4 However, these expanded recommendations are not supported by patient-oriented evidence.6
Attempts to broaden screening guidelines must be tempered by potential risks for harm, primarily overdiagnosis (ie, diagnosing AAAs that would not otherwise rise to clinical significance) and overtreatment (ie, resulting in unnecessary imaging, appointments, anxiety, or surgery). Negative psychological effects on quality of life after a diagnosis of AAA have not been shown to cause significant harm.6,18
A recent UK analysis found that screening programs for AAA in women modeled after those in men are not cost effective, with an NNS to prevent 1 death of 3900 in women vs 700 in men.15,18 Another recent trial of ultrasound screening in 5200 high-risk women ages 65 to 74 years found an AAA incidence of 0.29% (95% CI, 0.18%-0.48%) in which only 3 large aneurysms were identified.22
In the United States, rates of screening for AAA remain low.23 One study has shown electronic medical record–based reminders increased screening rates from 48% to 80%.24 Point-of-care bedside ultrasound performed by clinicians also could improve screening rates. Multiple studies have demonstrated that screening and diagnosis of AAA can be performed safely and effectively at the bedside by nonradiologists such as family physicians and emergency physicians.25-28 In 1 study, such exams added < 4 minutes to the patient encounter.26 Follow-up surveillance schedules for those identified as having a AAA are summarized in TABLE 2.4
Continue to: Management options
Management options: Immediate repair or surveillance?
After diagnosing AAA, important decisions must be made regarding management, including indications for surgical repair, appropriate follow-up surveillance, and medications for secondary prevention and cardiovascular risk reduction.
EVAR vs open repair
The 2 main surgical strategies for aneurysm repair are open repair and endovascular repair (EVAR). In the United States, EVAR is becoming the more common approach and was used to repair asymptomatic aneurysms in > 80% of patients and ruptured aneurysms in 50% of patients.6 There have been multiple RCTs assessing EVAR and open repair for large and small aneurysms.29-34 Findings across these studies consistently show EVAR is associated with lower immediate (ie, 30-day) morbidity and mortality but no longer-term survival benefit compared to open repair.
EVAR procedures require ongoing long-term surveillance for endovascular leakage and other complications, resulting in an increased need for re-intervention.31,33,35 For these reasons, the National Institute for Health and Care Excellence (NICE) guidelines suggest open repair as the preferred modality.7 However, SVS and the American College of Cardiology Foundation/American Heart Association guidance support either EVAR or open repair, noting that open repair may be preferable in patients unable to engage in long-term follow-up surveillance.36
Indications for repair. In general, repair is indicated when an aneurysm reaches or exceeds 5.5 cm.4,7 Both SVS and NICE also recommend clinicians consider surgical repair of smaller, rapidly expanding aneurysms (> 1 cm over a 1-year period).4,7 Based on evidence suggesting a higher risk for rupture in women with smaller aneurysms,14,37 SVS recommends clinicians consider surgical repair in women with an AAA ≥ 5.0 cm. Several RCTs evaluating the benefits of immediate repair for smaller-sized aneurysms (4.0-5.5 cm) favored surveillance.38,39 Accepted indications for surgical repair are summarized in TABLE 3.4,7,34Surgical repair recommendations also are based on aneurysm morphology, which can be fusiform or saccular (FIGURE). More than 90% of AAAs are fusiform.40 Although saccular AAAs are less common, some studies suggest they are more prone to rupture than fusiform AAAs, and SVS guidelines suggest surgical repair of saccular aneurysms regardless of size.4,41,42
Perioperative and long-term risks. Both EVAR and open repair of AAA carry a high perioperative and long-term risk for death, as patients often have multiple comorbidities. A 2019 trial comparing EVAR to open repair with 14 years of follow-up reported death in 68% of patients in the EVAR group and 70% in the open repair group. 31 Among these deaths, 2.7% in the EVAR group and 3.7% in the open repair group were aneurysm related.31 The study also found a second surgical intervention was required in 19.8% of patients in the open repair group and 26.7% in the EVAR group.31
Continue to: When assessing perioperative risk...
When assessing perioperative risk, SVS guidelines recommend clinicians employ a shared decision-making approach with patients that incorporates Vascular Quality Initiative (VQI) mortality risk score.4 (VQI risk calculators are available at https://qxmd.com/vascular-study-group-new-england-decision-support-tools.43)
Medication management
Based on the close association of aortic aneurysm with atherosclerotic CVD (ASCVD), professional societies such as the European Society of Cardiology and European Atherosclerosis Society (ESC/EAS) have suggested aortic aneurysm is equivalent to ASCVD and should be managed medically in a similar manner to peripheral arterial disease.44 Indeed, many patients with AAA may have concomitant CAD or other arterial vascular diseases (eg, carotid, lower extremity).
Statins. In its guidelines, the ESC/EAS consider patients with AAA at “very high risk” for adverse CV events and suggest pharmacotherapy with high-intensity statins, adding ezetimibe or proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors if needed, to reduce low-density lipoprotein cholesterol ≥ 50% from baseline, with a goal of < 55 mg/dL.44 Statin therapy additionally lowers all-cause postoperative mortality in patients undergoing AAA repair but does not affect the rate of aneurysm expansion.45
Aspirin and other anticoagulants. Although aspirin therapy may be indicated for the secondary prevention of other cardiovascular events that may coexist with AAA, it does not appear to affect the rate of growth or prevent rupture of aneurysms.46,47 In addition to aspirin, anticoagulants such as clopidogrel, enoxaparin, and warfarin are not recommended when the presence of AAA is the only indication.4
Other medications. Angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, beta-blockers, and antibiotics (eg, doxycycline) have been studied as a treatment for AAA. However, none has shown benefit in reducing aneurysm growth or rupture and they are not recommended for that sole purpose.4,48
Metformin. There is a negative association between diabetes and AAA expansion and rupture. Several cohort studies have indicated that this may be an independent effect driven primarily by exposure to metformin. While it is not unreasonable to consider this another important indication for metformin use in patients with diabetes, RCT evidence has yet to establish a role for metformin in patients without diabetes who have AAA.48,49
ACKNOWLEDGEMENT
The authors thank Gwen Wilson, MLS, AHIP, for her assistance with the literature searches performed in the preparation of this manuscript.
CORRESPONDENCE
Nicholas LeFevre, MD, Family and Community Medicine, University of Missouri–Columbia School of Medicine, One Hospital Drive, M224 Medical Science Building, Columbia, MO 65212; nlefevre@health.missouri.edu
Ruptured abdominal aortic aneurysms (AAAs) caused about 6000 deaths annually in the United States between 2014 and 20201 and are associated with a pooled mortality rate of 81%.2 They result from a distinct degenerative process of the layers of the aortic wall.2 An AAA is defined as an abdominal aorta whose dilation is > 50% normal (more commonly, a diameter > 3 cm).3,4 The risk for rupture correlates closely with size; most ruptures occur in aneurysms > 5.5 cm3,4 (TABLE 15).
Most AAAs are asymptomatic and often go undetected until rupture, resulting in poor outcomes. Because of a low and declining prevalence of AAA and ruptured AAA in developed countries, screening recommendations target high-risk groups rather than the general population.4,6-8 This review summarizes risk factors, prevalence, and current evidence-based screening and management recommendations for AAA.
Who’s at risk?
Age is the most significant nonmodifiable risk factor, with AAA rupture uncommon in patients younger than 55 years.9 One retrospective study found the odds ratio (OR) for diagnosing AAA was 9.41 in adults ages 65 to 69 years (95% CI, 8.76-10.12; P < .0001) and 14.46 (95% CI, 13.45-15.55; P < .0001) in adults ages 70 to 74 years, compared to adults younger than 55 years.10
Smoking is the most potent modifiable risk factor for AAA. Among patients with AAA, > 90% have a history of smoking.4 The association between smoking and AAA is dose dependent, with an OR of 2.61 (95% CI, 2.47-2.74) in patients with a pack-per-year history < 5 years and 12.13 (95% CI, 11.66-12.61) in patients with a pack-per-year history > 35 years, compared to nonsmokers.10 The risk for AAA increases with smoking duration but decreases with cessation duration.4,10 Smoking cessation remains an important intervention, as active smokers have higher AAA rupture rates.11
Other risk factors for AAA include concomitant cardiovascular disease (CVD) such as coronary artery disease (CAD), cerebrovascular disease, atherosclerosis, dyslipidemia, and hypertension.10 Factors associated with reduced risk for AAA include African American race, Hispanic ethnicity, Asian ethnicity, diabetes, smoking cessation, consuming fruits and vegetables > 3 times per week, and exercising more than once per week.6,10
Prevalence declines but sex-based disparities in outcomes persist
The prevalence of AAA has declined in the United States and Europe in recent decades, correlating with declining rates of smoking.4,12 Reports published between 2011 and 2019 estimate that AAA prevalence in men older than 60 years has declined over time, with a prevalence of 1.2% to 3.3%.6 The prevalence of AAA has also decreased in women,6,13,14 estimated in 1 study to be as low as 0.74%.13 Similarly, deaths from ruptured AAA have declined markedly in the United States—by 70% between 1999 and 2016 according to 1 analysis.9
One striking difference in the male-female data is that although AAAs are more common in men, there is a 2- to 4-fold higher risk for rupture in women, who account for nearly half of all AAA-related deaths.9,10,15-17 The reasons for this heightened risk to women despite lower prevalence are not fully understood but are likely multifactorial and related to a general lack of screening for AAA in women, tendency for AAA to rupture at smaller diameters in women, rupture at an older age in women, and a history of worse surgical outcomes in women than men (though the gap in surgical outcomes appears to be closing).9,10,18
Continue to: While declines in AAA and AAA-related...
While declines in AAA and AAA-related death are largely attributed to lower smoking rates, other likely contributing factors include the implementation of screening programs, incidental detection during cross-sectional imaging, and improved surgical techniques and management of CV risk factors (eg, hypertension, hyperlipidemia).9,10
The benefits of screening older men
Randomized controlled trials (RCTs) have demonstrated the benefits of AAA screening programs. A meta-analysis of 4 populationbased RCTs of AAA screening in men ≥ 65 years demonstrated statistically significant reductions in AAA rupture (OR = 0.62; 95% CI, 0.55-0.70) and death from AAA (OR = 0.65; 95% CI, 0.57-0.74) over 12 to 15 years, with a number needed to screen (NNS) of 305 (95% CI, 248-411) to prevent 1 AAA-related death.18 The study also found screening decreases the rate of emergent surgeries for AAA (OR = 0.57; 95% CI, 0.48-0.68) while increasing the number of elective surgeries (OR = 1.44; 95% CI, 1.34-1.55) over 4 to 15 years.18
Only 1 study has demonstrated an improvement in all-cause mortality with screening programs, with a relatively small benefit (OR = 0.97; 95% CI, 0.94-0.99).19 Only 1 of the studies included women and, while underpowered, showed no difference in AAA-related death or rupture.20 Guidelines and recommendations of various countries and professional societies focus screening on subgroups at highest risk for AAA.4,6-8,18
Screening recommendations from USPSTF and others
The US Preventive Services Task Force (USPSTF) currently recommends one-time ultrasound screening for AAA in men ages 65 to 75 years who have ever smoked (commonly defined as having smoked > 100 cigarettes) in their lifetime.6 This grade “B” recommendation, initially made in 2005 and reaffirmed in the 2014 and 2019 USPSTF updates, recommends screening the highest-risk segment of the population (ie, older male smokers).
In men ages 65 to 75 years with no smoking history, rather than routine screening, the USPSTF recommends selectively offering screening based on the patient’s medical history, family history, risk factors, and personal values (with a “C” grade).6 The USPSTF continues to recommend against screening for AAA in women with no smoking history and no family history of AAA.6 According to the USPSTF, the evidence is insufficient to recommend for or against screening women ages 65 to 75 years who have ever smoked or have a family history of AAA (“I” statement).6
Continue to: One critique of the USPSTF recommendations
One critique of the USPSTF recommendations is that they fail to detect a significant portion of patients with AAA and AAA rupture. For example, in a retrospective analysis of 55,197 patients undergoing AAA repair, only 33% would have been detected by the USPSTF grade “B” recommendation to screen male smokers ages 65 to 75 years, and an analysis of AAA-related fatalities found 43% would be missed by USPSTF criteria.9,21
Screening guidelines from the Society for Vascular Surgery (SVS) are broader than those of the USPSTF, in an attempt to capture a larger percentage of the population at risk for AAA-related disease by extrapolating from epidemiologic data. The SVS guidelines include screening for women ages 65 to 75 years with a smoking history, screening men and women ages 65 to 75 years who have a first-degree relative with AAA, and consideration of screening patients older than 75 years if they are in good health and have a first-degree relative with AAA or a smoking history and have not been previously screened.4 However, these expanded recommendations are not supported by patient-oriented evidence.6
Attempts to broaden screening guidelines must be tempered by potential risks for harm, primarily overdiagnosis (ie, diagnosing AAAs that would not otherwise rise to clinical significance) and overtreatment (ie, resulting in unnecessary imaging, appointments, anxiety, or surgery). Negative psychological effects on quality of life after a diagnosis of AAA have not been shown to cause significant harm.6,18
A recent UK analysis found that screening programs for AAA in women modeled after those in men are not cost effective, with an NNS to prevent 1 death of 3900 in women vs 700 in men.15,18 Another recent trial of ultrasound screening in 5200 high-risk women ages 65 to 74 years found an AAA incidence of 0.29% (95% CI, 0.18%-0.48%) in which only 3 large aneurysms were identified.22
In the United States, rates of screening for AAA remain low.23 One study has shown electronic medical record–based reminders increased screening rates from 48% to 80%.24 Point-of-care bedside ultrasound performed by clinicians also could improve screening rates. Multiple studies have demonstrated that screening and diagnosis of AAA can be performed safely and effectively at the bedside by nonradiologists such as family physicians and emergency physicians.25-28 In 1 study, such exams added < 4 minutes to the patient encounter.26 Follow-up surveillance schedules for those identified as having a AAA are summarized in TABLE 2.4
Continue to: Management options
Management options: Immediate repair or surveillance?
After diagnosing AAA, important decisions must be made regarding management, including indications for surgical repair, appropriate follow-up surveillance, and medications for secondary prevention and cardiovascular risk reduction.
EVAR vs open repair
The 2 main surgical strategies for aneurysm repair are open repair and endovascular repair (EVAR). In the United States, EVAR is becoming the more common approach and was used to repair asymptomatic aneurysms in > 80% of patients and ruptured aneurysms in 50% of patients.6 There have been multiple RCTs assessing EVAR and open repair for large and small aneurysms.29-34 Findings across these studies consistently show EVAR is associated with lower immediate (ie, 30-day) morbidity and mortality but no longer-term survival benefit compared to open repair.
EVAR procedures require ongoing long-term surveillance for endovascular leakage and other complications, resulting in an increased need for re-intervention.31,33,35 For these reasons, the National Institute for Health and Care Excellence (NICE) guidelines suggest open repair as the preferred modality.7 However, SVS and the American College of Cardiology Foundation/American Heart Association guidance support either EVAR or open repair, noting that open repair may be preferable in patients unable to engage in long-term follow-up surveillance.36
Indications for repair. In general, repair is indicated when an aneurysm reaches or exceeds 5.5 cm.4,7 Both SVS and NICE also recommend clinicians consider surgical repair of smaller, rapidly expanding aneurysms (> 1 cm over a 1-year period).4,7 Based on evidence suggesting a higher risk for rupture in women with smaller aneurysms,14,37 SVS recommends clinicians consider surgical repair in women with an AAA ≥ 5.0 cm. Several RCTs evaluating the benefits of immediate repair for smaller-sized aneurysms (4.0-5.5 cm) favored surveillance.38,39 Accepted indications for surgical repair are summarized in TABLE 3.4,7,34Surgical repair recommendations also are based on aneurysm morphology, which can be fusiform or saccular (FIGURE). More than 90% of AAAs are fusiform.40 Although saccular AAAs are less common, some studies suggest they are more prone to rupture than fusiform AAAs, and SVS guidelines suggest surgical repair of saccular aneurysms regardless of size.4,41,42
Perioperative and long-term risks. Both EVAR and open repair of AAA carry a high perioperative and long-term risk for death, as patients often have multiple comorbidities. A 2019 trial comparing EVAR to open repair with 14 years of follow-up reported death in 68% of patients in the EVAR group and 70% in the open repair group. 31 Among these deaths, 2.7% in the EVAR group and 3.7% in the open repair group were aneurysm related.31 The study also found a second surgical intervention was required in 19.8% of patients in the open repair group and 26.7% in the EVAR group.31
Continue to: When assessing perioperative risk...
When assessing perioperative risk, SVS guidelines recommend clinicians employ a shared decision-making approach with patients that incorporates Vascular Quality Initiative (VQI) mortality risk score.4 (VQI risk calculators are available at https://qxmd.com/vascular-study-group-new-england-decision-support-tools.43)
Medication management
Based on the close association of aortic aneurysm with atherosclerotic CVD (ASCVD), professional societies such as the European Society of Cardiology and European Atherosclerosis Society (ESC/EAS) have suggested aortic aneurysm is equivalent to ASCVD and should be managed medically in a similar manner to peripheral arterial disease.44 Indeed, many patients with AAA may have concomitant CAD or other arterial vascular diseases (eg, carotid, lower extremity).
Statins. In its guidelines, the ESC/EAS consider patients with AAA at “very high risk” for adverse CV events and suggest pharmacotherapy with high-intensity statins, adding ezetimibe or proprotein convertase subtilisin/kexin type 9 (PCSK9) inhibitors if needed, to reduce low-density lipoprotein cholesterol ≥ 50% from baseline, with a goal of < 55 mg/dL.44 Statin therapy additionally lowers all-cause postoperative mortality in patients undergoing AAA repair but does not affect the rate of aneurysm expansion.45
Aspirin and other anticoagulants. Although aspirin therapy may be indicated for the secondary prevention of other cardiovascular events that may coexist with AAA, it does not appear to affect the rate of growth or prevent rupture of aneurysms.46,47 In addition to aspirin, anticoagulants such as clopidogrel, enoxaparin, and warfarin are not recommended when the presence of AAA is the only indication.4
Other medications. Angiotensin-converting enzyme inhibitors, angiotensin receptor blockers, beta-blockers, and antibiotics (eg, doxycycline) have been studied as a treatment for AAA. However, none has shown benefit in reducing aneurysm growth or rupture and they are not recommended for that sole purpose.4,48
Metformin. There is a negative association between diabetes and AAA expansion and rupture. Several cohort studies have indicated that this may be an independent effect driven primarily by exposure to metformin. While it is not unreasonable to consider this another important indication for metformin use in patients with diabetes, RCT evidence has yet to establish a role for metformin in patients without diabetes who have AAA.48,49
ACKNOWLEDGEMENT
The authors thank Gwen Wilson, MLS, AHIP, for her assistance with the literature searches performed in the preparation of this manuscript.
CORRESPONDENCE
Nicholas LeFevre, MD, Family and Community Medicine, University of Missouri–Columbia School of Medicine, One Hospital Drive, M224 Medical Science Building, Columbia, MO 65212; nlefevre@health.missouri.edu
1. CDC. Wide-ranging Online Data for Epidemiologic Research (WONDER) database. Accessed August 30, 2023. https://wonder.cdc.gov/ucd-icd10.html
2. Reimerink JJ, van der Laan MJ, Koelemay MJ, et al. Systematic review and meta-analysis of population-based mortality from ruptured abdominal aortic aneurysm. Br J Surg. 2013;100:1405-1413. doi: 10.1002/bjs.9235
3. Kent KC. Clinical practice. Abdominal aortic aneurysms. N Engl J Med. 2014;371:2101-2108. doi: 10.1056/NEJMcp1401430
4. Chaikof EL, Dalman RL, Eskandari MK, et al. The Society for Vascular Surgery practice guidelines on the care of patients with an abdominal aortic aneurysm. J Vasc Surg. 2018;67:2-77.e2. doi: 10.1016/j.jvs.2017.10.044
5. Moll FL, Powell JT, Fraedrich G, et al. Management of abdominal aortic aneurysms clinical practice guidelines of the European society for vascular surgery. Eur J Vasc Endovasc Surg. 2011;41 suppl 1:S1-S58. doi: 10.1016/j.ejvs.2010.09.011
6. Owens DK, Davidson KW, Krist AH, et al; US Preventive Services Task Force. Screening for abdominal aortic aneurysm: US Preventive Services Task Force recommendation statement. JAMA. 2019;322:2211-2218. doi: 10.1001/jama.2019.18928
7. National Institute for Health and Care Excellence. Abdominal aortic aneurysm: diagnosis and management. NICE guideline [NG156]. March 19, 2020. Accessed June 30, 2023. www.nice.org.uk/guidance/ng156/chapter/recommendations
8. Canadian Task Force on Preventive Health Care. Recommendations on screening for abdominal aortic aneurysm in primary care. CMAJ. 2017;189:E1137-E1145. doi: 10.1503/cmaj.170118
9. Abdulameer H, Al Taii H, Al-Kindi SG, et al. Epidemiology of fatal ruptured aortic aneurysms in the United States (1999-2016). J Vasc Surg. 2019;69:378-384.e2. doi: 10.1016/j.jvs.2018.03.435
10. Kent KC, Zwolak RM, Egorova NN, et al. Analysis of risk factors for abdominal aortic aneurysm in a cohort of more than 3 million individuals. J Vasc Surg. 2010;52:539-548. doi: 10.1016/j.jvs.2010.05.090
11. [No authors listed] Smoking, lung function and the prognosis of abdominal aortic aneurysm. The UK Small Aneurysm Trial Participants. Eur J Vasc Endovasc Surg. 2000;19:636-642. doi: 10.1053/ejvs.2000.1066
12. Oliver-Williams C, Sweeting MJ, Turton G, et al. Lessons learned about prevalence and growth rates of abdominal aortic aneurysms from a 25-year ultrasound population screening programme. Br J Surg. 2018;105:68-74. doi: 10.1002/bjs.10715
13. Ulug P, Powell JT, Sweeting MJ, et al. Meta-analysis of the current prevalence of screen-detected abdominal aortic aneurysm in women. Br J Surg. 2016;103:1097-1104. doi: 10.1002/bjs.10225
14. Chabok M, Nicolaides A, Aslam M, et al. Risk factors associated with increased prevalence of abdominal aortic aneurysm in women. Br J Surg. 2016;103:1132-1138. doi: 10.1002/bjs.10179
15. Sweeting, MJ, Masconi KL, Jones E, et al. Analysis of clinical benefit, harms, and cost-effectiveness of screening women for abdominal aortic aneurysm. Lancet. 2018;392:487-495. doi: 10.1016/S0140-6736(18)31222-4
16. Sweeting MJ, Thompson SG, Brown LC, et al; RESCAN collaborators. Meta-analysis of individual patient data to examine factors affecting growth and rupture of small abdominal aortic aneurysms. Br J Surg. 2012;99:655-665. doi: 10.1002/bjs.8707
17. Skibba AA, Evans JR, Hopkins SP, et al. Reconsidering gender relative to risk of rupture in the contemporary management of abdominal aortic aneurysms. J Vasc Surg. 2015;62:1429-1436. doi: 10.1016/j.jvs.2015.07.079
18. Guirguis-Blake JM, Beil TL, Senger CA, et al. Primary care screening for abdominal aortic aneurysm: updated evidence report and systematic review for the US Preventive Services Task Force. JAMA. 2019;322:2219-2238. doi: 10.1001/jama.2019.17021
19. Thompson SG, Ashton HA, Gao L, et al; Multicentre Aneurysm Screening Study (MASS) Group. Final follow-up of the Multicentre Aneurysm Screening Study (MASS) randomized trial of abdominal aortic aneurysm screening. Br J Surg. 2012;99:1649-1656. doi: 10.1002/bjs.8897
20. Ashton HA, Gao L, Kim LG, et al. Fifteen-year follow-up of a randomized clinical trial of ultrasonographic screening for abdominal aortic aneurysms. Br J Surg. 2007;94:696-701. doi: 10.1002/bjs.5780
21. Carnevale ML, Koleilat I, Lipsitz EC, et al. Extended screening guidelines for the diagnosis of abdominal aortic aneurysm. J Vasc Surg. 2020;72:1917-1926. doi: 10.1016/j.jvs.2020.03.047
22. Duncan A, Maslen C, Gibson C, et al. Ultrasound screening for abdominal aortic aneurysm in high-risk women. Br J Surg. 2021;108:1192-1198. doi: 10.1093/bjs/znab220
23. Shreibati JB, Baker LC, Hlatky MA, et al. Impact of the Screening Abdominal Aortic Aneurysms Very Efficiently (SAAAVE) Act on abdominal ultrasonography use among Medicare beneficiaries. Arch Intern Med. 2012;172:1456-1462. doi: 10.1001/archinternmed.2012.4268
24. Hye RJ, Smith AE, Wong GH, et al. Leveraging the electronic medical record to implement an abdominal aortic aneurysm screening program. J Vasc Surg. 2014;59:1535-1542. doi: 10.1016/j.jvs.2013.12.016
25. Rubano E, Mehta N, Caputo W, et al., Systematic review: emergency department bedside ultrasonography for diagnosing suspected abdominal aortic aneurysm. Acad Emerg Med. 2013. 20:128-138. doi: 10.1111/acem.12080
26. Blois B. Office-based ultrasound screening for abdominal aortic aneurysm. Can Fam Physician. 2012;58:e172-e178.
27. Arnold MJ, Jonas CE, Carter RE. Point-of-care ultrasonography. Am Fam Physician. 2020;101:275-285.
28. Nixon G, Blattner K, Muirhead J, et al. Point-of-care ultrasound for FAST and AAA in rural New Zealand: quality and impact on patient care. Rural Remote Health. 2019;19:5027. doi: 10.22605/RRH5027
29. Lederle FA, Wilson SE, Johnson GR, et al. Immediate repair compared with surveillance of small abdominal aortic aneurysms. N Engl J Med. 2002;346:1437-1444. doi: 10.1056/NEJMoa012573
30. Filardo G, Lederle FA, Ballard DJ, et al. Immediate open repair vs surveillance in patients with small abdominal aortic aneurysms: survival differences by aneurysm size. Mayo Clin Proc. 2013;88:910-919. doi: 10.1016/j.mayocp.2013.05.014
31. Lederle FA, Kyriakides TC, Stroupe KT, et al. Open versus endovascular repair of abdominal aortic aneurysm. N Engl J Med. 2019;380:2126-2135. doi: 10.1056/NEJMoa1715955
32. Patel R, Sweeting MJ, Powell JT, et al., Endovascular versus open repair of abdominal aortic aneurysm in 15-years’ follow-up of the UK endovascular aneurysm repair trial 1 (EVAR trial 1): a randomised controlled trial. Lancet. 2016;388:2366-2374. doi: 10.1016/S0140-6736(16)31135-7
33. van Schaik TG, Yeung KK, Verhagen HJ, et al. Long-term survival and secondary procedures after open or endovascular repair of abdominal aortic aneurysms. J Vasc Surg. 2017;66:1379-1389. doi: 10.1016/j.jvs.2017.05.122
34. Powell JT, Brady AR, Brown, LC, et al; United Kingdom Small Aneurysm Trial Participants. Long-term outcomes of immediate repair compared with surveillance of small abdominal aortic aneurysms. N Engl J Med. 2002;346:1445-1452. doi: 10.1056/NEJMoa013527
35. Paravastu SC, Jayarajasingam R, Cottam R, et al. Endovascular repair of abdominal aortic aneurysm. Cochrane Database Syst Rev. 2014:CD004178. doi: 10.1002/14651858.CD004178.pub2
36. Rooke TW, Hirsch AT, Misra S, et al. 2011 ACCF/AHA focused update of the guideline for the management of patients with peripheral artery disease (updating the 2005 guideline): a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines. J Am Coll Cardiol. 2011;58:2020-2045. doi: 10.1016/j.jacc.2011.08.023
37. Bhak RH, Wininger M, Johnson GR, et al. Factors associated with small abdominal aortic aneurysm expansion rate. JAMA Surg. 2015;150:44-50. doi: 10.1001/jamasurg.2014.2025
38. Ouriel K, Clair DG, Kent KC, et al; Positive Impact of Endovascular Options for treating Aneurysms Early (PIVOTAL) Investigators. Endovascular repair compared with surveillance for patients with small abdominal aortic aneurysms. J Vasc Surg. 2010;51:1081-1087. doi: 10.1016/j.jvs.2009.10.113
39. Cao P, De Rango P, Verzini F, et al. Comparison of surveillance versus aortic endografting for small aneurysm repair (CAESAR): results from a randomised trial. Eur J Vasc Endovasc Surg. 2011;41:13-25. doi: 10.1016/j.ejvs.2010.08.026
40. Karthaus EG, Tong TML, Vahl A, et al; Dutch Society of Vascular Surgery, the Steering Committee of the Dutch Surgical Aneurysm Audit and the Dutch Institute for Clinical Auditing. Saccular abdominal aortic aneurysms: patient characteristics, clinical presentation, treatment, and outcomes in the Netherlands. Ann Surg. 2019;270:852-858. doi: 10.1097/SLA.0000000000003529
41. Nathan DP, Xu C, Pouch AM, et al. Increased wall stress of saccular versus fusiform aneurysms of the descending thoracic aorta. Ann Vasc Surg. 2011;25:1129-2237. doi: 10.1016/j.avsg.2011.07.008
42. Durojaye MS, Adeniyi TO, Alagbe OA. Multiple saccular aneurysms of the abdominal aorta: a case report and short review of risk factors for rupture on CT Scan. Ann Ib Postgrad Med. 2020;18:178-180.
43. Bertges DJ, Neal D, Schanzer A, et al. The Vascular Quality Initiative Cardiac Risk Index for prediction of myocardial infarction after vascular surgery. J Vasc Surg. 2016;64:1411-1421.e4. doi: 10.1016/j.jvs.2016.04.045
44. Mach F, Baigent C, Catapano AL, et al. 2019 ESC/EAS guidelines for the management of dyslipidaemias: lipid modification to reduce cardiovascular risk. Eur Heart J. 2020;41:111-188. doi: 10.1093/eurheartj/ehz455
45. Twine CP, Williams IM. Systematic review and meta-analysis of the effects of statin therapy on abdominal aortic aneurysms. Br J Surg. 2011;98:346-353. doi: 10.1002/bjs.7343
46. Arnett DK, Blumenthal RS, Albert MA, et al. 2019 ACC/AHA guideline on the primary prevention of cardiovascular disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Circulation. 2019;140:e596-e646. doi: 10.1161/CIR.0000000000000678
47. Erbel R, Aboyans V, Boileau C, et al. 2014 ESC guidelines on the diagnosis and treatment of aortic diseases: document covering acute and chronic aortic diseases of the thoracic and abdominal aorta of the adult. The Task Force for the Diagnosis and Treatment of Aortic Diseases of the European Society of Cardiology (ESC). Eur Heart J. 2014;35:2873-2926. doi: 10.1093/eurheartj/ehu281
48. Lederle FA, Noorbaloochi S, Nugent S, et al. Multicentre study of abdominal aortic aneurysm measurement and enlargement. Br J Surg. 2015;102:1480-1487. doi: 10.1002/bjs.9895
49. Itoga NK, Rothenberg KA, Suarez P, et al. Metformin prescription status and abdominal aortic aneurysm disease progression in the U.S. veteran population. J Vasc Surg. 2019;69:710-716.e3. doi: 10.1016/j.jvs.2018.06.19
1. CDC. Wide-ranging Online Data for Epidemiologic Research (WONDER) database. Accessed August 30, 2023. https://wonder.cdc.gov/ucd-icd10.html
2. Reimerink JJ, van der Laan MJ, Koelemay MJ, et al. Systematic review and meta-analysis of population-based mortality from ruptured abdominal aortic aneurysm. Br J Surg. 2013;100:1405-1413. doi: 10.1002/bjs.9235
3. Kent KC. Clinical practice. Abdominal aortic aneurysms. N Engl J Med. 2014;371:2101-2108. doi: 10.1056/NEJMcp1401430
4. Chaikof EL, Dalman RL, Eskandari MK, et al. The Society for Vascular Surgery practice guidelines on the care of patients with an abdominal aortic aneurysm. J Vasc Surg. 2018;67:2-77.e2. doi: 10.1016/j.jvs.2017.10.044
5. Moll FL, Powell JT, Fraedrich G, et al. Management of abdominal aortic aneurysms clinical practice guidelines of the European society for vascular surgery. Eur J Vasc Endovasc Surg. 2011;41 suppl 1:S1-S58. doi: 10.1016/j.ejvs.2010.09.011
6. Owens DK, Davidson KW, Krist AH, et al; US Preventive Services Task Force. Screening for abdominal aortic aneurysm: US Preventive Services Task Force recommendation statement. JAMA. 2019;322:2211-2218. doi: 10.1001/jama.2019.18928
7. National Institute for Health and Care Excellence. Abdominal aortic aneurysm: diagnosis and management. NICE guideline [NG156]. March 19, 2020. Accessed June 30, 2023. www.nice.org.uk/guidance/ng156/chapter/recommendations
8. Canadian Task Force on Preventive Health Care. Recommendations on screening for abdominal aortic aneurysm in primary care. CMAJ. 2017;189:E1137-E1145. doi: 10.1503/cmaj.170118
9. Abdulameer H, Al Taii H, Al-Kindi SG, et al. Epidemiology of fatal ruptured aortic aneurysms in the United States (1999-2016). J Vasc Surg. 2019;69:378-384.e2. doi: 10.1016/j.jvs.2018.03.435
10. Kent KC, Zwolak RM, Egorova NN, et al. Analysis of risk factors for abdominal aortic aneurysm in a cohort of more than 3 million individuals. J Vasc Surg. 2010;52:539-548. doi: 10.1016/j.jvs.2010.05.090
11. [No authors listed] Smoking, lung function and the prognosis of abdominal aortic aneurysm. The UK Small Aneurysm Trial Participants. Eur J Vasc Endovasc Surg. 2000;19:636-642. doi: 10.1053/ejvs.2000.1066
12. Oliver-Williams C, Sweeting MJ, Turton G, et al. Lessons learned about prevalence and growth rates of abdominal aortic aneurysms from a 25-year ultrasound population screening programme. Br J Surg. 2018;105:68-74. doi: 10.1002/bjs.10715
13. Ulug P, Powell JT, Sweeting MJ, et al. Meta-analysis of the current prevalence of screen-detected abdominal aortic aneurysm in women. Br J Surg. 2016;103:1097-1104. doi: 10.1002/bjs.10225
14. Chabok M, Nicolaides A, Aslam M, et al. Risk factors associated with increased prevalence of abdominal aortic aneurysm in women. Br J Surg. 2016;103:1132-1138. doi: 10.1002/bjs.10179
15. Sweeting, MJ, Masconi KL, Jones E, et al. Analysis of clinical benefit, harms, and cost-effectiveness of screening women for abdominal aortic aneurysm. Lancet. 2018;392:487-495. doi: 10.1016/S0140-6736(18)31222-4
16. Sweeting MJ, Thompson SG, Brown LC, et al; RESCAN collaborators. Meta-analysis of individual patient data to examine factors affecting growth and rupture of small abdominal aortic aneurysms. Br J Surg. 2012;99:655-665. doi: 10.1002/bjs.8707
17. Skibba AA, Evans JR, Hopkins SP, et al. Reconsidering gender relative to risk of rupture in the contemporary management of abdominal aortic aneurysms. J Vasc Surg. 2015;62:1429-1436. doi: 10.1016/j.jvs.2015.07.079
18. Guirguis-Blake JM, Beil TL, Senger CA, et al. Primary care screening for abdominal aortic aneurysm: updated evidence report and systematic review for the US Preventive Services Task Force. JAMA. 2019;322:2219-2238. doi: 10.1001/jama.2019.17021
19. Thompson SG, Ashton HA, Gao L, et al; Multicentre Aneurysm Screening Study (MASS) Group. Final follow-up of the Multicentre Aneurysm Screening Study (MASS) randomized trial of abdominal aortic aneurysm screening. Br J Surg. 2012;99:1649-1656. doi: 10.1002/bjs.8897
20. Ashton HA, Gao L, Kim LG, et al. Fifteen-year follow-up of a randomized clinical trial of ultrasonographic screening for abdominal aortic aneurysms. Br J Surg. 2007;94:696-701. doi: 10.1002/bjs.5780
21. Carnevale ML, Koleilat I, Lipsitz EC, et al. Extended screening guidelines for the diagnosis of abdominal aortic aneurysm. J Vasc Surg. 2020;72:1917-1926. doi: 10.1016/j.jvs.2020.03.047
22. Duncan A, Maslen C, Gibson C, et al. Ultrasound screening for abdominal aortic aneurysm in high-risk women. Br J Surg. 2021;108:1192-1198. doi: 10.1093/bjs/znab220
23. Shreibati JB, Baker LC, Hlatky MA, et al. Impact of the Screening Abdominal Aortic Aneurysms Very Efficiently (SAAAVE) Act on abdominal ultrasonography use among Medicare beneficiaries. Arch Intern Med. 2012;172:1456-1462. doi: 10.1001/archinternmed.2012.4268
24. Hye RJ, Smith AE, Wong GH, et al. Leveraging the electronic medical record to implement an abdominal aortic aneurysm screening program. J Vasc Surg. 2014;59:1535-1542. doi: 10.1016/j.jvs.2013.12.016
25. Rubano E, Mehta N, Caputo W, et al., Systematic review: emergency department bedside ultrasonography for diagnosing suspected abdominal aortic aneurysm. Acad Emerg Med. 2013. 20:128-138. doi: 10.1111/acem.12080
26. Blois B. Office-based ultrasound screening for abdominal aortic aneurysm. Can Fam Physician. 2012;58:e172-e178.
27. Arnold MJ, Jonas CE, Carter RE. Point-of-care ultrasonography. Am Fam Physician. 2020;101:275-285.
28. Nixon G, Blattner K, Muirhead J, et al. Point-of-care ultrasound for FAST and AAA in rural New Zealand: quality and impact on patient care. Rural Remote Health. 2019;19:5027. doi: 10.22605/RRH5027
29. Lederle FA, Wilson SE, Johnson GR, et al. Immediate repair compared with surveillance of small abdominal aortic aneurysms. N Engl J Med. 2002;346:1437-1444. doi: 10.1056/NEJMoa012573
30. Filardo G, Lederle FA, Ballard DJ, et al. Immediate open repair vs surveillance in patients with small abdominal aortic aneurysms: survival differences by aneurysm size. Mayo Clin Proc. 2013;88:910-919. doi: 10.1016/j.mayocp.2013.05.014
31. Lederle FA, Kyriakides TC, Stroupe KT, et al. Open versus endovascular repair of abdominal aortic aneurysm. N Engl J Med. 2019;380:2126-2135. doi: 10.1056/NEJMoa1715955
32. Patel R, Sweeting MJ, Powell JT, et al., Endovascular versus open repair of abdominal aortic aneurysm in 15-years’ follow-up of the UK endovascular aneurysm repair trial 1 (EVAR trial 1): a randomised controlled trial. Lancet. 2016;388:2366-2374. doi: 10.1016/S0140-6736(16)31135-7
33. van Schaik TG, Yeung KK, Verhagen HJ, et al. Long-term survival and secondary procedures after open or endovascular repair of abdominal aortic aneurysms. J Vasc Surg. 2017;66:1379-1389. doi: 10.1016/j.jvs.2017.05.122
34. Powell JT, Brady AR, Brown, LC, et al; United Kingdom Small Aneurysm Trial Participants. Long-term outcomes of immediate repair compared with surveillance of small abdominal aortic aneurysms. N Engl J Med. 2002;346:1445-1452. doi: 10.1056/NEJMoa013527
35. Paravastu SC, Jayarajasingam R, Cottam R, et al. Endovascular repair of abdominal aortic aneurysm. Cochrane Database Syst Rev. 2014:CD004178. doi: 10.1002/14651858.CD004178.pub2
36. Rooke TW, Hirsch AT, Misra S, et al. 2011 ACCF/AHA focused update of the guideline for the management of patients with peripheral artery disease (updating the 2005 guideline): a report of the American College of Cardiology Foundation/American Heart Association Task Force on Practice Guidelines. J Am Coll Cardiol. 2011;58:2020-2045. doi: 10.1016/j.jacc.2011.08.023
37. Bhak RH, Wininger M, Johnson GR, et al. Factors associated with small abdominal aortic aneurysm expansion rate. JAMA Surg. 2015;150:44-50. doi: 10.1001/jamasurg.2014.2025
38. Ouriel K, Clair DG, Kent KC, et al; Positive Impact of Endovascular Options for treating Aneurysms Early (PIVOTAL) Investigators. Endovascular repair compared with surveillance for patients with small abdominal aortic aneurysms. J Vasc Surg. 2010;51:1081-1087. doi: 10.1016/j.jvs.2009.10.113
39. Cao P, De Rango P, Verzini F, et al. Comparison of surveillance versus aortic endografting for small aneurysm repair (CAESAR): results from a randomised trial. Eur J Vasc Endovasc Surg. 2011;41:13-25. doi: 10.1016/j.ejvs.2010.08.026
40. Karthaus EG, Tong TML, Vahl A, et al; Dutch Society of Vascular Surgery, the Steering Committee of the Dutch Surgical Aneurysm Audit and the Dutch Institute for Clinical Auditing. Saccular abdominal aortic aneurysms: patient characteristics, clinical presentation, treatment, and outcomes in the Netherlands. Ann Surg. 2019;270:852-858. doi: 10.1097/SLA.0000000000003529
41. Nathan DP, Xu C, Pouch AM, et al. Increased wall stress of saccular versus fusiform aneurysms of the descending thoracic aorta. Ann Vasc Surg. 2011;25:1129-2237. doi: 10.1016/j.avsg.2011.07.008
42. Durojaye MS, Adeniyi TO, Alagbe OA. Multiple saccular aneurysms of the abdominal aorta: a case report and short review of risk factors for rupture on CT Scan. Ann Ib Postgrad Med. 2020;18:178-180.
43. Bertges DJ, Neal D, Schanzer A, et al. The Vascular Quality Initiative Cardiac Risk Index for prediction of myocardial infarction after vascular surgery. J Vasc Surg. 2016;64:1411-1421.e4. doi: 10.1016/j.jvs.2016.04.045
44. Mach F, Baigent C, Catapano AL, et al. 2019 ESC/EAS guidelines for the management of dyslipidaemias: lipid modification to reduce cardiovascular risk. Eur Heart J. 2020;41:111-188. doi: 10.1093/eurheartj/ehz455
45. Twine CP, Williams IM. Systematic review and meta-analysis of the effects of statin therapy on abdominal aortic aneurysms. Br J Surg. 2011;98:346-353. doi: 10.1002/bjs.7343
46. Arnett DK, Blumenthal RS, Albert MA, et al. 2019 ACC/AHA guideline on the primary prevention of cardiovascular disease: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Circulation. 2019;140:e596-e646. doi: 10.1161/CIR.0000000000000678
47. Erbel R, Aboyans V, Boileau C, et al. 2014 ESC guidelines on the diagnosis and treatment of aortic diseases: document covering acute and chronic aortic diseases of the thoracic and abdominal aorta of the adult. The Task Force for the Diagnosis and Treatment of Aortic Diseases of the European Society of Cardiology (ESC). Eur Heart J. 2014;35:2873-2926. doi: 10.1093/eurheartj/ehu281
48. Lederle FA, Noorbaloochi S, Nugent S, et al. Multicentre study of abdominal aortic aneurysm measurement and enlargement. Br J Surg. 2015;102:1480-1487. doi: 10.1002/bjs.9895
49. Itoga NK, Rothenberg KA, Suarez P, et al. Metformin prescription status and abdominal aortic aneurysm disease progression in the U.S. veteran population. J Vasc Surg. 2019;69:710-716.e3. doi: 10.1016/j.jvs.2018.06.19
PRACTICE RECOMMENDATIONS
› Perform a one-time abdominal aortic aneurysm (AAA) screening ultrasound in men ages 65 to 75 years who have ever smoked. B
› Consider performing a one-time AAA screening ultrasound in women ages 65 to 75 years who have ever smoked. C
› Prescribe high-intensity statin therapy for men and women with atherosclerotic AAA. A
Strength of recommendation (SOR)
A Good-quality patient-oriented evidence
B Inconsistent or limited-quality patient-oriented evidence
C Consensus, usual practice, opinion, disease-oriented evidence, case series
A 42-year-old woman presented with a few days of erosions on her buccal mucosa, tongue, and soft palate
in which lesions present in the same location upon repeated intake of the offending drug. The lesions typically present within 30 minutes to 8 hours of administration of the drug. These reactions can be considered allergic or pseudo-allergic, in which case, there is no notable adaptive immune response. CD8+ T cells appear to play a role in the epidermal injury via release of interferons and interactions with other inflammatory cells.
There are numerous drugs that can precipitate these findings. NSAIDs; antibiotics, such as tetracyclines, sulfonamides; and phenytoin are common offenders. In the case of our patient, naproxen was the offending medication.
The classic presentation of FDE features annular, erythematous to violaceous macules on the skin or mucosa that can be asymptomatic or can produce burning, pain, or pruritus. The most common locations include the trunk and extremities, but the palms, soles, face, scalp, and mucosa can also be impacted. The oral mucosa seems to be the most common mucosal location. Intravenous administration of a drug is associated with more severe symptoms. Systemic symptoms are typically absent, and the eruption may initially be in one location, but may appear elsewhere upon repeated exposure to the offending medication.
The differential diagnosis includes arthropod bite reactions, urticaria, and erythema multiforme. Although FDEs are typically a clinical diagnosis, the histopathology will commonly show a vacuolar interface dermatitis. Furthermore, a variety of immune cells can be found, including neutrophilic, eosinophilic, and lymphocytic infiltrate. A combination of two or more histological patterns often favors the diagnosis of FDE.
Steroid creams can be prescribed to decrease the inflammatory reaction and improve symptoms; however, the definitive treatment of this condition is cessation of the offending agent. Postinflammatory hyperpigmentation is a common symptom after resolution of the condition, and it may take months to fade away. Further darkening can be prevented by practicing sun safety measures such as wearing sunblock, covering the affected areas, and avoiding prolonged sun exposure.
This case and the photos were submitted by Lucas Shapiro, BS, of Nova Southeastern University College of Osteopathic Medicine, Fort Lauderdale, Fla., and Igor Chaplik, DO, Aesthetix Dermatology, Fort Lauderdale. The column was edited by Donna Bilu Martin, MD.
Dr. Bilu Martin is a board-certified dermatologist in private practice at Premier Dermatology, MD, in Aventura, Fla. More diagnostic cases are available at mdedge.com/dermatology. To submit a case for possible publication, send an email to dermnews@mdedge.com.
References
Shaker G et al. Cureus. 2022 Aug 23;14(8):e28299.
Srivastava R et al. Indian J Dent. 2015 Apr-Jun;6(2):103-6.
Weyers W, Metze D. Dermatol Pract Concept. 2011 Jan 31;1(1):33-47.
in which lesions present in the same location upon repeated intake of the offending drug. The lesions typically present within 30 minutes to 8 hours of administration of the drug. These reactions can be considered allergic or pseudo-allergic, in which case, there is no notable adaptive immune response. CD8+ T cells appear to play a role in the epidermal injury via release of interferons and interactions with other inflammatory cells.
There are numerous drugs that can precipitate these findings. NSAIDs; antibiotics, such as tetracyclines, sulfonamides; and phenytoin are common offenders. In the case of our patient, naproxen was the offending medication.
The classic presentation of FDE features annular, erythematous to violaceous macules on the skin or mucosa that can be asymptomatic or can produce burning, pain, or pruritus. The most common locations include the trunk and extremities, but the palms, soles, face, scalp, and mucosa can also be impacted. The oral mucosa seems to be the most common mucosal location. Intravenous administration of a drug is associated with more severe symptoms. Systemic symptoms are typically absent, and the eruption may initially be in one location, but may appear elsewhere upon repeated exposure to the offending medication.
The differential diagnosis includes arthropod bite reactions, urticaria, and erythema multiforme. Although FDEs are typically a clinical diagnosis, the histopathology will commonly show a vacuolar interface dermatitis. Furthermore, a variety of immune cells can be found, including neutrophilic, eosinophilic, and lymphocytic infiltrate. A combination of two or more histological patterns often favors the diagnosis of FDE.
Steroid creams can be prescribed to decrease the inflammatory reaction and improve symptoms; however, the definitive treatment of this condition is cessation of the offending agent. Postinflammatory hyperpigmentation is a common symptom after resolution of the condition, and it may take months to fade away. Further darkening can be prevented by practicing sun safety measures such as wearing sunblock, covering the affected areas, and avoiding prolonged sun exposure.
This case and the photos were submitted by Lucas Shapiro, BS, of Nova Southeastern University College of Osteopathic Medicine, Fort Lauderdale, Fla., and Igor Chaplik, DO, Aesthetix Dermatology, Fort Lauderdale. The column was edited by Donna Bilu Martin, MD.
Dr. Bilu Martin is a board-certified dermatologist in private practice at Premier Dermatology, MD, in Aventura, Fla. More diagnostic cases are available at mdedge.com/dermatology. To submit a case for possible publication, send an email to dermnews@mdedge.com.
References
Shaker G et al. Cureus. 2022 Aug 23;14(8):e28299.
Srivastava R et al. Indian J Dent. 2015 Apr-Jun;6(2):103-6.
Weyers W, Metze D. Dermatol Pract Concept. 2011 Jan 31;1(1):33-47.
in which lesions present in the same location upon repeated intake of the offending drug. The lesions typically present within 30 minutes to 8 hours of administration of the drug. These reactions can be considered allergic or pseudo-allergic, in which case, there is no notable adaptive immune response. CD8+ T cells appear to play a role in the epidermal injury via release of interferons and interactions with other inflammatory cells.
There are numerous drugs that can precipitate these findings. NSAIDs; antibiotics, such as tetracyclines, sulfonamides; and phenytoin are common offenders. In the case of our patient, naproxen was the offending medication.
The classic presentation of FDE features annular, erythematous to violaceous macules on the skin or mucosa that can be asymptomatic or can produce burning, pain, or pruritus. The most common locations include the trunk and extremities, but the palms, soles, face, scalp, and mucosa can also be impacted. The oral mucosa seems to be the most common mucosal location. Intravenous administration of a drug is associated with more severe symptoms. Systemic symptoms are typically absent, and the eruption may initially be in one location, but may appear elsewhere upon repeated exposure to the offending medication.
The differential diagnosis includes arthropod bite reactions, urticaria, and erythema multiforme. Although FDEs are typically a clinical diagnosis, the histopathology will commonly show a vacuolar interface dermatitis. Furthermore, a variety of immune cells can be found, including neutrophilic, eosinophilic, and lymphocytic infiltrate. A combination of two or more histological patterns often favors the diagnosis of FDE.
Steroid creams can be prescribed to decrease the inflammatory reaction and improve symptoms; however, the definitive treatment of this condition is cessation of the offending agent. Postinflammatory hyperpigmentation is a common symptom after resolution of the condition, and it may take months to fade away. Further darkening can be prevented by practicing sun safety measures such as wearing sunblock, covering the affected areas, and avoiding prolonged sun exposure.
This case and the photos were submitted by Lucas Shapiro, BS, of Nova Southeastern University College of Osteopathic Medicine, Fort Lauderdale, Fla., and Igor Chaplik, DO, Aesthetix Dermatology, Fort Lauderdale. The column was edited by Donna Bilu Martin, MD.
Dr. Bilu Martin is a board-certified dermatologist in private practice at Premier Dermatology, MD, in Aventura, Fla. More diagnostic cases are available at mdedge.com/dermatology. To submit a case for possible publication, send an email to dermnews@mdedge.com.
References
Shaker G et al. Cureus. 2022 Aug 23;14(8):e28299.
Srivastava R et al. Indian J Dent. 2015 Apr-Jun;6(2):103-6.
Weyers W, Metze D. Dermatol Pract Concept. 2011 Jan 31;1(1):33-47.
Can these salt substitutes prevent complications of hypertension?
ILLUSTRATIVE CASE
A 47-year-old man in generally good health presents to a family medicine clinic for a well visit. He does not use tobacco products and had a benign colonoscopy last year. He reports walking for 30 minutes 3 to 4 times per week for exercise, althoug h he has gained 3 lbs over the past 2 years. He has no family history of early coronary artery disease, but his father and older brother have hypertension. His mother has a history of diabetes and hyperlipidemia.
The patient’s physical exam is unremarkable except for an elevated BP reading of 151/82 mm Hg. A review of his chart indicates he has had multiple elevated readings in the past that have ranged from 132/72 mm Hg to 139/89 mm Hg. The patient is interested in antihypertensive treatment but wants to know if modifying his diet and replacing his regular table salt with a salt substitute will lower his high BP. What can you recommend?
Hypertension is a leading cause of CV morbidity and mortality worldwide and is linked to increased dietary sodium intake. An estimated 1.28 billion people worldwide have hypertension; however, more than half of cases are undiagnosed.2 The US Preventive Services Task Force recommends screening for hypertension in adults older than 18 years and confirming elevated measurements conducted in a nonclinical setting before starting medication (grade “A”).3
Cut-points for the diagnosis of hypertension vary. The American Academy of Family Physicians, 4 the Eighth Joint National Committee (JNC 8), 5 the International Society of Hypertension, 6 and the European Society of Cardiology 7 use ≥ 140 mm Hg systolic BP (SBP) or ≥ 90 mm Hg diastolic BP (DBP) to define hypertension. The American College of Cardiology/American Heart Association guidelines use ≥ 130/80 mm Hg. 8
When treating patients with hypertension, primary care physicians often recommend lifestyle modifications such as the
Systematic reviews have shown a measurable improvement in BP with sodium reduction and potassium substitution. 10-12 More importantly, high-quality evidence demonstrates a decreased risk for CV disease, kidney disease, and all-cause mortality with lower dietary sodium intake. 13 Previous studies have shown that potassium-enriched salt substitutes lower BP, but their impact on CV morbidity and mortality is not well defined. Although lowering BP is associated with improved clinical impact, there is a lack of patient-oriented evidence that demonstrates improvement in CV disease and mortality.
The Salt Substitute and Stroke Study (SSaSS), published in 2021, demonstrated the protective effect of salt substitution against stroke, other CV events, and death. 14 Furthermore, this 5-year, cluster-randomized controlled trial of 20,995 participants across 600 villages in China demonstrated reduced CV mortality and BP reduction similar to standard pharmacologic treatment. Prior to SSaSS, 17 randomized controlled trials demonstrated a BP-lowering effect of salt substitutes but did not directly study the impact on clinical outcomes. 13
Continue to: In this 2022 systematic review...
In this 2022 systematic review and meta-analysis, 1 Yin et al evaluated 21 trials, including SSaSS, for the effect of salt substitutes on BP and other clinical outcomes, and the generalizability of the study results to diverse populations. The systematic review included parallel-group, step-wedge, and cluster-randomized controlled trials reporting the effect of salt substitutes on BP or clinical outcomes.
STUDY SUMMARY
Salt substitutes reduced BP across diverse populations
This systematic review and meta-analysis reviewed existing literature for randomized controlled trials investigating the effects of potassium-enriched salt substitutes on clinical outcomes for patients without kidney disease. The most commonly used salt substitute was potassium chloride, at 25% to 65% potassium.
The systematic review identified 21 trials comprising 31,949 study participants from 15 different countries with 1 to 60 months’ duration. Meta-analyses were performed using 19 trials for BP outcomes and 5 trials for vascular outcomes. Eleven trials were rated as having low risk for bias, 8 were deemed to have some concern, and 2 were rated as high risk for bias. Comparisons of data excluding studies with high risk for bias yielded results similar to comparisons of all studies.
The meta-analysis of 19 trials demonstrated reduced SBP (–4.6 mm Hg; 95% CI, –6.1 to –3.1) and DBP (–1.6 mm Hg; 95% CI, –2.4 to –0.8) in participants using potassium-enriched salt substitutes. However, the authors noted substantial heterogeneity among the studies (I 2 > 70%) for both SBP and DBP outcomes. Although there were no subgroup differences for age, sex, hypertension history, or other biomarkers, outcome differences were associated with trial duration, baseline potassium intake, and composition of the salt substitute.
Potassium-enriched salt substitutes were associated with reduced total mortality (risk ratio [RR] = 0.89; 95% CI, 0.85-0.94), CV mortality (RR = 0.87; 95% CI, 0.81-0.94), and CV events (RR = 0.89; 95% CI, 0.85-0.94). In a meta-regression, each 10% reduction in the sodium content of the salt substitute was associated with a 1.5–mm Hg greater reduction in SBP (95% CI, –3.0 to –0.03) and a 1.0–mm Hg greater reduction in DBP (95% CI, –1.8 to –0.1). However, the authors suggest interpreting meta-regression results with caution.
Continue to: Only 2 of the studes...
Only 2 of the studies in the systematic review explicitly reported the adverse effect of hyperkalemia, and there was no statistical difference in events between randomized groups. Eight other studies reported no serious adverse events related to hyperkalemia , and 11 studies did not report on the risk for hyperkalemia.
WHAT’S NEW
High-quality data demonstrate beneficial outcomes
Previous observational and interventional studies demonstrated a BP-lowering effect of salt substitutes, but limited data with poor-quality evidence existed for the impact of salt substitutes on clinical outcomes such as mortality and CV events. This systematic review and meta-analysis suggests that potassium-supplemented salt may reduce BP and secondarily reduce the risk for CV events, CV mortality, and total mortality, without clear harmful effects reported.
CAVEATS
Some patient populations, comorbidities excluded from study
The study did not include patients with kidney disease or those taking potassium-sparing diuretics. Furthermore, the available data do not include primary prevention participants.
Subgroup analyses should be interpreted with caution due to the small number of trials available for individual subgroups. In addition, funnel plot asymmetry for studies reporting DBP suggests at least some effect of publication bias for that outcome.
Although BP reduction due to salt substitutes may be small at an individual level, these levels of reduction may be important at a population level.
CHALLENGES TO IMPLEMENTATION
For appropriate patients, no challenges anticipated
There are no significant challenges to implementing conclusions from this study in the primary care setting. Family physicians should be able to recommend potassium-enriched salt substitutes to patients with hypertension who are not at risk for hyperkalemia, including those with kidney disease, on potassium-sparing diuretics, or with a history of hyperkalemia/hyperkalemic conditions. Salt substitutes, including potassium-enriched salts, are readily available in stores.
1. Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart. 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
2. NCD Risk Factor Collaboration (NCD-RisC). Worldwide trends in hypertension prevalence and progress in treatment and control from 1990 to 2019: a pooled analysis of 1201 population-representative studies with 104 million participants. Lancet. 2021;398:957-980. doi: 10.1016/S0140-6736(21)01330-1
3. USPSTF. Hypertension in adults: screening. Final recommendation statement. Published April 27, 2021. Accessed September 18, 2023. www.uspreventiveservicestaskforce.org/uspstf/recommendation/hypertension-in-adults-screening
4. Coles S, Fisher L, Lin KW, et al. Blood pressure targets in adults with hypertension: a clinical practice guideline from the AAFP. Published November 4, 2022. Accessed September 18, 2023. www.aafp.org/dam/AAFP/documents/journals/afp/AAFPHypertensionGuideline.pdf
5. James PA, Oparil S, Carter BL, et al. 2014 evidence-based guideline for the management of high blood pressure in adults: report from the panel members appointed to the Eighth Joint National Committee (JNC 8). JAMA. 2014;311:507-520. doi: 10.1001/jama. 2013.284427
6. Unger T, Borgi C, Charchar F, et al. 2020 International Society of Hypertension global hypertension practice guidelines. Hypertension. 2020;75:1334-1357. doi: 10.1161/HYPERTENSIONAHA.120.15026
7. Mancia G, Kreutz R, Brunstrom M, et al; the Task Force for the Management of Arterial Hypertension of the European Society of Hypertension. 2023 ESH Guidelines for the management of arterial hypertension. Endorsed by the European Renal Association (ERA) and the International Society of Hypertension (ISH). J Hypertens. 2023; Jun 21. doi: 10.1097/HJH.0000000000003480
8. Whelton PK, Carey RM, Aronow WS, et al. 2017 ACC/AHA/AAPA/ABC/ACPM/AGS/APhA/ASH/ASPC/NMA/PCNA Guideline for the prevention, detection, evaluation, and management of high blood pressure in adults: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Hypertension. 2018;71:e13-e115. 10.1161/HYP.0000000000000065
9. National Center for Health Statistics. National Ambulatory Medical Care Survey: 2014 state and national summary tables. Accessed June 27, 2023. www.cdc.gov/nchs/data/ahcd/namcs_summary/2014_namcs_web_tables.pdf
10. Huang L, Trieu K, Yoshimura S, et al. Effect of dose and duration of reduction in dietary sodium on blood pressure levels: systematic review and meta-analysis of randomised trials. BMJ. 2020;368:m315. doi: 10.1136/bmj.m315
11. Filippini T, Violi F, D’Amico R, et al. The effect of potassium supplementation on blood pressure in hypertensive subjects: a systematic review and meta-analysis. Int J Cardiol. 2017;230:127-135. doi: 10.1016/j.ijcard.2016.12.048
12. Brand A, Visser ME, Schoonees A, et al. Replacing salt with low-sodium salt substitutes (LSSS) for cardiovascular health in adults, children and pregnant women. Cochrane Database Syst Rev. 2022;8:CD015207. doi: 10.1002/14651858.CD015207
13. He FJ, Tan M, Ma Y, et al. Salt reduction to prevent hypertension and cardiovascular disease: JACC state-of-the-art review. J Am Coll Cardiol. 2020;75:632-647. doi: 10.1016/j.jacc.2019.11.055
14. Neal B, Wu Y, Feng X, et al. Effect of salt substitution on cardiovascular events and death. N Engl J Med. 2021;385:1067-1077. doi: 10.1056/NEJMoa2105675
ILLUSTRATIVE CASE
A 47-year-old man in generally good health presents to a family medicine clinic for a well visit. He does not use tobacco products and had a benign colonoscopy last year. He reports walking for 30 minutes 3 to 4 times per week for exercise, althoug h he has gained 3 lbs over the past 2 years. He has no family history of early coronary artery disease, but his father and older brother have hypertension. His mother has a history of diabetes and hyperlipidemia.
The patient’s physical exam is unremarkable except for an elevated BP reading of 151/82 mm Hg. A review of his chart indicates he has had multiple elevated readings in the past that have ranged from 132/72 mm Hg to 139/89 mm Hg. The patient is interested in antihypertensive treatment but wants to know if modifying his diet and replacing his regular table salt with a salt substitute will lower his high BP. What can you recommend?
Hypertension is a leading cause of CV morbidity and mortality worldwide and is linked to increased dietary sodium intake. An estimated 1.28 billion people worldwide have hypertension; however, more than half of cases are undiagnosed.2 The US Preventive Services Task Force recommends screening for hypertension in adults older than 18 years and confirming elevated measurements conducted in a nonclinical setting before starting medication (grade “A”).3
Cut-points for the diagnosis of hypertension vary. The American Academy of Family Physicians, 4 the Eighth Joint National Committee (JNC 8), 5 the International Society of Hypertension, 6 and the European Society of Cardiology 7 use ≥ 140 mm Hg systolic BP (SBP) or ≥ 90 mm Hg diastolic BP (DBP) to define hypertension. The American College of Cardiology/American Heart Association guidelines use ≥ 130/80 mm Hg. 8
When treating patients with hypertension, primary care physicians often recommend lifestyle modifications such as the
Systematic reviews have shown a measurable improvement in BP with sodium reduction and potassium substitution. 10-12 More importantly, high-quality evidence demonstrates a decreased risk for CV disease, kidney disease, and all-cause mortality with lower dietary sodium intake. 13 Previous studies have shown that potassium-enriched salt substitutes lower BP, but their impact on CV morbidity and mortality is not well defined. Although lowering BP is associated with improved clinical impact, there is a lack of patient-oriented evidence that demonstrates improvement in CV disease and mortality.
The Salt Substitute and Stroke Study (SSaSS), published in 2021, demonstrated the protective effect of salt substitution against stroke, other CV events, and death. 14 Furthermore, this 5-year, cluster-randomized controlled trial of 20,995 participants across 600 villages in China demonstrated reduced CV mortality and BP reduction similar to standard pharmacologic treatment. Prior to SSaSS, 17 randomized controlled trials demonstrated a BP-lowering effect of salt substitutes but did not directly study the impact on clinical outcomes. 13
Continue to: In this 2022 systematic review...
In this 2022 systematic review and meta-analysis, 1 Yin et al evaluated 21 trials, including SSaSS, for the effect of salt substitutes on BP and other clinical outcomes, and the generalizability of the study results to diverse populations. The systematic review included parallel-group, step-wedge, and cluster-randomized controlled trials reporting the effect of salt substitutes on BP or clinical outcomes.
STUDY SUMMARY
Salt substitutes reduced BP across diverse populations
This systematic review and meta-analysis reviewed existing literature for randomized controlled trials investigating the effects of potassium-enriched salt substitutes on clinical outcomes for patients without kidney disease. The most commonly used salt substitute was potassium chloride, at 25% to 65% potassium.
The systematic review identified 21 trials comprising 31,949 study participants from 15 different countries with 1 to 60 months’ duration. Meta-analyses were performed using 19 trials for BP outcomes and 5 trials for vascular outcomes. Eleven trials were rated as having low risk for bias, 8 were deemed to have some concern, and 2 were rated as high risk for bias. Comparisons of data excluding studies with high risk for bias yielded results similar to comparisons of all studies.
The meta-analysis of 19 trials demonstrated reduced SBP (–4.6 mm Hg; 95% CI, –6.1 to –3.1) and DBP (–1.6 mm Hg; 95% CI, –2.4 to –0.8) in participants using potassium-enriched salt substitutes. However, the authors noted substantial heterogeneity among the studies (I 2 > 70%) for both SBP and DBP outcomes. Although there were no subgroup differences for age, sex, hypertension history, or other biomarkers, outcome differences were associated with trial duration, baseline potassium intake, and composition of the salt substitute.
Potassium-enriched salt substitutes were associated with reduced total mortality (risk ratio [RR] = 0.89; 95% CI, 0.85-0.94), CV mortality (RR = 0.87; 95% CI, 0.81-0.94), and CV events (RR = 0.89; 95% CI, 0.85-0.94). In a meta-regression, each 10% reduction in the sodium content of the salt substitute was associated with a 1.5–mm Hg greater reduction in SBP (95% CI, –3.0 to –0.03) and a 1.0–mm Hg greater reduction in DBP (95% CI, –1.8 to –0.1). However, the authors suggest interpreting meta-regression results with caution.
Continue to: Only 2 of the studes...
Only 2 of the studies in the systematic review explicitly reported the adverse effect of hyperkalemia, and there was no statistical difference in events between randomized groups. Eight other studies reported no serious adverse events related to hyperkalemia , and 11 studies did not report on the risk for hyperkalemia.
WHAT’S NEW
High-quality data demonstrate beneficial outcomes
Previous observational and interventional studies demonstrated a BP-lowering effect of salt substitutes, but limited data with poor-quality evidence existed for the impact of salt substitutes on clinical outcomes such as mortality and CV events. This systematic review and meta-analysis suggests that potassium-supplemented salt may reduce BP and secondarily reduce the risk for CV events, CV mortality, and total mortality, without clear harmful effects reported.
CAVEATS
Some patient populations, comorbidities excluded from study
The study did not include patients with kidney disease or those taking potassium-sparing diuretics. Furthermore, the available data do not include primary prevention participants.
Subgroup analyses should be interpreted with caution due to the small number of trials available for individual subgroups. In addition, funnel plot asymmetry for studies reporting DBP suggests at least some effect of publication bias for that outcome.
Although BP reduction due to salt substitutes may be small at an individual level, these levels of reduction may be important at a population level.
CHALLENGES TO IMPLEMENTATION
For appropriate patients, no challenges anticipated
There are no significant challenges to implementing conclusions from this study in the primary care setting. Family physicians should be able to recommend potassium-enriched salt substitutes to patients with hypertension who are not at risk for hyperkalemia, including those with kidney disease, on potassium-sparing diuretics, or with a history of hyperkalemia/hyperkalemic conditions. Salt substitutes, including potassium-enriched salts, are readily available in stores.
ILLUSTRATIVE CASE
A 47-year-old man in generally good health presents to a family medicine clinic for a well visit. He does not use tobacco products and had a benign colonoscopy last year. He reports walking for 30 minutes 3 to 4 times per week for exercise, althoug h he has gained 3 lbs over the past 2 years. He has no family history of early coronary artery disease, but his father and older brother have hypertension. His mother has a history of diabetes and hyperlipidemia.
The patient’s physical exam is unremarkable except for an elevated BP reading of 151/82 mm Hg. A review of his chart indicates he has had multiple elevated readings in the past that have ranged from 132/72 mm Hg to 139/89 mm Hg. The patient is interested in antihypertensive treatment but wants to know if modifying his diet and replacing his regular table salt with a salt substitute will lower his high BP. What can you recommend?
Hypertension is a leading cause of CV morbidity and mortality worldwide and is linked to increased dietary sodium intake. An estimated 1.28 billion people worldwide have hypertension; however, more than half of cases are undiagnosed.2 The US Preventive Services Task Force recommends screening for hypertension in adults older than 18 years and confirming elevated measurements conducted in a nonclinical setting before starting medication (grade “A”).3
Cut-points for the diagnosis of hypertension vary. The American Academy of Family Physicians, 4 the Eighth Joint National Committee (JNC 8), 5 the International Society of Hypertension, 6 and the European Society of Cardiology 7 use ≥ 140 mm Hg systolic BP (SBP) or ≥ 90 mm Hg diastolic BP (DBP) to define hypertension. The American College of Cardiology/American Heart Association guidelines use ≥ 130/80 mm Hg. 8
When treating patients with hypertension, primary care physicians often recommend lifestyle modifications such as the
Systematic reviews have shown a measurable improvement in BP with sodium reduction and potassium substitution. 10-12 More importantly, high-quality evidence demonstrates a decreased risk for CV disease, kidney disease, and all-cause mortality with lower dietary sodium intake. 13 Previous studies have shown that potassium-enriched salt substitutes lower BP, but their impact on CV morbidity and mortality is not well defined. Although lowering BP is associated with improved clinical impact, there is a lack of patient-oriented evidence that demonstrates improvement in CV disease and mortality.
The Salt Substitute and Stroke Study (SSaSS), published in 2021, demonstrated the protective effect of salt substitution against stroke, other CV events, and death. 14 Furthermore, this 5-year, cluster-randomized controlled trial of 20,995 participants across 600 villages in China demonstrated reduced CV mortality and BP reduction similar to standard pharmacologic treatment. Prior to SSaSS, 17 randomized controlled trials demonstrated a BP-lowering effect of salt substitutes but did not directly study the impact on clinical outcomes. 13
Continue to: In this 2022 systematic review...
In this 2022 systematic review and meta-analysis, 1 Yin et al evaluated 21 trials, including SSaSS, for the effect of salt substitutes on BP and other clinical outcomes, and the generalizability of the study results to diverse populations. The systematic review included parallel-group, step-wedge, and cluster-randomized controlled trials reporting the effect of salt substitutes on BP or clinical outcomes.
STUDY SUMMARY
Salt substitutes reduced BP across diverse populations
This systematic review and meta-analysis reviewed existing literature for randomized controlled trials investigating the effects of potassium-enriched salt substitutes on clinical outcomes for patients without kidney disease. The most commonly used salt substitute was potassium chloride, at 25% to 65% potassium.
The systematic review identified 21 trials comprising 31,949 study participants from 15 different countries with 1 to 60 months’ duration. Meta-analyses were performed using 19 trials for BP outcomes and 5 trials for vascular outcomes. Eleven trials were rated as having low risk for bias, 8 were deemed to have some concern, and 2 were rated as high risk for bias. Comparisons of data excluding studies with high risk for bias yielded results similar to comparisons of all studies.
The meta-analysis of 19 trials demonstrated reduced SBP (–4.6 mm Hg; 95% CI, –6.1 to –3.1) and DBP (–1.6 mm Hg; 95% CI, –2.4 to –0.8) in participants using potassium-enriched salt substitutes. However, the authors noted substantial heterogeneity among the studies (I 2 > 70%) for both SBP and DBP outcomes. Although there were no subgroup differences for age, sex, hypertension history, or other biomarkers, outcome differences were associated with trial duration, baseline potassium intake, and composition of the salt substitute.
Potassium-enriched salt substitutes were associated with reduced total mortality (risk ratio [RR] = 0.89; 95% CI, 0.85-0.94), CV mortality (RR = 0.87; 95% CI, 0.81-0.94), and CV events (RR = 0.89; 95% CI, 0.85-0.94). In a meta-regression, each 10% reduction in the sodium content of the salt substitute was associated with a 1.5–mm Hg greater reduction in SBP (95% CI, –3.0 to –0.03) and a 1.0–mm Hg greater reduction in DBP (95% CI, –1.8 to –0.1). However, the authors suggest interpreting meta-regression results with caution.
Continue to: Only 2 of the studes...
Only 2 of the studies in the systematic review explicitly reported the adverse effect of hyperkalemia, and there was no statistical difference in events between randomized groups. Eight other studies reported no serious adverse events related to hyperkalemia , and 11 studies did not report on the risk for hyperkalemia.
WHAT’S NEW
High-quality data demonstrate beneficial outcomes
Previous observational and interventional studies demonstrated a BP-lowering effect of salt substitutes, but limited data with poor-quality evidence existed for the impact of salt substitutes on clinical outcomes such as mortality and CV events. This systematic review and meta-analysis suggests that potassium-supplemented salt may reduce BP and secondarily reduce the risk for CV events, CV mortality, and total mortality, without clear harmful effects reported.
CAVEATS
Some patient populations, comorbidities excluded from study
The study did not include patients with kidney disease or those taking potassium-sparing diuretics. Furthermore, the available data do not include primary prevention participants.
Subgroup analyses should be interpreted with caution due to the small number of trials available for individual subgroups. In addition, funnel plot asymmetry for studies reporting DBP suggests at least some effect of publication bias for that outcome.
Although BP reduction due to salt substitutes may be small at an individual level, these levels of reduction may be important at a population level.
CHALLENGES TO IMPLEMENTATION
For appropriate patients, no challenges anticipated
There are no significant challenges to implementing conclusions from this study in the primary care setting. Family physicians should be able to recommend potassium-enriched salt substitutes to patients with hypertension who are not at risk for hyperkalemia, including those with kidney disease, on potassium-sparing diuretics, or with a history of hyperkalemia/hyperkalemic conditions. Salt substitutes, including potassium-enriched salts, are readily available in stores.
1. Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart. 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
2. NCD Risk Factor Collaboration (NCD-RisC). Worldwide trends in hypertension prevalence and progress in treatment and control from 1990 to 2019: a pooled analysis of 1201 population-representative studies with 104 million participants. Lancet. 2021;398:957-980. doi: 10.1016/S0140-6736(21)01330-1
3. USPSTF. Hypertension in adults: screening. Final recommendation statement. Published April 27, 2021. Accessed September 18, 2023. www.uspreventiveservicestaskforce.org/uspstf/recommendation/hypertension-in-adults-screening
4. Coles S, Fisher L, Lin KW, et al. Blood pressure targets in adults with hypertension: a clinical practice guideline from the AAFP. Published November 4, 2022. Accessed September 18, 2023. www.aafp.org/dam/AAFP/documents/journals/afp/AAFPHypertensionGuideline.pdf
5. James PA, Oparil S, Carter BL, et al. 2014 evidence-based guideline for the management of high blood pressure in adults: report from the panel members appointed to the Eighth Joint National Committee (JNC 8). JAMA. 2014;311:507-520. doi: 10.1001/jama. 2013.284427
6. Unger T, Borgi C, Charchar F, et al. 2020 International Society of Hypertension global hypertension practice guidelines. Hypertension. 2020;75:1334-1357. doi: 10.1161/HYPERTENSIONAHA.120.15026
7. Mancia G, Kreutz R, Brunstrom M, et al; the Task Force for the Management of Arterial Hypertension of the European Society of Hypertension. 2023 ESH Guidelines for the management of arterial hypertension. Endorsed by the European Renal Association (ERA) and the International Society of Hypertension (ISH). J Hypertens. 2023; Jun 21. doi: 10.1097/HJH.0000000000003480
8. Whelton PK, Carey RM, Aronow WS, et al. 2017 ACC/AHA/AAPA/ABC/ACPM/AGS/APhA/ASH/ASPC/NMA/PCNA Guideline for the prevention, detection, evaluation, and management of high blood pressure in adults: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Hypertension. 2018;71:e13-e115. 10.1161/HYP.0000000000000065
9. National Center for Health Statistics. National Ambulatory Medical Care Survey: 2014 state and national summary tables. Accessed June 27, 2023. www.cdc.gov/nchs/data/ahcd/namcs_summary/2014_namcs_web_tables.pdf
10. Huang L, Trieu K, Yoshimura S, et al. Effect of dose and duration of reduction in dietary sodium on blood pressure levels: systematic review and meta-analysis of randomised trials. BMJ. 2020;368:m315. doi: 10.1136/bmj.m315
11. Filippini T, Violi F, D’Amico R, et al. The effect of potassium supplementation on blood pressure in hypertensive subjects: a systematic review and meta-analysis. Int J Cardiol. 2017;230:127-135. doi: 10.1016/j.ijcard.2016.12.048
12. Brand A, Visser ME, Schoonees A, et al. Replacing salt with low-sodium salt substitutes (LSSS) for cardiovascular health in adults, children and pregnant women. Cochrane Database Syst Rev. 2022;8:CD015207. doi: 10.1002/14651858.CD015207
13. He FJ, Tan M, Ma Y, et al. Salt reduction to prevent hypertension and cardiovascular disease: JACC state-of-the-art review. J Am Coll Cardiol. 2020;75:632-647. doi: 10.1016/j.jacc.2019.11.055
14. Neal B, Wu Y, Feng X, et al. Effect of salt substitution on cardiovascular events and death. N Engl J Med. 2021;385:1067-1077. doi: 10.1056/NEJMoa2105675
1. Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart. 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
2. NCD Risk Factor Collaboration (NCD-RisC). Worldwide trends in hypertension prevalence and progress in treatment and control from 1990 to 2019: a pooled analysis of 1201 population-representative studies with 104 million participants. Lancet. 2021;398:957-980. doi: 10.1016/S0140-6736(21)01330-1
3. USPSTF. Hypertension in adults: screening. Final recommendation statement. Published April 27, 2021. Accessed September 18, 2023. www.uspreventiveservicestaskforce.org/uspstf/recommendation/hypertension-in-adults-screening
4. Coles S, Fisher L, Lin KW, et al. Blood pressure targets in adults with hypertension: a clinical practice guideline from the AAFP. Published November 4, 2022. Accessed September 18, 2023. www.aafp.org/dam/AAFP/documents/journals/afp/AAFPHypertensionGuideline.pdf
5. James PA, Oparil S, Carter BL, et al. 2014 evidence-based guideline for the management of high blood pressure in adults: report from the panel members appointed to the Eighth Joint National Committee (JNC 8). JAMA. 2014;311:507-520. doi: 10.1001/jama. 2013.284427
6. Unger T, Borgi C, Charchar F, et al. 2020 International Society of Hypertension global hypertension practice guidelines. Hypertension. 2020;75:1334-1357. doi: 10.1161/HYPERTENSIONAHA.120.15026
7. Mancia G, Kreutz R, Brunstrom M, et al; the Task Force for the Management of Arterial Hypertension of the European Society of Hypertension. 2023 ESH Guidelines for the management of arterial hypertension. Endorsed by the European Renal Association (ERA) and the International Society of Hypertension (ISH). J Hypertens. 2023; Jun 21. doi: 10.1097/HJH.0000000000003480
8. Whelton PK, Carey RM, Aronow WS, et al. 2017 ACC/AHA/AAPA/ABC/ACPM/AGS/APhA/ASH/ASPC/NMA/PCNA Guideline for the prevention, detection, evaluation, and management of high blood pressure in adults: a report of the American College of Cardiology/American Heart Association Task Force on Clinical Practice Guidelines. Hypertension. 2018;71:e13-e115. 10.1161/HYP.0000000000000065
9. National Center for Health Statistics. National Ambulatory Medical Care Survey: 2014 state and national summary tables. Accessed June 27, 2023. www.cdc.gov/nchs/data/ahcd/namcs_summary/2014_namcs_web_tables.pdf
10. Huang L, Trieu K, Yoshimura S, et al. Effect of dose and duration of reduction in dietary sodium on blood pressure levels: systematic review and meta-analysis of randomised trials. BMJ. 2020;368:m315. doi: 10.1136/bmj.m315
11. Filippini T, Violi F, D’Amico R, et al. The effect of potassium supplementation on blood pressure in hypertensive subjects: a systematic review and meta-analysis. Int J Cardiol. 2017;230:127-135. doi: 10.1016/j.ijcard.2016.12.048
12. Brand A, Visser ME, Schoonees A, et al. Replacing salt with low-sodium salt substitutes (LSSS) for cardiovascular health in adults, children and pregnant women. Cochrane Database Syst Rev. 2022;8:CD015207. doi: 10.1002/14651858.CD015207
13. He FJ, Tan M, Ma Y, et al. Salt reduction to prevent hypertension and cardiovascular disease: JACC state-of-the-art review. J Am Coll Cardiol. 2020;75:632-647. doi: 10.1016/j.jacc.2019.11.055
14. Neal B, Wu Y, Feng X, et al. Effect of salt substitution on cardiovascular events and death. N Engl J Med. 2021;385:1067-1077. doi: 10.1056/NEJMoa2105675
PRACTICE CHANGER
Consider recommending potassium-enriched salt substitutes for appropriate patients with hypertension to reduce blood pressure (BP) and risk for related cardiovascular (CV) events or mortality.
STRENGTH OF RECOMMENDATION
A: Based on a systematic review and meta-analysis of controlled trials. 1
Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart . 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
Feeling salty about our sodium intake
The World Health Organization (WHO) recently released its inaugural report on the devastating global effects of hypertension, including recommendations for combatting this “silent killer.”1 Notable in the 276-page report is the emphasis on improving access to antihypertensive medications, in part through team-based care and simple evidence-based protocols. This strategy is not surprising given that in clinical medicine we focus on the “high-risk” strategy for prevention—ie, identify people at increased risk for an adverse health outcome (in this case, cardiovascular disease events) and offer them medication to reduce that risk.2
As part of the high-risk strategy, we also counsel at the individual level about lifestyle modifications—but unfortunately, we tend not to get very far. Given the substantial evidence demonstrating its benefits, a low-sodium DASH (Dietary Approaches to Stop Hypertension) eating plan is one of the lifestyle recommendations we make for our patients with hypertension.3,4 The DASH part of the diet involves getting our patients to eat more fruits, vegetables, and whole grains and limit sugar and saturated fats. To achieve the low-sodium part, we might counsel against added table salt, but mostly we discourage consumption of canned and other foods that are commercially processed, packaged, and prepared, because that’s the source of more than 70% of our sodium intake.5 It’s not difficult to understand why real-world uptake of the low-sodium DASH eating plan is low.6
This issue of The Journal of Family Practice features a PURL that supports a much more prominent role for salt substitutes in our counseling recommendations.7 Potassium-enriched salt substitutes not only lower blood pressure (BP) but also reduce the risk for cardiovascular events and death.8 They are widely available, and while more expensive per ounce than regular salt (sodium chloride), are still affordable.
Still, encouraging salt substitution with one patient at a time is relying on the high-risk strategy, with its inherently limited potential.2 An alternative is the population strategy. For hypertension, that would mean doing something for the entire population that would lead to a downward shift in the distribution of BP.2 The shift does not have to be large. We’ve known for more than 3 decades that just a 2–mm Hg reduction in the population’s average systolic BP would reduce stroke mortality by about 6%, coronary heart disease mortality by 4%, and total mortality by 3%.9 A 5–mm Hg reduction more than doubles those benefits. We are talking about tens of thousands fewer patients with heart disease and stroke each year and billions of dollars in health care cost savings.
Reducing our nation’s sodium intake, a quintessential population approach, has proven difficult. Our average daily sodium intake is about 3600 mg.10 Guidance on sodium reduction from the US Food and Drug Administration (targeted to industry) has aimed to reduce Americans’ average sodium intake to 3000 mg/d over the short term, fully acknowledging that the recommended sodium limit is 2300 mg/d.11 We’ve got a long way to go.
Might salt substitution at the population level be a way to simultaneously reduce our sodium intake and increase our potassium intake?12 The closest I found to a populationwide substitution study was a cluster randomized trial conducted in 6 villages in Peru.13 In a stepped-wedge design, households had 25% of their regular salt replaced with potassium salt. Small shops, bakeries, community kitchens, and food vendors also had salt replacement. The intention-to-treat analysis showed a small reduction in systolic BP (1.3 mm Hg) among those with hypertension at baseline (n = 428) and a 51% reduced incidence of developing hypertension among the other 1891 participants over the 4673 person-years of follow-up.
I found this study interesting and its results compelling, leading me to wonder: In the United States, where most of our sodium comes from the food industry, should we replace even a small amount of the sodium in processed foods with potassium? We’re not getting there with DASH alone.
1. World Health Organization. Global report on hypertension: the race against a silent killer. Published September 19, 2023. Accessed September 29, 2023. www.who.int/publications/i/item/9789240081062
2. Rose G. Sick individuals and sick populations. Int J Epidemiol. 2001;30:427-432. doi: 10.1093/ije/30.3.427
3. Chiavaroli L, Viguiliouk E, Nishi SK, et al. DASH dietary pattern and cardiometabolic outcomes: an umbrella review of systematic reviews and meta-analyses. Nutrients. 2019;11:338. doi: 10.3390/nu11020338
4. Saneei P, Salehi-Abargouei A, Esmaillzadeh A, et al. Influence of Dietary Approaches to Stop Hypertension (DASH) diet on blood pressure: a systematic review and meta-analysis on randomized controlled trials. Nutr Metab Cardiovasc Dis. 2014;24:1253-1261. doi: 10.1016/j.numecd.2014.06.008
5. Harnack LJ, Cogswell ME, Shikany JM, et al. Sources of sodium in US adults from 3 geographic regions. Circulation. 2017;135:1775-1783. doi: 10.1161/CIRCULATIONAHA.116.024446
6. Mellen PB, Gao SK, Vitolins MZ, et al. Deteriorating dietary habits among adults with hypertension: DASH dietary accordance, NHANES 1988-1994 and 1999-2004. Arch Intern Med. 2008;168:308-314. doi: 10.1001/archinternmed.2007.119
7. Chang ET, Powell R, Reese T. Can potassium-enriched salt substitutes prevent complications of hypertension? J Fam Pract. 2023;72:342-344. doi: 10.12788/jfp.0667
8. Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart. 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
9. Whelton PK, He J, Appel LJ, et al; National High Blood Pressure Education Program Coordinating Committee. Primary prevention of hypertension: clinical and public health advisory from The National High Blood Pressure Education Program. JAMA. 2002;288:1882-1888. doi: 10.1001/jama.288.15.1882
10. Cogswell ME, Loria CM, Terry AL, et al. Estimated 24-Hour urinary sodium and potassium excretion in US adults. JAMA. 2018;319:1209-1220. doi: 1001/jama.2018.1156
11. FDA. Guidance for industry: voluntary sodium reduction goals. Published October 2021. Accessed September 28, 2023. www.fda.gov/regulatory-information/search-fda-guidance-documents/guidance-industry-voluntary-sodium-reduction-goals
12. Nissaisorakarn V, Ormseth G, Earle W, et al. Less sodium, more potassium, or both: population-wide strategies to prevent hypertension. Am J Physiol Renal Physiol. 2023;325:F99-F104. doi: 10.1152/ajprenal.00007.202
13. Bernabe-Ortiz A, Sal Y Rosas VG, Ponce-Lucero V, et al. Effect of salt substitution on community-wide blood pressure and hypertension incidence. Nat Med. 2020;26:374-378. doi: 10.1038/s41591-020-0754-2
Editor-in-Chief
jfp.eic@mdedge.com
Editor-in-Chief
jfp.eic@mdedge.com
Editor-in-Chief
jfp.eic@mdedge.com
The World Health Organization (WHO) recently released its inaugural report on the devastating global effects of hypertension, including recommendations for combatting this “silent killer.”1 Notable in the 276-page report is the emphasis on improving access to antihypertensive medications, in part through team-based care and simple evidence-based protocols. This strategy is not surprising given that in clinical medicine we focus on the “high-risk” strategy for prevention—ie, identify people at increased risk for an adverse health outcome (in this case, cardiovascular disease events) and offer them medication to reduce that risk.2
As part of the high-risk strategy, we also counsel at the individual level about lifestyle modifications—but unfortunately, we tend not to get very far. Given the substantial evidence demonstrating its benefits, a low-sodium DASH (Dietary Approaches to Stop Hypertension) eating plan is one of the lifestyle recommendations we make for our patients with hypertension.3,4 The DASH part of the diet involves getting our patients to eat more fruits, vegetables, and whole grains and limit sugar and saturated fats. To achieve the low-sodium part, we might counsel against added table salt, but mostly we discourage consumption of canned and other foods that are commercially processed, packaged, and prepared, because that’s the source of more than 70% of our sodium intake.5 It’s not difficult to understand why real-world uptake of the low-sodium DASH eating plan is low.6
This issue of The Journal of Family Practice features a PURL that supports a much more prominent role for salt substitutes in our counseling recommendations.7 Potassium-enriched salt substitutes not only lower blood pressure (BP) but also reduce the risk for cardiovascular events and death.8 They are widely available, and while more expensive per ounce than regular salt (sodium chloride), are still affordable.
Still, encouraging salt substitution with one patient at a time is relying on the high-risk strategy, with its inherently limited potential.2 An alternative is the population strategy. For hypertension, that would mean doing something for the entire population that would lead to a downward shift in the distribution of BP.2 The shift does not have to be large. We’ve known for more than 3 decades that just a 2–mm Hg reduction in the population’s average systolic BP would reduce stroke mortality by about 6%, coronary heart disease mortality by 4%, and total mortality by 3%.9 A 5–mm Hg reduction more than doubles those benefits. We are talking about tens of thousands fewer patients with heart disease and stroke each year and billions of dollars in health care cost savings.
Reducing our nation’s sodium intake, a quintessential population approach, has proven difficult. Our average daily sodium intake is about 3600 mg.10 Guidance on sodium reduction from the US Food and Drug Administration (targeted to industry) has aimed to reduce Americans’ average sodium intake to 3000 mg/d over the short term, fully acknowledging that the recommended sodium limit is 2300 mg/d.11 We’ve got a long way to go.
Might salt substitution at the population level be a way to simultaneously reduce our sodium intake and increase our potassium intake?12 The closest I found to a populationwide substitution study was a cluster randomized trial conducted in 6 villages in Peru.13 In a stepped-wedge design, households had 25% of their regular salt replaced with potassium salt. Small shops, bakeries, community kitchens, and food vendors also had salt replacement. The intention-to-treat analysis showed a small reduction in systolic BP (1.3 mm Hg) among those with hypertension at baseline (n = 428) and a 51% reduced incidence of developing hypertension among the other 1891 participants over the 4673 person-years of follow-up.
I found this study interesting and its results compelling, leading me to wonder: In the United States, where most of our sodium comes from the food industry, should we replace even a small amount of the sodium in processed foods with potassium? We’re not getting there with DASH alone.
The World Health Organization (WHO) recently released its inaugural report on the devastating global effects of hypertension, including recommendations for combatting this “silent killer.”1 Notable in the 276-page report is the emphasis on improving access to antihypertensive medications, in part through team-based care and simple evidence-based protocols. This strategy is not surprising given that in clinical medicine we focus on the “high-risk” strategy for prevention—ie, identify people at increased risk for an adverse health outcome (in this case, cardiovascular disease events) and offer them medication to reduce that risk.2
As part of the high-risk strategy, we also counsel at the individual level about lifestyle modifications—but unfortunately, we tend not to get very far. Given the substantial evidence demonstrating its benefits, a low-sodium DASH (Dietary Approaches to Stop Hypertension) eating plan is one of the lifestyle recommendations we make for our patients with hypertension.3,4 The DASH part of the diet involves getting our patients to eat more fruits, vegetables, and whole grains and limit sugar and saturated fats. To achieve the low-sodium part, we might counsel against added table salt, but mostly we discourage consumption of canned and other foods that are commercially processed, packaged, and prepared, because that’s the source of more than 70% of our sodium intake.5 It’s not difficult to understand why real-world uptake of the low-sodium DASH eating plan is low.6
This issue of The Journal of Family Practice features a PURL that supports a much more prominent role for salt substitutes in our counseling recommendations.7 Potassium-enriched salt substitutes not only lower blood pressure (BP) but also reduce the risk for cardiovascular events and death.8 They are widely available, and while more expensive per ounce than regular salt (sodium chloride), are still affordable.
Still, encouraging salt substitution with one patient at a time is relying on the high-risk strategy, with its inherently limited potential.2 An alternative is the population strategy. For hypertension, that would mean doing something for the entire population that would lead to a downward shift in the distribution of BP.2 The shift does not have to be large. We’ve known for more than 3 decades that just a 2–mm Hg reduction in the population’s average systolic BP would reduce stroke mortality by about 6%, coronary heart disease mortality by 4%, and total mortality by 3%.9 A 5–mm Hg reduction more than doubles those benefits. We are talking about tens of thousands fewer patients with heart disease and stroke each year and billions of dollars in health care cost savings.
Reducing our nation’s sodium intake, a quintessential population approach, has proven difficult. Our average daily sodium intake is about 3600 mg.10 Guidance on sodium reduction from the US Food and Drug Administration (targeted to industry) has aimed to reduce Americans’ average sodium intake to 3000 mg/d over the short term, fully acknowledging that the recommended sodium limit is 2300 mg/d.11 We’ve got a long way to go.
Might salt substitution at the population level be a way to simultaneously reduce our sodium intake and increase our potassium intake?12 The closest I found to a populationwide substitution study was a cluster randomized trial conducted in 6 villages in Peru.13 In a stepped-wedge design, households had 25% of their regular salt replaced with potassium salt. Small shops, bakeries, community kitchens, and food vendors also had salt replacement. The intention-to-treat analysis showed a small reduction in systolic BP (1.3 mm Hg) among those with hypertension at baseline (n = 428) and a 51% reduced incidence of developing hypertension among the other 1891 participants over the 4673 person-years of follow-up.
I found this study interesting and its results compelling, leading me to wonder: In the United States, where most of our sodium comes from the food industry, should we replace even a small amount of the sodium in processed foods with potassium? We’re not getting there with DASH alone.
1. World Health Organization. Global report on hypertension: the race against a silent killer. Published September 19, 2023. Accessed September 29, 2023. www.who.int/publications/i/item/9789240081062
2. Rose G. Sick individuals and sick populations. Int J Epidemiol. 2001;30:427-432. doi: 10.1093/ije/30.3.427
3. Chiavaroli L, Viguiliouk E, Nishi SK, et al. DASH dietary pattern and cardiometabolic outcomes: an umbrella review of systematic reviews and meta-analyses. Nutrients. 2019;11:338. doi: 10.3390/nu11020338
4. Saneei P, Salehi-Abargouei A, Esmaillzadeh A, et al. Influence of Dietary Approaches to Stop Hypertension (DASH) diet on blood pressure: a systematic review and meta-analysis on randomized controlled trials. Nutr Metab Cardiovasc Dis. 2014;24:1253-1261. doi: 10.1016/j.numecd.2014.06.008
5. Harnack LJ, Cogswell ME, Shikany JM, et al. Sources of sodium in US adults from 3 geographic regions. Circulation. 2017;135:1775-1783. doi: 10.1161/CIRCULATIONAHA.116.024446
6. Mellen PB, Gao SK, Vitolins MZ, et al. Deteriorating dietary habits among adults with hypertension: DASH dietary accordance, NHANES 1988-1994 and 1999-2004. Arch Intern Med. 2008;168:308-314. doi: 10.1001/archinternmed.2007.119
7. Chang ET, Powell R, Reese T. Can potassium-enriched salt substitutes prevent complications of hypertension? J Fam Pract. 2023;72:342-344. doi: 10.12788/jfp.0667
8. Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart. 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
9. Whelton PK, He J, Appel LJ, et al; National High Blood Pressure Education Program Coordinating Committee. Primary prevention of hypertension: clinical and public health advisory from The National High Blood Pressure Education Program. JAMA. 2002;288:1882-1888. doi: 10.1001/jama.288.15.1882
10. Cogswell ME, Loria CM, Terry AL, et al. Estimated 24-Hour urinary sodium and potassium excretion in US adults. JAMA. 2018;319:1209-1220. doi: 1001/jama.2018.1156
11. FDA. Guidance for industry: voluntary sodium reduction goals. Published October 2021. Accessed September 28, 2023. www.fda.gov/regulatory-information/search-fda-guidance-documents/guidance-industry-voluntary-sodium-reduction-goals
12. Nissaisorakarn V, Ormseth G, Earle W, et al. Less sodium, more potassium, or both: population-wide strategies to prevent hypertension. Am J Physiol Renal Physiol. 2023;325:F99-F104. doi: 10.1152/ajprenal.00007.202
13. Bernabe-Ortiz A, Sal Y Rosas VG, Ponce-Lucero V, et al. Effect of salt substitution on community-wide blood pressure and hypertension incidence. Nat Med. 2020;26:374-378. doi: 10.1038/s41591-020-0754-2
1. World Health Organization. Global report on hypertension: the race against a silent killer. Published September 19, 2023. Accessed September 29, 2023. www.who.int/publications/i/item/9789240081062
2. Rose G. Sick individuals and sick populations. Int J Epidemiol. 2001;30:427-432. doi: 10.1093/ije/30.3.427
3. Chiavaroli L, Viguiliouk E, Nishi SK, et al. DASH dietary pattern and cardiometabolic outcomes: an umbrella review of systematic reviews and meta-analyses. Nutrients. 2019;11:338. doi: 10.3390/nu11020338
4. Saneei P, Salehi-Abargouei A, Esmaillzadeh A, et al. Influence of Dietary Approaches to Stop Hypertension (DASH) diet on blood pressure: a systematic review and meta-analysis on randomized controlled trials. Nutr Metab Cardiovasc Dis. 2014;24:1253-1261. doi: 10.1016/j.numecd.2014.06.008
5. Harnack LJ, Cogswell ME, Shikany JM, et al. Sources of sodium in US adults from 3 geographic regions. Circulation. 2017;135:1775-1783. doi: 10.1161/CIRCULATIONAHA.116.024446
6. Mellen PB, Gao SK, Vitolins MZ, et al. Deteriorating dietary habits among adults with hypertension: DASH dietary accordance, NHANES 1988-1994 and 1999-2004. Arch Intern Med. 2008;168:308-314. doi: 10.1001/archinternmed.2007.119
7. Chang ET, Powell R, Reese T. Can potassium-enriched salt substitutes prevent complications of hypertension? J Fam Pract. 2023;72:342-344. doi: 10.12788/jfp.0667
8. Yin X, Rodgers A, Perkovic A, et al. Effects of salt substitutes on clinical outcomes: a systematic review and meta-analysis. Heart. 2022;108:1608-1615. doi: 10.1136/heartjnl-2022-321332
9. Whelton PK, He J, Appel LJ, et al; National High Blood Pressure Education Program Coordinating Committee. Primary prevention of hypertension: clinical and public health advisory from The National High Blood Pressure Education Program. JAMA. 2002;288:1882-1888. doi: 10.1001/jama.288.15.1882
10. Cogswell ME, Loria CM, Terry AL, et al. Estimated 24-Hour urinary sodium and potassium excretion in US adults. JAMA. 2018;319:1209-1220. doi: 1001/jama.2018.1156
11. FDA. Guidance for industry: voluntary sodium reduction goals. Published October 2021. Accessed September 28, 2023. www.fda.gov/regulatory-information/search-fda-guidance-documents/guidance-industry-voluntary-sodium-reduction-goals
12. Nissaisorakarn V, Ormseth G, Earle W, et al. Less sodium, more potassium, or both: population-wide strategies to prevent hypertension. Am J Physiol Renal Physiol. 2023;325:F99-F104. doi: 10.1152/ajprenal.00007.202
13. Bernabe-Ortiz A, Sal Y Rosas VG, Ponce-Lucero V, et al. Effect of salt substitution on community-wide blood pressure and hypertension incidence. Nat Med. 2020;26:374-378. doi: 10.1038/s41591-020-0754-2
52-year-old man • intermittent fevers • recently received second dose of COVID-19 vaccine • tremors in all 4 extremities • Dx?
THE CASE
A 52-year-old man sought care at the emergency department for intermittent fevers that started within 6 days of receiving his second dose of the BNT162b2 mRNA COVID-19 vaccine (Pfizer/BioNTech). After an unremarkable work-up, he was discharged home. Six days later, he returned to the emergency department with a fever of 102 °F and new-onset, progressive tremors in all 4 of his extremities.
The patient had a history of rheumatoid arthritis, for which he was taking oral methotrexate 15 mg once weekly and golimumab 50 mg SQ once monthly, and atrial fibrillation. He’d also had mechanical aortic and mitral valves implanted and was taking warfarin (9 mg/d on weekdays, 6 mg/d on Saturday and Sunday). Aside from his fever, his vital signs were normal. He also had horizontal nystagmus (chronically present) and diffuse tremors/myoclonic movements throughout his upper and lower extremities. The tremors were present at rest and worsened with intention/activity, which affected the patient’s ability to walk and perform activities of daily living.
He was admitted the next day to the family medicine service for further evaluation. Neurology and infectious disease consultations were requested, and a broad initial work-up was undertaken. Hyperreflexia was present in all of his extremities, but his neurologic examination was otherwise normal. Initial laboratory tests demonstrated leukocytosis and elevated liver transaminases. His international normalized ratio (INR) and prothrombin time (PT) also were elevated (> 8 [goal, 2.5-3.5 for mechanical heart valves] and > 90 seconds [normal range, 9.7-13.0 seconds], respectively), thus his warfarin was held and oral vitamin K was started (initial dose of 2.5 mg, which was increased to 5 mg when his INR did not decrease enough).
By Day 2, his INR and PT had normalized enough to reinitiate his warfarin dosing. Results from the viral antibody and polymerase chain reaction testing indicated the presence of cytomegalovirus (CMV) infection with viremia; blood cultures for bacterial infection were negative. Brain magnetic resonance imaging was ordered and identified a small, acute left-side cerebellar stroke. Lumbar puncture also was ordered but deferred until his INR was below 1.5 (on Day 8), at which point it confirmed the absence of CMV or herpes simplex virus in his central nervous system.
THE DIAGNOSIS
The patient started oral valganciclovir 900 mg twice daily to ameliorate his tremors, but he did not tolerate it well, vomiting after dosing. He was switched to IV ganciclovir 5 mg/kg every 12 hours; however, his tremors were not improving, leading the team to suspect an etiology other than viral infection. A presumptive diagnosis of autoimmune movement disorder was made, and serum tests were ordered; the results were positive for antiphospholipid antibodies, including anticardiolipin and anti-ß2 glycoprotein-I antibodies. A final diagnosis of autoimmune antiphospholipid antibody syndrome (APS)–related movement disorder1 with coagulopathy was reached, and the patient was started on methylprednisolone 1 g/d IV.
We suspected the CMV viremia was reactivated by the COVID-19 vaccine and caused the APS that led to the movement disorder, coagulopathy, and likely, the thrombotic cerebellar stroke. The case was reported to the Vaccine Adverse Event Reporting System (VAERS).2
DISCUSSION
Continue to: The development of antiphospholipid antibodies...
The development of antiphospholipid antibodies has been independently associated with rheumatoid arthritis,5 COVID-19,6 and CMV infection,7 as well as with vaccination for influenza and tetanus.8 There also are reports of antiphospholipid antibodies occurring in patients who have received adenovirus-vectored and mRNA COVID-19 vaccines.9-11
Movement disorders occurring with APS are unusual, with approximately 1.3% to 4.5% of patients with APS demonstrating this manifestation.12 One of multiple autoimmune-related movement disorders, APS-related movement disorder is most commonly associated with systemic lupus erythematosus (SLE), although it can occur outside an SLE diagnosis.4
While APS-related movement disorder occurs with the presence of antiphospholipid antibodies, the pathogenesis of the movement disorder is unclear.4 Patients are typically young women, and the associated movements are choreiform. The condition often occurs with coagulopathy and arterial thrombosis.4 Psychiatric manifestations also can occur, including changes in behavior—up to and including psychosis.4
Evidence of COVID-19 vaccination reactivating herpesviruses exists, although it is rare and usually does not cause serious health outcomes.13 The annual incidence of reactivation related to vaccination is estimated to be 0.7 per 100,000 for varicella zoster virus and 0.03 per 100,000 for herpes simplex virus.13 The literature also suggests that the occurrence of Bell palsy—the onset of which may be related to the reactivation of a latent virus—may increase in relation to particular COVID-19 vaccines.14,15 Although there is no confirmed explanation for these reactivation events at this time, different theories related to altering the focus of immune cells from latent disease to the newly generated antigen have been suggested.16
To date, reactivation has not been demonstrated with CMV specifically. However, based on the literature reviewed here on the reactivation of herpesviruses and the temporal relationship to infection in our patient, we propose that the BNT162b2 mRNA vaccination reactivated his CMV infection and led to his APS-related movement disorder.
Continue to: Treatment is focused on resolved the autoimmune condition
Treatment is focused on resolving the autoimmune condition, usually with corticosteroids. Longer-term treatment of the movement disorder with antiepileptics such as carbamazepine and valproic acid may be necessary.4
Our patient received methylprednisolone IV 1 g/d for 3 days and responded quickly to the treatment. He was discharged to a post-acute rehabilitation hospital on Day 16 with a plan for 21 days of antiviral treatment for an acute CMV infection, 1 month of oral steroid taper for the APS, and continued warfarin treatment. This regimen resulted in complete resolution of his movement disorder and negative testing of antiphospholipid antibodies 16 days after he was discharged from the hospital.
THE TAKEAWAY
This case illustrates the possible reactivation of a herpesvirus (CMV) related to COVID-19 vaccination, as well as the development of APS-related movement disorder and coagulopathy related to acute CMV infection with viremia. Vaccination for the COVID-19 virus is seen as the best intervention available for preventing serious illness and death associated with COVID-19 infection. Thus, it is important to be aware of these unusual events when vaccinating large populations. This case also demonstrates the need to understand the interplay of immune status and possible disorders associated with autoimmune conditions. Keeping an open mind when evaluating patients with post-vaccination complaints is beneficial—especially given the volume of distrust and misinformation associated with COVID-19 vaccination.
CORRESPONDENCE
Aaron Lear, MD, MSc, CAQ, Cleveland Clinic Akron General Center for Family Medicine, 1 Akron General Avenue, Building 301, Akron, OH 44307; Leara@ccf.org
1. Martino D, Chew N-K, Mir P, et al. Atypical movement disorders in antiphospholipid syndrome. 2006;21:944-949. doi: 10.1002/mds.20842
2. Vaccine Adverse Event Reporting System. Accessed February 9, 2022. vaers.hhs.gov
3. Duarte-García A, Pham MM, Crowson CS, et al. The epidemiology of antiphospholipid syndrome: a population-based Study. Arthritis Rheumatol. 2019;71:1545-1552. doi: 10.1002/art.40901
4. Baizabal-Carvallo JF, Jankovic J. Autoimmune and paraneoplastic movement disorders: an update. J Neurol Sci. 2018;385:175-184. doi: 10.1016/j.jns.2017.12.035
5. O’Leary RE, Hsiao JL, Worswick SD. Antiphospholipid syndrome in a patient with rheumatoid arthritis. Cutis. 2017;99:E21-E24.
6. Taha M, Samavati L. Antiphospholipid antibodies in COVID-19: a meta-analysis and systematic review. RMD Open. 2021;7:e001580. doi: 10.1136/rmdopen-2021-001580
7. Nakayama T, Akahoshi M, Irino K, et al. Transient antiphospholipid syndrome associated with primary cytomegalovirus infection: a case report and literature review. Case Rep Rheumatol. 2014;2014:27154. doi: 10.1155/2014/271548
8. Cruz-Tapias P, Blank M, Anaya J-M, et al. Infections and vaccines in the etiology of antiphospholipid syndrome. Curr Opin Rheumatol. 2012;24:389-393. doi: 10.1097/BOR.0b013e32835448b8
9. Schultz NH, Sørvoll IH, Michelsen AE, et al. Thrombosis and thrombocytopenia after ChAdOx1 nCoV-19 vaccination. N Engl J Med. 2021;384:2124-2130. doi: 10.1056/nejmoa2104882
10. Cimolai N. Untangling the intricacies of infection, thrombosis, vaccination, and antiphospholipid antibodies for COVID-19. SN Compr Clin Med. 2021;3:2093-2108. doi: 10.1007/s42399-021-00992-3
11. Jinno S, Naka I, Nakazawa T. Catastrophic antiphospholipid syndrome complicated with essential thrombocythaemia after COVID-19 vaccination: in search of the underlying mechanism. Rheumatol Adv Pract. 2021;5:rkab096. doi: 10.1093/rap/rkab096
12. Ricarte IF, Dutra LA, Abrantes FF, et al. Neurologic manifestations of antiphospholipid syndrome. Lupus. 2018;27:1404-1414. doi: 10.1177/0961203318776110
13. Gringeri M, Battini V, Cammarata G, et al. Herpes zoster and simplex reactivation following COVID-19 vaccination: new insights from a vaccine adverse event reporting system (VAERS) database analysis. Expert Rev Vaccines. 2022;21:675-684. doi: 10.1080/14760584.2022.2044799
14. Cirillo N, Doan R. The association between COVID-19 vaccination and Bell’s palsy. Lancet Infect Dis. 2022;22:5-6. doi: 10.1016/s1473-3099(21)00467-9
15. Poudel S, Nepali P, Baniya S, et al. Bell’s palsy as a possible complication of mRNA-1273 (Moderna) vaccine against COVID-19. Ann Med Surg (Lond). 2022;78:103897. doi: 10.1016/j.amsu.2022.103897
16. Furer V, Zisman D, Kibari A, et al. Herpes zoster following BNT162b2 mRNA COVID-19 vaccination in patients with autoimmune inflammatory rheumatic diseases: a case series. Rheumatology (Oxford). 2021;60:SI90-SI95. doi: 10.1093/rheumatology/keab345
THE CASE
A 52-year-old man sought care at the emergency department for intermittent fevers that started within 6 days of receiving his second dose of the BNT162b2 mRNA COVID-19 vaccine (Pfizer/BioNTech). After an unremarkable work-up, he was discharged home. Six days later, he returned to the emergency department with a fever of 102 °F and new-onset, progressive tremors in all 4 of his extremities.
The patient had a history of rheumatoid arthritis, for which he was taking oral methotrexate 15 mg once weekly and golimumab 50 mg SQ once monthly, and atrial fibrillation. He’d also had mechanical aortic and mitral valves implanted and was taking warfarin (9 mg/d on weekdays, 6 mg/d on Saturday and Sunday). Aside from his fever, his vital signs were normal. He also had horizontal nystagmus (chronically present) and diffuse tremors/myoclonic movements throughout his upper and lower extremities. The tremors were present at rest and worsened with intention/activity, which affected the patient’s ability to walk and perform activities of daily living.
He was admitted the next day to the family medicine service for further evaluation. Neurology and infectious disease consultations were requested, and a broad initial work-up was undertaken. Hyperreflexia was present in all of his extremities, but his neurologic examination was otherwise normal. Initial laboratory tests demonstrated leukocytosis and elevated liver transaminases. His international normalized ratio (INR) and prothrombin time (PT) also were elevated (> 8 [goal, 2.5-3.5 for mechanical heart valves] and > 90 seconds [normal range, 9.7-13.0 seconds], respectively), thus his warfarin was held and oral vitamin K was started (initial dose of 2.5 mg, which was increased to 5 mg when his INR did not decrease enough).
By Day 2, his INR and PT had normalized enough to reinitiate his warfarin dosing. Results from the viral antibody and polymerase chain reaction testing indicated the presence of cytomegalovirus (CMV) infection with viremia; blood cultures for bacterial infection were negative. Brain magnetic resonance imaging was ordered and identified a small, acute left-side cerebellar stroke. Lumbar puncture also was ordered but deferred until his INR was below 1.5 (on Day 8), at which point it confirmed the absence of CMV or herpes simplex virus in his central nervous system.
THE DIAGNOSIS
The patient started oral valganciclovir 900 mg twice daily to ameliorate his tremors, but he did not tolerate it well, vomiting after dosing. He was switched to IV ganciclovir 5 mg/kg every 12 hours; however, his tremors were not improving, leading the team to suspect an etiology other than viral infection. A presumptive diagnosis of autoimmune movement disorder was made, and serum tests were ordered; the results were positive for antiphospholipid antibodies, including anticardiolipin and anti-ß2 glycoprotein-I antibodies. A final diagnosis of autoimmune antiphospholipid antibody syndrome (APS)–related movement disorder1 with coagulopathy was reached, and the patient was started on methylprednisolone 1 g/d IV.
We suspected the CMV viremia was reactivated by the COVID-19 vaccine and caused the APS that led to the movement disorder, coagulopathy, and likely, the thrombotic cerebellar stroke. The case was reported to the Vaccine Adverse Event Reporting System (VAERS).2
DISCUSSION
Continue to: The development of antiphospholipid antibodies...
The development of antiphospholipid antibodies has been independently associated with rheumatoid arthritis,5 COVID-19,6 and CMV infection,7 as well as with vaccination for influenza and tetanus.8 There also are reports of antiphospholipid antibodies occurring in patients who have received adenovirus-vectored and mRNA COVID-19 vaccines.9-11
Movement disorders occurring with APS are unusual, with approximately 1.3% to 4.5% of patients with APS demonstrating this manifestation.12 One of multiple autoimmune-related movement disorders, APS-related movement disorder is most commonly associated with systemic lupus erythematosus (SLE), although it can occur outside an SLE diagnosis.4
While APS-related movement disorder occurs with the presence of antiphospholipid antibodies, the pathogenesis of the movement disorder is unclear.4 Patients are typically young women, and the associated movements are choreiform. The condition often occurs with coagulopathy and arterial thrombosis.4 Psychiatric manifestations also can occur, including changes in behavior—up to and including psychosis.4
Evidence of COVID-19 vaccination reactivating herpesviruses exists, although it is rare and usually does not cause serious health outcomes.13 The annual incidence of reactivation related to vaccination is estimated to be 0.7 per 100,000 for varicella zoster virus and 0.03 per 100,000 for herpes simplex virus.13 The literature also suggests that the occurrence of Bell palsy—the onset of which may be related to the reactivation of a latent virus—may increase in relation to particular COVID-19 vaccines.14,15 Although there is no confirmed explanation for these reactivation events at this time, different theories related to altering the focus of immune cells from latent disease to the newly generated antigen have been suggested.16
To date, reactivation has not been demonstrated with CMV specifically. However, based on the literature reviewed here on the reactivation of herpesviruses and the temporal relationship to infection in our patient, we propose that the BNT162b2 mRNA vaccination reactivated his CMV infection and led to his APS-related movement disorder.
Continue to: Treatment is focused on resolved the autoimmune condition
Treatment is focused on resolving the autoimmune condition, usually with corticosteroids. Longer-term treatment of the movement disorder with antiepileptics such as carbamazepine and valproic acid may be necessary.4
Our patient received methylprednisolone IV 1 g/d for 3 days and responded quickly to the treatment. He was discharged to a post-acute rehabilitation hospital on Day 16 with a plan for 21 days of antiviral treatment for an acute CMV infection, 1 month of oral steroid taper for the APS, and continued warfarin treatment. This regimen resulted in complete resolution of his movement disorder and negative testing of antiphospholipid antibodies 16 days after he was discharged from the hospital.
THE TAKEAWAY
This case illustrates the possible reactivation of a herpesvirus (CMV) related to COVID-19 vaccination, as well as the development of APS-related movement disorder and coagulopathy related to acute CMV infection with viremia. Vaccination for the COVID-19 virus is seen as the best intervention available for preventing serious illness and death associated with COVID-19 infection. Thus, it is important to be aware of these unusual events when vaccinating large populations. This case also demonstrates the need to understand the interplay of immune status and possible disorders associated with autoimmune conditions. Keeping an open mind when evaluating patients with post-vaccination complaints is beneficial—especially given the volume of distrust and misinformation associated with COVID-19 vaccination.
CORRESPONDENCE
Aaron Lear, MD, MSc, CAQ, Cleveland Clinic Akron General Center for Family Medicine, 1 Akron General Avenue, Building 301, Akron, OH 44307; Leara@ccf.org
THE CASE
A 52-year-old man sought care at the emergency department for intermittent fevers that started within 6 days of receiving his second dose of the BNT162b2 mRNA COVID-19 vaccine (Pfizer/BioNTech). After an unremarkable work-up, he was discharged home. Six days later, he returned to the emergency department with a fever of 102 °F and new-onset, progressive tremors in all 4 of his extremities.
The patient had a history of rheumatoid arthritis, for which he was taking oral methotrexate 15 mg once weekly and golimumab 50 mg SQ once monthly, and atrial fibrillation. He’d also had mechanical aortic and mitral valves implanted and was taking warfarin (9 mg/d on weekdays, 6 mg/d on Saturday and Sunday). Aside from his fever, his vital signs were normal. He also had horizontal nystagmus (chronically present) and diffuse tremors/myoclonic movements throughout his upper and lower extremities. The tremors were present at rest and worsened with intention/activity, which affected the patient’s ability to walk and perform activities of daily living.
He was admitted the next day to the family medicine service for further evaluation. Neurology and infectious disease consultations were requested, and a broad initial work-up was undertaken. Hyperreflexia was present in all of his extremities, but his neurologic examination was otherwise normal. Initial laboratory tests demonstrated leukocytosis and elevated liver transaminases. His international normalized ratio (INR) and prothrombin time (PT) also were elevated (> 8 [goal, 2.5-3.5 for mechanical heart valves] and > 90 seconds [normal range, 9.7-13.0 seconds], respectively), thus his warfarin was held and oral vitamin K was started (initial dose of 2.5 mg, which was increased to 5 mg when his INR did not decrease enough).
By Day 2, his INR and PT had normalized enough to reinitiate his warfarin dosing. Results from the viral antibody and polymerase chain reaction testing indicated the presence of cytomegalovirus (CMV) infection with viremia; blood cultures for bacterial infection were negative. Brain magnetic resonance imaging was ordered and identified a small, acute left-side cerebellar stroke. Lumbar puncture also was ordered but deferred until his INR was below 1.5 (on Day 8), at which point it confirmed the absence of CMV or herpes simplex virus in his central nervous system.
THE DIAGNOSIS
The patient started oral valganciclovir 900 mg twice daily to ameliorate his tremors, but he did not tolerate it well, vomiting after dosing. He was switched to IV ganciclovir 5 mg/kg every 12 hours; however, his tremors were not improving, leading the team to suspect an etiology other than viral infection. A presumptive diagnosis of autoimmune movement disorder was made, and serum tests were ordered; the results were positive for antiphospholipid antibodies, including anticardiolipin and anti-ß2 glycoprotein-I antibodies. A final diagnosis of autoimmune antiphospholipid antibody syndrome (APS)–related movement disorder1 with coagulopathy was reached, and the patient was started on methylprednisolone 1 g/d IV.
We suspected the CMV viremia was reactivated by the COVID-19 vaccine and caused the APS that led to the movement disorder, coagulopathy, and likely, the thrombotic cerebellar stroke. The case was reported to the Vaccine Adverse Event Reporting System (VAERS).2
DISCUSSION
Continue to: The development of antiphospholipid antibodies...
The development of antiphospholipid antibodies has been independently associated with rheumatoid arthritis,5 COVID-19,6 and CMV infection,7 as well as with vaccination for influenza and tetanus.8 There also are reports of antiphospholipid antibodies occurring in patients who have received adenovirus-vectored and mRNA COVID-19 vaccines.9-11
Movement disorders occurring with APS are unusual, with approximately 1.3% to 4.5% of patients with APS demonstrating this manifestation.12 One of multiple autoimmune-related movement disorders, APS-related movement disorder is most commonly associated with systemic lupus erythematosus (SLE), although it can occur outside an SLE diagnosis.4
While APS-related movement disorder occurs with the presence of antiphospholipid antibodies, the pathogenesis of the movement disorder is unclear.4 Patients are typically young women, and the associated movements are choreiform. The condition often occurs with coagulopathy and arterial thrombosis.4 Psychiatric manifestations also can occur, including changes in behavior—up to and including psychosis.4
Evidence of COVID-19 vaccination reactivating herpesviruses exists, although it is rare and usually does not cause serious health outcomes.13 The annual incidence of reactivation related to vaccination is estimated to be 0.7 per 100,000 for varicella zoster virus and 0.03 per 100,000 for herpes simplex virus.13 The literature also suggests that the occurrence of Bell palsy—the onset of which may be related to the reactivation of a latent virus—may increase in relation to particular COVID-19 vaccines.14,15 Although there is no confirmed explanation for these reactivation events at this time, different theories related to altering the focus of immune cells from latent disease to the newly generated antigen have been suggested.16
To date, reactivation has not been demonstrated with CMV specifically. However, based on the literature reviewed here on the reactivation of herpesviruses and the temporal relationship to infection in our patient, we propose that the BNT162b2 mRNA vaccination reactivated his CMV infection and led to his APS-related movement disorder.
Continue to: Treatment is focused on resolved the autoimmune condition
Treatment is focused on resolving the autoimmune condition, usually with corticosteroids. Longer-term treatment of the movement disorder with antiepileptics such as carbamazepine and valproic acid may be necessary.4
Our patient received methylprednisolone IV 1 g/d for 3 days and responded quickly to the treatment. He was discharged to a post-acute rehabilitation hospital on Day 16 with a plan for 21 days of antiviral treatment for an acute CMV infection, 1 month of oral steroid taper for the APS, and continued warfarin treatment. This regimen resulted in complete resolution of his movement disorder and negative testing of antiphospholipid antibodies 16 days after he was discharged from the hospital.
THE TAKEAWAY
This case illustrates the possible reactivation of a herpesvirus (CMV) related to COVID-19 vaccination, as well as the development of APS-related movement disorder and coagulopathy related to acute CMV infection with viremia. Vaccination for the COVID-19 virus is seen as the best intervention available for preventing serious illness and death associated with COVID-19 infection. Thus, it is important to be aware of these unusual events when vaccinating large populations. This case also demonstrates the need to understand the interplay of immune status and possible disorders associated with autoimmune conditions. Keeping an open mind when evaluating patients with post-vaccination complaints is beneficial—especially given the volume of distrust and misinformation associated with COVID-19 vaccination.
CORRESPONDENCE
Aaron Lear, MD, MSc, CAQ, Cleveland Clinic Akron General Center for Family Medicine, 1 Akron General Avenue, Building 301, Akron, OH 44307; Leara@ccf.org
1. Martino D, Chew N-K, Mir P, et al. Atypical movement disorders in antiphospholipid syndrome. 2006;21:944-949. doi: 10.1002/mds.20842
2. Vaccine Adverse Event Reporting System. Accessed February 9, 2022. vaers.hhs.gov
3. Duarte-García A, Pham MM, Crowson CS, et al. The epidemiology of antiphospholipid syndrome: a population-based Study. Arthritis Rheumatol. 2019;71:1545-1552. doi: 10.1002/art.40901
4. Baizabal-Carvallo JF, Jankovic J. Autoimmune and paraneoplastic movement disorders: an update. J Neurol Sci. 2018;385:175-184. doi: 10.1016/j.jns.2017.12.035
5. O’Leary RE, Hsiao JL, Worswick SD. Antiphospholipid syndrome in a patient with rheumatoid arthritis. Cutis. 2017;99:E21-E24.
6. Taha M, Samavati L. Antiphospholipid antibodies in COVID-19: a meta-analysis and systematic review. RMD Open. 2021;7:e001580. doi: 10.1136/rmdopen-2021-001580
7. Nakayama T, Akahoshi M, Irino K, et al. Transient antiphospholipid syndrome associated with primary cytomegalovirus infection: a case report and literature review. Case Rep Rheumatol. 2014;2014:27154. doi: 10.1155/2014/271548
8. Cruz-Tapias P, Blank M, Anaya J-M, et al. Infections and vaccines in the etiology of antiphospholipid syndrome. Curr Opin Rheumatol. 2012;24:389-393. doi: 10.1097/BOR.0b013e32835448b8
9. Schultz NH, Sørvoll IH, Michelsen AE, et al. Thrombosis and thrombocytopenia after ChAdOx1 nCoV-19 vaccination. N Engl J Med. 2021;384:2124-2130. doi: 10.1056/nejmoa2104882
10. Cimolai N. Untangling the intricacies of infection, thrombosis, vaccination, and antiphospholipid antibodies for COVID-19. SN Compr Clin Med. 2021;3:2093-2108. doi: 10.1007/s42399-021-00992-3
11. Jinno S, Naka I, Nakazawa T. Catastrophic antiphospholipid syndrome complicated with essential thrombocythaemia after COVID-19 vaccination: in search of the underlying mechanism. Rheumatol Adv Pract. 2021;5:rkab096. doi: 10.1093/rap/rkab096
12. Ricarte IF, Dutra LA, Abrantes FF, et al. Neurologic manifestations of antiphospholipid syndrome. Lupus. 2018;27:1404-1414. doi: 10.1177/0961203318776110
13. Gringeri M, Battini V, Cammarata G, et al. Herpes zoster and simplex reactivation following COVID-19 vaccination: new insights from a vaccine adverse event reporting system (VAERS) database analysis. Expert Rev Vaccines. 2022;21:675-684. doi: 10.1080/14760584.2022.2044799
14. Cirillo N, Doan R. The association between COVID-19 vaccination and Bell’s palsy. Lancet Infect Dis. 2022;22:5-6. doi: 10.1016/s1473-3099(21)00467-9
15. Poudel S, Nepali P, Baniya S, et al. Bell’s palsy as a possible complication of mRNA-1273 (Moderna) vaccine against COVID-19. Ann Med Surg (Lond). 2022;78:103897. doi: 10.1016/j.amsu.2022.103897
16. Furer V, Zisman D, Kibari A, et al. Herpes zoster following BNT162b2 mRNA COVID-19 vaccination in patients with autoimmune inflammatory rheumatic diseases: a case series. Rheumatology (Oxford). 2021;60:SI90-SI95. doi: 10.1093/rheumatology/keab345
1. Martino D, Chew N-K, Mir P, et al. Atypical movement disorders in antiphospholipid syndrome. 2006;21:944-949. doi: 10.1002/mds.20842
2. Vaccine Adverse Event Reporting System. Accessed February 9, 2022. vaers.hhs.gov
3. Duarte-García A, Pham MM, Crowson CS, et al. The epidemiology of antiphospholipid syndrome: a population-based Study. Arthritis Rheumatol. 2019;71:1545-1552. doi: 10.1002/art.40901
4. Baizabal-Carvallo JF, Jankovic J. Autoimmune and paraneoplastic movement disorders: an update. J Neurol Sci. 2018;385:175-184. doi: 10.1016/j.jns.2017.12.035
5. O’Leary RE, Hsiao JL, Worswick SD. Antiphospholipid syndrome in a patient with rheumatoid arthritis. Cutis. 2017;99:E21-E24.
6. Taha M, Samavati L. Antiphospholipid antibodies in COVID-19: a meta-analysis and systematic review. RMD Open. 2021;7:e001580. doi: 10.1136/rmdopen-2021-001580
7. Nakayama T, Akahoshi M, Irino K, et al. Transient antiphospholipid syndrome associated with primary cytomegalovirus infection: a case report and literature review. Case Rep Rheumatol. 2014;2014:27154. doi: 10.1155/2014/271548
8. Cruz-Tapias P, Blank M, Anaya J-M, et al. Infections and vaccines in the etiology of antiphospholipid syndrome. Curr Opin Rheumatol. 2012;24:389-393. doi: 10.1097/BOR.0b013e32835448b8
9. Schultz NH, Sørvoll IH, Michelsen AE, et al. Thrombosis and thrombocytopenia after ChAdOx1 nCoV-19 vaccination. N Engl J Med. 2021;384:2124-2130. doi: 10.1056/nejmoa2104882
10. Cimolai N. Untangling the intricacies of infection, thrombosis, vaccination, and antiphospholipid antibodies for COVID-19. SN Compr Clin Med. 2021;3:2093-2108. doi: 10.1007/s42399-021-00992-3
11. Jinno S, Naka I, Nakazawa T. Catastrophic antiphospholipid syndrome complicated with essential thrombocythaemia after COVID-19 vaccination: in search of the underlying mechanism. Rheumatol Adv Pract. 2021;5:rkab096. doi: 10.1093/rap/rkab096
12. Ricarte IF, Dutra LA, Abrantes FF, et al. Neurologic manifestations of antiphospholipid syndrome. Lupus. 2018;27:1404-1414. doi: 10.1177/0961203318776110
13. Gringeri M, Battini V, Cammarata G, et al. Herpes zoster and simplex reactivation following COVID-19 vaccination: new insights from a vaccine adverse event reporting system (VAERS) database analysis. Expert Rev Vaccines. 2022;21:675-684. doi: 10.1080/14760584.2022.2044799
14. Cirillo N, Doan R. The association between COVID-19 vaccination and Bell’s palsy. Lancet Infect Dis. 2022;22:5-6. doi: 10.1016/s1473-3099(21)00467-9
15. Poudel S, Nepali P, Baniya S, et al. Bell’s palsy as a possible complication of mRNA-1273 (Moderna) vaccine against COVID-19. Ann Med Surg (Lond). 2022;78:103897. doi: 10.1016/j.amsu.2022.103897
16. Furer V, Zisman D, Kibari A, et al. Herpes zoster following BNT162b2 mRNA COVID-19 vaccination in patients with autoimmune inflammatory rheumatic diseases: a case series. Rheumatology (Oxford). 2021;60:SI90-SI95. doi: 10.1093/rheumatology/keab345
► Intermittent fevers
► Recently received second dose of COVID-19 vaccine
► Tremors in all 4 extremities
Inadequate sleep & obesity: Breaking the vicious cycle
Sleep is fundamental to overall health and longevity, with the average person spending about one-third of their life sleeping.1 Adequate sleep is critical for optimal cognition, memory consolidation, mood regulation, metabolism, appetite regulation, and immune and hormone functioning. According to the American Academy of Sleep Medicine and the Sleep Research Society, adults should sleep at least 7 hours per night on a regular basis “to promote optimal health.”2 Yet, between 2013 and 2020, only about 65% of adults in the United States were meeting this amount.3 Insufficient sleep is associated with an increased risk for chronic health conditions, including obesity, diabetes, cardiovascular diseases, and even premature death.4
In a population-based longitudinal study of sleep disorders, short sleep duration was associated with increased body mass index (BMI), low blood levels of leptin, and high ghrelin levels.5 In addition to physical impairments, poor sleep can impair cognitive performance and lead to vehicular accidents and increased accidents at work.4 The potential economic impact that this may have is significant, and includes increased costs and loss of productivity in the workplace.6
Many factors may contribute to short sleep duration: environment, mental and physical condition, and social influences such as occupation, family responsibilities, travel, group activities, and personal care. Furthermore, the rapidly evolving and developing media, communication, and entertainment industries are already strongly implicated in poor sleep quality and quantity, both contributing to excessive daytime sleepiness.7 Poor sleep quality is most notable in modern societies, and it correlates with the increasing prevalence of obesity, likely due to sleep’s effect on food consumption and physical activity.8 Optimizing a person’s sleep will improve overall health and longevity by inhibiting the development of chronic disease.
How insufficient sleep raises the risk for obesity
Not only is sleep beneficial for brain health, memory, learning, and growth, its effect on food consumption and physical activity likely correlates with the increased prevalence of obesity in modern society. Yet the optimal amount of sleep is controversial, and current recommendations of 7 or more hours of sleep per night for adults are derived from expert panels only.2 The recommended sleep duration for children is longer, and it varies by age.9 The quality of sleep and its impact on neuroendocrine hormones, not just the quantity of sleep, needs to be factored into these recommendations.
Sleep restriction activates the orexigenic system via the hormones leptin and ghrelin. These hormones control the food reward system, essentially increasing hunger and food intake. Leptin, created by white adipose tissue, is responsible for satiety and decreased food consumption.10 Ghrelin, made by oxyntic glands in the stomach, is responsible for the sensation of hunger.
In a 2004 study by Spiegel et al,11 leptin and ghrelin levels were measured during 2 days of sleep restriction (4 hours in bed) and sleep extension (10 hours in bed). Sleep restriction was associated with a decrease in leptin levels and an increase in ghrelin levels. The researchers reported that participants experienced an increase in hunger and appetite—especially for calorie-dense foods with high carbohydrate content.
Although research design has limitations with predominantly self-reported sleep data, studies have shown that short sleep time leads to increased food intake by increasing hunger signals and craving of unhealthy foods, and by providing more opportunities to eat while awake. It also may lead to decreased physical activity, creating a sedentary lifestyle that further encourages obesity.8 Reduced sleep is even correlated to decreased efficacy of weight-loss treatments.12
Continue to: Other sleep characteristics weakly correlated with obesity
Other sleep characteristics weakly correlated with obesity are sleep variability, timing, efficiency, quality, and daytime napping.8 Sleep variability causes dysregulation of eating patterns, leading to increased food intake. A shift to later sleep and waking times often results in higher consumption of calories after 8
Poor sleep efficiency and quality decreases N3-stage (deep non-REM) sleep, affects the autonomic nervous system, and has been associated with increased abdominal obesity. Daytime napping, which can cause irregular circadian rhythms and sleep schedules, is associated with increased obesity.15 Thus, each component of sleep needs to be assessed to promote optimal regulation of the orexigenic system.
Another study showed that inadequate sleep not only promotes unhealthy lifestyle habits that can lead to obesity but also decreases the ability to lose weight.16 This small study with 10 overweight patients provided its subjects with a controlled caloric intake over 2 weeks. Patients spent two 14-day periods 3 months apart in the laboratory, divided into 2 time-in-bed arms of 8.5 and 5.5 hours per night. Neuroendocrine changes caused by decreased sleep were associated with a significant lean body mass loss while conserving energy-dense fat.16 This study highlights the importance of sleep hygiene counseling when developing a weight-management plan with patients.
Sleep, and its many components, play an integral role in the prevention and treatment of obesity.17 Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.
The sleep–obesity link in children and the elderly
Childhood obesity is linked to several chronic diseases in adulthood, including type 2 diabetes, cardiovascular disease, nonalcoholic fatty liver disease, asthma, and obstructive sleep apnea (OSA).18 According to 2017-2018 NHANES (National Health and Nutrition Examination Surveys) data, obesity (BMI ≥ 95th percentile) prevalence among children and adolescents was reported at 19.3% and severe obesity (BMI ≥ 120% of the 95th percentile) at 6.1%. Pediatric overweight prevalence (≥ 85th percentile and < 95th percentile) was 16.1%.19
Continue to: Although poor sleep is associated...
Although poor sleep is associated with increased risk for obesity, there is no proven cause-effect relationship.20 Nutrition and physical activity have been identified as 2 critical factors in childhood obesity, but sleep health also needs to be investigated. Shorter sleep duration is strongly associated with the development of obesity. Furthermore, children with obesity are more likely to have shorter sleep duration.21 A short sleep duration alters plasma levels of insulin, low-density lipoprotein, and high-sensitivity C-reactive protein. It is associated with lower diet quality, an increased intake of nutrient-poor foods, and a lower intake of vegetables and fruits.22 Recent studies have shown that interventions to promote earlier bedtimes can improve sleep duration in children.
Older adults have many sleeping issues, including insomnia, circadian rhythm sleep-wake disorders, sleep-related movement disorders, and sleep-breathing disorders. Additionally, the older population has increased sleep latency, decreased sleep efficiency and total sleep time, decreased REM sleep, more frequent nighttime awakenings, and more daytime napping.23 The increased sleep disturbance with age is mainly related to higher risk factors for sleep disorders than the aging process itself. Sleeping 5 or fewer hours is associated with an increased risk for obesity and central abdominal fat compared with those who sleep 7 to 8 hours per night.24 Similar to children and youth, older adults also show a strong correlation between inadequate sleep and obesity.24
The consequence: A vicious cycle
Obesity in turn leads to shorter sleep duration and more disruptions. This negatively affects the orexigenic system, and the resulting hormonal derangement promotes worsening obesity. It is a cycle of poor sleep causing obesity and obesity causing poor sleep. Insomnia, in combination with shorter (and longer) sleep times, also has been linked with obesity.25 These patients experience more daytime sleepiness, fatigue, and nighttime sleep disturbances, all correlated with decreased quality of life and higher prevalence of medical comorbidities.8,26 Additional comorbidities secondary to obesity, including gastroesophageal reflux, depression, and asthma, also have been linked to sleep disturbances.8
OSA is a common sleep complication associated with obesity. With the increasing prevalence of obesity, the prevalence of OSA is rising.8,27 Factors that heighten the risk for OSA are male sex, age 40 to 70 years, postmenopausal status, elevated BMI, and craniofacial and upper airway abnormality.28 However, the US Preventive Services Task Force found insufficient evidence to screen for or treat OSA in asymptomatic adults.28 Signs and symptoms of OSA include nighttime awakenings with choking, loud snoring, and feeling unrefreshed after sleep.29
OSA is caused by the intermittent narrowing and obstruction of the pharyngeal airway due to anatomical and structural irregularities or neuromuscular impairments. Untreated OSA is associated with cardiovascular disease and cardiac arrhythmias such as atrial fibrillation. Even with this correlation between obesity and sleep, it is estimated that 80% of OSA remains undiagnosed.30 Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.31 Screening tools that have been validated are the STOP, STOP-BANG, Epworth Sleepiness Scale, and 4-Variable Screening Tool. However, the US Department of Veterans Affairs and the US Department of Defense have a more recent guideline recommending STOP as an easier-to-administer screen for OSA.32 A positive result with a screening tool should be confirmed with polysomnography.32
Continue to: Intervention for OSA
Intervention for OSA. The longest randomized controlled study to date, Sleep AHEAD, evaluated over a period of 10 years the effect of weight loss on OSA severity achieved with either an intensive lifestyle intervention (ILI) or with diabetes support and education (DSE).33 OSA severity is rated on an Apnea-Hypopnea Index (AHI), with scores reflecting the number of sleep apnea events per hour. This study demonstrated that weight loss was associated with decreased OSA severity. At 4-year follow-up, the greater the weight loss with ILI intervention, the lower the patients’ OSA severity scores. The study found an average decrease in AHI of 0.68 events per hour for every kilogram of weight loss in the ILI group (P < .0001).33,34 Over the follow-up visits, the ILI participants had 7.4 events per hour, a more significantly reduced AHI than the DSE participants (P < .0001).33,34
Additionally, a small cohort of study participants achieved OSA remission (ILI, 34.4%; DSE, 22.2%), indicated by a low AHI score (< 5 events per hour). At the conclusion of the study, OSA severity decreased to a greater degree with ILI intervention.33,34
Alcohol and drug use can negatively influence sleep patterns and obesity. Higher alcohol consumption is associated with poorer sleep quality and higher chances of developing short sleep duration and snoring.35 Alcohol, a muscle relaxant, causes upper airway narrowing and reduced tongue muscle tone, thereby increasing snoring and OSA as demonstrated by increased AHI on polysomnography after alcohol intake. Alcohol also changes sleep architecture by increasing slow-wave sleep, decreasing REM sleep duration, and increasing sleep arousal in the second half of the night.36 Disrupted circadian rhythm after alcohol consumption was correlated with increased adenosine neurotransmitters derived from ethanol metabolism.37 Alcohol dependence may be related to other psychiatric symptoms, and chronic alcohol use eventually alters sleep mechanisms leading to persistent insomnia, further perpetuating adverse outcomes such as suicidal ideation.36 There are positive associations between beer drinking and measures of abdominal adiposity in men, and “the combination of short sleep duration [and] disinhibited eating … is associated with greater alcohol intake and excess weight.”38
Therefore, counsel patients to avoid alcohol since it is a modifiable risk factor with pervasive adverse health effects.
Many drugs have a profound effect on sleep patterns. Illicit drug use in particular can affect the brain’s neurotransmitter serotonin system. For example, ecstasy users have an increased risk for OSA.39 People with cocaine and heroin use disorder tend to have more sleep-maintenance insomnia.40
Continue to: In contrast, those with alcohol...
In contrast, those with alcohol or cannabis use disorder tend to have more sleep-onset insomnia.40 Not only do illicit drugs interrupt sleep, but daily tobacco use also has been correlated with increased insomnia and shorter sleep duration since nicotine is a stimulant.41
Insomnia is commonly treated with sedative antidepressants and hypnotics—eg, mirtazapine and olanzapine—that contribute to weight gain.42 In addition, other common pharmaceuticals used for sleep disorders, such as diphenhydramine, have sedative properties and tend to lead to weight gain.43 Because so many medications affect sleep and weight, carefully review patients’ medication lists and switch offending agents to weight-neutral drugs if possible.
Treatment and tools to improve sleep in patients with obesity
Given the strong correlation between obesity and sleep disorders, validated screening tools should be used to assess sleep quality, including onset and potential symptoms associated with poor sleep (TABLE 144). For weight management to succeed in patients with obesity, it is crucial to address sleep in addition to nutrition and physical activity.17,45
Physical activity has many benefits to overall health, especially for chronic diseases such as type 2 diabetes and hypertension. The Centers for Disease Control and Prevention recommends at least 150 minutes of moderate-intensity aerobic activity or 75 minutes of vigorous-intensity aerobic exercise per week in addition to muscle-strengthening activities 2 or more days per week.46 However, approximately 300 minutes of moderate-
Physical activity and diet in combination are vital, but diet restriction has a more substantial effect on weight loss than physical activity alone.48 Still, physical activity is essential in helping maintain and prevent weight regain.
Continue to: Nonpharmacologic interventions
Nonpharmacologic interventions include promoting greater sleep quality and quantity by emphasizing good sleep hygiene practices. Developing a practical and effective bedtime routine, creating a quiet sleep environment, and practicing healthy daily habits are essential components to sleep hygiene (TABLE 249,50). Relaxation techniques and cognitive behavioral therapy (CBT) also can help. CBT for insomnia (CBT-I) is the first-line intervention for chronic insomnia.51 Sleep restriction is a type of CBT used to treat insomnia, encouraging short-term sleep loss in the hopes of improving insomnia. A trial by Logue et al showed that patients with overweight and obesity randomized to undergo CBT with better sleep hygiene (nonpharmacologic) interventions had a greater mean weight loss percentage (5% vs 2%; P = .04) than did those who received CBT alone.52
Eastern medicine including herbal interventions lack evidence of efficacy and safety. Further studies need to be done on the effects that chamomile, kava, valerian root (Valeriana officinalis), tryptophan, and Wu Ling (from mycelia Xylaria nigripes) might have on sleep.53
Proceed cautiously with medication. The American College of Physicians recommends a shared decision-making approach when considering pharmacologic therapy for chronic insomnia and the American Academy of Sleep Medicine (AASM) offers guidance on options.51,54 However, the evidence behind AASM sleep pharmacologic recommendations is weak, implying a lesser degree of confidence in the outcome and, therefore, in its appropriateness. Thus, it falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia. If indicated, medications suggested to treat sleep onset and sleep maintenance insomnia are eszopiclone, zolpidem, and temazepam. Zaleplon, triazolam, and ramelteon may improve sleep initiation. Suvorexant and doxepin are used for sleep-maintenance insomnia.54 Exploring patient preferences, cost of treatment, health care options, and available resources should all be considered.
CORRESPONDENCE
Ecler Ercole Jaqua, MD, MBA, FAAFP, AGSF, FACLM, DipABOM, Loma Linda University Health, 25455 Barton Road, Suite 206A, Loma Linda, CA 92354; ejaqua@llu.edu
1. Aminoff MJ, Boller F, Swaab DF. We spend about one-third of our life either sleeping or attempting to do so. Handb Clin Neurol. 2011;98:vii. doi: 10.1016/B978-0-444-52006-7.00047-2
2. Watson NF, Badr MS, Belenky G, et al. Recommended amount of sleep for a healthy adult: a joint consensus statement of the American Academy of Sleep Medicine and Sleep Research Society. Sleep. 2015;38:843-844. doi: 10.5665/sleep.4716
3. CDC. Sleep and sleep disorders, adults. Accessed September 21, 2023. www.cdc.gov/sleep/data-and-statistics/adults.html
4. Chattu VK, Manzar MD, Kumary S. The global problem of insufficient sleep and its serious public health implications. Healthcare (Basel). 2019;7:1. doi: 10.3390/healthcare7010001
5. Taheri S, Lin L, Austin D, et al. Short sleep duration is associated with reduced leptin, elevated ghrelin, and increased body mass index. PLoS Med. 2004;1:e62. doi: 10.1371/journal.pmed.0010062
6. Hafner M, Stepanek M, Taylor J, et al. Why sleep matters—the economic costs of insufficient sleep. Rand Health Q. 2017;6:11.
7. Hisler G, Twenge JM, Krizan Z. Associations between screen time and short sleep duration among adolescents varies by media type: evidence from a cohort study. Sleep Med. 2020;66:92-102. doi: 10.1016/j.sleep.2019.08.007
8. Ogilvie RP, Patel SR. The epidemiology of sleep and obesity. Sleep Health. 2017;3:383-388. doi: 10.1016/j.sleh.2017.07.013
9. CDC. Sleep and sleep disorders: How much sleep do I need? Accessed September 21, 2023. www.cdc.gov/sleep/about_sleep/how_much_sleep.html
10. van Egmond LT, Meth EMS, Engström J, et al. Effects of acute sleep loss on leptin, ghrelin, and adiponectin in adults with healthy weight and obesity: a laboratory study. Obesity (Silver Spring). 2023;31:635-641. doi: 10.1002/oby.23616
11. Spiegel K, Tasali E, Penev P, et al. Brief communication: sleep curtailment in healthy young men is associated with decreased leptin levels, elevated ghrelin levels, and increased hunger and appetite. Ann Intern Med. 2004;141:846-850. doi: 10.7326/0003-4819-141-11-200412070-00008
12. Antza C, Kostopoulos G, Mostafa S, et al. The links between sleep duration, obesity and type 2 diabetes mellitus. J Endocrinol. 2021;252:125-141. doi: 10.1530/JOE-21-0155
13. Baron KG, Reid KJ, Kern AS, et al. Role of sleep timing in caloric intake and BMI. Obesity (Silver Spring). 2011;19:1374-1381. doi: 10.1038/oby.2011.100
14. Liu XY, Zheng CL, Xu C, et al. Nighttime snacking is associated with risk of obesity and hyperglycemia in adults: a cross-sectional survey from Chinese adult teachers J Biomed Res. 2017;31:541-547. doi: 10.7555/JBR.31.20160083
15. Cai Z, Yang Y, Zhang J, et al. The relationship between daytime napping and obesity: a systematic review and meta-analysis. Sci Rep. 2023.13:12124. doi: 10.1038/s41598-023-37883-7
16. Nedeltcheva AV, Kilkus JM, Imperial J, et al. Insufficient sleep undermines dietary efforts to reduce adiposity. Ann Intern Med. 2010;153:435-441. doi: 10.7326/0003-4819-153-7-201010050-00006
17. Chaput JP, Tremblay A. Adequate sleep to improve the treatment of obesity. CMAJ. 2012;184:1975-1976. doi: 10.1503/cmaj.120876
18. Kelsey MM, Zaepfel A, Bjornstad P, et al. Age-related consequences of childhood obesity. Gerontology. 2014;60:222-228. doi: 10.1159/000356023
19. Fryar CD, Carroll MD, Afful J. Prevalence of overweight, obesity, and severe obesity among children and adolescents aged 2-19 years: United States, 1963-1965 through 2017-2018. National Center for Health Statistics Health E-Stats. Updated January 29, 2021. Accessed September 21, 2021. www.cdc.gov/nchs/data/hestat/obesity-child-17-18/overweight-obesity-child-H.pdf
20. Fatima Y, Doi SAR, Mamun AA. Sleep quality and obesity in young subjects: a meta-analysis. Obes Rev. 2016;17:1154-1166. doi: 10.1111/obr.12444
21. Gohil A, Hannon TS. Poor sleep and obesity: concurrent epidemics in adolescent youth. Front Endocrinol. 2018;9:364. doi: 10.3389/fendo.2018.00364
22. Golley RK, Maher CA, Matricciani L, et al. Sleep duration or bedtime? Exploring the association between sleep timing behaviour, diet and BMI in children and adolescents. Int J Obes (Lond). 2013;37:546-551. doi: 10.1038/ijo.2012.212
23. Alessi CA. Sleep issues. In: Harper GM, Lyons WL, Potter JF, eds. Geriatrics Review Syllabus (GRS 10). Updated January 2021. Accessed August 29, 2023. http://geriatricscareonline.org
24. Patel SR, Blackwell T, Redline S, et al. The association between sleep duration and obesity in older adults. Int J Obes (Lond). 2008;32:1825-1834. doi: 10.1038/ijo.2008.198
25. Cai GH, Theorell-Haglöw J, Janson C, et al. Insomnia symptoms and sleep duration and their combined effects in relation to associations with obesity and central obesity. Sleep Med. 2018;46:81-87. doi: 10.1016/j.sleep.2018.03.009
26. Beccuti G, Pannain S. Sleep and obesity. Curr Opin Clin Nutr Metab Care. 2011;14:402-412. doi: 10.1097/MCO.0b013 e3283479109
27. Franklin KA, Lindberg E. Obstructive sleep apnea is a common disorder in the population–a review on the epidemiology of sleep apnea. J Thorac Dis. 2015;7:1311-1322. doi: 10.3978/j.issn.2072-1439.2015.06.11
28. USPSTF. Bibbins-Domingo K, Grossman DC, Curry SJ, et al. Screening for obstructive sleep apnea in adults: US Preventive Services Task Force recommendation statement. JAMA. 2017;317:407-414. doi: 10.1001/jama.2016.20325
29. Goyal M, Johnson J. Obstructive sleep apnea diagnosis and management. Mo Med. 2017;114:120-124.
30. American Academy of Sleep Medicine. Hidden health crisis costing America billions: underdiagnosing and undertreating obstructive sleep apnea draining healthcare system. 2016. Accessed September 25, 2023. https://aasm.org/wp-content/uploads/2017/10/sleep-apnea-economic-crisis.pdf
31. Devaraj, NK. Knowledge, attitude, and practice regarding obstructive sleep apnea among primary care physicians. Sleep Breath. 2020;24:1581-1590. doi: 10.1007/s11325-020-02040-1
32. Mysliwiec V, Martin JL, Ulmer CS, et al. The management of chronic insomnia disorder and obstructive sleep apnea: synopsis of the 2019 U.S. Department of Veterans Affairs and U.S. Department of Defense Clinical Practice Guidelines. Ann Intern Med. 2020;172:325-336. doi: 10.7326/M19-3575
33. Kuna ST, Reboussin DM, Strotmeyer ES, et al. Effects of weight loss on obstructive sleep apnea severity. Ten-year results of the Sleep AHEAD study. Am J Respir Crit Care Med. 2021;203:221-229. doi: 10.1164/rccm.201912-2511OC
34. St-Onge MP, Tasali E. Weight loss is integral to obstructive sleep apnea management. Ten-year follow-up in Sleep AHEAD. Am J Respir Crit Care Med. 2021;203:161-162. doi: 10.1164/rccm.202007-2906ED
35. Zheng D, Yuan X, Ma C, et al. Alcohol consumption and sleep quality: a community-based study. Public Health Nutr. 2021;24:4851-4858. doi: 10.1017/S1368980020004553
36. Chakravorty S, Chaudhary NS, Brower KJ. Alcohol dependence and its relationship with insomnia and other sleep disorders. Alcohol Clin Exp Res. 2016;40:2271-2282. doi: 10.1111/acer.13217
37. Elmenhorst EM, Elmenhorst D, Benderoth S, et al. Cognitive impairments by alcohol and sleep deprivation indicate trait characteristics and a potential role for adenosine A1 receptors. Proc Natl Acad Sci U S A. 2018;115:8009-8014. doi: 10.1073/pnas.1803770115
38. Traversy G, Chaput JP. Alcohol consumption and obesity: an update. Curr Obes Rep. 2015;4:122-130. doi: 10.1007/s13679-014-0129-4
39. McCann UD, Sgambati FP, Schwartz AR, et al. Sleep apnea in young abstinent recreational MDMA (“ecstasy”) consumers. Neurology. 2009;73:2011-2017. doi: 10.1212/WNL.0b013e3181c51a62
40. Grau-López L, Grau-López L, Daigre C, et al. Insomnia symptoms in patients with substance use disorders during detoxification and associated clinical features. Front Psychiatry. 2020;11:540022. doi: 10.3389/fpsyt.2020.540022
41. Boehm MA, Lei QM, Lloyd RM, et al. Depression, anxiety, and tobacco use: overlapping impediments to sleep in a national sample of college students. J Am Coll Health. 2016;64:565-574. doi: 10.1080/07448481.2016.1205073
42. Gracious BL, Meyer AE. Psychotropic-induced weight gain and potential pharmacologic treatment strategies. Psychiatry (Edgmont). 2005;2:36-42.
43. Ratliff JC, Barber JA, Palmese LB, et al. Association of prescription H1 antihistamine use with obesity: results from the National Health and Nutrition Examination Survey. Obesity (Silver Spring). 2010;18:2398-2400. doi: 10.1038/oby.2010.176
44. Pataka A, Daskalopoulou E, Kalamaras G, et al. Evaluation of five different questionnaires for assessing sleep apnea syndrome in a sleep clinic. Sleep Med. 2014;15:776-781. doi: 10.1016/j.sleep.2014.03.012
45. Kline CE, Chasens ER, Bizhanova Z, et al. The association between sleep health and weight change during a 12-month behavioral weight loss intervention. Int J Obes (Lond). 2021;45:639-649. doi: 10.1038/s41366-020-00728-8
46. CDC. How much physical activity do adults need? Accessed August 23, 2023. www.cdc.gov/physicalactivity/basics/adults/index.htm
47. Flack KD, Hays HM, Moreland J, et al. Exercise for weight loss: further evaluating energy compensation with exercise. Med Sci Sports Exerc. 2020;52:2466-2475. doi: 10.1249/MSS.0000000000002376
48. Swift DL, Johannsen NM, Lavie CJ, et al. The role of exercise and physical activity in weight loss and maintenance. Prog Cardiovasc Dis. 2014;56:441-447. doi: 10.1016/j.pcad.2013.09.012
49. Irish LA, Kline CE, Gunn HE, et al. The role of sleep hygiene in promoting public health: a review of empirical evidence. Sleep Med Rev. 2015;22:23-36. doi: 10.1016/j.smrv.2014.10.001
50. CDC. Tips for better sleep. 2022. Accessed August 4, 2023. www.cdc.gov/sleep/about_sleep/sleep_hygiene.html
51. Qaseem A, Kansagara D, Forciea MA, et al. Management of chronic insomnia disorder in adults: a clinical practice guideline from the American College of Physicians. Ann Intern Med. 2016;165:125-133. doi: 10.7326/M15-2175
52. Logue EE, Bourguet CC, Palmieri PA, et al. The better weight-better sleep study: a pilot intervention in primary care. Am J Health Behav. 2012;36:319-334. doi: 10.5993/AJHB.36.3.4
53. Leach MJ, Page AT. Herbal medicine for insomnia: a systematic review and meta-analysis. Sleep Med Rev. 2015;24:1-12. doi: 10.1016/j.smrv.2014.12.003
54. Sateia MJ, Buysse DJ, Krystal AD, et al. Clinical practice guideline for the pharmacologic treatment of chronic insomnia in adults: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2017;13:307-349. doi: 10.5664/jcsm.6470
Sleep is fundamental to overall health and longevity, with the average person spending about one-third of their life sleeping.1 Adequate sleep is critical for optimal cognition, memory consolidation, mood regulation, metabolism, appetite regulation, and immune and hormone functioning. According to the American Academy of Sleep Medicine and the Sleep Research Society, adults should sleep at least 7 hours per night on a regular basis “to promote optimal health.”2 Yet, between 2013 and 2020, only about 65% of adults in the United States were meeting this amount.3 Insufficient sleep is associated with an increased risk for chronic health conditions, including obesity, diabetes, cardiovascular diseases, and even premature death.4
In a population-based longitudinal study of sleep disorders, short sleep duration was associated with increased body mass index (BMI), low blood levels of leptin, and high ghrelin levels.5 In addition to physical impairments, poor sleep can impair cognitive performance and lead to vehicular accidents and increased accidents at work.4 The potential economic impact that this may have is significant, and includes increased costs and loss of productivity in the workplace.6
Many factors may contribute to short sleep duration: environment, mental and physical condition, and social influences such as occupation, family responsibilities, travel, group activities, and personal care. Furthermore, the rapidly evolving and developing media, communication, and entertainment industries are already strongly implicated in poor sleep quality and quantity, both contributing to excessive daytime sleepiness.7 Poor sleep quality is most notable in modern societies, and it correlates with the increasing prevalence of obesity, likely due to sleep’s effect on food consumption and physical activity.8 Optimizing a person’s sleep will improve overall health and longevity by inhibiting the development of chronic disease.
How insufficient sleep raises the risk for obesity
Not only is sleep beneficial for brain health, memory, learning, and growth, its effect on food consumption and physical activity likely correlates with the increased prevalence of obesity in modern society. Yet the optimal amount of sleep is controversial, and current recommendations of 7 or more hours of sleep per night for adults are derived from expert panels only.2 The recommended sleep duration for children is longer, and it varies by age.9 The quality of sleep and its impact on neuroendocrine hormones, not just the quantity of sleep, needs to be factored into these recommendations.
Sleep restriction activates the orexigenic system via the hormones leptin and ghrelin. These hormones control the food reward system, essentially increasing hunger and food intake. Leptin, created by white adipose tissue, is responsible for satiety and decreased food consumption.10 Ghrelin, made by oxyntic glands in the stomach, is responsible for the sensation of hunger.
In a 2004 study by Spiegel et al,11 leptin and ghrelin levels were measured during 2 days of sleep restriction (4 hours in bed) and sleep extension (10 hours in bed). Sleep restriction was associated with a decrease in leptin levels and an increase in ghrelin levels. The researchers reported that participants experienced an increase in hunger and appetite—especially for calorie-dense foods with high carbohydrate content.
Although research design has limitations with predominantly self-reported sleep data, studies have shown that short sleep time leads to increased food intake by increasing hunger signals and craving of unhealthy foods, and by providing more opportunities to eat while awake. It also may lead to decreased physical activity, creating a sedentary lifestyle that further encourages obesity.8 Reduced sleep is even correlated to decreased efficacy of weight-loss treatments.12
Continue to: Other sleep characteristics weakly correlated with obesity
Other sleep characteristics weakly correlated with obesity are sleep variability, timing, efficiency, quality, and daytime napping.8 Sleep variability causes dysregulation of eating patterns, leading to increased food intake. A shift to later sleep and waking times often results in higher consumption of calories after 8
Poor sleep efficiency and quality decreases N3-stage (deep non-REM) sleep, affects the autonomic nervous system, and has been associated with increased abdominal obesity. Daytime napping, which can cause irregular circadian rhythms and sleep schedules, is associated with increased obesity.15 Thus, each component of sleep needs to be assessed to promote optimal regulation of the orexigenic system.
Another study showed that inadequate sleep not only promotes unhealthy lifestyle habits that can lead to obesity but also decreases the ability to lose weight.16 This small study with 10 overweight patients provided its subjects with a controlled caloric intake over 2 weeks. Patients spent two 14-day periods 3 months apart in the laboratory, divided into 2 time-in-bed arms of 8.5 and 5.5 hours per night. Neuroendocrine changes caused by decreased sleep were associated with a significant lean body mass loss while conserving energy-dense fat.16 This study highlights the importance of sleep hygiene counseling when developing a weight-management plan with patients.
Sleep, and its many components, play an integral role in the prevention and treatment of obesity.17 Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.
The sleep–obesity link in children and the elderly
Childhood obesity is linked to several chronic diseases in adulthood, including type 2 diabetes, cardiovascular disease, nonalcoholic fatty liver disease, asthma, and obstructive sleep apnea (OSA).18 According to 2017-2018 NHANES (National Health and Nutrition Examination Surveys) data, obesity (BMI ≥ 95th percentile) prevalence among children and adolescents was reported at 19.3% and severe obesity (BMI ≥ 120% of the 95th percentile) at 6.1%. Pediatric overweight prevalence (≥ 85th percentile and < 95th percentile) was 16.1%.19
Continue to: Although poor sleep is associated...
Although poor sleep is associated with increased risk for obesity, there is no proven cause-effect relationship.20 Nutrition and physical activity have been identified as 2 critical factors in childhood obesity, but sleep health also needs to be investigated. Shorter sleep duration is strongly associated with the development of obesity. Furthermore, children with obesity are more likely to have shorter sleep duration.21 A short sleep duration alters plasma levels of insulin, low-density lipoprotein, and high-sensitivity C-reactive protein. It is associated with lower diet quality, an increased intake of nutrient-poor foods, and a lower intake of vegetables and fruits.22 Recent studies have shown that interventions to promote earlier bedtimes can improve sleep duration in children.
Older adults have many sleeping issues, including insomnia, circadian rhythm sleep-wake disorders, sleep-related movement disorders, and sleep-breathing disorders. Additionally, the older population has increased sleep latency, decreased sleep efficiency and total sleep time, decreased REM sleep, more frequent nighttime awakenings, and more daytime napping.23 The increased sleep disturbance with age is mainly related to higher risk factors for sleep disorders than the aging process itself. Sleeping 5 or fewer hours is associated with an increased risk for obesity and central abdominal fat compared with those who sleep 7 to 8 hours per night.24 Similar to children and youth, older adults also show a strong correlation between inadequate sleep and obesity.24
The consequence: A vicious cycle
Obesity in turn leads to shorter sleep duration and more disruptions. This negatively affects the orexigenic system, and the resulting hormonal derangement promotes worsening obesity. It is a cycle of poor sleep causing obesity and obesity causing poor sleep. Insomnia, in combination with shorter (and longer) sleep times, also has been linked with obesity.25 These patients experience more daytime sleepiness, fatigue, and nighttime sleep disturbances, all correlated with decreased quality of life and higher prevalence of medical comorbidities.8,26 Additional comorbidities secondary to obesity, including gastroesophageal reflux, depression, and asthma, also have been linked to sleep disturbances.8
OSA is a common sleep complication associated with obesity. With the increasing prevalence of obesity, the prevalence of OSA is rising.8,27 Factors that heighten the risk for OSA are male sex, age 40 to 70 years, postmenopausal status, elevated BMI, and craniofacial and upper airway abnormality.28 However, the US Preventive Services Task Force found insufficient evidence to screen for or treat OSA in asymptomatic adults.28 Signs and symptoms of OSA include nighttime awakenings with choking, loud snoring, and feeling unrefreshed after sleep.29
OSA is caused by the intermittent narrowing and obstruction of the pharyngeal airway due to anatomical and structural irregularities or neuromuscular impairments. Untreated OSA is associated with cardiovascular disease and cardiac arrhythmias such as atrial fibrillation. Even with this correlation between obesity and sleep, it is estimated that 80% of OSA remains undiagnosed.30 Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.31 Screening tools that have been validated are the STOP, STOP-BANG, Epworth Sleepiness Scale, and 4-Variable Screening Tool. However, the US Department of Veterans Affairs and the US Department of Defense have a more recent guideline recommending STOP as an easier-to-administer screen for OSA.32 A positive result with a screening tool should be confirmed with polysomnography.32
Continue to: Intervention for OSA
Intervention for OSA. The longest randomized controlled study to date, Sleep AHEAD, evaluated over a period of 10 years the effect of weight loss on OSA severity achieved with either an intensive lifestyle intervention (ILI) or with diabetes support and education (DSE).33 OSA severity is rated on an Apnea-Hypopnea Index (AHI), with scores reflecting the number of sleep apnea events per hour. This study demonstrated that weight loss was associated with decreased OSA severity. At 4-year follow-up, the greater the weight loss with ILI intervention, the lower the patients’ OSA severity scores. The study found an average decrease in AHI of 0.68 events per hour for every kilogram of weight loss in the ILI group (P < .0001).33,34 Over the follow-up visits, the ILI participants had 7.4 events per hour, a more significantly reduced AHI than the DSE participants (P < .0001).33,34
Additionally, a small cohort of study participants achieved OSA remission (ILI, 34.4%; DSE, 22.2%), indicated by a low AHI score (< 5 events per hour). At the conclusion of the study, OSA severity decreased to a greater degree with ILI intervention.33,34
Alcohol and drug use can negatively influence sleep patterns and obesity. Higher alcohol consumption is associated with poorer sleep quality and higher chances of developing short sleep duration and snoring.35 Alcohol, a muscle relaxant, causes upper airway narrowing and reduced tongue muscle tone, thereby increasing snoring and OSA as demonstrated by increased AHI on polysomnography after alcohol intake. Alcohol also changes sleep architecture by increasing slow-wave sleep, decreasing REM sleep duration, and increasing sleep arousal in the second half of the night.36 Disrupted circadian rhythm after alcohol consumption was correlated with increased adenosine neurotransmitters derived from ethanol metabolism.37 Alcohol dependence may be related to other psychiatric symptoms, and chronic alcohol use eventually alters sleep mechanisms leading to persistent insomnia, further perpetuating adverse outcomes such as suicidal ideation.36 There are positive associations between beer drinking and measures of abdominal adiposity in men, and “the combination of short sleep duration [and] disinhibited eating … is associated with greater alcohol intake and excess weight.”38
Therefore, counsel patients to avoid alcohol since it is a modifiable risk factor with pervasive adverse health effects.
Many drugs have a profound effect on sleep patterns. Illicit drug use in particular can affect the brain’s neurotransmitter serotonin system. For example, ecstasy users have an increased risk for OSA.39 People with cocaine and heroin use disorder tend to have more sleep-maintenance insomnia.40
Continue to: In contrast, those with alcohol...
In contrast, those with alcohol or cannabis use disorder tend to have more sleep-onset insomnia.40 Not only do illicit drugs interrupt sleep, but daily tobacco use also has been correlated with increased insomnia and shorter sleep duration since nicotine is a stimulant.41
Insomnia is commonly treated with sedative antidepressants and hypnotics—eg, mirtazapine and olanzapine—that contribute to weight gain.42 In addition, other common pharmaceuticals used for sleep disorders, such as diphenhydramine, have sedative properties and tend to lead to weight gain.43 Because so many medications affect sleep and weight, carefully review patients’ medication lists and switch offending agents to weight-neutral drugs if possible.
Treatment and tools to improve sleep in patients with obesity
Given the strong correlation between obesity and sleep disorders, validated screening tools should be used to assess sleep quality, including onset and potential symptoms associated with poor sleep (TABLE 144). For weight management to succeed in patients with obesity, it is crucial to address sleep in addition to nutrition and physical activity.17,45
Physical activity has many benefits to overall health, especially for chronic diseases such as type 2 diabetes and hypertension. The Centers for Disease Control and Prevention recommends at least 150 minutes of moderate-intensity aerobic activity or 75 minutes of vigorous-intensity aerobic exercise per week in addition to muscle-strengthening activities 2 or more days per week.46 However, approximately 300 minutes of moderate-
Physical activity and diet in combination are vital, but diet restriction has a more substantial effect on weight loss than physical activity alone.48 Still, physical activity is essential in helping maintain and prevent weight regain.
Continue to: Nonpharmacologic interventions
Nonpharmacologic interventions include promoting greater sleep quality and quantity by emphasizing good sleep hygiene practices. Developing a practical and effective bedtime routine, creating a quiet sleep environment, and practicing healthy daily habits are essential components to sleep hygiene (TABLE 249,50). Relaxation techniques and cognitive behavioral therapy (CBT) also can help. CBT for insomnia (CBT-I) is the first-line intervention for chronic insomnia.51 Sleep restriction is a type of CBT used to treat insomnia, encouraging short-term sleep loss in the hopes of improving insomnia. A trial by Logue et al showed that patients with overweight and obesity randomized to undergo CBT with better sleep hygiene (nonpharmacologic) interventions had a greater mean weight loss percentage (5% vs 2%; P = .04) than did those who received CBT alone.52
Eastern medicine including herbal interventions lack evidence of efficacy and safety. Further studies need to be done on the effects that chamomile, kava, valerian root (Valeriana officinalis), tryptophan, and Wu Ling (from mycelia Xylaria nigripes) might have on sleep.53
Proceed cautiously with medication. The American College of Physicians recommends a shared decision-making approach when considering pharmacologic therapy for chronic insomnia and the American Academy of Sleep Medicine (AASM) offers guidance on options.51,54 However, the evidence behind AASM sleep pharmacologic recommendations is weak, implying a lesser degree of confidence in the outcome and, therefore, in its appropriateness. Thus, it falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia. If indicated, medications suggested to treat sleep onset and sleep maintenance insomnia are eszopiclone, zolpidem, and temazepam. Zaleplon, triazolam, and ramelteon may improve sleep initiation. Suvorexant and doxepin are used for sleep-maintenance insomnia.54 Exploring patient preferences, cost of treatment, health care options, and available resources should all be considered.
CORRESPONDENCE
Ecler Ercole Jaqua, MD, MBA, FAAFP, AGSF, FACLM, DipABOM, Loma Linda University Health, 25455 Barton Road, Suite 206A, Loma Linda, CA 92354; ejaqua@llu.edu
Sleep is fundamental to overall health and longevity, with the average person spending about one-third of their life sleeping.1 Adequate sleep is critical for optimal cognition, memory consolidation, mood regulation, metabolism, appetite regulation, and immune and hormone functioning. According to the American Academy of Sleep Medicine and the Sleep Research Society, adults should sleep at least 7 hours per night on a regular basis “to promote optimal health.”2 Yet, between 2013 and 2020, only about 65% of adults in the United States were meeting this amount.3 Insufficient sleep is associated with an increased risk for chronic health conditions, including obesity, diabetes, cardiovascular diseases, and even premature death.4
In a population-based longitudinal study of sleep disorders, short sleep duration was associated with increased body mass index (BMI), low blood levels of leptin, and high ghrelin levels.5 In addition to physical impairments, poor sleep can impair cognitive performance and lead to vehicular accidents and increased accidents at work.4 The potential economic impact that this may have is significant, and includes increased costs and loss of productivity in the workplace.6
Many factors may contribute to short sleep duration: environment, mental and physical condition, and social influences such as occupation, family responsibilities, travel, group activities, and personal care. Furthermore, the rapidly evolving and developing media, communication, and entertainment industries are already strongly implicated in poor sleep quality and quantity, both contributing to excessive daytime sleepiness.7 Poor sleep quality is most notable in modern societies, and it correlates with the increasing prevalence of obesity, likely due to sleep’s effect on food consumption and physical activity.8 Optimizing a person’s sleep will improve overall health and longevity by inhibiting the development of chronic disease.
How insufficient sleep raises the risk for obesity
Not only is sleep beneficial for brain health, memory, learning, and growth, its effect on food consumption and physical activity likely correlates with the increased prevalence of obesity in modern society. Yet the optimal amount of sleep is controversial, and current recommendations of 7 or more hours of sleep per night for adults are derived from expert panels only.2 The recommended sleep duration for children is longer, and it varies by age.9 The quality of sleep and its impact on neuroendocrine hormones, not just the quantity of sleep, needs to be factored into these recommendations.
Sleep restriction activates the orexigenic system via the hormones leptin and ghrelin. These hormones control the food reward system, essentially increasing hunger and food intake. Leptin, created by white adipose tissue, is responsible for satiety and decreased food consumption.10 Ghrelin, made by oxyntic glands in the stomach, is responsible for the sensation of hunger.
In a 2004 study by Spiegel et al,11 leptin and ghrelin levels were measured during 2 days of sleep restriction (4 hours in bed) and sleep extension (10 hours in bed). Sleep restriction was associated with a decrease in leptin levels and an increase in ghrelin levels. The researchers reported that participants experienced an increase in hunger and appetite—especially for calorie-dense foods with high carbohydrate content.
Although research design has limitations with predominantly self-reported sleep data, studies have shown that short sleep time leads to increased food intake by increasing hunger signals and craving of unhealthy foods, and by providing more opportunities to eat while awake. It also may lead to decreased physical activity, creating a sedentary lifestyle that further encourages obesity.8 Reduced sleep is even correlated to decreased efficacy of weight-loss treatments.12
Continue to: Other sleep characteristics weakly correlated with obesity
Other sleep characteristics weakly correlated with obesity are sleep variability, timing, efficiency, quality, and daytime napping.8 Sleep variability causes dysregulation of eating patterns, leading to increased food intake. A shift to later sleep and waking times often results in higher consumption of calories after 8
Poor sleep efficiency and quality decreases N3-stage (deep non-REM) sleep, affects the autonomic nervous system, and has been associated with increased abdominal obesity. Daytime napping, which can cause irregular circadian rhythms and sleep schedules, is associated with increased obesity.15 Thus, each component of sleep needs to be assessed to promote optimal regulation of the orexigenic system.
Another study showed that inadequate sleep not only promotes unhealthy lifestyle habits that can lead to obesity but also decreases the ability to lose weight.16 This small study with 10 overweight patients provided its subjects with a controlled caloric intake over 2 weeks. Patients spent two 14-day periods 3 months apart in the laboratory, divided into 2 time-in-bed arms of 8.5 and 5.5 hours per night. Neuroendocrine changes caused by decreased sleep were associated with a significant lean body mass loss while conserving energy-dense fat.16 This study highlights the importance of sleep hygiene counseling when developing a weight-management plan with patients.
Sleep, and its many components, play an integral role in the prevention and treatment of obesity.17 Poor sleep will increase the risk for obesity and hinder its treatment. Therefore, sleep quality and duration are vital components of obesity management.
The sleep–obesity link in children and the elderly
Childhood obesity is linked to several chronic diseases in adulthood, including type 2 diabetes, cardiovascular disease, nonalcoholic fatty liver disease, asthma, and obstructive sleep apnea (OSA).18 According to 2017-2018 NHANES (National Health and Nutrition Examination Surveys) data, obesity (BMI ≥ 95th percentile) prevalence among children and adolescents was reported at 19.3% and severe obesity (BMI ≥ 120% of the 95th percentile) at 6.1%. Pediatric overweight prevalence (≥ 85th percentile and < 95th percentile) was 16.1%.19
Continue to: Although poor sleep is associated...
Although poor sleep is associated with increased risk for obesity, there is no proven cause-effect relationship.20 Nutrition and physical activity have been identified as 2 critical factors in childhood obesity, but sleep health also needs to be investigated. Shorter sleep duration is strongly associated with the development of obesity. Furthermore, children with obesity are more likely to have shorter sleep duration.21 A short sleep duration alters plasma levels of insulin, low-density lipoprotein, and high-sensitivity C-reactive protein. It is associated with lower diet quality, an increased intake of nutrient-poor foods, and a lower intake of vegetables and fruits.22 Recent studies have shown that interventions to promote earlier bedtimes can improve sleep duration in children.
Older adults have many sleeping issues, including insomnia, circadian rhythm sleep-wake disorders, sleep-related movement disorders, and sleep-breathing disorders. Additionally, the older population has increased sleep latency, decreased sleep efficiency and total sleep time, decreased REM sleep, more frequent nighttime awakenings, and more daytime napping.23 The increased sleep disturbance with age is mainly related to higher risk factors for sleep disorders than the aging process itself. Sleeping 5 or fewer hours is associated with an increased risk for obesity and central abdominal fat compared with those who sleep 7 to 8 hours per night.24 Similar to children and youth, older adults also show a strong correlation between inadequate sleep and obesity.24
The consequence: A vicious cycle
Obesity in turn leads to shorter sleep duration and more disruptions. This negatively affects the orexigenic system, and the resulting hormonal derangement promotes worsening obesity. It is a cycle of poor sleep causing obesity and obesity causing poor sleep. Insomnia, in combination with shorter (and longer) sleep times, also has been linked with obesity.25 These patients experience more daytime sleepiness, fatigue, and nighttime sleep disturbances, all correlated with decreased quality of life and higher prevalence of medical comorbidities.8,26 Additional comorbidities secondary to obesity, including gastroesophageal reflux, depression, and asthma, also have been linked to sleep disturbances.8
OSA is a common sleep complication associated with obesity. With the increasing prevalence of obesity, the prevalence of OSA is rising.8,27 Factors that heighten the risk for OSA are male sex, age 40 to 70 years, postmenopausal status, elevated BMI, and craniofacial and upper airway abnormality.28 However, the US Preventive Services Task Force found insufficient evidence to screen for or treat OSA in asymptomatic adults.28 Signs and symptoms of OSA include nighttime awakenings with choking, loud snoring, and feeling unrefreshed after sleep.29
OSA is caused by the intermittent narrowing and obstruction of the pharyngeal airway due to anatomical and structural irregularities or neuromuscular impairments. Untreated OSA is associated with cardiovascular disease and cardiac arrhythmias such as atrial fibrillation. Even with this correlation between obesity and sleep, it is estimated that 80% of OSA remains undiagnosed.30 Approximately half of primary care clinicians do not screen at-risk patients for OSA, and 90% do not use validated OSA screening tools.31 Screening tools that have been validated are the STOP, STOP-BANG, Epworth Sleepiness Scale, and 4-Variable Screening Tool. However, the US Department of Veterans Affairs and the US Department of Defense have a more recent guideline recommending STOP as an easier-to-administer screen for OSA.32 A positive result with a screening tool should be confirmed with polysomnography.32
Continue to: Intervention for OSA
Intervention for OSA. The longest randomized controlled study to date, Sleep AHEAD, evaluated over a period of 10 years the effect of weight loss on OSA severity achieved with either an intensive lifestyle intervention (ILI) or with diabetes support and education (DSE).33 OSA severity is rated on an Apnea-Hypopnea Index (AHI), with scores reflecting the number of sleep apnea events per hour. This study demonstrated that weight loss was associated with decreased OSA severity. At 4-year follow-up, the greater the weight loss with ILI intervention, the lower the patients’ OSA severity scores. The study found an average decrease in AHI of 0.68 events per hour for every kilogram of weight loss in the ILI group (P < .0001).33,34 Over the follow-up visits, the ILI participants had 7.4 events per hour, a more significantly reduced AHI than the DSE participants (P < .0001).33,34
Additionally, a small cohort of study participants achieved OSA remission (ILI, 34.4%; DSE, 22.2%), indicated by a low AHI score (< 5 events per hour). At the conclusion of the study, OSA severity decreased to a greater degree with ILI intervention.33,34
Alcohol and drug use can negatively influence sleep patterns and obesity. Higher alcohol consumption is associated with poorer sleep quality and higher chances of developing short sleep duration and snoring.35 Alcohol, a muscle relaxant, causes upper airway narrowing and reduced tongue muscle tone, thereby increasing snoring and OSA as demonstrated by increased AHI on polysomnography after alcohol intake. Alcohol also changes sleep architecture by increasing slow-wave sleep, decreasing REM sleep duration, and increasing sleep arousal in the second half of the night.36 Disrupted circadian rhythm after alcohol consumption was correlated with increased adenosine neurotransmitters derived from ethanol metabolism.37 Alcohol dependence may be related to other psychiatric symptoms, and chronic alcohol use eventually alters sleep mechanisms leading to persistent insomnia, further perpetuating adverse outcomes such as suicidal ideation.36 There are positive associations between beer drinking and measures of abdominal adiposity in men, and “the combination of short sleep duration [and] disinhibited eating … is associated with greater alcohol intake and excess weight.”38
Therefore, counsel patients to avoid alcohol since it is a modifiable risk factor with pervasive adverse health effects.
Many drugs have a profound effect on sleep patterns. Illicit drug use in particular can affect the brain’s neurotransmitter serotonin system. For example, ecstasy users have an increased risk for OSA.39 People with cocaine and heroin use disorder tend to have more sleep-maintenance insomnia.40
Continue to: In contrast, those with alcohol...
In contrast, those with alcohol or cannabis use disorder tend to have more sleep-onset insomnia.40 Not only do illicit drugs interrupt sleep, but daily tobacco use also has been correlated with increased insomnia and shorter sleep duration since nicotine is a stimulant.41
Insomnia is commonly treated with sedative antidepressants and hypnotics—eg, mirtazapine and olanzapine—that contribute to weight gain.42 In addition, other common pharmaceuticals used for sleep disorders, such as diphenhydramine, have sedative properties and tend to lead to weight gain.43 Because so many medications affect sleep and weight, carefully review patients’ medication lists and switch offending agents to weight-neutral drugs if possible.
Treatment and tools to improve sleep in patients with obesity
Given the strong correlation between obesity and sleep disorders, validated screening tools should be used to assess sleep quality, including onset and potential symptoms associated with poor sleep (TABLE 144). For weight management to succeed in patients with obesity, it is crucial to address sleep in addition to nutrition and physical activity.17,45
Physical activity has many benefits to overall health, especially for chronic diseases such as type 2 diabetes and hypertension. The Centers for Disease Control and Prevention recommends at least 150 minutes of moderate-intensity aerobic activity or 75 minutes of vigorous-intensity aerobic exercise per week in addition to muscle-strengthening activities 2 or more days per week.46 However, approximately 300 minutes of moderate-
Physical activity and diet in combination are vital, but diet restriction has a more substantial effect on weight loss than physical activity alone.48 Still, physical activity is essential in helping maintain and prevent weight regain.
Continue to: Nonpharmacologic interventions
Nonpharmacologic interventions include promoting greater sleep quality and quantity by emphasizing good sleep hygiene practices. Developing a practical and effective bedtime routine, creating a quiet sleep environment, and practicing healthy daily habits are essential components to sleep hygiene (TABLE 249,50). Relaxation techniques and cognitive behavioral therapy (CBT) also can help. CBT for insomnia (CBT-I) is the first-line intervention for chronic insomnia.51 Sleep restriction is a type of CBT used to treat insomnia, encouraging short-term sleep loss in the hopes of improving insomnia. A trial by Logue et al showed that patients with overweight and obesity randomized to undergo CBT with better sleep hygiene (nonpharmacologic) interventions had a greater mean weight loss percentage (5% vs 2%; P = .04) than did those who received CBT alone.52
Eastern medicine including herbal interventions lack evidence of efficacy and safety. Further studies need to be done on the effects that chamomile, kava, valerian root (Valeriana officinalis), tryptophan, and Wu Ling (from mycelia Xylaria nigripes) might have on sleep.53
Proceed cautiously with medication. The American College of Physicians recommends a shared decision-making approach when considering pharmacologic therapy for chronic insomnia and the American Academy of Sleep Medicine (AASM) offers guidance on options.51,54 However, the evidence behind AASM sleep pharmacologic recommendations is weak, implying a lesser degree of confidence in the outcome and, therefore, in its appropriateness. Thus, it falls upon the clinician and patient to weigh the benefits and burdens of the pharmacologic treatments of insomnia. If indicated, medications suggested to treat sleep onset and sleep maintenance insomnia are eszopiclone, zolpidem, and temazepam. Zaleplon, triazolam, and ramelteon may improve sleep initiation. Suvorexant and doxepin are used for sleep-maintenance insomnia.54 Exploring patient preferences, cost of treatment, health care options, and available resources should all be considered.
CORRESPONDENCE
Ecler Ercole Jaqua, MD, MBA, FAAFP, AGSF, FACLM, DipABOM, Loma Linda University Health, 25455 Barton Road, Suite 206A, Loma Linda, CA 92354; ejaqua@llu.edu
1. Aminoff MJ, Boller F, Swaab DF. We spend about one-third of our life either sleeping or attempting to do so. Handb Clin Neurol. 2011;98:vii. doi: 10.1016/B978-0-444-52006-7.00047-2
2. Watson NF, Badr MS, Belenky G, et al. Recommended amount of sleep for a healthy adult: a joint consensus statement of the American Academy of Sleep Medicine and Sleep Research Society. Sleep. 2015;38:843-844. doi: 10.5665/sleep.4716
3. CDC. Sleep and sleep disorders, adults. Accessed September 21, 2023. www.cdc.gov/sleep/data-and-statistics/adults.html
4. Chattu VK, Manzar MD, Kumary S. The global problem of insufficient sleep and its serious public health implications. Healthcare (Basel). 2019;7:1. doi: 10.3390/healthcare7010001
5. Taheri S, Lin L, Austin D, et al. Short sleep duration is associated with reduced leptin, elevated ghrelin, and increased body mass index. PLoS Med. 2004;1:e62. doi: 10.1371/journal.pmed.0010062
6. Hafner M, Stepanek M, Taylor J, et al. Why sleep matters—the economic costs of insufficient sleep. Rand Health Q. 2017;6:11.
7. Hisler G, Twenge JM, Krizan Z. Associations between screen time and short sleep duration among adolescents varies by media type: evidence from a cohort study. Sleep Med. 2020;66:92-102. doi: 10.1016/j.sleep.2019.08.007
8. Ogilvie RP, Patel SR. The epidemiology of sleep and obesity. Sleep Health. 2017;3:383-388. doi: 10.1016/j.sleh.2017.07.013
9. CDC. Sleep and sleep disorders: How much sleep do I need? Accessed September 21, 2023. www.cdc.gov/sleep/about_sleep/how_much_sleep.html
10. van Egmond LT, Meth EMS, Engström J, et al. Effects of acute sleep loss on leptin, ghrelin, and adiponectin in adults with healthy weight and obesity: a laboratory study. Obesity (Silver Spring). 2023;31:635-641. doi: 10.1002/oby.23616
11. Spiegel K, Tasali E, Penev P, et al. Brief communication: sleep curtailment in healthy young men is associated with decreased leptin levels, elevated ghrelin levels, and increased hunger and appetite. Ann Intern Med. 2004;141:846-850. doi: 10.7326/0003-4819-141-11-200412070-00008
12. Antza C, Kostopoulos G, Mostafa S, et al. The links between sleep duration, obesity and type 2 diabetes mellitus. J Endocrinol. 2021;252:125-141. doi: 10.1530/JOE-21-0155
13. Baron KG, Reid KJ, Kern AS, et al. Role of sleep timing in caloric intake and BMI. Obesity (Silver Spring). 2011;19:1374-1381. doi: 10.1038/oby.2011.100
14. Liu XY, Zheng CL, Xu C, et al. Nighttime snacking is associated with risk of obesity and hyperglycemia in adults: a cross-sectional survey from Chinese adult teachers J Biomed Res. 2017;31:541-547. doi: 10.7555/JBR.31.20160083
15. Cai Z, Yang Y, Zhang J, et al. The relationship between daytime napping and obesity: a systematic review and meta-analysis. Sci Rep. 2023.13:12124. doi: 10.1038/s41598-023-37883-7
16. Nedeltcheva AV, Kilkus JM, Imperial J, et al. Insufficient sleep undermines dietary efforts to reduce adiposity. Ann Intern Med. 2010;153:435-441. doi: 10.7326/0003-4819-153-7-201010050-00006
17. Chaput JP, Tremblay A. Adequate sleep to improve the treatment of obesity. CMAJ. 2012;184:1975-1976. doi: 10.1503/cmaj.120876
18. Kelsey MM, Zaepfel A, Bjornstad P, et al. Age-related consequences of childhood obesity. Gerontology. 2014;60:222-228. doi: 10.1159/000356023
19. Fryar CD, Carroll MD, Afful J. Prevalence of overweight, obesity, and severe obesity among children and adolescents aged 2-19 years: United States, 1963-1965 through 2017-2018. National Center for Health Statistics Health E-Stats. Updated January 29, 2021. Accessed September 21, 2021. www.cdc.gov/nchs/data/hestat/obesity-child-17-18/overweight-obesity-child-H.pdf
20. Fatima Y, Doi SAR, Mamun AA. Sleep quality and obesity in young subjects: a meta-analysis. Obes Rev. 2016;17:1154-1166. doi: 10.1111/obr.12444
21. Gohil A, Hannon TS. Poor sleep and obesity: concurrent epidemics in adolescent youth. Front Endocrinol. 2018;9:364. doi: 10.3389/fendo.2018.00364
22. Golley RK, Maher CA, Matricciani L, et al. Sleep duration or bedtime? Exploring the association between sleep timing behaviour, diet and BMI in children and adolescents. Int J Obes (Lond). 2013;37:546-551. doi: 10.1038/ijo.2012.212
23. Alessi CA. Sleep issues. In: Harper GM, Lyons WL, Potter JF, eds. Geriatrics Review Syllabus (GRS 10). Updated January 2021. Accessed August 29, 2023. http://geriatricscareonline.org
24. Patel SR, Blackwell T, Redline S, et al. The association between sleep duration and obesity in older adults. Int J Obes (Lond). 2008;32:1825-1834. doi: 10.1038/ijo.2008.198
25. Cai GH, Theorell-Haglöw J, Janson C, et al. Insomnia symptoms and sleep duration and their combined effects in relation to associations with obesity and central obesity. Sleep Med. 2018;46:81-87. doi: 10.1016/j.sleep.2018.03.009
26. Beccuti G, Pannain S. Sleep and obesity. Curr Opin Clin Nutr Metab Care. 2011;14:402-412. doi: 10.1097/MCO.0b013 e3283479109
27. Franklin KA, Lindberg E. Obstructive sleep apnea is a common disorder in the population–a review on the epidemiology of sleep apnea. J Thorac Dis. 2015;7:1311-1322. doi: 10.3978/j.issn.2072-1439.2015.06.11
28. USPSTF. Bibbins-Domingo K, Grossman DC, Curry SJ, et al. Screening for obstructive sleep apnea in adults: US Preventive Services Task Force recommendation statement. JAMA. 2017;317:407-414. doi: 10.1001/jama.2016.20325
29. Goyal M, Johnson J. Obstructive sleep apnea diagnosis and management. Mo Med. 2017;114:120-124.
30. American Academy of Sleep Medicine. Hidden health crisis costing America billions: underdiagnosing and undertreating obstructive sleep apnea draining healthcare system. 2016. Accessed September 25, 2023. https://aasm.org/wp-content/uploads/2017/10/sleep-apnea-economic-crisis.pdf
31. Devaraj, NK. Knowledge, attitude, and practice regarding obstructive sleep apnea among primary care physicians. Sleep Breath. 2020;24:1581-1590. doi: 10.1007/s11325-020-02040-1
32. Mysliwiec V, Martin JL, Ulmer CS, et al. The management of chronic insomnia disorder and obstructive sleep apnea: synopsis of the 2019 U.S. Department of Veterans Affairs and U.S. Department of Defense Clinical Practice Guidelines. Ann Intern Med. 2020;172:325-336. doi: 10.7326/M19-3575
33. Kuna ST, Reboussin DM, Strotmeyer ES, et al. Effects of weight loss on obstructive sleep apnea severity. Ten-year results of the Sleep AHEAD study. Am J Respir Crit Care Med. 2021;203:221-229. doi: 10.1164/rccm.201912-2511OC
34. St-Onge MP, Tasali E. Weight loss is integral to obstructive sleep apnea management. Ten-year follow-up in Sleep AHEAD. Am J Respir Crit Care Med. 2021;203:161-162. doi: 10.1164/rccm.202007-2906ED
35. Zheng D, Yuan X, Ma C, et al. Alcohol consumption and sleep quality: a community-based study. Public Health Nutr. 2021;24:4851-4858. doi: 10.1017/S1368980020004553
36. Chakravorty S, Chaudhary NS, Brower KJ. Alcohol dependence and its relationship with insomnia and other sleep disorders. Alcohol Clin Exp Res. 2016;40:2271-2282. doi: 10.1111/acer.13217
37. Elmenhorst EM, Elmenhorst D, Benderoth S, et al. Cognitive impairments by alcohol and sleep deprivation indicate trait characteristics and a potential role for adenosine A1 receptors. Proc Natl Acad Sci U S A. 2018;115:8009-8014. doi: 10.1073/pnas.1803770115
38. Traversy G, Chaput JP. Alcohol consumption and obesity: an update. Curr Obes Rep. 2015;4:122-130. doi: 10.1007/s13679-014-0129-4
39. McCann UD, Sgambati FP, Schwartz AR, et al. Sleep apnea in young abstinent recreational MDMA (“ecstasy”) consumers. Neurology. 2009;73:2011-2017. doi: 10.1212/WNL.0b013e3181c51a62
40. Grau-López L, Grau-López L, Daigre C, et al. Insomnia symptoms in patients with substance use disorders during detoxification and associated clinical features. Front Psychiatry. 2020;11:540022. doi: 10.3389/fpsyt.2020.540022
41. Boehm MA, Lei QM, Lloyd RM, et al. Depression, anxiety, and tobacco use: overlapping impediments to sleep in a national sample of college students. J Am Coll Health. 2016;64:565-574. doi: 10.1080/07448481.2016.1205073
42. Gracious BL, Meyer AE. Psychotropic-induced weight gain and potential pharmacologic treatment strategies. Psychiatry (Edgmont). 2005;2:36-42.
43. Ratliff JC, Barber JA, Palmese LB, et al. Association of prescription H1 antihistamine use with obesity: results from the National Health and Nutrition Examination Survey. Obesity (Silver Spring). 2010;18:2398-2400. doi: 10.1038/oby.2010.176
44. Pataka A, Daskalopoulou E, Kalamaras G, et al. Evaluation of five different questionnaires for assessing sleep apnea syndrome in a sleep clinic. Sleep Med. 2014;15:776-781. doi: 10.1016/j.sleep.2014.03.012
45. Kline CE, Chasens ER, Bizhanova Z, et al. The association between sleep health and weight change during a 12-month behavioral weight loss intervention. Int J Obes (Lond). 2021;45:639-649. doi: 10.1038/s41366-020-00728-8
46. CDC. How much physical activity do adults need? Accessed August 23, 2023. www.cdc.gov/physicalactivity/basics/adults/index.htm
47. Flack KD, Hays HM, Moreland J, et al. Exercise for weight loss: further evaluating energy compensation with exercise. Med Sci Sports Exerc. 2020;52:2466-2475. doi: 10.1249/MSS.0000000000002376
48. Swift DL, Johannsen NM, Lavie CJ, et al. The role of exercise and physical activity in weight loss and maintenance. Prog Cardiovasc Dis. 2014;56:441-447. doi: 10.1016/j.pcad.2013.09.012
49. Irish LA, Kline CE, Gunn HE, et al. The role of sleep hygiene in promoting public health: a review of empirical evidence. Sleep Med Rev. 2015;22:23-36. doi: 10.1016/j.smrv.2014.10.001
50. CDC. Tips for better sleep. 2022. Accessed August 4, 2023. www.cdc.gov/sleep/about_sleep/sleep_hygiene.html
51. Qaseem A, Kansagara D, Forciea MA, et al. Management of chronic insomnia disorder in adults: a clinical practice guideline from the American College of Physicians. Ann Intern Med. 2016;165:125-133. doi: 10.7326/M15-2175
52. Logue EE, Bourguet CC, Palmieri PA, et al. The better weight-better sleep study: a pilot intervention in primary care. Am J Health Behav. 2012;36:319-334. doi: 10.5993/AJHB.36.3.4
53. Leach MJ, Page AT. Herbal medicine for insomnia: a systematic review and meta-analysis. Sleep Med Rev. 2015;24:1-12. doi: 10.1016/j.smrv.2014.12.003
54. Sateia MJ, Buysse DJ, Krystal AD, et al. Clinical practice guideline for the pharmacologic treatment of chronic insomnia in adults: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2017;13:307-349. doi: 10.5664/jcsm.6470
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39. McCann UD, Sgambati FP, Schwartz AR, et al. Sleep apnea in young abstinent recreational MDMA (“ecstasy”) consumers. Neurology. 2009;73:2011-2017. doi: 10.1212/WNL.0b013e3181c51a62
40. Grau-López L, Grau-López L, Daigre C, et al. Insomnia symptoms in patients with substance use disorders during detoxification and associated clinical features. Front Psychiatry. 2020;11:540022. doi: 10.3389/fpsyt.2020.540022
41. Boehm MA, Lei QM, Lloyd RM, et al. Depression, anxiety, and tobacco use: overlapping impediments to sleep in a national sample of college students. J Am Coll Health. 2016;64:565-574. doi: 10.1080/07448481.2016.1205073
42. Gracious BL, Meyer AE. Psychotropic-induced weight gain and potential pharmacologic treatment strategies. Psychiatry (Edgmont). 2005;2:36-42.
43. Ratliff JC, Barber JA, Palmese LB, et al. Association of prescription H1 antihistamine use with obesity: results from the National Health and Nutrition Examination Survey. Obesity (Silver Spring). 2010;18:2398-2400. doi: 10.1038/oby.2010.176
44. Pataka A, Daskalopoulou E, Kalamaras G, et al. Evaluation of five different questionnaires for assessing sleep apnea syndrome in a sleep clinic. Sleep Med. 2014;15:776-781. doi: 10.1016/j.sleep.2014.03.012
45. Kline CE, Chasens ER, Bizhanova Z, et al. The association between sleep health and weight change during a 12-month behavioral weight loss intervention. Int J Obes (Lond). 2021;45:639-649. doi: 10.1038/s41366-020-00728-8
46. CDC. How much physical activity do adults need? Accessed August 23, 2023. www.cdc.gov/physicalactivity/basics/adults/index.htm
47. Flack KD, Hays HM, Moreland J, et al. Exercise for weight loss: further evaluating energy compensation with exercise. Med Sci Sports Exerc. 2020;52:2466-2475. doi: 10.1249/MSS.0000000000002376
48. Swift DL, Johannsen NM, Lavie CJ, et al. The role of exercise and physical activity in weight loss and maintenance. Prog Cardiovasc Dis. 2014;56:441-447. doi: 10.1016/j.pcad.2013.09.012
49. Irish LA, Kline CE, Gunn HE, et al. The role of sleep hygiene in promoting public health: a review of empirical evidence. Sleep Med Rev. 2015;22:23-36. doi: 10.1016/j.smrv.2014.10.001
50. CDC. Tips for better sleep. 2022. Accessed August 4, 2023. www.cdc.gov/sleep/about_sleep/sleep_hygiene.html
51. Qaseem A, Kansagara D, Forciea MA, et al. Management of chronic insomnia disorder in adults: a clinical practice guideline from the American College of Physicians. Ann Intern Med. 2016;165:125-133. doi: 10.7326/M15-2175
52. Logue EE, Bourguet CC, Palmieri PA, et al. The better weight-better sleep study: a pilot intervention in primary care. Am J Health Behav. 2012;36:319-334. doi: 10.5993/AJHB.36.3.4
53. Leach MJ, Page AT. Herbal medicine for insomnia: a systematic review and meta-analysis. Sleep Med Rev. 2015;24:1-12. doi: 10.1016/j.smrv.2014.12.003
54. Sateia MJ, Buysse DJ, Krystal AD, et al. Clinical practice guideline for the pharmacologic treatment of chronic insomnia in adults: an American Academy of Sleep Medicine clinical practice guideline. J Clin Sleep Med. 2017;13:307-349. doi: 10.5664/jcsm.6470
PRACTICE RECOMMENDATIONS
› Consider cognitive behaviorial therapy for insomnia (CBT-I) first-line treatment for insomnia. A
› Carefully review patients’ medication lists, as many pharmaceuticals can affect weight and sleep. C
Strength of recommendation (SOR)
A Good-quality patient-oriented evidence
B Inconsistent or limited-quality patient-oriented evidence
C Consensus, usual practice, opinion, disease-oriented evidence, case series
FDA denies approval for patisiran in ATTR cardiomyopathy, despite panel nod
the company has announced.
ATTR amyloidosis is an underdiagnosed, rapidly progressive, debilitating, fatal disease caused by misfolded TTR proteins, which accumulate as amyloid deposits in various parts of the body, including the heart.
In September, the FDA Cardiovascular and Renal Drugs Advisory Committee voted 9 to 3 that the benefits of patisiran outweigh the risks for the treatment of ATTR amyloidosis cardiomyopathy on the basis of the results of the APOLLO-B phase 3 study.
However, many panel members questioned whether the benefits are clinically meaningful – a view shared by the FDA in a complete response letter (CRL) the FDA sent to Alnylam.
According to the company, the FDA indicated in the letter that the clinical meaningfulness of patisiran’s treatment effects for the cardiomyopathy of ATTR amyloidosis have “not been established,” and therefore, the supplemental new drug application for patisiran “could not be approved in its present form.”
The FDA did not identify any issues with respect to clinical safety, study conduct, drug quality, or manufacturing.
Nonetheless, as a result of the CRL, the company said it will no longer pursue an expanded indication for patisiran in cardiomyopathy of ATTR amyloidosis in the United States.
The company said it will continue to make patisiran available for patients with cardiomyopathy of ATTR amyloidosis who are enrolled in the open-label extension period of the APOLLO-B study and the patisiran expanded access protocol.
The company also said it will continue to focus on the HELIOS-B phase 3 study of vutrisiran, an investigational RNAi therapeutic in development for the treatment of cardiomyopathy of ATTR amyloidosis.
“We remain confident in the HELIOS-B phase 3 study of vutrisiran and look forward to sharing topline results in early 2024. If successful, we believe vutrisiran will offer convenient, quarterly subcutaneous dosing with a therapeutic profile that may potentially include cardiovascular outcome benefits,” Alnylam CEO Yvonne Greenstreet, MBChB, said in the statement.
Intravenously administered patisiran is already approved in the United States and Canada for the treatment of polyneuropathy of hereditary ATTR amyloidosis in adults.
A version of this article first appeared on Medscape.com.
the company has announced.
ATTR amyloidosis is an underdiagnosed, rapidly progressive, debilitating, fatal disease caused by misfolded TTR proteins, which accumulate as amyloid deposits in various parts of the body, including the heart.
In September, the FDA Cardiovascular and Renal Drugs Advisory Committee voted 9 to 3 that the benefits of patisiran outweigh the risks for the treatment of ATTR amyloidosis cardiomyopathy on the basis of the results of the APOLLO-B phase 3 study.
However, many panel members questioned whether the benefits are clinically meaningful – a view shared by the FDA in a complete response letter (CRL) the FDA sent to Alnylam.
According to the company, the FDA indicated in the letter that the clinical meaningfulness of patisiran’s treatment effects for the cardiomyopathy of ATTR amyloidosis have “not been established,” and therefore, the supplemental new drug application for patisiran “could not be approved in its present form.”
The FDA did not identify any issues with respect to clinical safety, study conduct, drug quality, or manufacturing.
Nonetheless, as a result of the CRL, the company said it will no longer pursue an expanded indication for patisiran in cardiomyopathy of ATTR amyloidosis in the United States.
The company said it will continue to make patisiran available for patients with cardiomyopathy of ATTR amyloidosis who are enrolled in the open-label extension period of the APOLLO-B study and the patisiran expanded access protocol.
The company also said it will continue to focus on the HELIOS-B phase 3 study of vutrisiran, an investigational RNAi therapeutic in development for the treatment of cardiomyopathy of ATTR amyloidosis.
“We remain confident in the HELIOS-B phase 3 study of vutrisiran and look forward to sharing topline results in early 2024. If successful, we believe vutrisiran will offer convenient, quarterly subcutaneous dosing with a therapeutic profile that may potentially include cardiovascular outcome benefits,” Alnylam CEO Yvonne Greenstreet, MBChB, said in the statement.
Intravenously administered patisiran is already approved in the United States and Canada for the treatment of polyneuropathy of hereditary ATTR amyloidosis in adults.
A version of this article first appeared on Medscape.com.
the company has announced.
ATTR amyloidosis is an underdiagnosed, rapidly progressive, debilitating, fatal disease caused by misfolded TTR proteins, which accumulate as amyloid deposits in various parts of the body, including the heart.
In September, the FDA Cardiovascular and Renal Drugs Advisory Committee voted 9 to 3 that the benefits of patisiran outweigh the risks for the treatment of ATTR amyloidosis cardiomyopathy on the basis of the results of the APOLLO-B phase 3 study.
However, many panel members questioned whether the benefits are clinically meaningful – a view shared by the FDA in a complete response letter (CRL) the FDA sent to Alnylam.
According to the company, the FDA indicated in the letter that the clinical meaningfulness of patisiran’s treatment effects for the cardiomyopathy of ATTR amyloidosis have “not been established,” and therefore, the supplemental new drug application for patisiran “could not be approved in its present form.”
The FDA did not identify any issues with respect to clinical safety, study conduct, drug quality, or manufacturing.
Nonetheless, as a result of the CRL, the company said it will no longer pursue an expanded indication for patisiran in cardiomyopathy of ATTR amyloidosis in the United States.
The company said it will continue to make patisiran available for patients with cardiomyopathy of ATTR amyloidosis who are enrolled in the open-label extension period of the APOLLO-B study and the patisiran expanded access protocol.
The company also said it will continue to focus on the HELIOS-B phase 3 study of vutrisiran, an investigational RNAi therapeutic in development for the treatment of cardiomyopathy of ATTR amyloidosis.
“We remain confident in the HELIOS-B phase 3 study of vutrisiran and look forward to sharing topline results in early 2024. If successful, we believe vutrisiran will offer convenient, quarterly subcutaneous dosing with a therapeutic profile that may potentially include cardiovascular outcome benefits,” Alnylam CEO Yvonne Greenstreet, MBChB, said in the statement.
Intravenously administered patisiran is already approved in the United States and Canada for the treatment of polyneuropathy of hereditary ATTR amyloidosis in adults.
A version of this article first appeared on Medscape.com.