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Intimate partner violence: Opening the door to a safer future
THE CASE
Louise T* is a 42-year-old woman who presented to her family medicine office for a routine annual visit. During the exam, her physician noticed bruises on Ms. T’s arms and back. Upon further inquiry, Ms. T reported that she and her husband had argued the night before the appointment. With some hesitancy, she went on to say that this was not the first time this had happened. She said that she and her husband had been arguing frequently for several years and that 6 months earlier, when he lost his job, he began hitting and pushing her.
●
*The patient’s name has been changed to protect her identity.
Intimate partner violence (IPV) includes physical, sexual, or psychological aggression or stalking perpetrated by a current or former relationship partner.1 IPV affects more than 12 million men and women living in the United States each year.2 According to a national survey of IPV, approximately one-third (35.6%) of women and one-quarter (28.5%) of men living in the United States experience rape, physical violence, or stalking by an intimate partner during their lifetime.2 Lifetime exposure to psychological IPV is even more prevalent, affecting nearly half of women and men (48.4% and 48.8%, respectively).2
Lifetime prevalence of any form of IPV is higher among women who identify as bisexual (59.8%) and lesbian (46.3%) compared with those who identify as heterosexual (37.2%); rates are comparable among men who identify as heterosexual (31.9%), bisexual (35.3%), and gay (35.1%).3 Preliminary data suggest that IPV may have increased in frequency and severity during the COVID-19 pandemic, particularly in the context of mandated shelter-in-place and stay-at-home orders.4-6
IPV is associated with numerous negative health consequences. They include fear and concern for safety, mental health disorders such as posttraumatic stress disorder (PTSD), and physical health problems including physical injury, chronic pain, sleep disturbance, and frequent headaches.2 IPV is also associated with a greater number of missed days from school and work and increased utilization of legal, health care, and housing services.2,7 The overall annual cost of IPV against women is estimated at $5.8 billion, with health care costs accounting for approximately $4.1 billion.7 Family physicians can play an important role in curbing the devastating effects of IPV by screening patients and providing resources when needed.
Facilitate disclosure using screening tools and protocol
In Ms. T’s case, evidence of violence was clearly visible. However, not all instances of IPV leave physical marks. The US Preventive Services Task Force (USPSTF) recommends that all women of childbearing age be screened for IPV, whether or not they exhibit signs of violence.8 While the USPSTF has only published recommendations regarding screening women for IPV, there has been a recent push to screen all patients given that men also experience high rates of IPV.9
Utilize a brief screening tool. Directly ask patients about IPV; this can help reduce stigma, facilitate disclosure, and initiate the process of connecting patients to potentially lifesaving resources. The USPSTF lists several brief screening measures that can be used in primary care settings to assess exposure to IPV (TABLE 18,10-17). The brevity of these screening tools makes them well suited for busy physicians; cutoff scores facilitate the rapid identification of positive screens. While the USPSTF has not made specific recommendations regarding a screening interval, many studies examining the utility of these measures have reported on annual screenings.8 While there is limited evidence that brief screening alone leads to reductions in IPV,8 discussing IPV in a supportive and empathic manner and connecting patients to resources, such as supportive counseling, does have an important benefit: It can reduce symptoms of depression.18
Continue to: Screen patients in private; this protocol can help
Screen patients in private; this protocol can help. Given the sensitive nature of IPV and the potential danger some patients may be facing, it is important to screen patients in a safe and supportive environment.19,20 Screening should be conducted by the primary care clinician, ideally when a trusting relationship already has been formed. Screen patients only when they are alone in a private room; avoid screening in public spaces such as clinic waiting rooms or in the vicinity of the patient’s partner or children older than age 2 years.19,20
To provide all patients with an opportunity for private and safe IPV screening, clinics are encouraged to develop a clinic-wide policy whereby patients are routinely escorted to the exam room alone for the first portion of their visit, after which any accompanying individuals may be invited to join.21 Clinic staff can inform patients and accompanying individuals of this policy when they first arrive. Once in the exam room, and before the screening process begins, clearly state reporting requirements to ensure that patients can make an informed decision about whether to disclose IPV.19
Set a receptive tone. The manner in which clinicians discuss IPV with their patients is just as important as the setting. Demonstrating sensitivity and genuine concern for the patient’s safety and well-being may increase the patient’s comfort level throughout the screening process and may facilitate disclosures of IPV.19,22 When screening patients for IPV, sit face to face rather than standing over them, maintain warm and open body language, and speak in a soft tone of voice.22
Patients may feel more comfortable if you ask screening questions in a straightforward, nonjudgmental manner, as this helps to normalize the screening experience. We also recommend using behaviorally specific language (eg, “Do arguments [with your partner] ever result in hitting, kicking, or pushing?”16 or “How often does your partner scream or curse at you?”),13 as some patients who have experienced IPV will not label their experiences as “abuse” or “violence.” Not every patient who experiences IPV will be ready to disclose these events; however, maintaining a positive and supportive relationship during routine IPV screening and throughout the remainder of the medical visit may help facilitate future disclosures if, and when, a patient is ready to seek support.19
CRITICAL INTERVENTION ELEMENTS: EMPATHY AND SAFETY
A physician’s response to an IPV disclosure can have a lasting impact on the patient. We encourage family physicians to respond to IPV disclosures with empathy. Maintain eye contact and warm body language, validate the patient’s experiences (“I am sorry this happened to you,” “that must have been terrifying”), tell the patient that the violence was not their fault, and thank the patient for disclosing.23
Continue to: Assess patient safety
Assess patient safety. Another critical component of intervention is to assess the patient’s safety and engage in safety planning. If the patient agrees to this next step, you may wish to provide a warm handoff to a trained social worker, nurse, or psychologist in the clinic who can spend more time covering this information with the patient. Some key components of a safety assessment include determining whether the violence or threat of violence is ongoing and identifying who lives in the home (eg, the partner, children, and any pets). You and the patient can also discuss red flags that would indicate elevated risk. You should discuss red flags that are unique to the patient’s relationship as well as common factors that have been found to heighten risk for IPV (eg, partner engaging in heavy alcohol use).1
With the patient’s permission, collaboratively construct a safety plan that details how the patient can stay safe on a daily basis and how to safely leave should a dangerous situation arise (TABLE 29,24). The interactive safety planning tool available on the National Domestic Violence Hotline’s website can be a valuable resource (www.thehotline.org/plan-for-safety/).24 Finally, if a patient is experiencing mental health concerns associated with IPV (eg, PTSD, depression, substance misuse, suicidal ideation), consider a referral to a domestic violence counseling center or mental health provider.
Move at the patient’s pace. Even if patients are willing to disclose IPV, they will differ in their readiness to discuss psychoeducation, safety planning, and referrals. Similarly, even if a patient is experiencing severe violence, they may not be ready to leave the relationship. Thus, it’s important to ask the patient for permission before initiating each successive step of the follow-up intervention. You and the patient may wish to schedule additional appointments to discuss this information at a pace the patient finds appropriate.
You may need to spend some time helping the patient recognize the severity of their situation and to feel empowered to take action. In addition, offer information and resources to all patients, even those who do not disclose IPV. Some patients may want to receive this information even if they do not feel comfortable sharing their experiences during the appointment.20 You can also inform patients that they are welcome to bring up issues related to IPV at any future appointments in order to leave the door open to future disclosures.
THE CASE
The physician determined that Ms. T had been experiencing physical and psychological IPV in her current relationship. After responding empathically and obtaining the patient’s consent, the physician provided a warm handoff to the psychologist in the clinic. With Ms. T’s permission, the psychologist provided psychoeducation about IPV, and they discussed Ms. T’s current situation and risk level. They determined that Ms. T was at risk for subsequent episodes of IPV and they collaborated on a safety plan, making sure to discuss contact information for local and national crisis resources.
Continue to: Ms. T saved the phone number...
Ms. T saved the phone number for her local domestic violence shelter in her phone under a false name in case her husband looked through her phone. She said she planned to work on several safety plan items when her husband was away from the house and it was safe to do so. For example, she planned to identify additional ways to exit the house in an emergency and she was going to put together a bag with a change of clothes and some money and drop it off at a trusted friend’s house.
Ms. T and the psychologist agreed to follow up with an office visit in 1 week to discuss any additional safety concerns and to determine whether Ms. T could benefit from a referral to domestic violence counseling services or mental health treatment. The psychologist provided a summary of the topics she and Ms. T had discussed to the physician. The physician scheduled a follow-up appointment with Ms. T in 3 weeks to assess her current safety, troubleshoot any difficulties in implementing her safety plan, and offer additional resources, as needed.
CORRESPONDENCE
Andrea Massa, PhD, 125 Doughty Street, Suite 300, Charleston, SC 29403; massa@musc.edu
1. CDC. National Center for Injury Prevention and Control. Preventing intimate partner violence. 2021. Accessed June 27, 2022. www.cdc.gov/violenceprevention/intimatepartnerviolence/fastfact.html
2. CDC. Black MC, Basile KC, Breiding MJ, et al. The National Intimate Partner and Sexual Violence Survey: 2010 Summary Report. Accessed June 27, 2022. www.cdc.gov/violenceprevention/pdf/nisvs_executive_summary-a.pdf
3. Chen J, Walters ML, Gilbert LK, et al. Sexual violence, stalking, and intimate partner violence by sexual orientation, United States. Psychol Violence. 2020;10:110-119. doi:10.1037/vio0000252
4. Kofman YB, Garfin DR. Home is not always a haven: the domestic violence crisis amid the COVID-19 pandemic. Psychol Trauma. 2020;12:S199-S201. doi:10.1037/tra0000866
5. Lyons M, Brewer G. Experiences of intimate partner violence during lockdown and the COVID-19 pandemic. J Fam Violence. 2021:1-9. doi:10.1007/s10896-021-00260-x
6. Parrott DJ, Halmos MB, Stappenbeck CA, et al. Intimate partner aggression during the COVID-19 pandemic: associations with stress and heavy drinking. Psychol Violence. 2021;12:95-103. doi:10.1037/vio0000395
7. CDC. National Center for Injury Prevention and
8. US Preventive Services Task Force. Screening for intimate partner violence, elder abuse, and abuse of vulnerable adults: US Preventive Services Task Force final recommendation statement. JAMA. 2018;320:1678-1687. doi:10.1001/jama.2018.14741
9. Sprunger JG, Schumacher JA, Coffey SF, et al. It’s time to start asking all patients about intimate partner violence. J Fam Pract. 2019;68:152-161.
10. Chan CC, Chan YC, Au A, et al. Reliability and validity of the “Extended - Hurt, Insult, Threaten, Scream” (E-HITS) screening tool in detecting intimate partner violence in hospital emergency departments in Hong Kong. Hong Kong J Emerg Med. 2010;17:109-117. doi:10.1177/102490791001700202
11. Iverson KM, King MW, Gerber MR, et al. Accuracy of an intimate partner violence screening tool for female VHA patients: a replication and extension. J Trauma Stress. 2015;28:79-82. doi:10.1002/jts.21985
12. Sohal H, Eldridge S, Feder G. The sensitivity and specificity of four questions (HARK) to identify intimate partner violence: a diagnostic accuracy study in general practice. BMC Fam Pract. 2007;8:49. doi:10.1186/1471-2296-8-49
13. Sherin KM, Sinacore JM, Li X, et al. HITS: a short domestic violence screening tool for use in a family practice setting. Fam Med. 1998;30:508-512.
14. Rabin RF, Jennings JM, Campbell JC, et al. Intimate partner violence screening tools: a systematic review. Am J Prev Med. 2009;36:439-445.e4. doi:10.1016/j.amepre.2009.01.024
15. Feldhaus KM, Koziol-McLain J, Amsbury HL, et al. Accuracy of 3 brief screening questions for detecting partner violence in the emergency department. JAMA. 1997;277:1357-1361. doi:10.1001/jama.1997.03540410035027
16. Brown JB, Lent B, Schmidt G, et al. Application of the Woman Abuse Screening Tool (WAST) and WAST-short in the family practice setting. J Fam Pract. 2000;49:896-903.
17. Wathen CN, Jamieson E, MacMillan HL, MVAWRG. Who is identified by screening for intimate partner violence? Womens Health Issues. 2008;18:423-432. doi:10.1016/j.whi.2008.08.003
18. Hegarty K, O’Doherty L, Taft A, et al. Screening and counselling in the primary care setting for women who have experienced intimate partner violence (WEAVE): a cluster randomised controlled trial. Lancet. 2013;382:249-258. doi: 10.1016/S0140-6736(13)60052-5
19. Correa NP, Cain CM, Bertenthal M, et al. Women’s experiences of being screened for intimate partner violence in the health care setting. Nurs Womens Health. 2020;24:185-196. doi:10.1016/j.nwh.2020.04.002
20. Chang JC, Decker MR, Moracco KE, et al. Asking about intimate partner violence: advice from female survivors to health care providers. Patient Educ Couns. 2005;59:141-147. doi:10.1016/j.pec.2004.10.008
21. Paterno MT, Draughon JE. Screening for intimate partner violence. J Midwifery Womens Health. 2016;61:370-375. doi:10.1111/jmwh.12443
22. Iverson KM, Huang K, Wells SY, et al. Women veterans’ preferences for intimate partner violence screening and response procedures within the Veterans Health Administration. Res Nurs Health. 2014;37:302-311. doi:10.1002/nur.21602
23. National Sexual Violence Research Center. Assessing patients for sexual violence: A guide for health care providers. 2011. Accessed June 28, 2022. www.nsvrc.org/publications/assessing-patients-sexual-violence-guide-health-care-providers
24. National Domestic Violence Hotline. Interactive guide to safety planning. Accessed August 22, 2022. https://www.thehotline.org/plan-for-safety/create-a-safety-plan/
THE CASE
Louise T* is a 42-year-old woman who presented to her family medicine office for a routine annual visit. During the exam, her physician noticed bruises on Ms. T’s arms and back. Upon further inquiry, Ms. T reported that she and her husband had argued the night before the appointment. With some hesitancy, she went on to say that this was not the first time this had happened. She said that she and her husband had been arguing frequently for several years and that 6 months earlier, when he lost his job, he began hitting and pushing her.
●
*The patient’s name has been changed to protect her identity.
Intimate partner violence (IPV) includes physical, sexual, or psychological aggression or stalking perpetrated by a current or former relationship partner.1 IPV affects more than 12 million men and women living in the United States each year.2 According to a national survey of IPV, approximately one-third (35.6%) of women and one-quarter (28.5%) of men living in the United States experience rape, physical violence, or stalking by an intimate partner during their lifetime.2 Lifetime exposure to psychological IPV is even more prevalent, affecting nearly half of women and men (48.4% and 48.8%, respectively).2
Lifetime prevalence of any form of IPV is higher among women who identify as bisexual (59.8%) and lesbian (46.3%) compared with those who identify as heterosexual (37.2%); rates are comparable among men who identify as heterosexual (31.9%), bisexual (35.3%), and gay (35.1%).3 Preliminary data suggest that IPV may have increased in frequency and severity during the COVID-19 pandemic, particularly in the context of mandated shelter-in-place and stay-at-home orders.4-6
IPV is associated with numerous negative health consequences. They include fear and concern for safety, mental health disorders such as posttraumatic stress disorder (PTSD), and physical health problems including physical injury, chronic pain, sleep disturbance, and frequent headaches.2 IPV is also associated with a greater number of missed days from school and work and increased utilization of legal, health care, and housing services.2,7 The overall annual cost of IPV against women is estimated at $5.8 billion, with health care costs accounting for approximately $4.1 billion.7 Family physicians can play an important role in curbing the devastating effects of IPV by screening patients and providing resources when needed.
Facilitate disclosure using screening tools and protocol
In Ms. T’s case, evidence of violence was clearly visible. However, not all instances of IPV leave physical marks. The US Preventive Services Task Force (USPSTF) recommends that all women of childbearing age be screened for IPV, whether or not they exhibit signs of violence.8 While the USPSTF has only published recommendations regarding screening women for IPV, there has been a recent push to screen all patients given that men also experience high rates of IPV.9
Utilize a brief screening tool. Directly ask patients about IPV; this can help reduce stigma, facilitate disclosure, and initiate the process of connecting patients to potentially lifesaving resources. The USPSTF lists several brief screening measures that can be used in primary care settings to assess exposure to IPV (TABLE 18,10-17). The brevity of these screening tools makes them well suited for busy physicians; cutoff scores facilitate the rapid identification of positive screens. While the USPSTF has not made specific recommendations regarding a screening interval, many studies examining the utility of these measures have reported on annual screenings.8 While there is limited evidence that brief screening alone leads to reductions in IPV,8 discussing IPV in a supportive and empathic manner and connecting patients to resources, such as supportive counseling, does have an important benefit: It can reduce symptoms of depression.18
Continue to: Screen patients in private; this protocol can help
Screen patients in private; this protocol can help. Given the sensitive nature of IPV and the potential danger some patients may be facing, it is important to screen patients in a safe and supportive environment.19,20 Screening should be conducted by the primary care clinician, ideally when a trusting relationship already has been formed. Screen patients only when they are alone in a private room; avoid screening in public spaces such as clinic waiting rooms or in the vicinity of the patient’s partner or children older than age 2 years.19,20
To provide all patients with an opportunity for private and safe IPV screening, clinics are encouraged to develop a clinic-wide policy whereby patients are routinely escorted to the exam room alone for the first portion of their visit, after which any accompanying individuals may be invited to join.21 Clinic staff can inform patients and accompanying individuals of this policy when they first arrive. Once in the exam room, and before the screening process begins, clearly state reporting requirements to ensure that patients can make an informed decision about whether to disclose IPV.19
Set a receptive tone. The manner in which clinicians discuss IPV with their patients is just as important as the setting. Demonstrating sensitivity and genuine concern for the patient’s safety and well-being may increase the patient’s comfort level throughout the screening process and may facilitate disclosures of IPV.19,22 When screening patients for IPV, sit face to face rather than standing over them, maintain warm and open body language, and speak in a soft tone of voice.22
Patients may feel more comfortable if you ask screening questions in a straightforward, nonjudgmental manner, as this helps to normalize the screening experience. We also recommend using behaviorally specific language (eg, “Do arguments [with your partner] ever result in hitting, kicking, or pushing?”16 or “How often does your partner scream or curse at you?”),13 as some patients who have experienced IPV will not label their experiences as “abuse” or “violence.” Not every patient who experiences IPV will be ready to disclose these events; however, maintaining a positive and supportive relationship during routine IPV screening and throughout the remainder of the medical visit may help facilitate future disclosures if, and when, a patient is ready to seek support.19
CRITICAL INTERVENTION ELEMENTS: EMPATHY AND SAFETY
A physician’s response to an IPV disclosure can have a lasting impact on the patient. We encourage family physicians to respond to IPV disclosures with empathy. Maintain eye contact and warm body language, validate the patient’s experiences (“I am sorry this happened to you,” “that must have been terrifying”), tell the patient that the violence was not their fault, and thank the patient for disclosing.23
Continue to: Assess patient safety
Assess patient safety. Another critical component of intervention is to assess the patient’s safety and engage in safety planning. If the patient agrees to this next step, you may wish to provide a warm handoff to a trained social worker, nurse, or psychologist in the clinic who can spend more time covering this information with the patient. Some key components of a safety assessment include determining whether the violence or threat of violence is ongoing and identifying who lives in the home (eg, the partner, children, and any pets). You and the patient can also discuss red flags that would indicate elevated risk. You should discuss red flags that are unique to the patient’s relationship as well as common factors that have been found to heighten risk for IPV (eg, partner engaging in heavy alcohol use).1
With the patient’s permission, collaboratively construct a safety plan that details how the patient can stay safe on a daily basis and how to safely leave should a dangerous situation arise (TABLE 29,24). The interactive safety planning tool available on the National Domestic Violence Hotline’s website can be a valuable resource (www.thehotline.org/plan-for-safety/).24 Finally, if a patient is experiencing mental health concerns associated with IPV (eg, PTSD, depression, substance misuse, suicidal ideation), consider a referral to a domestic violence counseling center or mental health provider.
Move at the patient’s pace. Even if patients are willing to disclose IPV, they will differ in their readiness to discuss psychoeducation, safety planning, and referrals. Similarly, even if a patient is experiencing severe violence, they may not be ready to leave the relationship. Thus, it’s important to ask the patient for permission before initiating each successive step of the follow-up intervention. You and the patient may wish to schedule additional appointments to discuss this information at a pace the patient finds appropriate.
You may need to spend some time helping the patient recognize the severity of their situation and to feel empowered to take action. In addition, offer information and resources to all patients, even those who do not disclose IPV. Some patients may want to receive this information even if they do not feel comfortable sharing their experiences during the appointment.20 You can also inform patients that they are welcome to bring up issues related to IPV at any future appointments in order to leave the door open to future disclosures.
THE CASE
The physician determined that Ms. T had been experiencing physical and psychological IPV in her current relationship. After responding empathically and obtaining the patient’s consent, the physician provided a warm handoff to the psychologist in the clinic. With Ms. T’s permission, the psychologist provided psychoeducation about IPV, and they discussed Ms. T’s current situation and risk level. They determined that Ms. T was at risk for subsequent episodes of IPV and they collaborated on a safety plan, making sure to discuss contact information for local and national crisis resources.
Continue to: Ms. T saved the phone number...
Ms. T saved the phone number for her local domestic violence shelter in her phone under a false name in case her husband looked through her phone. She said she planned to work on several safety plan items when her husband was away from the house and it was safe to do so. For example, she planned to identify additional ways to exit the house in an emergency and she was going to put together a bag with a change of clothes and some money and drop it off at a trusted friend’s house.
Ms. T and the psychologist agreed to follow up with an office visit in 1 week to discuss any additional safety concerns and to determine whether Ms. T could benefit from a referral to domestic violence counseling services or mental health treatment. The psychologist provided a summary of the topics she and Ms. T had discussed to the physician. The physician scheduled a follow-up appointment with Ms. T in 3 weeks to assess her current safety, troubleshoot any difficulties in implementing her safety plan, and offer additional resources, as needed.
CORRESPONDENCE
Andrea Massa, PhD, 125 Doughty Street, Suite 300, Charleston, SC 29403; massa@musc.edu
THE CASE
Louise T* is a 42-year-old woman who presented to her family medicine office for a routine annual visit. During the exam, her physician noticed bruises on Ms. T’s arms and back. Upon further inquiry, Ms. T reported that she and her husband had argued the night before the appointment. With some hesitancy, she went on to say that this was not the first time this had happened. She said that she and her husband had been arguing frequently for several years and that 6 months earlier, when he lost his job, he began hitting and pushing her.
●
*The patient’s name has been changed to protect her identity.
Intimate partner violence (IPV) includes physical, sexual, or psychological aggression or stalking perpetrated by a current or former relationship partner.1 IPV affects more than 12 million men and women living in the United States each year.2 According to a national survey of IPV, approximately one-third (35.6%) of women and one-quarter (28.5%) of men living in the United States experience rape, physical violence, or stalking by an intimate partner during their lifetime.2 Lifetime exposure to psychological IPV is even more prevalent, affecting nearly half of women and men (48.4% and 48.8%, respectively).2
Lifetime prevalence of any form of IPV is higher among women who identify as bisexual (59.8%) and lesbian (46.3%) compared with those who identify as heterosexual (37.2%); rates are comparable among men who identify as heterosexual (31.9%), bisexual (35.3%), and gay (35.1%).3 Preliminary data suggest that IPV may have increased in frequency and severity during the COVID-19 pandemic, particularly in the context of mandated shelter-in-place and stay-at-home orders.4-6
IPV is associated with numerous negative health consequences. They include fear and concern for safety, mental health disorders such as posttraumatic stress disorder (PTSD), and physical health problems including physical injury, chronic pain, sleep disturbance, and frequent headaches.2 IPV is also associated with a greater number of missed days from school and work and increased utilization of legal, health care, and housing services.2,7 The overall annual cost of IPV against women is estimated at $5.8 billion, with health care costs accounting for approximately $4.1 billion.7 Family physicians can play an important role in curbing the devastating effects of IPV by screening patients and providing resources when needed.
Facilitate disclosure using screening tools and protocol
In Ms. T’s case, evidence of violence was clearly visible. However, not all instances of IPV leave physical marks. The US Preventive Services Task Force (USPSTF) recommends that all women of childbearing age be screened for IPV, whether or not they exhibit signs of violence.8 While the USPSTF has only published recommendations regarding screening women for IPV, there has been a recent push to screen all patients given that men also experience high rates of IPV.9
Utilize a brief screening tool. Directly ask patients about IPV; this can help reduce stigma, facilitate disclosure, and initiate the process of connecting patients to potentially lifesaving resources. The USPSTF lists several brief screening measures that can be used in primary care settings to assess exposure to IPV (TABLE 18,10-17). The brevity of these screening tools makes them well suited for busy physicians; cutoff scores facilitate the rapid identification of positive screens. While the USPSTF has not made specific recommendations regarding a screening interval, many studies examining the utility of these measures have reported on annual screenings.8 While there is limited evidence that brief screening alone leads to reductions in IPV,8 discussing IPV in a supportive and empathic manner and connecting patients to resources, such as supportive counseling, does have an important benefit: It can reduce symptoms of depression.18
Continue to: Screen patients in private; this protocol can help
Screen patients in private; this protocol can help. Given the sensitive nature of IPV and the potential danger some patients may be facing, it is important to screen patients in a safe and supportive environment.19,20 Screening should be conducted by the primary care clinician, ideally when a trusting relationship already has been formed. Screen patients only when they are alone in a private room; avoid screening in public spaces such as clinic waiting rooms or in the vicinity of the patient’s partner or children older than age 2 years.19,20
To provide all patients with an opportunity for private and safe IPV screening, clinics are encouraged to develop a clinic-wide policy whereby patients are routinely escorted to the exam room alone for the first portion of their visit, after which any accompanying individuals may be invited to join.21 Clinic staff can inform patients and accompanying individuals of this policy when they first arrive. Once in the exam room, and before the screening process begins, clearly state reporting requirements to ensure that patients can make an informed decision about whether to disclose IPV.19
Set a receptive tone. The manner in which clinicians discuss IPV with their patients is just as important as the setting. Demonstrating sensitivity and genuine concern for the patient’s safety and well-being may increase the patient’s comfort level throughout the screening process and may facilitate disclosures of IPV.19,22 When screening patients for IPV, sit face to face rather than standing over them, maintain warm and open body language, and speak in a soft tone of voice.22
Patients may feel more comfortable if you ask screening questions in a straightforward, nonjudgmental manner, as this helps to normalize the screening experience. We also recommend using behaviorally specific language (eg, “Do arguments [with your partner] ever result in hitting, kicking, or pushing?”16 or “How often does your partner scream or curse at you?”),13 as some patients who have experienced IPV will not label their experiences as “abuse” or “violence.” Not every patient who experiences IPV will be ready to disclose these events; however, maintaining a positive and supportive relationship during routine IPV screening and throughout the remainder of the medical visit may help facilitate future disclosures if, and when, a patient is ready to seek support.19
CRITICAL INTERVENTION ELEMENTS: EMPATHY AND SAFETY
A physician’s response to an IPV disclosure can have a lasting impact on the patient. We encourage family physicians to respond to IPV disclosures with empathy. Maintain eye contact and warm body language, validate the patient’s experiences (“I am sorry this happened to you,” “that must have been terrifying”), tell the patient that the violence was not their fault, and thank the patient for disclosing.23
Continue to: Assess patient safety
Assess patient safety. Another critical component of intervention is to assess the patient’s safety and engage in safety planning. If the patient agrees to this next step, you may wish to provide a warm handoff to a trained social worker, nurse, or psychologist in the clinic who can spend more time covering this information with the patient. Some key components of a safety assessment include determining whether the violence or threat of violence is ongoing and identifying who lives in the home (eg, the partner, children, and any pets). You and the patient can also discuss red flags that would indicate elevated risk. You should discuss red flags that are unique to the patient’s relationship as well as common factors that have been found to heighten risk for IPV (eg, partner engaging in heavy alcohol use).1
With the patient’s permission, collaboratively construct a safety plan that details how the patient can stay safe on a daily basis and how to safely leave should a dangerous situation arise (TABLE 29,24). The interactive safety planning tool available on the National Domestic Violence Hotline’s website can be a valuable resource (www.thehotline.org/plan-for-safety/).24 Finally, if a patient is experiencing mental health concerns associated with IPV (eg, PTSD, depression, substance misuse, suicidal ideation), consider a referral to a domestic violence counseling center or mental health provider.
Move at the patient’s pace. Even if patients are willing to disclose IPV, they will differ in their readiness to discuss psychoeducation, safety planning, and referrals. Similarly, even if a patient is experiencing severe violence, they may not be ready to leave the relationship. Thus, it’s important to ask the patient for permission before initiating each successive step of the follow-up intervention. You and the patient may wish to schedule additional appointments to discuss this information at a pace the patient finds appropriate.
You may need to spend some time helping the patient recognize the severity of their situation and to feel empowered to take action. In addition, offer information and resources to all patients, even those who do not disclose IPV. Some patients may want to receive this information even if they do not feel comfortable sharing their experiences during the appointment.20 You can also inform patients that they are welcome to bring up issues related to IPV at any future appointments in order to leave the door open to future disclosures.
THE CASE
The physician determined that Ms. T had been experiencing physical and psychological IPV in her current relationship. After responding empathically and obtaining the patient’s consent, the physician provided a warm handoff to the psychologist in the clinic. With Ms. T’s permission, the psychologist provided psychoeducation about IPV, and they discussed Ms. T’s current situation and risk level. They determined that Ms. T was at risk for subsequent episodes of IPV and they collaborated on a safety plan, making sure to discuss contact information for local and national crisis resources.
Continue to: Ms. T saved the phone number...
Ms. T saved the phone number for her local domestic violence shelter in her phone under a false name in case her husband looked through her phone. She said she planned to work on several safety plan items when her husband was away from the house and it was safe to do so. For example, she planned to identify additional ways to exit the house in an emergency and she was going to put together a bag with a change of clothes and some money and drop it off at a trusted friend’s house.
Ms. T and the psychologist agreed to follow up with an office visit in 1 week to discuss any additional safety concerns and to determine whether Ms. T could benefit from a referral to domestic violence counseling services or mental health treatment. The psychologist provided a summary of the topics she and Ms. T had discussed to the physician. The physician scheduled a follow-up appointment with Ms. T in 3 weeks to assess her current safety, troubleshoot any difficulties in implementing her safety plan, and offer additional resources, as needed.
CORRESPONDENCE
Andrea Massa, PhD, 125 Doughty Street, Suite 300, Charleston, SC 29403; massa@musc.edu
1. CDC. National Center for Injury Prevention and Control. Preventing intimate partner violence. 2021. Accessed June 27, 2022. www.cdc.gov/violenceprevention/intimatepartnerviolence/fastfact.html
2. CDC. Black MC, Basile KC, Breiding MJ, et al. The National Intimate Partner and Sexual Violence Survey: 2010 Summary Report. Accessed June 27, 2022. www.cdc.gov/violenceprevention/pdf/nisvs_executive_summary-a.pdf
3. Chen J, Walters ML, Gilbert LK, et al. Sexual violence, stalking, and intimate partner violence by sexual orientation, United States. Psychol Violence. 2020;10:110-119. doi:10.1037/vio0000252
4. Kofman YB, Garfin DR. Home is not always a haven: the domestic violence crisis amid the COVID-19 pandemic. Psychol Trauma. 2020;12:S199-S201. doi:10.1037/tra0000866
5. Lyons M, Brewer G. Experiences of intimate partner violence during lockdown and the COVID-19 pandemic. J Fam Violence. 2021:1-9. doi:10.1007/s10896-021-00260-x
6. Parrott DJ, Halmos MB, Stappenbeck CA, et al. Intimate partner aggression during the COVID-19 pandemic: associations with stress and heavy drinking. Psychol Violence. 2021;12:95-103. doi:10.1037/vio0000395
7. CDC. National Center for Injury Prevention and
8. US Preventive Services Task Force. Screening for intimate partner violence, elder abuse, and abuse of vulnerable adults: US Preventive Services Task Force final recommendation statement. JAMA. 2018;320:1678-1687. doi:10.1001/jama.2018.14741
9. Sprunger JG, Schumacher JA, Coffey SF, et al. It’s time to start asking all patients about intimate partner violence. J Fam Pract. 2019;68:152-161.
10. Chan CC, Chan YC, Au A, et al. Reliability and validity of the “Extended - Hurt, Insult, Threaten, Scream” (E-HITS) screening tool in detecting intimate partner violence in hospital emergency departments in Hong Kong. Hong Kong J Emerg Med. 2010;17:109-117. doi:10.1177/102490791001700202
11. Iverson KM, King MW, Gerber MR, et al. Accuracy of an intimate partner violence screening tool for female VHA patients: a replication and extension. J Trauma Stress. 2015;28:79-82. doi:10.1002/jts.21985
12. Sohal H, Eldridge S, Feder G. The sensitivity and specificity of four questions (HARK) to identify intimate partner violence: a diagnostic accuracy study in general practice. BMC Fam Pract. 2007;8:49. doi:10.1186/1471-2296-8-49
13. Sherin KM, Sinacore JM, Li X, et al. HITS: a short domestic violence screening tool for use in a family practice setting. Fam Med. 1998;30:508-512.
14. Rabin RF, Jennings JM, Campbell JC, et al. Intimate partner violence screening tools: a systematic review. Am J Prev Med. 2009;36:439-445.e4. doi:10.1016/j.amepre.2009.01.024
15. Feldhaus KM, Koziol-McLain J, Amsbury HL, et al. Accuracy of 3 brief screening questions for detecting partner violence in the emergency department. JAMA. 1997;277:1357-1361. doi:10.1001/jama.1997.03540410035027
16. Brown JB, Lent B, Schmidt G, et al. Application of the Woman Abuse Screening Tool (WAST) and WAST-short in the family practice setting. J Fam Pract. 2000;49:896-903.
17. Wathen CN, Jamieson E, MacMillan HL, MVAWRG. Who is identified by screening for intimate partner violence? Womens Health Issues. 2008;18:423-432. doi:10.1016/j.whi.2008.08.003
18. Hegarty K, O’Doherty L, Taft A, et al. Screening and counselling in the primary care setting for women who have experienced intimate partner violence (WEAVE): a cluster randomised controlled trial. Lancet. 2013;382:249-258. doi: 10.1016/S0140-6736(13)60052-5
19. Correa NP, Cain CM, Bertenthal M, et al. Women’s experiences of being screened for intimate partner violence in the health care setting. Nurs Womens Health. 2020;24:185-196. doi:10.1016/j.nwh.2020.04.002
20. Chang JC, Decker MR, Moracco KE, et al. Asking about intimate partner violence: advice from female survivors to health care providers. Patient Educ Couns. 2005;59:141-147. doi:10.1016/j.pec.2004.10.008
21. Paterno MT, Draughon JE. Screening for intimate partner violence. J Midwifery Womens Health. 2016;61:370-375. doi:10.1111/jmwh.12443
22. Iverson KM, Huang K, Wells SY, et al. Women veterans’ preferences for intimate partner violence screening and response procedures within the Veterans Health Administration. Res Nurs Health. 2014;37:302-311. doi:10.1002/nur.21602
23. National Sexual Violence Research Center. Assessing patients for sexual violence: A guide for health care providers. 2011. Accessed June 28, 2022. www.nsvrc.org/publications/assessing-patients-sexual-violence-guide-health-care-providers
24. National Domestic Violence Hotline. Interactive guide to safety planning. Accessed August 22, 2022. https://www.thehotline.org/plan-for-safety/create-a-safety-plan/
1. CDC. National Center for Injury Prevention and Control. Preventing intimate partner violence. 2021. Accessed June 27, 2022. www.cdc.gov/violenceprevention/intimatepartnerviolence/fastfact.html
2. CDC. Black MC, Basile KC, Breiding MJ, et al. The National Intimate Partner and Sexual Violence Survey: 2010 Summary Report. Accessed June 27, 2022. www.cdc.gov/violenceprevention/pdf/nisvs_executive_summary-a.pdf
3. Chen J, Walters ML, Gilbert LK, et al. Sexual violence, stalking, and intimate partner violence by sexual orientation, United States. Psychol Violence. 2020;10:110-119. doi:10.1037/vio0000252
4. Kofman YB, Garfin DR. Home is not always a haven: the domestic violence crisis amid the COVID-19 pandemic. Psychol Trauma. 2020;12:S199-S201. doi:10.1037/tra0000866
5. Lyons M, Brewer G. Experiences of intimate partner violence during lockdown and the COVID-19 pandemic. J Fam Violence. 2021:1-9. doi:10.1007/s10896-021-00260-x
6. Parrott DJ, Halmos MB, Stappenbeck CA, et al. Intimate partner aggression during the COVID-19 pandemic: associations with stress and heavy drinking. Psychol Violence. 2021;12:95-103. doi:10.1037/vio0000395
7. CDC. National Center for Injury Prevention and
8. US Preventive Services Task Force. Screening for intimate partner violence, elder abuse, and abuse of vulnerable adults: US Preventive Services Task Force final recommendation statement. JAMA. 2018;320:1678-1687. doi:10.1001/jama.2018.14741
9. Sprunger JG, Schumacher JA, Coffey SF, et al. It’s time to start asking all patients about intimate partner violence. J Fam Pract. 2019;68:152-161.
10. Chan CC, Chan YC, Au A, et al. Reliability and validity of the “Extended - Hurt, Insult, Threaten, Scream” (E-HITS) screening tool in detecting intimate partner violence in hospital emergency departments in Hong Kong. Hong Kong J Emerg Med. 2010;17:109-117. doi:10.1177/102490791001700202
11. Iverson KM, King MW, Gerber MR, et al. Accuracy of an intimate partner violence screening tool for female VHA patients: a replication and extension. J Trauma Stress. 2015;28:79-82. doi:10.1002/jts.21985
12. Sohal H, Eldridge S, Feder G. The sensitivity and specificity of four questions (HARK) to identify intimate partner violence: a diagnostic accuracy study in general practice. BMC Fam Pract. 2007;8:49. doi:10.1186/1471-2296-8-49
13. Sherin KM, Sinacore JM, Li X, et al. HITS: a short domestic violence screening tool for use in a family practice setting. Fam Med. 1998;30:508-512.
14. Rabin RF, Jennings JM, Campbell JC, et al. Intimate partner violence screening tools: a systematic review. Am J Prev Med. 2009;36:439-445.e4. doi:10.1016/j.amepre.2009.01.024
15. Feldhaus KM, Koziol-McLain J, Amsbury HL, et al. Accuracy of 3 brief screening questions for detecting partner violence in the emergency department. JAMA. 1997;277:1357-1361. doi:10.1001/jama.1997.03540410035027
16. Brown JB, Lent B, Schmidt G, et al. Application of the Woman Abuse Screening Tool (WAST) and WAST-short in the family practice setting. J Fam Pract. 2000;49:896-903.
17. Wathen CN, Jamieson E, MacMillan HL, MVAWRG. Who is identified by screening for intimate partner violence? Womens Health Issues. 2008;18:423-432. doi:10.1016/j.whi.2008.08.003
18. Hegarty K, O’Doherty L, Taft A, et al. Screening and counselling in the primary care setting for women who have experienced intimate partner violence (WEAVE): a cluster randomised controlled trial. Lancet. 2013;382:249-258. doi: 10.1016/S0140-6736(13)60052-5
19. Correa NP, Cain CM, Bertenthal M, et al. Women’s experiences of being screened for intimate partner violence in the health care setting. Nurs Womens Health. 2020;24:185-196. doi:10.1016/j.nwh.2020.04.002
20. Chang JC, Decker MR, Moracco KE, et al. Asking about intimate partner violence: advice from female survivors to health care providers. Patient Educ Couns. 2005;59:141-147. doi:10.1016/j.pec.2004.10.008
21. Paterno MT, Draughon JE. Screening for intimate partner violence. J Midwifery Womens Health. 2016;61:370-375. doi:10.1111/jmwh.12443
22. Iverson KM, Huang K, Wells SY, et al. Women veterans’ preferences for intimate partner violence screening and response procedures within the Veterans Health Administration. Res Nurs Health. 2014;37:302-311. doi:10.1002/nur.21602
23. National Sexual Violence Research Center. Assessing patients for sexual violence: A guide for health care providers. 2011. Accessed June 28, 2022. www.nsvrc.org/publications/assessing-patients-sexual-violence-guide-health-care-providers
24. National Domestic Violence Hotline. Interactive guide to safety planning. Accessed August 22, 2022. https://www.thehotline.org/plan-for-safety/create-a-safety-plan/
Barriers to System Quality Improvement in Health Care
Corresponding author: Ebrahim Barkoudah, MD, MPH, Department of Medicine, Brigham and Women’s Hospital, Boston, MA; ebarkoudah@bwh.harvard.edu
Process improvement in any industry sector aims to increase the efficiency of resource utilization and delivery methods (cost) and the quality of the product (outcomes), with the goal of ultimately achieving continuous development.1 In the health care industry, variation in processes and outcomes along with inefficiency in resource use that result in changes in value (the product of outcomes/costs) are the general targets of quality improvement (QI) efforts employing various implementation methodologies.2 When the ultimate aim is to serve the patient (customer), best clinical practice includes both maintaining high quality (individual care delivery) and controlling costs (efficient care system delivery), leading to optimal delivery (value-based care). High-quality individual care and efficient care delivery are not competing concepts, but when working to improve both health care outcomes and cost, traditional and nontraditional barriers to system QI often arise.3
The possible scenarios after a QI intervention include backsliding (regression to the mean over time), steady-state (minimal fixed improvement that could sustain), and continuous improvement (tangible enhancement after completing the intervention with legacy effect).4 The scalability of results can be considered during the process measurement and the intervention design phases of all QI projects; however, the complex nature of barriers in the health care environment during each level of implementation should be accounted for to prevent failure in the scalability phase.5
The barriers to optimal QI outcomes leading to continuous improvement are multifactorial and are related to intrinsic and extrinsic factors.6 These factors include 3 fundamental levels: (1) individual level inertia/beliefs, prior personal knowledge, and team-related factors7,8; (2) intervention-related and process-specific barriers and clinical practice obstacles; and (3) organizational level challenges and macro-level and population-level barriers (Figure). The obstacles faced during the implementation phase will likely include 2 of these levels simultaneously, which could add complexity and hinder or prevent the implementation of a tangible successful QI process and eventually lead to backsliding or minimal fixed improvement rather than continuous improvement. Furthermore, a patient-centered approach to QI would contribute to further complexity in design and execution, given the importance of reaching sustainable, meaningful improvement by adding elements of patient’s preferences, caregiver engagement, and the shared decision-making processes.9
Overcoming these multidomain barriers and reaching resilience and sustainability requires thoughtful planning and execution through a multifaceted approach.10 A meaningful start could include addressing the clinical inertia for the individual and the team by promoting open innovation and allowing outside institutional collaborations and ideas through networks.11 On the individual level, encouraging participation and motivating health care workers in QI to reach a multidisciplinary operation approach will lead to harmony in collaboration. Concurrently, the organization should support the QI capability and scalability by removing competing priorities and establishing effective leadership that ensures resource allocation, communicates clear value-based principles, and engenders a psychological safety environment.
A continuous improvement state is the optimal QI target, a target that can be attained by removing obstacles and paving a clear pathway to implementation. Focusing on the 3 levels of barriers will position the organization for meaningful and successful QI phases to achieve continuous improvement.
1. Adesola S, Baines T. Developing and evaluating a methodology for business process improvement. Business Process Manage J. 2005;11(1):37-46. doi:10.1108/14637150510578719
2. Gershon M. Choosing which process improvement methodology to implement. J Appl Business & Economics. 2010;10(5):61-69.
3. Porter ME, Teisberg EO. Redefining Health Care: Creating Value-Based Competition on Results. Harvard Business Press; 2006.
4. Holweg M, Davies J, De Meyer A, Lawson B, Schmenner RW. Process Theory: The Principles of Operations Management. Oxford University Press; 2018.
5. Shortell SM, Bennett CL, Byck GR. Assessing the impact of continuous quality improvement on clinical practice: what it will take to accelerate progress. Milbank Q. 1998;76(4):593-624. doi:10.1111/1468-0009.00107
6. Solomons NM, Spross JA. Evidence‐based practice barriers and facilitators from a continuous quality improvement perspective: an integrative review. J Nurs Manage. 2011;19(1):109-120. doi:10.1111/j.1365-2834.2010.01144.x
7. Phillips LS, Branch WT, Cook CB, et al. Clinical inertia. Ann Intern Med. 2001;135(9):825-34. doi:10.7326/0003-4819-135-9-200111060-00012
8. Stevenson K, Baker R, Farooqi A, Sorrie R, Khunti K. Features of primary health care teams associated with successful quality improvement of diabetes care: a qualitative study. Fam Pract. 2001;18(1):21-26. doi:10.1093/fampra/18.1.21
9. What is patient-centered care? NEJM Catalyst. January 1, 2017. Accessed August 31, 2022. https://catalyst.nejm.org/doi/full/10.1056/CAT.17.0559
10. Kilbourne AM, Beck K, Spaeth‐Rublee B, et al. Measuring and improving the quality of mental health care: a global perspective. World Psychiatry. 2018;17(1):30-8. doi:10.1002/wps.20482
11. Huang HC, Lai MC, Lin LH, Chen CT. Overcoming organizational inertia to strengthen business model innovation: An open innovation perspective. J Organizational Change Manage. 2013;26(6):977-1002. doi:10.1108/JOCM-04-2012-0047
Corresponding author: Ebrahim Barkoudah, MD, MPH, Department of Medicine, Brigham and Women’s Hospital, Boston, MA; ebarkoudah@bwh.harvard.edu
Process improvement in any industry sector aims to increase the efficiency of resource utilization and delivery methods (cost) and the quality of the product (outcomes), with the goal of ultimately achieving continuous development.1 In the health care industry, variation in processes and outcomes along with inefficiency in resource use that result in changes in value (the product of outcomes/costs) are the general targets of quality improvement (QI) efforts employing various implementation methodologies.2 When the ultimate aim is to serve the patient (customer), best clinical practice includes both maintaining high quality (individual care delivery) and controlling costs (efficient care system delivery), leading to optimal delivery (value-based care). High-quality individual care and efficient care delivery are not competing concepts, but when working to improve both health care outcomes and cost, traditional and nontraditional barriers to system QI often arise.3
The possible scenarios after a QI intervention include backsliding (regression to the mean over time), steady-state (minimal fixed improvement that could sustain), and continuous improvement (tangible enhancement after completing the intervention with legacy effect).4 The scalability of results can be considered during the process measurement and the intervention design phases of all QI projects; however, the complex nature of barriers in the health care environment during each level of implementation should be accounted for to prevent failure in the scalability phase.5
The barriers to optimal QI outcomes leading to continuous improvement are multifactorial and are related to intrinsic and extrinsic factors.6 These factors include 3 fundamental levels: (1) individual level inertia/beliefs, prior personal knowledge, and team-related factors7,8; (2) intervention-related and process-specific barriers and clinical practice obstacles; and (3) organizational level challenges and macro-level and population-level barriers (Figure). The obstacles faced during the implementation phase will likely include 2 of these levels simultaneously, which could add complexity and hinder or prevent the implementation of a tangible successful QI process and eventually lead to backsliding or minimal fixed improvement rather than continuous improvement. Furthermore, a patient-centered approach to QI would contribute to further complexity in design and execution, given the importance of reaching sustainable, meaningful improvement by adding elements of patient’s preferences, caregiver engagement, and the shared decision-making processes.9
Overcoming these multidomain barriers and reaching resilience and sustainability requires thoughtful planning and execution through a multifaceted approach.10 A meaningful start could include addressing the clinical inertia for the individual and the team by promoting open innovation and allowing outside institutional collaborations and ideas through networks.11 On the individual level, encouraging participation and motivating health care workers in QI to reach a multidisciplinary operation approach will lead to harmony in collaboration. Concurrently, the organization should support the QI capability and scalability by removing competing priorities and establishing effective leadership that ensures resource allocation, communicates clear value-based principles, and engenders a psychological safety environment.
A continuous improvement state is the optimal QI target, a target that can be attained by removing obstacles and paving a clear pathway to implementation. Focusing on the 3 levels of barriers will position the organization for meaningful and successful QI phases to achieve continuous improvement.
Corresponding author: Ebrahim Barkoudah, MD, MPH, Department of Medicine, Brigham and Women’s Hospital, Boston, MA; ebarkoudah@bwh.harvard.edu
Process improvement in any industry sector aims to increase the efficiency of resource utilization and delivery methods (cost) and the quality of the product (outcomes), with the goal of ultimately achieving continuous development.1 In the health care industry, variation in processes and outcomes along with inefficiency in resource use that result in changes in value (the product of outcomes/costs) are the general targets of quality improvement (QI) efforts employing various implementation methodologies.2 When the ultimate aim is to serve the patient (customer), best clinical practice includes both maintaining high quality (individual care delivery) and controlling costs (efficient care system delivery), leading to optimal delivery (value-based care). High-quality individual care and efficient care delivery are not competing concepts, but when working to improve both health care outcomes and cost, traditional and nontraditional barriers to system QI often arise.3
The possible scenarios after a QI intervention include backsliding (regression to the mean over time), steady-state (minimal fixed improvement that could sustain), and continuous improvement (tangible enhancement after completing the intervention with legacy effect).4 The scalability of results can be considered during the process measurement and the intervention design phases of all QI projects; however, the complex nature of barriers in the health care environment during each level of implementation should be accounted for to prevent failure in the scalability phase.5
The barriers to optimal QI outcomes leading to continuous improvement are multifactorial and are related to intrinsic and extrinsic factors.6 These factors include 3 fundamental levels: (1) individual level inertia/beliefs, prior personal knowledge, and team-related factors7,8; (2) intervention-related and process-specific barriers and clinical practice obstacles; and (3) organizational level challenges and macro-level and population-level barriers (Figure). The obstacles faced during the implementation phase will likely include 2 of these levels simultaneously, which could add complexity and hinder or prevent the implementation of a tangible successful QI process and eventually lead to backsliding or minimal fixed improvement rather than continuous improvement. Furthermore, a patient-centered approach to QI would contribute to further complexity in design and execution, given the importance of reaching sustainable, meaningful improvement by adding elements of patient’s preferences, caregiver engagement, and the shared decision-making processes.9
Overcoming these multidomain barriers and reaching resilience and sustainability requires thoughtful planning and execution through a multifaceted approach.10 A meaningful start could include addressing the clinical inertia for the individual and the team by promoting open innovation and allowing outside institutional collaborations and ideas through networks.11 On the individual level, encouraging participation and motivating health care workers in QI to reach a multidisciplinary operation approach will lead to harmony in collaboration. Concurrently, the organization should support the QI capability and scalability by removing competing priorities and establishing effective leadership that ensures resource allocation, communicates clear value-based principles, and engenders a psychological safety environment.
A continuous improvement state is the optimal QI target, a target that can be attained by removing obstacles and paving a clear pathway to implementation. Focusing on the 3 levels of barriers will position the organization for meaningful and successful QI phases to achieve continuous improvement.
1. Adesola S, Baines T. Developing and evaluating a methodology for business process improvement. Business Process Manage J. 2005;11(1):37-46. doi:10.1108/14637150510578719
2. Gershon M. Choosing which process improvement methodology to implement. J Appl Business & Economics. 2010;10(5):61-69.
3. Porter ME, Teisberg EO. Redefining Health Care: Creating Value-Based Competition on Results. Harvard Business Press; 2006.
4. Holweg M, Davies J, De Meyer A, Lawson B, Schmenner RW. Process Theory: The Principles of Operations Management. Oxford University Press; 2018.
5. Shortell SM, Bennett CL, Byck GR. Assessing the impact of continuous quality improvement on clinical practice: what it will take to accelerate progress. Milbank Q. 1998;76(4):593-624. doi:10.1111/1468-0009.00107
6. Solomons NM, Spross JA. Evidence‐based practice barriers and facilitators from a continuous quality improvement perspective: an integrative review. J Nurs Manage. 2011;19(1):109-120. doi:10.1111/j.1365-2834.2010.01144.x
7. Phillips LS, Branch WT, Cook CB, et al. Clinical inertia. Ann Intern Med. 2001;135(9):825-34. doi:10.7326/0003-4819-135-9-200111060-00012
8. Stevenson K, Baker R, Farooqi A, Sorrie R, Khunti K. Features of primary health care teams associated with successful quality improvement of diabetes care: a qualitative study. Fam Pract. 2001;18(1):21-26. doi:10.1093/fampra/18.1.21
9. What is patient-centered care? NEJM Catalyst. January 1, 2017. Accessed August 31, 2022. https://catalyst.nejm.org/doi/full/10.1056/CAT.17.0559
10. Kilbourne AM, Beck K, Spaeth‐Rublee B, et al. Measuring and improving the quality of mental health care: a global perspective. World Psychiatry. 2018;17(1):30-8. doi:10.1002/wps.20482
11. Huang HC, Lai MC, Lin LH, Chen CT. Overcoming organizational inertia to strengthen business model innovation: An open innovation perspective. J Organizational Change Manage. 2013;26(6):977-1002. doi:10.1108/JOCM-04-2012-0047
1. Adesola S, Baines T. Developing and evaluating a methodology for business process improvement. Business Process Manage J. 2005;11(1):37-46. doi:10.1108/14637150510578719
2. Gershon M. Choosing which process improvement methodology to implement. J Appl Business & Economics. 2010;10(5):61-69.
3. Porter ME, Teisberg EO. Redefining Health Care: Creating Value-Based Competition on Results. Harvard Business Press; 2006.
4. Holweg M, Davies J, De Meyer A, Lawson B, Schmenner RW. Process Theory: The Principles of Operations Management. Oxford University Press; 2018.
5. Shortell SM, Bennett CL, Byck GR. Assessing the impact of continuous quality improvement on clinical practice: what it will take to accelerate progress. Milbank Q. 1998;76(4):593-624. doi:10.1111/1468-0009.00107
6. Solomons NM, Spross JA. Evidence‐based practice barriers and facilitators from a continuous quality improvement perspective: an integrative review. J Nurs Manage. 2011;19(1):109-120. doi:10.1111/j.1365-2834.2010.01144.x
7. Phillips LS, Branch WT, Cook CB, et al. Clinical inertia. Ann Intern Med. 2001;135(9):825-34. doi:10.7326/0003-4819-135-9-200111060-00012
8. Stevenson K, Baker R, Farooqi A, Sorrie R, Khunti K. Features of primary health care teams associated with successful quality improvement of diabetes care: a qualitative study. Fam Pract. 2001;18(1):21-26. doi:10.1093/fampra/18.1.21
9. What is patient-centered care? NEJM Catalyst. January 1, 2017. Accessed August 31, 2022. https://catalyst.nejm.org/doi/full/10.1056/CAT.17.0559
10. Kilbourne AM, Beck K, Spaeth‐Rublee B, et al. Measuring and improving the quality of mental health care: a global perspective. World Psychiatry. 2018;17(1):30-8. doi:10.1002/wps.20482
11. Huang HC, Lai MC, Lin LH, Chen CT. Overcoming organizational inertia to strengthen business model innovation: An open innovation perspective. J Organizational Change Manage. 2013;26(6):977-1002. doi:10.1108/JOCM-04-2012-0047
When the public misplaces their trust
Not long ago, the grandmother of my son’s friend died of COVID-19 infection. She was elderly and unvaccinated. Her grandson had no regrets over her unvaccinated status. “Why would she inject poison into her body?” he said, and then expressed a strong opinion that she had died because the hospital physicians refused to give her ivermectin and hydroxychloroquine. My son, wisely, did not push the issue.
Soon thereafter, my personal family physician emailed a newsletter to his patients (me included) with 3 important messages: (1) COVID vaccines were available in the office; (2) He was not going to prescribe hydroxychloroquine, no matter how adamantly it was requested; and (3) He warned against threatening him or his staff with lawsuits or violence over refusal to prescribe any unproven medication.
How, as a country, have we come to this? A sizeable portion of the public trusts the advice of quacks, hacks, and political opportunists over that of the nation’s most expert scientists and physicians. The National Institutes of Health maintains a website with up-to-date recommendations on the use of treatments for COVID-19. They assess the existing evidence and make recommendations for or against a wide array of interventions. (They recommend against the use of both ivermectin and hydroxychloroquine.) The Centers for Disease Control and Prevention publishes extensively about the current knowledge on the safety and efficacy of vaccines. Neither agency is part of a “deep state” or conspiracy. They are comprised of some of the nation’s leading scientists, including physicians, trying to protect the public from disease and foster good health.
Sadly, some physicians have been a source of inaccurate vaccine information; some even prescribe ineffective treatments despite the evidence. These physicians are either letting their politics override their good sense or are improperly assessing the scientific literature, or both. Medical licensing agencies, and specialty certification boards, need to find ways to prevent this—ways that can survive judicial scrutiny and allow for legitimate scientific debate.
I have been tempted to just accept the current situation as the inevitable outcome of social media–fueled tribalism. But when we know that the COVID death rate among the unvaccinated is 9 times that of people who have received a booster dose,1 I can’t sit idly and watch the Internet pundits prevail. Instead, I continue to advise and teach my students to have confidence in trustworthy authorities and websites. Mistakes will be made; corrections will be issued. However, this is not evidence of malintent or incompetence, but rather, the scientific process in action.
I tell my students that one of the biggest challenges facing them and society is to figure out how to stop, or at least minimize the effects of, incorrect information, misleading statements, and outright lies in a society that values free speech. Physicians—young and old alike—must remain committed to communicating factual information to a not-always-receptive audience. And I wish my young colleagues luck; I hope that their passion for family medicine and their insights into social media may be just the combination that’s needed to redirect the public’s trust back to where it belongs during a health care crisis.
1. Fleming-Dutra KE. COVID-19 Epidemiology and Vaccination Rates in the United States. Presented to the Authorization Committee on Immunization Practices, July 19, 2022. Accessed August 9, 2022. https://www.cdc.gov/vaccines/acip/meetings/downloads/slides-2022-07-19/02-COVID-Fleming-Dutra-508.pdf
Not long ago, the grandmother of my son’s friend died of COVID-19 infection. She was elderly and unvaccinated. Her grandson had no regrets over her unvaccinated status. “Why would she inject poison into her body?” he said, and then expressed a strong opinion that she had died because the hospital physicians refused to give her ivermectin and hydroxychloroquine. My son, wisely, did not push the issue.
Soon thereafter, my personal family physician emailed a newsletter to his patients (me included) with 3 important messages: (1) COVID vaccines were available in the office; (2) He was not going to prescribe hydroxychloroquine, no matter how adamantly it was requested; and (3) He warned against threatening him or his staff with lawsuits or violence over refusal to prescribe any unproven medication.
How, as a country, have we come to this? A sizeable portion of the public trusts the advice of quacks, hacks, and political opportunists over that of the nation’s most expert scientists and physicians. The National Institutes of Health maintains a website with up-to-date recommendations on the use of treatments for COVID-19. They assess the existing evidence and make recommendations for or against a wide array of interventions. (They recommend against the use of both ivermectin and hydroxychloroquine.) The Centers for Disease Control and Prevention publishes extensively about the current knowledge on the safety and efficacy of vaccines. Neither agency is part of a “deep state” or conspiracy. They are comprised of some of the nation’s leading scientists, including physicians, trying to protect the public from disease and foster good health.
Sadly, some physicians have been a source of inaccurate vaccine information; some even prescribe ineffective treatments despite the evidence. These physicians are either letting their politics override their good sense or are improperly assessing the scientific literature, or both. Medical licensing agencies, and specialty certification boards, need to find ways to prevent this—ways that can survive judicial scrutiny and allow for legitimate scientific debate.
I have been tempted to just accept the current situation as the inevitable outcome of social media–fueled tribalism. But when we know that the COVID death rate among the unvaccinated is 9 times that of people who have received a booster dose,1 I can’t sit idly and watch the Internet pundits prevail. Instead, I continue to advise and teach my students to have confidence in trustworthy authorities and websites. Mistakes will be made; corrections will be issued. However, this is not evidence of malintent or incompetence, but rather, the scientific process in action.
I tell my students that one of the biggest challenges facing them and society is to figure out how to stop, or at least minimize the effects of, incorrect information, misleading statements, and outright lies in a society that values free speech. Physicians—young and old alike—must remain committed to communicating factual information to a not-always-receptive audience. And I wish my young colleagues luck; I hope that their passion for family medicine and their insights into social media may be just the combination that’s needed to redirect the public’s trust back to where it belongs during a health care crisis.
Not long ago, the grandmother of my son’s friend died of COVID-19 infection. She was elderly and unvaccinated. Her grandson had no regrets over her unvaccinated status. “Why would she inject poison into her body?” he said, and then expressed a strong opinion that she had died because the hospital physicians refused to give her ivermectin and hydroxychloroquine. My son, wisely, did not push the issue.
Soon thereafter, my personal family physician emailed a newsletter to his patients (me included) with 3 important messages: (1) COVID vaccines were available in the office; (2) He was not going to prescribe hydroxychloroquine, no matter how adamantly it was requested; and (3) He warned against threatening him or his staff with lawsuits or violence over refusal to prescribe any unproven medication.
How, as a country, have we come to this? A sizeable portion of the public trusts the advice of quacks, hacks, and political opportunists over that of the nation’s most expert scientists and physicians. The National Institutes of Health maintains a website with up-to-date recommendations on the use of treatments for COVID-19. They assess the existing evidence and make recommendations for or against a wide array of interventions. (They recommend against the use of both ivermectin and hydroxychloroquine.) The Centers for Disease Control and Prevention publishes extensively about the current knowledge on the safety and efficacy of vaccines. Neither agency is part of a “deep state” or conspiracy. They are comprised of some of the nation’s leading scientists, including physicians, trying to protect the public from disease and foster good health.
Sadly, some physicians have been a source of inaccurate vaccine information; some even prescribe ineffective treatments despite the evidence. These physicians are either letting their politics override their good sense or are improperly assessing the scientific literature, or both. Medical licensing agencies, and specialty certification boards, need to find ways to prevent this—ways that can survive judicial scrutiny and allow for legitimate scientific debate.
I have been tempted to just accept the current situation as the inevitable outcome of social media–fueled tribalism. But when we know that the COVID death rate among the unvaccinated is 9 times that of people who have received a booster dose,1 I can’t sit idly and watch the Internet pundits prevail. Instead, I continue to advise and teach my students to have confidence in trustworthy authorities and websites. Mistakes will be made; corrections will be issued. However, this is not evidence of malintent or incompetence, but rather, the scientific process in action.
I tell my students that one of the biggest challenges facing them and society is to figure out how to stop, or at least minimize the effects of, incorrect information, misleading statements, and outright lies in a society that values free speech. Physicians—young and old alike—must remain committed to communicating factual information to a not-always-receptive audience. And I wish my young colleagues luck; I hope that their passion for family medicine and their insights into social media may be just the combination that’s needed to redirect the public’s trust back to where it belongs during a health care crisis.
1. Fleming-Dutra KE. COVID-19 Epidemiology and Vaccination Rates in the United States. Presented to the Authorization Committee on Immunization Practices, July 19, 2022. Accessed August 9, 2022. https://www.cdc.gov/vaccines/acip/meetings/downloads/slides-2022-07-19/02-COVID-Fleming-Dutra-508.pdf
1. Fleming-Dutra KE. COVID-19 Epidemiology and Vaccination Rates in the United States. Presented to the Authorization Committee on Immunization Practices, July 19, 2022. Accessed August 9, 2022. https://www.cdc.gov/vaccines/acip/meetings/downloads/slides-2022-07-19/02-COVID-Fleming-Dutra-508.pdf
How docs in firearm-friendly states talk gun safety
Samuel Mathis, MD, tries to cover a lot of ground during a wellness exam for his patients. Nutrition, immunizations, dental hygiene, and staying safe at school are a few of the topics on his list. And the Texas pediatrician asks one more question of children and their parents: “Are there any firearms in the house?”
If the answer is “yes,” Dr. Mathis discusses safety courses and other ideas with the families. “Rather than ask a bunch of questions, often I will say it’s recommended to keep them locked up and don’t forget toddlers can climb heights that you never would have envisioned,” said Dr. Mathis, an assistant professor at the University of Texas Medical Branch, Galveston.
Dr. Mathis said some of his physician colleagues are wary of bringing up the topic of guns in a state that leads the nation with more than 1 million registered firearms. “My discussion is more on firearm responsibility and just making sure they are taking extra steps to keep themselves and everyone around them safe. That works much better in these discussions.”
Gun safety: Public health concern, not politics
The statistics tell why:
- Unintentional shooting deaths by children rose by nearly one third in a 3-month period in 2020, compared with the same period in 2019.
- Of every 10 gun deaths in the United States, 6 are by suicide.
- As of July 28, 372 mass shootings have occured.
- Firearms now represent the leading cause of death among the nation’s youth.
In 2018, the editors of Annals of Internal Medicine urged physicians in the United States to sign a pledge to talk with their patients about guns in the home. To date, at least 3,664 have done so.
In 2019, the American Academy of Family Medicine, with other leading physician and public health organizations, issued a “call to action,” recommending ways to reduce firearm-related injury and death in the United States. Physicians can and should address the issue, it said, by counseling patients about firearm safety.
“This is just another part of healthcare,” said Sarah C. Nosal, MD, a member of the board of directors of the AAFP, who practices at the Urban Horizons Family Health Center, New York.
Dr. Nosal said she asks about firearms during every well-child visit. She also focuses on patients with a history of depression or suicide attempts and those who have experienced domestic violence.
Are physicians counseling patients about gun safety?
A 2018 survey of physicians found that 73% of the 71 who responded agreed to discuss gun safety with at-risk patients. But just 5% said they always talk to those at-risk patients, according to Melanie G. Hagen, MD, professor of internal medicine at the University of Florida, Gainesville, who led the study. While the overwhelming majority agreed that gun safety is a public health issue, only 55% said they felt comfortable initiating conversations about firearms with their patients.
Have things changed since then? “Probably not,” Dr. Hagen said in an interview. She cited some reasons, at least in her state.
One obstacle is that many people, including physicians, believe that Florida’s physician gag law, which prohibited physicians from asking about a patient’s firearm ownership, was still in effect. The law, passed in 2011, was overturned in 2017. In her survey, 76% said they were aware it had been overturned. But that awareness appears not to be universal, she said.
In a 2020 report about physician involvement in promoting gun safety, researchers noted four main challenges: lingering fears about the overturned law and potential liability from violating it, feeling unprepared, worry that patients don’t want to discuss the topic, and lack of time to talk about it during a rushed office visit.
But recent research suggests that patients are often open to talking about gun safety, and another study found that if physicians are given educational materials on firearm safety, more will counsel patients about gun safety.
Are patients and parents receptive?
Parents welcome discussion from health care providers about gun safety, according to a study from the University of Pennsylvania, Philadelphia.
Researchers asked roughly 100 parents to watch a short video about a firearm safety program designed to prevent accidents and suicides from guns. The program, still under study, involves a discussion between a parent and a pediatrician, with information given on secure storage of guns and the offering of a free cable lock.
The parents, about equally divided between gun owners and non–gun owners, said they were open to discussion about firearm safety, especially when the conversation involves their child’s pediatrician. Among the gun owners, only one in three said all their firearms were locked, unloaded, and stored properly. But after getting the safety information, 64% said they would change the way they stored their firearms.
A different program that offered pediatricians educational materials on firearm safety, as well as free firearm locks for distribution, increased the likelihood that the physicians would counsel patients on gun safety, other researchers reported.
Getting the conversation started
Some patients “bristle” when they’re asked about guns, Dr. Hagen said. Focusing on the “why” of the question can soften their response. One of her patients, a man in his 80s, had worked as a prison guard. After he was diagnosed with clinical depression, she asked him if he ever thought about ending his life. He said yes.
“And in Florida, I know a lot of people have guns,” she said. The state ranks second in the nation, with more than a half million registered weapons.
When Dr. Hagen asked him if he had firearms at home, he balked. Why did she need to know? “People do get defensive,” she said. “Luckily, I had a good relationship with this man, and he was willing to listen to me. If it’s someone I have a good relationship with, and I have this initial bristling, if I say: ‘I’m worried about you, I’m worried about your safety,’ that changes the entire conversation.”
She talked through the best plan for this patient, and he agreed to give his weapons to his son to keep.
Likewise, she talks with family members of dementia patients, urging them to be sure the weapons are stored and locked to prevent tragic accidents.
Dr. Nosal said reading the room is key. “Often, we are having the conversation with a parent with a child present,” she said. “Perhaps that is not the conversation the parent or guardian wanted to have with the child present.” In such a situation, she suggests asking the parent if they would talk about it solo.
“It can be a challenge to know the appropriate way to start the conversation,” Dr. Mathis said. The topic is not taught in medical school, although many experts think it should be. Dr. Hagen recently delivered a lecture to medical students about how to broach the topic with patients. She said she hopes it will become a regular event.
“It really comes down to being willing to be open and just ask that first question in a nonjudgmental way,” Dr. Mathis said. It helps, too, he said, for physicians to remember what he always tries to keep in mind: “My job isn’t politics, my job is health.”
Among the points Dr. Hagen makes in her lecture about talking to patients about guns are the following:
- Every day, more than 110 Americans are killed with guns.
- Gun violence accounts for just 1%-2% of those deaths, but mass shootings serve to shine a light on the issue of gun safety.
- 110,000 firearm injuries a year require medical or legal attention. Each year, more than 1,200 children in this country die from gun-related injuries.
- More than 33,000 people, on average, die in the United States each year from gun violence, including more than 21,000 from suicide.
- About 31% of all U.S. households have firearms; 22% of U.S. adults own one or more.
- Guns are 70% less likely to be stored locked and unloaded in homes where suicides or unintentional gun injuries occur.
- Action points: Identify risk, counsel patients at risk, act when someone is in imminent danger (such as unsafe practices or suicide threats).
- Focus on identifying adults who have a risk of inflicting violence on self or others.
- Focus on health and well-being with all; be conversational and educational.
- Clinicians should ask five crucial questions, all with an “L,” if firearms are in the home: Is it Loaded? Locked? Are Little children present? Is the owner feeling Low? Are they Learned [educated] in gun safety?
A version of this article first appeared on Medscape.com.
Samuel Mathis, MD, tries to cover a lot of ground during a wellness exam for his patients. Nutrition, immunizations, dental hygiene, and staying safe at school are a few of the topics on his list. And the Texas pediatrician asks one more question of children and their parents: “Are there any firearms in the house?”
If the answer is “yes,” Dr. Mathis discusses safety courses and other ideas with the families. “Rather than ask a bunch of questions, often I will say it’s recommended to keep them locked up and don’t forget toddlers can climb heights that you never would have envisioned,” said Dr. Mathis, an assistant professor at the University of Texas Medical Branch, Galveston.
Dr. Mathis said some of his physician colleagues are wary of bringing up the topic of guns in a state that leads the nation with more than 1 million registered firearms. “My discussion is more on firearm responsibility and just making sure they are taking extra steps to keep themselves and everyone around them safe. That works much better in these discussions.”
Gun safety: Public health concern, not politics
The statistics tell why:
- Unintentional shooting deaths by children rose by nearly one third in a 3-month period in 2020, compared with the same period in 2019.
- Of every 10 gun deaths in the United States, 6 are by suicide.
- As of July 28, 372 mass shootings have occured.
- Firearms now represent the leading cause of death among the nation’s youth.
In 2018, the editors of Annals of Internal Medicine urged physicians in the United States to sign a pledge to talk with their patients about guns in the home. To date, at least 3,664 have done so.
In 2019, the American Academy of Family Medicine, with other leading physician and public health organizations, issued a “call to action,” recommending ways to reduce firearm-related injury and death in the United States. Physicians can and should address the issue, it said, by counseling patients about firearm safety.
“This is just another part of healthcare,” said Sarah C. Nosal, MD, a member of the board of directors of the AAFP, who practices at the Urban Horizons Family Health Center, New York.
Dr. Nosal said she asks about firearms during every well-child visit. She also focuses on patients with a history of depression or suicide attempts and those who have experienced domestic violence.
Are physicians counseling patients about gun safety?
A 2018 survey of physicians found that 73% of the 71 who responded agreed to discuss gun safety with at-risk patients. But just 5% said they always talk to those at-risk patients, according to Melanie G. Hagen, MD, professor of internal medicine at the University of Florida, Gainesville, who led the study. While the overwhelming majority agreed that gun safety is a public health issue, only 55% said they felt comfortable initiating conversations about firearms with their patients.
Have things changed since then? “Probably not,” Dr. Hagen said in an interview. She cited some reasons, at least in her state.
One obstacle is that many people, including physicians, believe that Florida’s physician gag law, which prohibited physicians from asking about a patient’s firearm ownership, was still in effect. The law, passed in 2011, was overturned in 2017. In her survey, 76% said they were aware it had been overturned. But that awareness appears not to be universal, she said.
In a 2020 report about physician involvement in promoting gun safety, researchers noted four main challenges: lingering fears about the overturned law and potential liability from violating it, feeling unprepared, worry that patients don’t want to discuss the topic, and lack of time to talk about it during a rushed office visit.
But recent research suggests that patients are often open to talking about gun safety, and another study found that if physicians are given educational materials on firearm safety, more will counsel patients about gun safety.
Are patients and parents receptive?
Parents welcome discussion from health care providers about gun safety, according to a study from the University of Pennsylvania, Philadelphia.
Researchers asked roughly 100 parents to watch a short video about a firearm safety program designed to prevent accidents and suicides from guns. The program, still under study, involves a discussion between a parent and a pediatrician, with information given on secure storage of guns and the offering of a free cable lock.
The parents, about equally divided between gun owners and non–gun owners, said they were open to discussion about firearm safety, especially when the conversation involves their child’s pediatrician. Among the gun owners, only one in three said all their firearms were locked, unloaded, and stored properly. But after getting the safety information, 64% said they would change the way they stored their firearms.
A different program that offered pediatricians educational materials on firearm safety, as well as free firearm locks for distribution, increased the likelihood that the physicians would counsel patients on gun safety, other researchers reported.
Getting the conversation started
Some patients “bristle” when they’re asked about guns, Dr. Hagen said. Focusing on the “why” of the question can soften their response. One of her patients, a man in his 80s, had worked as a prison guard. After he was diagnosed with clinical depression, she asked him if he ever thought about ending his life. He said yes.
“And in Florida, I know a lot of people have guns,” she said. The state ranks second in the nation, with more than a half million registered weapons.
When Dr. Hagen asked him if he had firearms at home, he balked. Why did she need to know? “People do get defensive,” she said. “Luckily, I had a good relationship with this man, and he was willing to listen to me. If it’s someone I have a good relationship with, and I have this initial bristling, if I say: ‘I’m worried about you, I’m worried about your safety,’ that changes the entire conversation.”
She talked through the best plan for this patient, and he agreed to give his weapons to his son to keep.
Likewise, she talks with family members of dementia patients, urging them to be sure the weapons are stored and locked to prevent tragic accidents.
Dr. Nosal said reading the room is key. “Often, we are having the conversation with a parent with a child present,” she said. “Perhaps that is not the conversation the parent or guardian wanted to have with the child present.” In such a situation, she suggests asking the parent if they would talk about it solo.
“It can be a challenge to know the appropriate way to start the conversation,” Dr. Mathis said. The topic is not taught in medical school, although many experts think it should be. Dr. Hagen recently delivered a lecture to medical students about how to broach the topic with patients. She said she hopes it will become a regular event.
“It really comes down to being willing to be open and just ask that first question in a nonjudgmental way,” Dr. Mathis said. It helps, too, he said, for physicians to remember what he always tries to keep in mind: “My job isn’t politics, my job is health.”
Among the points Dr. Hagen makes in her lecture about talking to patients about guns are the following:
- Every day, more than 110 Americans are killed with guns.
- Gun violence accounts for just 1%-2% of those deaths, but mass shootings serve to shine a light on the issue of gun safety.
- 110,000 firearm injuries a year require medical or legal attention. Each year, more than 1,200 children in this country die from gun-related injuries.
- More than 33,000 people, on average, die in the United States each year from gun violence, including more than 21,000 from suicide.
- About 31% of all U.S. households have firearms; 22% of U.S. adults own one or more.
- Guns are 70% less likely to be stored locked and unloaded in homes where suicides or unintentional gun injuries occur.
- Action points: Identify risk, counsel patients at risk, act when someone is in imminent danger (such as unsafe practices or suicide threats).
- Focus on identifying adults who have a risk of inflicting violence on self or others.
- Focus on health and well-being with all; be conversational and educational.
- Clinicians should ask five crucial questions, all with an “L,” if firearms are in the home: Is it Loaded? Locked? Are Little children present? Is the owner feeling Low? Are they Learned [educated] in gun safety?
A version of this article first appeared on Medscape.com.
Samuel Mathis, MD, tries to cover a lot of ground during a wellness exam for his patients. Nutrition, immunizations, dental hygiene, and staying safe at school are a few of the topics on his list. And the Texas pediatrician asks one more question of children and their parents: “Are there any firearms in the house?”
If the answer is “yes,” Dr. Mathis discusses safety courses and other ideas with the families. “Rather than ask a bunch of questions, often I will say it’s recommended to keep them locked up and don’t forget toddlers can climb heights that you never would have envisioned,” said Dr. Mathis, an assistant professor at the University of Texas Medical Branch, Galveston.
Dr. Mathis said some of his physician colleagues are wary of bringing up the topic of guns in a state that leads the nation with more than 1 million registered firearms. “My discussion is more on firearm responsibility and just making sure they are taking extra steps to keep themselves and everyone around them safe. That works much better in these discussions.”
Gun safety: Public health concern, not politics
The statistics tell why:
- Unintentional shooting deaths by children rose by nearly one third in a 3-month period in 2020, compared with the same period in 2019.
- Of every 10 gun deaths in the United States, 6 are by suicide.
- As of July 28, 372 mass shootings have occured.
- Firearms now represent the leading cause of death among the nation’s youth.
In 2018, the editors of Annals of Internal Medicine urged physicians in the United States to sign a pledge to talk with their patients about guns in the home. To date, at least 3,664 have done so.
In 2019, the American Academy of Family Medicine, with other leading physician and public health organizations, issued a “call to action,” recommending ways to reduce firearm-related injury and death in the United States. Physicians can and should address the issue, it said, by counseling patients about firearm safety.
“This is just another part of healthcare,” said Sarah C. Nosal, MD, a member of the board of directors of the AAFP, who practices at the Urban Horizons Family Health Center, New York.
Dr. Nosal said she asks about firearms during every well-child visit. She also focuses on patients with a history of depression or suicide attempts and those who have experienced domestic violence.
Are physicians counseling patients about gun safety?
A 2018 survey of physicians found that 73% of the 71 who responded agreed to discuss gun safety with at-risk patients. But just 5% said they always talk to those at-risk patients, according to Melanie G. Hagen, MD, professor of internal medicine at the University of Florida, Gainesville, who led the study. While the overwhelming majority agreed that gun safety is a public health issue, only 55% said they felt comfortable initiating conversations about firearms with their patients.
Have things changed since then? “Probably not,” Dr. Hagen said in an interview. She cited some reasons, at least in her state.
One obstacle is that many people, including physicians, believe that Florida’s physician gag law, which prohibited physicians from asking about a patient’s firearm ownership, was still in effect. The law, passed in 2011, was overturned in 2017. In her survey, 76% said they were aware it had been overturned. But that awareness appears not to be universal, she said.
In a 2020 report about physician involvement in promoting gun safety, researchers noted four main challenges: lingering fears about the overturned law and potential liability from violating it, feeling unprepared, worry that patients don’t want to discuss the topic, and lack of time to talk about it during a rushed office visit.
But recent research suggests that patients are often open to talking about gun safety, and another study found that if physicians are given educational materials on firearm safety, more will counsel patients about gun safety.
Are patients and parents receptive?
Parents welcome discussion from health care providers about gun safety, according to a study from the University of Pennsylvania, Philadelphia.
Researchers asked roughly 100 parents to watch a short video about a firearm safety program designed to prevent accidents and suicides from guns. The program, still under study, involves a discussion between a parent and a pediatrician, with information given on secure storage of guns and the offering of a free cable lock.
The parents, about equally divided between gun owners and non–gun owners, said they were open to discussion about firearm safety, especially when the conversation involves their child’s pediatrician. Among the gun owners, only one in three said all their firearms were locked, unloaded, and stored properly. But after getting the safety information, 64% said they would change the way they stored their firearms.
A different program that offered pediatricians educational materials on firearm safety, as well as free firearm locks for distribution, increased the likelihood that the physicians would counsel patients on gun safety, other researchers reported.
Getting the conversation started
Some patients “bristle” when they’re asked about guns, Dr. Hagen said. Focusing on the “why” of the question can soften their response. One of her patients, a man in his 80s, had worked as a prison guard. After he was diagnosed with clinical depression, she asked him if he ever thought about ending his life. He said yes.
“And in Florida, I know a lot of people have guns,” she said. The state ranks second in the nation, with more than a half million registered weapons.
When Dr. Hagen asked him if he had firearms at home, he balked. Why did she need to know? “People do get defensive,” she said. “Luckily, I had a good relationship with this man, and he was willing to listen to me. If it’s someone I have a good relationship with, and I have this initial bristling, if I say: ‘I’m worried about you, I’m worried about your safety,’ that changes the entire conversation.”
She talked through the best plan for this patient, and he agreed to give his weapons to his son to keep.
Likewise, she talks with family members of dementia patients, urging them to be sure the weapons are stored and locked to prevent tragic accidents.
Dr. Nosal said reading the room is key. “Often, we are having the conversation with a parent with a child present,” she said. “Perhaps that is not the conversation the parent or guardian wanted to have with the child present.” In such a situation, she suggests asking the parent if they would talk about it solo.
“It can be a challenge to know the appropriate way to start the conversation,” Dr. Mathis said. The topic is not taught in medical school, although many experts think it should be. Dr. Hagen recently delivered a lecture to medical students about how to broach the topic with patients. She said she hopes it will become a regular event.
“It really comes down to being willing to be open and just ask that first question in a nonjudgmental way,” Dr. Mathis said. It helps, too, he said, for physicians to remember what he always tries to keep in mind: “My job isn’t politics, my job is health.”
Among the points Dr. Hagen makes in her lecture about talking to patients about guns are the following:
- Every day, more than 110 Americans are killed with guns.
- Gun violence accounts for just 1%-2% of those deaths, but mass shootings serve to shine a light on the issue of gun safety.
- 110,000 firearm injuries a year require medical or legal attention. Each year, more than 1,200 children in this country die from gun-related injuries.
- More than 33,000 people, on average, die in the United States each year from gun violence, including more than 21,000 from suicide.
- About 31% of all U.S. households have firearms; 22% of U.S. adults own one or more.
- Guns are 70% less likely to be stored locked and unloaded in homes where suicides or unintentional gun injuries occur.
- Action points: Identify risk, counsel patients at risk, act when someone is in imminent danger (such as unsafe practices or suicide threats).
- Focus on identifying adults who have a risk of inflicting violence on self or others.
- Focus on health and well-being with all; be conversational and educational.
- Clinicians should ask five crucial questions, all with an “L,” if firearms are in the home: Is it Loaded? Locked? Are Little children present? Is the owner feeling Low? Are they Learned [educated] in gun safety?
A version of this article first appeared on Medscape.com.
Experts: EPA should assess risk of sunscreens’ UV filters
The
, an expert panel of the National Academies of Sciences, Engineering, and Medicine (NAS) said on Aug. 9.The assessment is urgently needed, the experts said, and the results should be shared with the Food and Drug Administration, which oversees sunscreens.
In its 400-page report, titled the Review of Fate, Exposure, and Effects of Sunscreens in Aquatic Environments and Implications for Sunscreen Usage and Human Health, the panel does not make recommendations but suggests that such an EPA risk assessment should highlight gaps in knowledge.
“We are teeing up the critical information that will be used to take on the challenge of risk assessment,” Charles A. Menzie, PhD, chair of the committee that wrote the report, said at a media briefing Aug. 9 when the report was released. Dr. Menzie is a principal at Exponent, Inc., an engineering and scientific consulting firm. He is former executive director of the Society of Environmental Toxicology and Chemistry.
The EPA sponsored the study, which was conducted by a committee of the National Academy of Sciences, a nonprofit, nongovernmental organization authorized by Congress that studies issues related to science, technology, and medicine.
Balancing aquatic, human health concerns
Such an EPA assessment, Dr. Menzie said in a statement, will help inform efforts to understand the environmental effects of UV filters as well as clarify a path forward for managing sunscreens. For years, concerns have been raised about the potential toxicity of sunscreens regarding many marine and freshwater aquatic organisms, especially coral. That concern, however, must be balanced against the benefits of sunscreens, which are known to protect against skin cancer. A low percentage of people use sunscreen regularly, Dr. Menzie and other panel members said.
“Only about a third of the U.S. population regularly uses sunscreen,” Mark Cullen, MD, vice chair of the NAS committee and former director of the Center for Population Health Sciences, Stanford (Calif.) University, said at the briefing. About 70% or 80% of people use it at the beach or outdoors, he said.
Report background, details
UV filters are the active ingredients in physical as well as chemical sunscreen products. They decrease the amount of UV radiation that reaches the skin. They have been found in water, sediments, and marine organisms, both saltwater and freshwater.
Currently, 17 UV filters are used in U.S. sunscreens; 15 of those are organic, such as oxybenzone and avobenzone, and are used in chemical sunscreens. They work by absorbing the rays before they damage the skin. In addition, two inorganic filters, which are used in physical sunscreens, sit on the skin and as a shield to block the rays.
UV filters enter bodies of water by direct release, as when sunscreens rinse off people while swimming or while engaging in other water activities. They also enter bodies of water in storm water runoff and wastewater.
Lab toxicity tests, which are the most widely used, provide effects data for ecologic risk assessment. The tests are more often used in the study of short-term, not long-term exposure. Test results have shown that in high enough concentrations, some UV filters can be toxic to algal, invertebrate, and fish species.
But much information is lacking, the experts said. Toxicity data for many species, for instance, are limited. There are few studies on the longer-term environmental effects of UV filter exposure. Not enough is known about the rate at which the filters degrade in the environment. The filters accumulate in higher amounts in different areas. Recreational water areas have higher concentrations.
The recommendations
The panel is urging the EPA to complete a formal risk assessment of the UV filters “with some urgency,” Dr. Cullen said. That will enable decisions to be made about the use of the products. The risks to aquatic life must be balanced against the need for sun protection to reduce skin cancer risk.
The experts made two recommendations:
- The EPA should conduct ecologic risk assessments for all the UV filters now marketed and for all new ones. The assessment should evaluate the filters individually as well as the risk from co-occurring filters. The assessments should take into account the different exposure scenarios.
- The EPA, along with partner agencies, and sunscreen and UV filter manufacturers should fund, support, and conduct research and share data. Research should include study of human health outcomes if usage and availability of sunscreens change.
Dermatologists should “continue to emphasize the importance of protection from UV radiation in every way that can be done,” Dr. Cullen said, including the use of sunscreen as well as other protective practices, such as wearing long sleeves and hats, seeking shade, and avoiding the sun during peak hours.
A dermatologist’s perspective
“I applaud their scientific curiosity to know one way or the other whether this is an issue,” said Adam Friedman, MD, professor and chair of dermatology at George Washington University, Washington, DC. “I welcome this investigation.”
The multitude of studies, Dr. Friedman said, don’t always agree about whether the filters pose dangers. He noted that the concentration of UV filters detected in water is often lower than the concentrations found to be harmful in a lab setting to marine life, specifically coral.
However, he said, “these studies are snapshots.” For that reason, calling for more assessment of risk is desirable, Dr. Friedman said, but “I want to be sure the call to do more research is not an admission of guilt. It’s very easy to vilify sunscreens – but the facts we know are that UV light causes skin cancer and aging, and sunscreen protects us against this.”
Dr. Friedman has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
The
, an expert panel of the National Academies of Sciences, Engineering, and Medicine (NAS) said on Aug. 9.The assessment is urgently needed, the experts said, and the results should be shared with the Food and Drug Administration, which oversees sunscreens.
In its 400-page report, titled the Review of Fate, Exposure, and Effects of Sunscreens in Aquatic Environments and Implications for Sunscreen Usage and Human Health, the panel does not make recommendations but suggests that such an EPA risk assessment should highlight gaps in knowledge.
“We are teeing up the critical information that will be used to take on the challenge of risk assessment,” Charles A. Menzie, PhD, chair of the committee that wrote the report, said at a media briefing Aug. 9 when the report was released. Dr. Menzie is a principal at Exponent, Inc., an engineering and scientific consulting firm. He is former executive director of the Society of Environmental Toxicology and Chemistry.
The EPA sponsored the study, which was conducted by a committee of the National Academy of Sciences, a nonprofit, nongovernmental organization authorized by Congress that studies issues related to science, technology, and medicine.
Balancing aquatic, human health concerns
Such an EPA assessment, Dr. Menzie said in a statement, will help inform efforts to understand the environmental effects of UV filters as well as clarify a path forward for managing sunscreens. For years, concerns have been raised about the potential toxicity of sunscreens regarding many marine and freshwater aquatic organisms, especially coral. That concern, however, must be balanced against the benefits of sunscreens, which are known to protect against skin cancer. A low percentage of people use sunscreen regularly, Dr. Menzie and other panel members said.
“Only about a third of the U.S. population regularly uses sunscreen,” Mark Cullen, MD, vice chair of the NAS committee and former director of the Center for Population Health Sciences, Stanford (Calif.) University, said at the briefing. About 70% or 80% of people use it at the beach or outdoors, he said.
Report background, details
UV filters are the active ingredients in physical as well as chemical sunscreen products. They decrease the amount of UV radiation that reaches the skin. They have been found in water, sediments, and marine organisms, both saltwater and freshwater.
Currently, 17 UV filters are used in U.S. sunscreens; 15 of those are organic, such as oxybenzone and avobenzone, and are used in chemical sunscreens. They work by absorbing the rays before they damage the skin. In addition, two inorganic filters, which are used in physical sunscreens, sit on the skin and as a shield to block the rays.
UV filters enter bodies of water by direct release, as when sunscreens rinse off people while swimming or while engaging in other water activities. They also enter bodies of water in storm water runoff and wastewater.
Lab toxicity tests, which are the most widely used, provide effects data for ecologic risk assessment. The tests are more often used in the study of short-term, not long-term exposure. Test results have shown that in high enough concentrations, some UV filters can be toxic to algal, invertebrate, and fish species.
But much information is lacking, the experts said. Toxicity data for many species, for instance, are limited. There are few studies on the longer-term environmental effects of UV filter exposure. Not enough is known about the rate at which the filters degrade in the environment. The filters accumulate in higher amounts in different areas. Recreational water areas have higher concentrations.
The recommendations
The panel is urging the EPA to complete a formal risk assessment of the UV filters “with some urgency,” Dr. Cullen said. That will enable decisions to be made about the use of the products. The risks to aquatic life must be balanced against the need for sun protection to reduce skin cancer risk.
The experts made two recommendations:
- The EPA should conduct ecologic risk assessments for all the UV filters now marketed and for all new ones. The assessment should evaluate the filters individually as well as the risk from co-occurring filters. The assessments should take into account the different exposure scenarios.
- The EPA, along with partner agencies, and sunscreen and UV filter manufacturers should fund, support, and conduct research and share data. Research should include study of human health outcomes if usage and availability of sunscreens change.
Dermatologists should “continue to emphasize the importance of protection from UV radiation in every way that can be done,” Dr. Cullen said, including the use of sunscreen as well as other protective practices, such as wearing long sleeves and hats, seeking shade, and avoiding the sun during peak hours.
A dermatologist’s perspective
“I applaud their scientific curiosity to know one way or the other whether this is an issue,” said Adam Friedman, MD, professor and chair of dermatology at George Washington University, Washington, DC. “I welcome this investigation.”
The multitude of studies, Dr. Friedman said, don’t always agree about whether the filters pose dangers. He noted that the concentration of UV filters detected in water is often lower than the concentrations found to be harmful in a lab setting to marine life, specifically coral.
However, he said, “these studies are snapshots.” For that reason, calling for more assessment of risk is desirable, Dr. Friedman said, but “I want to be sure the call to do more research is not an admission of guilt. It’s very easy to vilify sunscreens – but the facts we know are that UV light causes skin cancer and aging, and sunscreen protects us against this.”
Dr. Friedman has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
The
, an expert panel of the National Academies of Sciences, Engineering, and Medicine (NAS) said on Aug. 9.The assessment is urgently needed, the experts said, and the results should be shared with the Food and Drug Administration, which oversees sunscreens.
In its 400-page report, titled the Review of Fate, Exposure, and Effects of Sunscreens in Aquatic Environments and Implications for Sunscreen Usage and Human Health, the panel does not make recommendations but suggests that such an EPA risk assessment should highlight gaps in knowledge.
“We are teeing up the critical information that will be used to take on the challenge of risk assessment,” Charles A. Menzie, PhD, chair of the committee that wrote the report, said at a media briefing Aug. 9 when the report was released. Dr. Menzie is a principal at Exponent, Inc., an engineering and scientific consulting firm. He is former executive director of the Society of Environmental Toxicology and Chemistry.
The EPA sponsored the study, which was conducted by a committee of the National Academy of Sciences, a nonprofit, nongovernmental organization authorized by Congress that studies issues related to science, technology, and medicine.
Balancing aquatic, human health concerns
Such an EPA assessment, Dr. Menzie said in a statement, will help inform efforts to understand the environmental effects of UV filters as well as clarify a path forward for managing sunscreens. For years, concerns have been raised about the potential toxicity of sunscreens regarding many marine and freshwater aquatic organisms, especially coral. That concern, however, must be balanced against the benefits of sunscreens, which are known to protect against skin cancer. A low percentage of people use sunscreen regularly, Dr. Menzie and other panel members said.
“Only about a third of the U.S. population regularly uses sunscreen,” Mark Cullen, MD, vice chair of the NAS committee and former director of the Center for Population Health Sciences, Stanford (Calif.) University, said at the briefing. About 70% or 80% of people use it at the beach or outdoors, he said.
Report background, details
UV filters are the active ingredients in physical as well as chemical sunscreen products. They decrease the amount of UV radiation that reaches the skin. They have been found in water, sediments, and marine organisms, both saltwater and freshwater.
Currently, 17 UV filters are used in U.S. sunscreens; 15 of those are organic, such as oxybenzone and avobenzone, and are used in chemical sunscreens. They work by absorbing the rays before they damage the skin. In addition, two inorganic filters, which are used in physical sunscreens, sit on the skin and as a shield to block the rays.
UV filters enter bodies of water by direct release, as when sunscreens rinse off people while swimming or while engaging in other water activities. They also enter bodies of water in storm water runoff and wastewater.
Lab toxicity tests, which are the most widely used, provide effects data for ecologic risk assessment. The tests are more often used in the study of short-term, not long-term exposure. Test results have shown that in high enough concentrations, some UV filters can be toxic to algal, invertebrate, and fish species.
But much information is lacking, the experts said. Toxicity data for many species, for instance, are limited. There are few studies on the longer-term environmental effects of UV filter exposure. Not enough is known about the rate at which the filters degrade in the environment. The filters accumulate in higher amounts in different areas. Recreational water areas have higher concentrations.
The recommendations
The panel is urging the EPA to complete a formal risk assessment of the UV filters “with some urgency,” Dr. Cullen said. That will enable decisions to be made about the use of the products. The risks to aquatic life must be balanced against the need for sun protection to reduce skin cancer risk.
The experts made two recommendations:
- The EPA should conduct ecologic risk assessments for all the UV filters now marketed and for all new ones. The assessment should evaluate the filters individually as well as the risk from co-occurring filters. The assessments should take into account the different exposure scenarios.
- The EPA, along with partner agencies, and sunscreen and UV filter manufacturers should fund, support, and conduct research and share data. Research should include study of human health outcomes if usage and availability of sunscreens change.
Dermatologists should “continue to emphasize the importance of protection from UV radiation in every way that can be done,” Dr. Cullen said, including the use of sunscreen as well as other protective practices, such as wearing long sleeves and hats, seeking shade, and avoiding the sun during peak hours.
A dermatologist’s perspective
“I applaud their scientific curiosity to know one way or the other whether this is an issue,” said Adam Friedman, MD, professor and chair of dermatology at George Washington University, Washington, DC. “I welcome this investigation.”
The multitude of studies, Dr. Friedman said, don’t always agree about whether the filters pose dangers. He noted that the concentration of UV filters detected in water is often lower than the concentrations found to be harmful in a lab setting to marine life, specifically coral.
However, he said, “these studies are snapshots.” For that reason, calling for more assessment of risk is desirable, Dr. Friedman said, but “I want to be sure the call to do more research is not an admission of guilt. It’s very easy to vilify sunscreens – but the facts we know are that UV light causes skin cancer and aging, and sunscreen protects us against this.”
Dr. Friedman has disclosed no relevant financial relationships.
A version of this article first appeared on Medscape.com.
FDA acts against sales of unapproved mole and skin tag products on Amazon, other sites
press release issued on Aug. 9.
In addition to Amazon.com, the other two companies are Ariella Naturals, and Justified Laboratories.
Currently, no over-the-counter products are FDA-approved for the at-home removal of moles and skin tags, and use of unapproved products could be dangerous to consumers, according to the statement. These products may be sold as ointments, gels, sticks, or liquids, and may contain high concentrations of salicylic acid or other harmful ingredients. Introducing unapproved products in to interstate commerce violates the Federal Food, Drug, and Cosmetic Act.
Two products sold on Amazon are the “Deisana Skin Tag Remover, Mole Remover and Repair Gel Set” and “Skincell Mole Skin Tag Corrector Serum,” according to the letter sent to Amazon.
The warning letters alert the three companies that they have 15 days from receipt to address any violations. However, warning letters are not a final FDA action, according to the statement.
“The agency’s rigorous surveillance works to identify threats to public health and stop these products from reaching our communities,” Donald D. Ashley, JD, director of the Office of Compliance in the FDA’s Center for Drug Evaluation and Research, said in the press release. “This includes where online retailers like Amazon are involved in the interstate sale of unapproved drug products. We will continue to work diligently to ensure that online retailers do not sell products that violate federal law,” he added.
The statement emphasized that moles should be evaluated by a health care professional, as attempts at self-diagnosis and at-home treatment could lead to a delayed cancer diagnosis, and potentially to cancer progression.
Products marketed to consumers for at-home removal of moles, skin tags, and other skin lesions could cause injuries, infections, and scarring, according to a related consumer update first posted by the FDA in June, which was updated after the warning letters were sent out.
Consumers and health care professionals are encouraged to report any adverse events related to mole removal or skin tag removal products to the agency’s MedWatch Adverse Event Reporting program.
The FDA also offers an online guide, BeSafeRx, with advice for consumers about potential risks of using online pharmacies and how to do so safely.
press release issued on Aug. 9.
In addition to Amazon.com, the other two companies are Ariella Naturals, and Justified Laboratories.
Currently, no over-the-counter products are FDA-approved for the at-home removal of moles and skin tags, and use of unapproved products could be dangerous to consumers, according to the statement. These products may be sold as ointments, gels, sticks, or liquids, and may contain high concentrations of salicylic acid or other harmful ingredients. Introducing unapproved products in to interstate commerce violates the Federal Food, Drug, and Cosmetic Act.
Two products sold on Amazon are the “Deisana Skin Tag Remover, Mole Remover and Repair Gel Set” and “Skincell Mole Skin Tag Corrector Serum,” according to the letter sent to Amazon.
The warning letters alert the three companies that they have 15 days from receipt to address any violations. However, warning letters are not a final FDA action, according to the statement.
“The agency’s rigorous surveillance works to identify threats to public health and stop these products from reaching our communities,” Donald D. Ashley, JD, director of the Office of Compliance in the FDA’s Center for Drug Evaluation and Research, said in the press release. “This includes where online retailers like Amazon are involved in the interstate sale of unapproved drug products. We will continue to work diligently to ensure that online retailers do not sell products that violate federal law,” he added.
The statement emphasized that moles should be evaluated by a health care professional, as attempts at self-diagnosis and at-home treatment could lead to a delayed cancer diagnosis, and potentially to cancer progression.
Products marketed to consumers for at-home removal of moles, skin tags, and other skin lesions could cause injuries, infections, and scarring, according to a related consumer update first posted by the FDA in June, which was updated after the warning letters were sent out.
Consumers and health care professionals are encouraged to report any adverse events related to mole removal or skin tag removal products to the agency’s MedWatch Adverse Event Reporting program.
The FDA also offers an online guide, BeSafeRx, with advice for consumers about potential risks of using online pharmacies and how to do so safely.
press release issued on Aug. 9.
In addition to Amazon.com, the other two companies are Ariella Naturals, and Justified Laboratories.
Currently, no over-the-counter products are FDA-approved for the at-home removal of moles and skin tags, and use of unapproved products could be dangerous to consumers, according to the statement. These products may be sold as ointments, gels, sticks, or liquids, and may contain high concentrations of salicylic acid or other harmful ingredients. Introducing unapproved products in to interstate commerce violates the Federal Food, Drug, and Cosmetic Act.
Two products sold on Amazon are the “Deisana Skin Tag Remover, Mole Remover and Repair Gel Set” and “Skincell Mole Skin Tag Corrector Serum,” according to the letter sent to Amazon.
The warning letters alert the three companies that they have 15 days from receipt to address any violations. However, warning letters are not a final FDA action, according to the statement.
“The agency’s rigorous surveillance works to identify threats to public health and stop these products from reaching our communities,” Donald D. Ashley, JD, director of the Office of Compliance in the FDA’s Center for Drug Evaluation and Research, said in the press release. “This includes where online retailers like Amazon are involved in the interstate sale of unapproved drug products. We will continue to work diligently to ensure that online retailers do not sell products that violate federal law,” he added.
The statement emphasized that moles should be evaluated by a health care professional, as attempts at self-diagnosis and at-home treatment could lead to a delayed cancer diagnosis, and potentially to cancer progression.
Products marketed to consumers for at-home removal of moles, skin tags, and other skin lesions could cause injuries, infections, and scarring, according to a related consumer update first posted by the FDA in June, which was updated after the warning letters were sent out.
Consumers and health care professionals are encouraged to report any adverse events related to mole removal or skin tag removal products to the agency’s MedWatch Adverse Event Reporting program.
The FDA also offers an online guide, BeSafeRx, with advice for consumers about potential risks of using online pharmacies and how to do so safely.
Audit Proof Your Mohs Note
In October 2020, Medicare released an updated guidance to reduce Mohs micrographic surgery (MMS) reimbursement issues,1 which initially was released in 2013. This guidance defines the latest performance and documentation requirements that Medicare requires for MMS. Understanding these requirements and making sure that your Mohs surgical reports have all the needed documentation details are critical because auditors from not only Medicare Administrative Contractors (MACs) but also private insurers and Medicare Advantage plans have adopted these standards and will deny payment for Mohs surgical codes if they are not met. This article provides a review of the updated Medicare requirements to make sure your MMS procedure notes are audit proof.
Notes Must Indicate Mohs Is the Most Appropriate Treatment
I review many of my colleagues’ Mohs notes and can tell you that some of the requirements laid out in the updated guidance typically are already reported by Mohs surgeons in their notes, including the location, number, and size of the lesion or lesions treated and the number of stages performed. However, there are some new requirements that often are not reported by Mohs surgeons that now need to be included. The guidance indicates the following:
The majority of skin cancers can be managed by simple excision or destruction techniques. The medical record of a patient undergoing MMS should clearly show that this procedure was chosen because of the complexity (eg, poorly defined clinical borders, possible deep invasion, prior irradiation), size or location (eg, maximum conservation of tumor-free tissue is important). Medicare will consider reimbursement for MMS for accepted diagnoses and indications, which you must document in the patient’s medical record as being appropriate for MMS and that MMS is the most appropriate choice for the treatment of a particular lesion.1
In my experience, most Mohs notes include some statement that the skin cancer treated is appropriate based on the Mohs appropriate use criteria (AUC) or the AUC score. However, notes should make clear not just that the lesion treated is “appropriate” for MMS but also that it is the most appropriate treatment (eg, why the lesion was not managed by standard excision or destruction technique).
Mohs Surgeon Must Perform the Surgery and Interpret Slides
The updated guidance clearly indicates that MMS may only be performed by a physician who is specifically trained and highly skilled in Mohs techniques and pathologic identification: “Medicare will only reimburse for MMS services when the Mohs surgeon acts as both surgeon and pathologist.”1 Mohs micrographic surgery codes may not be billed if preparation or interpretation of the pathology slides is performed by a physician other than the Mohs surgeon. Operative notes and pathology documentation in the patient’s medical record should clearly show that MMS was performed using an accepted MMS technique in which the physician acts in 2 integrated and distinct capacities—surgeon and pathologist—thereby confirming that the procedure meets the definition of the Current Procedural Terminology code(s).
Furthermore, the Mohs operative report should detail “the number of specimens per stage.”1 I interpret this statement to indicate that the Mohs surgeon should document the number of tissue blocks examined in each stage of Mohs surgery. For example, a statement in the notes such as “the specimen from the first Mohs stage was oriented, mapped, and divided into 4 blocks” should suffice to meet this requirement.
Histologic Description Must Be Included in Mohs Notes
Medicare will require the Mohs surgeon to document “the histology of the specimens taken. That description should include depth of invasion, pathological pattern, cell morphology, and, if present, perineural invasion or presence of scar tissue.”1 Although this histologic description requirement appears daunting, it is common for Mohs surgeons to indicate their pathologic findings on their Mohs map such as “NBCC” next to a red area to indicate “nodular basal cell carcinoma visualized.” A template-based system to translate typical pathologic findings can be employed to rapidly and accurately populate a Mohs note with histologic description such as “NBBC=nodular aggregates of palisaded basaloid epithelial tumor arising from the epidermis forming a palisade with a cleft forming from the adjacent mucinous stroma extending to the mid dermis. Centrally the nuclei become crowded with scattered mitotic figures and necrotic bodies evident.”
Recent Improvement for 1-Stage Mohs Surgeries
The most notable improvement in the
Final Thoughts
Overall, the updated Medicare guidance provides important details in the requirements for performance and documentation of Mohs surgery cases. However, additional critical information will be found in Mohs coverage policies and local coverage determinations (LCDs) from MACs and private insurers.2-4 Each LCD and insurer Mohs payment policy has unique wording and requirements. Coverage of MMS for specific malignant diagnoses, histologic subtypes, locations, and clinical scenarios varies between LCDs; most are based directly on the Mohs AUC, while others have a less specific coverage criteria. To understand the specific documentation and coverage requirements of the MAC for a particular region or private insurer, Mohs surgeons are encouraged to familiarize themselves with the Mohs surgery LCD of their local MAC and coverage policies of their insurers and to ensure their documentation substantiates these requirements. Making sure that your MMS documentation is accurate and complies with Medicare and insurer requirements will keep you out of hot water with auditors and allow reimbursement for this critical skin cancer procedure.
- Centers for Disease Control and Prevention. Guidance to reduce Mohs surgery reimbursement issues. MLN Matters. Published October 27, 2020. Accessed July 18, 2022. https://www.cms.gov/Outreach-and-Education/Medicare-Learning-Network-MLN/MLNMattersArticles/Downloads/SE1318.pdf
- Mohs micrographic surgery policy, professional. United Healthcare website. Accessed July 12, 2022. https://www.uhcprovider.com/content/dam/provider/docs/public/policies/comm-reimbursement/COMM-Mohs-Micrographic-Surgery-Policy.pdf#:~:text=This%20policy%20describes%20reimbursement%20guidelines%20for%20reporting%20Mohs,CCI%20Editing%20Policy%20and%20the%20Laboratory%20Services%20Policy.
- Clinical UM guideline—Mohs micrographic surgery. Anthem Insurance Companies website. Published October 6, 2021. Accessed July 27, 2022. https://www.anthem.com/dam/medpolicies/abcbs/active/guidelines/gl_pw_d085074.html
- Local coverage determinations. Centers for Medicare and Medicaid Services website. Updated July 12, 2022. Accessed July 12, 2022. https://www.cms.gov/Medicare/Coverage/DeterminationProcess/LCDs
In October 2020, Medicare released an updated guidance to reduce Mohs micrographic surgery (MMS) reimbursement issues,1 which initially was released in 2013. This guidance defines the latest performance and documentation requirements that Medicare requires for MMS. Understanding these requirements and making sure that your Mohs surgical reports have all the needed documentation details are critical because auditors from not only Medicare Administrative Contractors (MACs) but also private insurers and Medicare Advantage plans have adopted these standards and will deny payment for Mohs surgical codes if they are not met. This article provides a review of the updated Medicare requirements to make sure your MMS procedure notes are audit proof.
Notes Must Indicate Mohs Is the Most Appropriate Treatment
I review many of my colleagues’ Mohs notes and can tell you that some of the requirements laid out in the updated guidance typically are already reported by Mohs surgeons in their notes, including the location, number, and size of the lesion or lesions treated and the number of stages performed. However, there are some new requirements that often are not reported by Mohs surgeons that now need to be included. The guidance indicates the following:
The majority of skin cancers can be managed by simple excision or destruction techniques. The medical record of a patient undergoing MMS should clearly show that this procedure was chosen because of the complexity (eg, poorly defined clinical borders, possible deep invasion, prior irradiation), size or location (eg, maximum conservation of tumor-free tissue is important). Medicare will consider reimbursement for MMS for accepted diagnoses and indications, which you must document in the patient’s medical record as being appropriate for MMS and that MMS is the most appropriate choice for the treatment of a particular lesion.1
In my experience, most Mohs notes include some statement that the skin cancer treated is appropriate based on the Mohs appropriate use criteria (AUC) or the AUC score. However, notes should make clear not just that the lesion treated is “appropriate” for MMS but also that it is the most appropriate treatment (eg, why the lesion was not managed by standard excision or destruction technique).
Mohs Surgeon Must Perform the Surgery and Interpret Slides
The updated guidance clearly indicates that MMS may only be performed by a physician who is specifically trained and highly skilled in Mohs techniques and pathologic identification: “Medicare will only reimburse for MMS services when the Mohs surgeon acts as both surgeon and pathologist.”1 Mohs micrographic surgery codes may not be billed if preparation or interpretation of the pathology slides is performed by a physician other than the Mohs surgeon. Operative notes and pathology documentation in the patient’s medical record should clearly show that MMS was performed using an accepted MMS technique in which the physician acts in 2 integrated and distinct capacities—surgeon and pathologist—thereby confirming that the procedure meets the definition of the Current Procedural Terminology code(s).
Furthermore, the Mohs operative report should detail “the number of specimens per stage.”1 I interpret this statement to indicate that the Mohs surgeon should document the number of tissue blocks examined in each stage of Mohs surgery. For example, a statement in the notes such as “the specimen from the first Mohs stage was oriented, mapped, and divided into 4 blocks” should suffice to meet this requirement.
Histologic Description Must Be Included in Mohs Notes
Medicare will require the Mohs surgeon to document “the histology of the specimens taken. That description should include depth of invasion, pathological pattern, cell morphology, and, if present, perineural invasion or presence of scar tissue.”1 Although this histologic description requirement appears daunting, it is common for Mohs surgeons to indicate their pathologic findings on their Mohs map such as “NBCC” next to a red area to indicate “nodular basal cell carcinoma visualized.” A template-based system to translate typical pathologic findings can be employed to rapidly and accurately populate a Mohs note with histologic description such as “NBBC=nodular aggregates of palisaded basaloid epithelial tumor arising from the epidermis forming a palisade with a cleft forming from the adjacent mucinous stroma extending to the mid dermis. Centrally the nuclei become crowded with scattered mitotic figures and necrotic bodies evident.”
Recent Improvement for 1-Stage Mohs Surgeries
The most notable improvement in the
Final Thoughts
Overall, the updated Medicare guidance provides important details in the requirements for performance and documentation of Mohs surgery cases. However, additional critical information will be found in Mohs coverage policies and local coverage determinations (LCDs) from MACs and private insurers.2-4 Each LCD and insurer Mohs payment policy has unique wording and requirements. Coverage of MMS for specific malignant diagnoses, histologic subtypes, locations, and clinical scenarios varies between LCDs; most are based directly on the Mohs AUC, while others have a less specific coverage criteria. To understand the specific documentation and coverage requirements of the MAC for a particular region or private insurer, Mohs surgeons are encouraged to familiarize themselves with the Mohs surgery LCD of their local MAC and coverage policies of their insurers and to ensure their documentation substantiates these requirements. Making sure that your MMS documentation is accurate and complies with Medicare and insurer requirements will keep you out of hot water with auditors and allow reimbursement for this critical skin cancer procedure.
In October 2020, Medicare released an updated guidance to reduce Mohs micrographic surgery (MMS) reimbursement issues,1 which initially was released in 2013. This guidance defines the latest performance and documentation requirements that Medicare requires for MMS. Understanding these requirements and making sure that your Mohs surgical reports have all the needed documentation details are critical because auditors from not only Medicare Administrative Contractors (MACs) but also private insurers and Medicare Advantage plans have adopted these standards and will deny payment for Mohs surgical codes if they are not met. This article provides a review of the updated Medicare requirements to make sure your MMS procedure notes are audit proof.
Notes Must Indicate Mohs Is the Most Appropriate Treatment
I review many of my colleagues’ Mohs notes and can tell you that some of the requirements laid out in the updated guidance typically are already reported by Mohs surgeons in their notes, including the location, number, and size of the lesion or lesions treated and the number of stages performed. However, there are some new requirements that often are not reported by Mohs surgeons that now need to be included. The guidance indicates the following:
The majority of skin cancers can be managed by simple excision or destruction techniques. The medical record of a patient undergoing MMS should clearly show that this procedure was chosen because of the complexity (eg, poorly defined clinical borders, possible deep invasion, prior irradiation), size or location (eg, maximum conservation of tumor-free tissue is important). Medicare will consider reimbursement for MMS for accepted diagnoses and indications, which you must document in the patient’s medical record as being appropriate for MMS and that MMS is the most appropriate choice for the treatment of a particular lesion.1
In my experience, most Mohs notes include some statement that the skin cancer treated is appropriate based on the Mohs appropriate use criteria (AUC) or the AUC score. However, notes should make clear not just that the lesion treated is “appropriate” for MMS but also that it is the most appropriate treatment (eg, why the lesion was not managed by standard excision or destruction technique).
Mohs Surgeon Must Perform the Surgery and Interpret Slides
The updated guidance clearly indicates that MMS may only be performed by a physician who is specifically trained and highly skilled in Mohs techniques and pathologic identification: “Medicare will only reimburse for MMS services when the Mohs surgeon acts as both surgeon and pathologist.”1 Mohs micrographic surgery codes may not be billed if preparation or interpretation of the pathology slides is performed by a physician other than the Mohs surgeon. Operative notes and pathology documentation in the patient’s medical record should clearly show that MMS was performed using an accepted MMS technique in which the physician acts in 2 integrated and distinct capacities—surgeon and pathologist—thereby confirming that the procedure meets the definition of the Current Procedural Terminology code(s).
Furthermore, the Mohs operative report should detail “the number of specimens per stage.”1 I interpret this statement to indicate that the Mohs surgeon should document the number of tissue blocks examined in each stage of Mohs surgery. For example, a statement in the notes such as “the specimen from the first Mohs stage was oriented, mapped, and divided into 4 blocks” should suffice to meet this requirement.
Histologic Description Must Be Included in Mohs Notes
Medicare will require the Mohs surgeon to document “the histology of the specimens taken. That description should include depth of invasion, pathological pattern, cell morphology, and, if present, perineural invasion or presence of scar tissue.”1 Although this histologic description requirement appears daunting, it is common for Mohs surgeons to indicate their pathologic findings on their Mohs map such as “NBCC” next to a red area to indicate “nodular basal cell carcinoma visualized.” A template-based system to translate typical pathologic findings can be employed to rapidly and accurately populate a Mohs note with histologic description such as “NBBC=nodular aggregates of palisaded basaloid epithelial tumor arising from the epidermis forming a palisade with a cleft forming from the adjacent mucinous stroma extending to the mid dermis. Centrally the nuclei become crowded with scattered mitotic figures and necrotic bodies evident.”
Recent Improvement for 1-Stage Mohs Surgeries
The most notable improvement in the
Final Thoughts
Overall, the updated Medicare guidance provides important details in the requirements for performance and documentation of Mohs surgery cases. However, additional critical information will be found in Mohs coverage policies and local coverage determinations (LCDs) from MACs and private insurers.2-4 Each LCD and insurer Mohs payment policy has unique wording and requirements. Coverage of MMS for specific malignant diagnoses, histologic subtypes, locations, and clinical scenarios varies between LCDs; most are based directly on the Mohs AUC, while others have a less specific coverage criteria. To understand the specific documentation and coverage requirements of the MAC for a particular region or private insurer, Mohs surgeons are encouraged to familiarize themselves with the Mohs surgery LCD of their local MAC and coverage policies of their insurers and to ensure their documentation substantiates these requirements. Making sure that your MMS documentation is accurate and complies with Medicare and insurer requirements will keep you out of hot water with auditors and allow reimbursement for this critical skin cancer procedure.
- Centers for Disease Control and Prevention. Guidance to reduce Mohs surgery reimbursement issues. MLN Matters. Published October 27, 2020. Accessed July 18, 2022. https://www.cms.gov/Outreach-and-Education/Medicare-Learning-Network-MLN/MLNMattersArticles/Downloads/SE1318.pdf
- Mohs micrographic surgery policy, professional. United Healthcare website. Accessed July 12, 2022. https://www.uhcprovider.com/content/dam/provider/docs/public/policies/comm-reimbursement/COMM-Mohs-Micrographic-Surgery-Policy.pdf#:~:text=This%20policy%20describes%20reimbursement%20guidelines%20for%20reporting%20Mohs,CCI%20Editing%20Policy%20and%20the%20Laboratory%20Services%20Policy.
- Clinical UM guideline—Mohs micrographic surgery. Anthem Insurance Companies website. Published October 6, 2021. Accessed July 27, 2022. https://www.anthem.com/dam/medpolicies/abcbs/active/guidelines/gl_pw_d085074.html
- Local coverage determinations. Centers for Medicare and Medicaid Services website. Updated July 12, 2022. Accessed July 12, 2022. https://www.cms.gov/Medicare/Coverage/DeterminationProcess/LCDs
- Centers for Disease Control and Prevention. Guidance to reduce Mohs surgery reimbursement issues. MLN Matters. Published October 27, 2020. Accessed July 18, 2022. https://www.cms.gov/Outreach-and-Education/Medicare-Learning-Network-MLN/MLNMattersArticles/Downloads/SE1318.pdf
- Mohs micrographic surgery policy, professional. United Healthcare website. Accessed July 12, 2022. https://www.uhcprovider.com/content/dam/provider/docs/public/policies/comm-reimbursement/COMM-Mohs-Micrographic-Surgery-Policy.pdf#:~:text=This%20policy%20describes%20reimbursement%20guidelines%20for%20reporting%20Mohs,CCI%20Editing%20Policy%20and%20the%20Laboratory%20Services%20Policy.
- Clinical UM guideline—Mohs micrographic surgery. Anthem Insurance Companies website. Published October 6, 2021. Accessed July 27, 2022. https://www.anthem.com/dam/medpolicies/abcbs/active/guidelines/gl_pw_d085074.html
- Local coverage determinations. Centers for Medicare and Medicaid Services website. Updated July 12, 2022. Accessed July 12, 2022. https://www.cms.gov/Medicare/Coverage/DeterminationProcess/LCDs
Practice Points
- Medicare’s updated guidance for documentation of Mohs micrographic surgery (MMS) includes some new requirements that Mohs surgeons should ensure are implemented in their Mohs records.
- Per Medicare guidance, MMS records should include a justification of why MMS was the most appropriate treatment and a description of the histologic findings from the Mohs slides.
- One major improvement with the updated documentation requirements is that if no tumor is visualized in the first stage of MMS, then no histology description of the tumor is required.
Discrepancies in Skin Cancer Screening Reporting Among Patients, Primary Care Physicians, and Patient Medical Records
Keratinocyte carcinoma (KC), or nonmelanoma skin cancer, is the most commonly diagnosed cancer in the United States.1 Basal cell carcinoma comprises the majority of all KCs.2,3 Squamous cell carcinoma is the second most common skin cancer, representing approximately 20% of KCs and accounting for the majority of KC-related deaths.4-7 Malignant melanoma represents the majority of all skin cancer–related deaths.8 The incidence of basal cell carcinoma, squamous cell carcinoma, and malignant melanoma in the United States is on the rise and carries substantial morbidity and mortality with notable social and economic burdens.1,8-10
Prevention is necessary to reduce skin cancer morbidity and mortality as well as rising treatment costs. The most commonly used skin cancer screening method among dermatologists is the visual full-body skin examination (FBSE), which is a noninvasive, safe, quick, and cost-effective method of early detection and prevention.11 To effectively confront the growing incidence and health care burden of skin cancer, primary care providers (PCPs) must join dermatologists in conducting FBSEs.12,13
Despite being the predominant means of secondary skin cancer prevention, the US Preventive Services Task Force (USPSTF) issued an I rating for insufficient evidence to assess the benefits vs harms of screening the adult general population by PCPs.14,15 A major barrier to studying screening is the lack of a standardized method for conducting and reporting FBSEs.13 Systematic thorough skin examination generally is not performed in the primary care setting.16-18
We aimed to investigate what occurs during an FBSE in the primary care setting and how often they are performed. We examined whether there was potential variation in the execution of the examination, what was perceived by the patient vs reported by the physician, and what was ultimately included in the medical record. Miscommunication between patient and provider regarding performance of FBSEs has previously been noted,17-19 and we sought to characterize and quantify that miscommunication. We hypothesized that there would be lower patient-reported FBSEs compared to physicians and patient medical records. We also hypothesized that there would be variability in how physicians screened for skin cancer.
METHODS
This study was cross-sectional and was conducted based on interviews and a review of medical records at secondary- and tertiary-level units (clinics and hospitals) across the United States. We examined baseline data from a randomized controlled trial of a Web-based skin cancer early detection continuing education course—the Basic Skin Cancer Triage curriculum. Complete details have been described elsewhere.12 This study was approved by the institutional review boards of the Providence Veterans Affairs Medical Center, Rhode Island Hospital, and Brown University (all in Providence, Rhode Island), as well as those of all recruitment sites.
Data were collected from 2005 to 2008 and included physician online surveys, patient telephone interviews, and patient medical record data abstracted by research assistants. Primary care providers included in the study were general internists, family physicians, or medicine-pediatrics practitioners who were recruited from 4 collaborating centers across the United States in the mid-Atlantic region, Ohio, Kansas, and southern California, and who had been in practice for at least a year. Patients were recruited from participating physician practices and selected by research assistants who traveled to each clinic for coordination, recruitment, and performance of medical record reviews. Patients were selected as having minimal risk of melanoma (eg, no signs of severe photodamage to the skin). Patients completed structured telephone surveys within 1 to 2 weeks of the office visit regarding the practices observed and clinical questions asked during their recent clinical encounter with their PCP.
Measures
Demographics—Demographic variables asked of physicians included age, sex, ethnicity, academic degree (MD vs DO), years in practice, training, and prior dermatology training. Demographic information asked of patients included age, sex, ethnicity, education, and household income.
Physician-Reported Examination and Counseling Variables—Physicians were asked to characterize their clinical practices, prompted by questions regarding performance of FBSEs: “Please think of a typical month and using the scale below, indicate how frequently you perform a total body skin exam during an annual exam (eg, periodic follow-up exam).” Physicians responded to 3 questions on a 5-point scale (1=never, 2=sometimes, 3=about half, 4=often, 5=almost always).
Patient-Reported Examination Variables—Patients also were asked to characterize the skin examination experienced in their clinical encounter with their PCP, including: “During your last visit, as far as you could tell, did your physician: (1) look at the skin on your back? (2) look at the skin on your belly area? (3) look at the skin on the back of your legs?” Patient responses were coded as yes, no, don’t know, or refused. Participants who refused were excluded from analysis; participants who responded are detailed in Table 1. In addition, patients also reported the level of undress with their physician by answering the following question: “During your last medical exam, did you: 1=keep your clothes on; 2=partially undress; 3=totally undress except for undergarments; 4=totally undress, including all undergarments?”
Patient Medical Record–Extracted Data—Research assistants used a structured abstract form to extract the information from the patient’s medical record and graded it as 0 (absence) or 1 (presence) from the medical record.
Statistical Analysis
Descriptive statistics included mean and standard deviation (SD) for continuous variables as well as frequency and percentage for categorical variables. Logit/logistic regression analysis was used to predict the odds of patient-reported outcomes that were binary with physician-reported variables as the predictor. Linear regression analysis was used to assess the association between 2 continuous variables. All analyses were conducted using SPSS version 24 (IBM).20 Significance criterion was set at α of .05.
RESULTS Demographics
The final sample included data from 53 physicians and 3343 patients. The study sample mean age (SD) was 50.3 (9.9) years for PCPs (n=53) and 59.8 (16.9) years for patients (n=3343). The physician sample was 36% female and predominantly White (83%). Ninety-one percent of the PCPs had an MD (the remaining had a DO degree), and the mean (SD) years practicing was 21.8 (10.6) years. Seventeen percent of PCPs were trained in internal medicine, 4% in internal medicine and pediatrics, and 79% family medicine; 79% of PCPs had received prior training in dermatology. The patient sample was 58% female, predominantly White (84%), non-Hispanic/Latinx (95%), had completed high school (94%), and earned more than $40,000 annually (66%).
Physician- and Patient-Reported FBSEs
Physicians reported performing FBSEs with variable frequency. Among PCPs who conducted FBSEs with greater frequency, there was a modest increase in the odds that patients reported a particular body part was examined (back: odds ratio [OR], 24.5% [95% CI, 1.18-1.31; P<.001]; abdomen: OR, 23.3% [95% CI, 1.17-1.30; P<.001]; backs of legs: OR, 20.4% [95% CI, 1.13-1.28; P<.001])(Table 1). The patient-reported level of undress during examination was significantly associated with physician-reported FBSE (β=0.16 [95% CI, 0.13-0.18; P<.001])(Table 2).
Because of the bimodal distribution of scores in the physician-reported frequency of FBSEs, particularly pertaining to the extreme points of the scale, we further repeated analysis with only the never and almost always groups (Table 1). Primary care providers who reported almost always for FBSE had 29.6% increased odds of patient-reported back examination (95% CI, 1.00-1.68; P=.048) and 59.3% increased odds of patient-reported abdomen examination (95% CI, 1.23-2.06; P<.001). The raw percentages of patients who reported having their back, abdomen, and backs of legs examined when the PCP reported having never conducted an FBSE were 56%, 40%, and 26%, respectively. The raw percentages of patients who reported having their back, abdomen, and backs of legs examined when the PCP reported having almost always conducted an FBSE were 52%, 51%, and 30%, respectively. Raw percentages were calculated by dividing the number of "yes" responses by participants for each body part examined by thetotal number of participant responses (“yes” and “no”) for each respective body part. There was no significant change in odds of patient-reported backs of legs examined with PCP-reported never vs almost always conducting an FBSE. In addition, a greater patient-reported level of undress was associated with 20.2% increased odds of PCPs reporting almost always conducting an FBSE (95% CI, 1.08-1.34; P=.001).
FBSEs in Patient Medical Records
When comparing PCP-reported FBSE and report of FBSE in patient medical records, there was a 39.0% increased odds of the patient medical record indicating FBSE when physicians reported conducting an FBSE with greater frequency (95% CI, 1.30-1.48; P<.001)(eTable 1). When examining PCP-reported never vs almost always conducting an FBSE, a report of almost always was associated with 79.0% increased odds of the patient medical record indicating that an FBSE was conducted (95% CI, 1.28-2.49; P=.001). The raw percentage of the patient medical record indicating an FBSE was conducted when the PCP reported having never conducted an FBSE was 17% and 26% when the PCP reported having almost always conducted an FBSE.
When comparing the patient-reported body part examined with patient FBSE medical record documentation, an indication of yes for FBSE on the patient medical record was associated with a considerable increase in odds that patients reported a particular body part was examined (back: 91.4% [95% CI, 1.59-2.31; P<.001]; abdomen: 75.0% [95% CI, 1.45-2.11; P<.001]; backs of legs: 91.6% [95% CI, 1.56-2.36; P<.001])(eTable 2). The raw percentages of patients who reported having their back, abdomen, and backs of legs examined vs not examined when the patient medical record indicated an FBSE was completed were 24% vs 14%, 23% vs 15%, and 26% vs 16%, respectively. An increase in patient-reported level of undress was associated with a 57.0% increased odds of their medical record indicating an FBSE was conducted (95% CI, 1.45-1.70; P<.001).
COMMENT How PCPs Perform FBSEs Varies
We found that PCPs performed FBSEs with variable frequency, and among those who did, the patient report of their examination varied considerably (Table 1). There appears to be considerable ambiguity in each of these means of determining the extent to which the skin was inspected for skin cancer, which may render the task of improving such inspection more difficult. We asked patients whether their back, abdomen, and backs of legs were examined as an assessment of some of the variety of areas inspected during an FBSE. During a general well-visit appointment, a patient’s back and abdomen may be examined for multiple reasons. Patients may have misinterpreted elements of the pulmonary, cardiac, abdominal, or musculoskeletal examinations as being part of the FBSE. The back and abdomen—the least specific features of the FBSE—were reported by patients to be the most often examined. Conversely, the backs of the legs—the most specific feature of the FBSE—had the lowest odds of being examined (Table 1).
In addition to the potential limitations of patient awareness of physician activity, our results also could be explained by differences among PCPs in how they performed FBSEs. There is no standardized method of conducting an FBSE. Furthermore, not all medical students and residents are exposed to dermatology training. In our sample of 53 physicians, 79% had reported receiving dermatology training; however, we did not assess the extent to which they had been trained in conducting an FBSE and/or identifying malignant lesions. In an American survey of 659 medical students, more than two-thirds of students had never been trained or never examined a patient for skin cancer.21 In another American survey of 342 internal medicine, family medicine, pediatrics, and obstetrics/gynecology residents across 7 medical schools and 4 residency programs, more than three-quarters of residents had never been trained in skin cancer screening.22 Our findings reflect insufficient and inconsistent training in skin cancer screening and underscore the need for mandatory education to ensure quality FBSEs are performed in the primary care setting.
Frequency of PCPs Performing FBSEs
Similar to prior studies analyzing the frequency of FBSE performance in the primary care setting,16,19,23,24 more than half of our PCP sample reported sometimes to never conducting FBSEs. The percentage of physicians who reported conducting FBSEs in our sample was greater than the proportion reported by the National Health Interview Survey, in which only 8% of patients received an FBSE in the prior year by a PCP or obstetrician/gynecologist,16 but similar to a smaller patient study.19 In that study, 87% of patients, regardless of their skin cancer history, also reported that they would like their PCP to perform an FBSE regularly.19 Although some of our patient participants may have declined an FBSE, it is unlikely that that would have entirely accounted for the relatively low number of PCPs who reported frequently performing FBSEs.
Documentation in Medical Records of FBSEs
Compared to PCP self-reported performance of FBSEs, considerably fewer PCPs marked the patient medical record as having completed an FBSE. Among patients with medical records that indicated an FBSE had been conducted, they reported higher odds of all 3 body parts being examined, the highest being the backs of the legs. Also, when the patient medical record indicated an FBSE had been completed, the odds that the PCP reported an FBSE also were higher. The relatively low medical record documentation of FBSEs highlights the need for more rigorous enforcement of accurate documentation. However, among the cases that were recorded, it appeared that the content of the examinations was more consistent.
Benefits of PCP-Led FBSEs
Although the USPSTF issued an I rating for PCP-led FBSEs,14 multiple national medical societies, including the American Cancer Society,25 American Academy of Dermatology,26 and Skin Cancer Foundation,27 as well as international guidelines in Germany,28 Australia,29,30 and New Zealand,31 recommend regular FBSEs among the general or at-risk population; New Zealand and Australia have the highest incidence and prevalence of melanoma in the world.8 The benefits of physician-led FBSEs on detection of early-stage skin cancer, and in particular, melanoma detection, have been documented in numerous studies.30,32-38 However, the variability and often poor quality of skin screening may contribute in part to the just as numerous null results from prior skin screening studies,15 perpetuating the insufficient status of skin examinations by USPSTF standards.14 Our study underscores both the variability in frequency and content of PCP-administered FBSEs. It also highlights the need for standardization of screening examinations at the medical student, trainee, and physician level.
Study Limitations
The present study has several limitations. First, there was an unknown time lag between the FBSEs and physician self-reported surveys. Similarly, there was a variable time lag between the patient examination encounter and subsequent telephone survey. Both the physician and patient survey data may have been affected by recall bias. Second, patients were not asked directly whether an FBSE had been conducted. Furthermore, patients may not have appreciated whether the body part examined was part of the FBSE or another examination. Also, screenings often were not recorded in the medical record, assuming that the patient report and/or physician report was more accurate than the medical record.
Our study also was limited by demographics; our patient sample was largely comprised of White, educated, US adults, potentially limiting the generalizability of our findings. Conversely, a notable strength of our study was that our participants were recruited from 4 geographically diverse centers. Furthermore, we had a comparatively large sample size of patients and physicians. Also, the independent assessment of provider-reported examinations, objective assessment of medical records, and patient reports of their encounters provides a strong foundation for assessing the independent contributions of each data source.
CONCLUSION
Our study highlights the challenges future studies face in promoting skin cancer screening in the primary care setting. Our findings underscore the need for a standardized FBSE as well as clear clinical expectations regarding skin cancer screening that is expected of PCPs.
As long as skin cancer screening rates remain low in the United States, patients will be subject to potential delays and missed diagnoses, impacting morbidity and mortality.8 There are burgeoning resources and efforts in place to increase skin cancer screening. For example, free validated online training is available for early detection of melanoma and other skin cancers (https://www.visualdx.com/skin-cancer-education/).39-42 Future directions for bolstering screening numbers must focus on educating PCPs about skin cancer prevention and perhaps narrowing the screening population by age-appropriate risk assessments.
- Rogers HW, Weinstock MA, Feldman SR, et al. Incidence estimate of nonmelanoma skin cancer (keratinocyte carcinomas) in the U.S. population, 2012. JAMA Dermatol. 2015;151:1081-1086.
- Marzuka AG, Book SE. Basal cell carcinoma: pathogenesis, epidemiology, clinical features, diagnosis, histopathology, and management. Yale J Biol Med. 2015;88:167-179.
- Dourmishev LA, Rusinova D, Botev I. Clinical variants, stages, and management of basal cell carcinoma. Indian Dermatol Online J. 2013;4:12-17.
- Thompson AK, Kelley BF, Prokop LJ, et al. Risk factors for cutaneous squamous cell carcinoma outcomes: a systematic review and meta-analysis. JAMA Dermatol. 2016;152:419-428.
- Motaparthi K, Kapil JP, Velazquez EF. Cutaneous squamous cell carcinoma: review of the eighth edition of the American Joint Committee on Cancer Staging Guidelines, Prognostic Factors, and Histopathologic Variants. Adv Anat Pathol. 2017;24:171-194.
- Barton V, Armeson K, Hampras S, et al. Nonmelanoma skin cancer and risk of all-cause and cancer-related mortality: a systematic review. Arch Dermatol Res. 2017;309:243-251.
- Weinstock MA, Bogaars HA, Ashley M, et al. Nonmelanoma skin cancer mortality. a population-based study. Arch Dermatol. 1991;127:1194-1197.
- Matthews NH, Li W-Q, Qureshi AA, et al. Epidemiology of melanoma. In: Ward WH, Farma JM, eds. Cutaneous Melanoma: Etiology and Therapy. Codon Publications; 2017:3-22.
- Cakir BO, Adamson P, Cingi C. Epidemiology and economic burden of nonmelanoma skin cancer. Facial Plast Surg Clin North Am. 2012;20:419-422.
- Guy GP, Machlin SR, Ekwueme DU, et al. Prevalence and costs of skin cancer treatment in the U.S., 2002-2006 and 2007-2011. Am J Prev Med. 2015;48:183-187.
- Losina E, Walensky RP, Geller A, et al. Visual screening for malignant melanoma: a cost-effectiveness analysis. Arch Dermatol. 2007;143:21-28.
- Markova A, Weinstock MA, Risica P, et al. Effect of a web-based curriculum on primary care practice: basic skin cancer triage trial. Fam Med. 2013;45:558-568.
- Johnson MM, Leachman SA, Aspinwall LG, et al. Skin cancer screening: recommendations for data-driven screening guidelines and a review of the US Preventive Services Task Force controversy. Melanoma Manag. 2017;4:13-37.
- Agency for Healthcare Research and Quality. Screening for skin cancer in adults: an updated systematic evidence review for the U.S. Preventive Services Task Force. November 30, 2015. Accessed July 25, 2022. http://uspreventiveservicestaskforce.org/Page/Document/draft-evidence-review159/skin-cancer-screening2
- Wernli KJ, Henrikson NB, Morrison CC, et al. Screening for skin cancer in adults: updated evidence report and systematic review forthe US Preventive Services Task Force. JAMA. 2016;316:436-447.
- LeBlanc WG, Vidal L, Kirsner RS, et al. Reported skin cancer screening of US adult workers. J Am Acad Dermatol. 2008;59:55-63.
- Federman DG, Concato J, Caralis PV, et al. Screening for skin cancer in primary care settings. Arch Dermatol. 1997;133:1423-1425.
- Kirsner RS, Muhkerjee S, Federman DG. Skin cancer screening in primary care: prevalence and barriers. J Am Acad Dermatol. 1999;41:564-566.
- Federman DG, Kravetz JD, Tobin DG, et al. Full-body skin examinations: the patient’s perspective. Arch Dermatol. 2004;140:530-534.
- IBM. IBM SPSS Statistics for Windows. IBM Corp; 2015.
- Moore MM, Geller AC, Zhang Z, et al. Skin cancer examination teaching in US medical education. Arch Dermatol. 2006;142:439-444.
- Wise E, Singh D, Moore M, et al. Rates of skin cancer screening and prevention counseling by US medical residents. Arch Dermatol. 2009;145:1131-1136.
- Lakhani NA, Saraiya M, Thompson TD, et al. Total body skin examination for skin cancer screening among U.S. adults from 2000 to 2010. Prev Med. 2014;61:75-80.
- Coups EJ, Geller AC, Weinstock MA, et al. Prevalence and correlates of skin cancer screening among middle-aged and older white adults in the United States. Am J Med. 2010;123:439-445.
- American Cancer Society. Cancer facts & figures 2016. Accessed March 13, 2022. https://cancer.org/research/cancerfactsstatistics/cancerfactsfigures2016/
- American Academy of Dermatology. Skin cancer incidence rates. Updated April 22, 2022. Accessed August 1, 2022. https://www.aad.org/media/stats-skin-cancer
- Skin Cancer Foundation. Skin cancer prevention. Accessed July 25, 2022. http://skincancer.org/prevention/sun-protection/prevention-guidelines
- Katalinic A, Eisemann N, Waldmann A. Skin cancer screening in Germany. documenting melanoma incidence and mortality from 2008 to 2013. Dtsch Arztebl Int. 2015;112:629-634.
- Cancer Council Australia. Position statement: screening and early detection of skin cancer. Published July 2014. Accessed July 25, 2022. https://dermcoll.edu.au/wp-content/uploads/2014/05/PosStatEarlyDetectSkinCa.pdf
- Royal Australian College of General Practitioners. Guidelines for Preventive Activities in General Practice. 9th ed. The Royal Australian College of General Practitioners; 2016. Accessed July 27, 2022. https://www.racgp.org.au/download/Documents/Guidelines/Redbook9/17048-Red-Book-9th-Edition.pdf
- Cancer Council Australia and Australian Cancer Network and New Zealand Guidelines Group. Clinical Practice Guidelines for the Management of Melanoma in Australia and New Zealand. The Cancer Council Australia and Australian Cancer Network, Sydney and New Zealand Guidelines Group, Wellington; 2008. Accessed July 27, 2022. https://www.health.govt.nz/system/files/documents/publications/melanoma-guideline-nov08-v2.pdf
- Swetter SM, Pollitt RA, Johnson TM, et al. Behavioral determinants of successful early melanoma detection: role of self and physician skin examination. Cancer. 2012;118:3725-3734.
- Terushkin V, Halpern AC. Melanoma early detection. Hematol Oncol Clin North Am. 2009;23:481-500, viii.
- Aitken JF, Elwood M, Baade PD, et al. Clinical whole-body skin examination reduces the incidence of thick melanomas. Int J Cancer. 2010;126:450-458.
- Aitken JF, Elwood JM, Lowe JB, et al. A randomised trial of population screening for melanoma. J Med Screen. 2002;9:33-37.
- Breitbart EW, Waldmann A, Nolte S, et al. Systematic skin cancer screening in Northern Germany. J Am Acad Dermatol. 2012;66:201-211.
- Janda M, Lowe JB, Elwood M, et al. Do centralised skin screening clinics increase participation in melanoma screening (Australia)? Cancer Causes Control. 2006;17:161-168.
- Aitken JF, Janda M, Elwood M, et al. Clinical outcomes from skin screening clinics within a community-based melanoma screening program. J Am Acad Dermatol. 2006;54:105-114.
- Eide MJ, Asgari MM, Fletcher SW, et al. Effects on skills and practice from a web-based skin cancer course for primary care providers. J Am Board Fam Med. 2013;26:648-657.
- Weinstock MA, Ferris LK, Saul MI, et al. Downstream consequences of melanoma screening in a community practice setting: first results. Cancer. 2016;122:3152-3156.
- Matthews NH, Risica PM, Ferris LK, et al. Psychosocial impact of skin biopsies in the setting of melanoma screening: a cross-sectional survey. Br J Dermatol. 2019;180:664-665.
- Risica PM, Matthews NH, Dionne L, et al. Psychosocial consequences of skin cancer screening. Prev Med Rep. 2018;10:310-316.
Keratinocyte carcinoma (KC), or nonmelanoma skin cancer, is the most commonly diagnosed cancer in the United States.1 Basal cell carcinoma comprises the majority of all KCs.2,3 Squamous cell carcinoma is the second most common skin cancer, representing approximately 20% of KCs and accounting for the majority of KC-related deaths.4-7 Malignant melanoma represents the majority of all skin cancer–related deaths.8 The incidence of basal cell carcinoma, squamous cell carcinoma, and malignant melanoma in the United States is on the rise and carries substantial morbidity and mortality with notable social and economic burdens.1,8-10
Prevention is necessary to reduce skin cancer morbidity and mortality as well as rising treatment costs. The most commonly used skin cancer screening method among dermatologists is the visual full-body skin examination (FBSE), which is a noninvasive, safe, quick, and cost-effective method of early detection and prevention.11 To effectively confront the growing incidence and health care burden of skin cancer, primary care providers (PCPs) must join dermatologists in conducting FBSEs.12,13
Despite being the predominant means of secondary skin cancer prevention, the US Preventive Services Task Force (USPSTF) issued an I rating for insufficient evidence to assess the benefits vs harms of screening the adult general population by PCPs.14,15 A major barrier to studying screening is the lack of a standardized method for conducting and reporting FBSEs.13 Systematic thorough skin examination generally is not performed in the primary care setting.16-18
We aimed to investigate what occurs during an FBSE in the primary care setting and how often they are performed. We examined whether there was potential variation in the execution of the examination, what was perceived by the patient vs reported by the physician, and what was ultimately included in the medical record. Miscommunication between patient and provider regarding performance of FBSEs has previously been noted,17-19 and we sought to characterize and quantify that miscommunication. We hypothesized that there would be lower patient-reported FBSEs compared to physicians and patient medical records. We also hypothesized that there would be variability in how physicians screened for skin cancer.
METHODS
This study was cross-sectional and was conducted based on interviews and a review of medical records at secondary- and tertiary-level units (clinics and hospitals) across the United States. We examined baseline data from a randomized controlled trial of a Web-based skin cancer early detection continuing education course—the Basic Skin Cancer Triage curriculum. Complete details have been described elsewhere.12 This study was approved by the institutional review boards of the Providence Veterans Affairs Medical Center, Rhode Island Hospital, and Brown University (all in Providence, Rhode Island), as well as those of all recruitment sites.
Data were collected from 2005 to 2008 and included physician online surveys, patient telephone interviews, and patient medical record data abstracted by research assistants. Primary care providers included in the study were general internists, family physicians, or medicine-pediatrics practitioners who were recruited from 4 collaborating centers across the United States in the mid-Atlantic region, Ohio, Kansas, and southern California, and who had been in practice for at least a year. Patients were recruited from participating physician practices and selected by research assistants who traveled to each clinic for coordination, recruitment, and performance of medical record reviews. Patients were selected as having minimal risk of melanoma (eg, no signs of severe photodamage to the skin). Patients completed structured telephone surveys within 1 to 2 weeks of the office visit regarding the practices observed and clinical questions asked during their recent clinical encounter with their PCP.
Measures
Demographics—Demographic variables asked of physicians included age, sex, ethnicity, academic degree (MD vs DO), years in practice, training, and prior dermatology training. Demographic information asked of patients included age, sex, ethnicity, education, and household income.
Physician-Reported Examination and Counseling Variables—Physicians were asked to characterize their clinical practices, prompted by questions regarding performance of FBSEs: “Please think of a typical month and using the scale below, indicate how frequently you perform a total body skin exam during an annual exam (eg, periodic follow-up exam).” Physicians responded to 3 questions on a 5-point scale (1=never, 2=sometimes, 3=about half, 4=often, 5=almost always).
Patient-Reported Examination Variables—Patients also were asked to characterize the skin examination experienced in their clinical encounter with their PCP, including: “During your last visit, as far as you could tell, did your physician: (1) look at the skin on your back? (2) look at the skin on your belly area? (3) look at the skin on the back of your legs?” Patient responses were coded as yes, no, don’t know, or refused. Participants who refused were excluded from analysis; participants who responded are detailed in Table 1. In addition, patients also reported the level of undress with their physician by answering the following question: “During your last medical exam, did you: 1=keep your clothes on; 2=partially undress; 3=totally undress except for undergarments; 4=totally undress, including all undergarments?”
Patient Medical Record–Extracted Data—Research assistants used a structured abstract form to extract the information from the patient’s medical record and graded it as 0 (absence) or 1 (presence) from the medical record.
Statistical Analysis
Descriptive statistics included mean and standard deviation (SD) for continuous variables as well as frequency and percentage for categorical variables. Logit/logistic regression analysis was used to predict the odds of patient-reported outcomes that were binary with physician-reported variables as the predictor. Linear regression analysis was used to assess the association between 2 continuous variables. All analyses were conducted using SPSS version 24 (IBM).20 Significance criterion was set at α of .05.
RESULTS Demographics
The final sample included data from 53 physicians and 3343 patients. The study sample mean age (SD) was 50.3 (9.9) years for PCPs (n=53) and 59.8 (16.9) years for patients (n=3343). The physician sample was 36% female and predominantly White (83%). Ninety-one percent of the PCPs had an MD (the remaining had a DO degree), and the mean (SD) years practicing was 21.8 (10.6) years. Seventeen percent of PCPs were trained in internal medicine, 4% in internal medicine and pediatrics, and 79% family medicine; 79% of PCPs had received prior training in dermatology. The patient sample was 58% female, predominantly White (84%), non-Hispanic/Latinx (95%), had completed high school (94%), and earned more than $40,000 annually (66%).
Physician- and Patient-Reported FBSEs
Physicians reported performing FBSEs with variable frequency. Among PCPs who conducted FBSEs with greater frequency, there was a modest increase in the odds that patients reported a particular body part was examined (back: odds ratio [OR], 24.5% [95% CI, 1.18-1.31; P<.001]; abdomen: OR, 23.3% [95% CI, 1.17-1.30; P<.001]; backs of legs: OR, 20.4% [95% CI, 1.13-1.28; P<.001])(Table 1). The patient-reported level of undress during examination was significantly associated with physician-reported FBSE (β=0.16 [95% CI, 0.13-0.18; P<.001])(Table 2).
Because of the bimodal distribution of scores in the physician-reported frequency of FBSEs, particularly pertaining to the extreme points of the scale, we further repeated analysis with only the never and almost always groups (Table 1). Primary care providers who reported almost always for FBSE had 29.6% increased odds of patient-reported back examination (95% CI, 1.00-1.68; P=.048) and 59.3% increased odds of patient-reported abdomen examination (95% CI, 1.23-2.06; P<.001). The raw percentages of patients who reported having their back, abdomen, and backs of legs examined when the PCP reported having never conducted an FBSE were 56%, 40%, and 26%, respectively. The raw percentages of patients who reported having their back, abdomen, and backs of legs examined when the PCP reported having almost always conducted an FBSE were 52%, 51%, and 30%, respectively. Raw percentages were calculated by dividing the number of "yes" responses by participants for each body part examined by thetotal number of participant responses (“yes” and “no”) for each respective body part. There was no significant change in odds of patient-reported backs of legs examined with PCP-reported never vs almost always conducting an FBSE. In addition, a greater patient-reported level of undress was associated with 20.2% increased odds of PCPs reporting almost always conducting an FBSE (95% CI, 1.08-1.34; P=.001).
FBSEs in Patient Medical Records
When comparing PCP-reported FBSE and report of FBSE in patient medical records, there was a 39.0% increased odds of the patient medical record indicating FBSE when physicians reported conducting an FBSE with greater frequency (95% CI, 1.30-1.48; P<.001)(eTable 1). When examining PCP-reported never vs almost always conducting an FBSE, a report of almost always was associated with 79.0% increased odds of the patient medical record indicating that an FBSE was conducted (95% CI, 1.28-2.49; P=.001). The raw percentage of the patient medical record indicating an FBSE was conducted when the PCP reported having never conducted an FBSE was 17% and 26% when the PCP reported having almost always conducted an FBSE.
When comparing the patient-reported body part examined with patient FBSE medical record documentation, an indication of yes for FBSE on the patient medical record was associated with a considerable increase in odds that patients reported a particular body part was examined (back: 91.4% [95% CI, 1.59-2.31; P<.001]; abdomen: 75.0% [95% CI, 1.45-2.11; P<.001]; backs of legs: 91.6% [95% CI, 1.56-2.36; P<.001])(eTable 2). The raw percentages of patients who reported having their back, abdomen, and backs of legs examined vs not examined when the patient medical record indicated an FBSE was completed were 24% vs 14%, 23% vs 15%, and 26% vs 16%, respectively. An increase in patient-reported level of undress was associated with a 57.0% increased odds of their medical record indicating an FBSE was conducted (95% CI, 1.45-1.70; P<.001).
COMMENT How PCPs Perform FBSEs Varies
We found that PCPs performed FBSEs with variable frequency, and among those who did, the patient report of their examination varied considerably (Table 1). There appears to be considerable ambiguity in each of these means of determining the extent to which the skin was inspected for skin cancer, which may render the task of improving such inspection more difficult. We asked patients whether their back, abdomen, and backs of legs were examined as an assessment of some of the variety of areas inspected during an FBSE. During a general well-visit appointment, a patient’s back and abdomen may be examined for multiple reasons. Patients may have misinterpreted elements of the pulmonary, cardiac, abdominal, or musculoskeletal examinations as being part of the FBSE. The back and abdomen—the least specific features of the FBSE—were reported by patients to be the most often examined. Conversely, the backs of the legs—the most specific feature of the FBSE—had the lowest odds of being examined (Table 1).
In addition to the potential limitations of patient awareness of physician activity, our results also could be explained by differences among PCPs in how they performed FBSEs. There is no standardized method of conducting an FBSE. Furthermore, not all medical students and residents are exposed to dermatology training. In our sample of 53 physicians, 79% had reported receiving dermatology training; however, we did not assess the extent to which they had been trained in conducting an FBSE and/or identifying malignant lesions. In an American survey of 659 medical students, more than two-thirds of students had never been trained or never examined a patient for skin cancer.21 In another American survey of 342 internal medicine, family medicine, pediatrics, and obstetrics/gynecology residents across 7 medical schools and 4 residency programs, more than three-quarters of residents had never been trained in skin cancer screening.22 Our findings reflect insufficient and inconsistent training in skin cancer screening and underscore the need for mandatory education to ensure quality FBSEs are performed in the primary care setting.
Frequency of PCPs Performing FBSEs
Similar to prior studies analyzing the frequency of FBSE performance in the primary care setting,16,19,23,24 more than half of our PCP sample reported sometimes to never conducting FBSEs. The percentage of physicians who reported conducting FBSEs in our sample was greater than the proportion reported by the National Health Interview Survey, in which only 8% of patients received an FBSE in the prior year by a PCP or obstetrician/gynecologist,16 but similar to a smaller patient study.19 In that study, 87% of patients, regardless of their skin cancer history, also reported that they would like their PCP to perform an FBSE regularly.19 Although some of our patient participants may have declined an FBSE, it is unlikely that that would have entirely accounted for the relatively low number of PCPs who reported frequently performing FBSEs.
Documentation in Medical Records of FBSEs
Compared to PCP self-reported performance of FBSEs, considerably fewer PCPs marked the patient medical record as having completed an FBSE. Among patients with medical records that indicated an FBSE had been conducted, they reported higher odds of all 3 body parts being examined, the highest being the backs of the legs. Also, when the patient medical record indicated an FBSE had been completed, the odds that the PCP reported an FBSE also were higher. The relatively low medical record documentation of FBSEs highlights the need for more rigorous enforcement of accurate documentation. However, among the cases that were recorded, it appeared that the content of the examinations was more consistent.
Benefits of PCP-Led FBSEs
Although the USPSTF issued an I rating for PCP-led FBSEs,14 multiple national medical societies, including the American Cancer Society,25 American Academy of Dermatology,26 and Skin Cancer Foundation,27 as well as international guidelines in Germany,28 Australia,29,30 and New Zealand,31 recommend regular FBSEs among the general or at-risk population; New Zealand and Australia have the highest incidence and prevalence of melanoma in the world.8 The benefits of physician-led FBSEs on detection of early-stage skin cancer, and in particular, melanoma detection, have been documented in numerous studies.30,32-38 However, the variability and often poor quality of skin screening may contribute in part to the just as numerous null results from prior skin screening studies,15 perpetuating the insufficient status of skin examinations by USPSTF standards.14 Our study underscores both the variability in frequency and content of PCP-administered FBSEs. It also highlights the need for standardization of screening examinations at the medical student, trainee, and physician level.
Study Limitations
The present study has several limitations. First, there was an unknown time lag between the FBSEs and physician self-reported surveys. Similarly, there was a variable time lag between the patient examination encounter and subsequent telephone survey. Both the physician and patient survey data may have been affected by recall bias. Second, patients were not asked directly whether an FBSE had been conducted. Furthermore, patients may not have appreciated whether the body part examined was part of the FBSE or another examination. Also, screenings often were not recorded in the medical record, assuming that the patient report and/or physician report was more accurate than the medical record.
Our study also was limited by demographics; our patient sample was largely comprised of White, educated, US adults, potentially limiting the generalizability of our findings. Conversely, a notable strength of our study was that our participants were recruited from 4 geographically diverse centers. Furthermore, we had a comparatively large sample size of patients and physicians. Also, the independent assessment of provider-reported examinations, objective assessment of medical records, and patient reports of their encounters provides a strong foundation for assessing the independent contributions of each data source.
CONCLUSION
Our study highlights the challenges future studies face in promoting skin cancer screening in the primary care setting. Our findings underscore the need for a standardized FBSE as well as clear clinical expectations regarding skin cancer screening that is expected of PCPs.
As long as skin cancer screening rates remain low in the United States, patients will be subject to potential delays and missed diagnoses, impacting morbidity and mortality.8 There are burgeoning resources and efforts in place to increase skin cancer screening. For example, free validated online training is available for early detection of melanoma and other skin cancers (https://www.visualdx.com/skin-cancer-education/).39-42 Future directions for bolstering screening numbers must focus on educating PCPs about skin cancer prevention and perhaps narrowing the screening population by age-appropriate risk assessments.
Keratinocyte carcinoma (KC), or nonmelanoma skin cancer, is the most commonly diagnosed cancer in the United States.1 Basal cell carcinoma comprises the majority of all KCs.2,3 Squamous cell carcinoma is the second most common skin cancer, representing approximately 20% of KCs and accounting for the majority of KC-related deaths.4-7 Malignant melanoma represents the majority of all skin cancer–related deaths.8 The incidence of basal cell carcinoma, squamous cell carcinoma, and malignant melanoma in the United States is on the rise and carries substantial morbidity and mortality with notable social and economic burdens.1,8-10
Prevention is necessary to reduce skin cancer morbidity and mortality as well as rising treatment costs. The most commonly used skin cancer screening method among dermatologists is the visual full-body skin examination (FBSE), which is a noninvasive, safe, quick, and cost-effective method of early detection and prevention.11 To effectively confront the growing incidence and health care burden of skin cancer, primary care providers (PCPs) must join dermatologists in conducting FBSEs.12,13
Despite being the predominant means of secondary skin cancer prevention, the US Preventive Services Task Force (USPSTF) issued an I rating for insufficient evidence to assess the benefits vs harms of screening the adult general population by PCPs.14,15 A major barrier to studying screening is the lack of a standardized method for conducting and reporting FBSEs.13 Systematic thorough skin examination generally is not performed in the primary care setting.16-18
We aimed to investigate what occurs during an FBSE in the primary care setting and how often they are performed. We examined whether there was potential variation in the execution of the examination, what was perceived by the patient vs reported by the physician, and what was ultimately included in the medical record. Miscommunication between patient and provider regarding performance of FBSEs has previously been noted,17-19 and we sought to characterize and quantify that miscommunication. We hypothesized that there would be lower patient-reported FBSEs compared to physicians and patient medical records. We also hypothesized that there would be variability in how physicians screened for skin cancer.
METHODS
This study was cross-sectional and was conducted based on interviews and a review of medical records at secondary- and tertiary-level units (clinics and hospitals) across the United States. We examined baseline data from a randomized controlled trial of a Web-based skin cancer early detection continuing education course—the Basic Skin Cancer Triage curriculum. Complete details have been described elsewhere.12 This study was approved by the institutional review boards of the Providence Veterans Affairs Medical Center, Rhode Island Hospital, and Brown University (all in Providence, Rhode Island), as well as those of all recruitment sites.
Data were collected from 2005 to 2008 and included physician online surveys, patient telephone interviews, and patient medical record data abstracted by research assistants. Primary care providers included in the study were general internists, family physicians, or medicine-pediatrics practitioners who were recruited from 4 collaborating centers across the United States in the mid-Atlantic region, Ohio, Kansas, and southern California, and who had been in practice for at least a year. Patients were recruited from participating physician practices and selected by research assistants who traveled to each clinic for coordination, recruitment, and performance of medical record reviews. Patients were selected as having minimal risk of melanoma (eg, no signs of severe photodamage to the skin). Patients completed structured telephone surveys within 1 to 2 weeks of the office visit regarding the practices observed and clinical questions asked during their recent clinical encounter with their PCP.
Measures
Demographics—Demographic variables asked of physicians included age, sex, ethnicity, academic degree (MD vs DO), years in practice, training, and prior dermatology training. Demographic information asked of patients included age, sex, ethnicity, education, and household income.
Physician-Reported Examination and Counseling Variables—Physicians were asked to characterize their clinical practices, prompted by questions regarding performance of FBSEs: “Please think of a typical month and using the scale below, indicate how frequently you perform a total body skin exam during an annual exam (eg, periodic follow-up exam).” Physicians responded to 3 questions on a 5-point scale (1=never, 2=sometimes, 3=about half, 4=often, 5=almost always).
Patient-Reported Examination Variables—Patients also were asked to characterize the skin examination experienced in their clinical encounter with their PCP, including: “During your last visit, as far as you could tell, did your physician: (1) look at the skin on your back? (2) look at the skin on your belly area? (3) look at the skin on the back of your legs?” Patient responses were coded as yes, no, don’t know, or refused. Participants who refused were excluded from analysis; participants who responded are detailed in Table 1. In addition, patients also reported the level of undress with their physician by answering the following question: “During your last medical exam, did you: 1=keep your clothes on; 2=partially undress; 3=totally undress except for undergarments; 4=totally undress, including all undergarments?”
Patient Medical Record–Extracted Data—Research assistants used a structured abstract form to extract the information from the patient’s medical record and graded it as 0 (absence) or 1 (presence) from the medical record.
Statistical Analysis
Descriptive statistics included mean and standard deviation (SD) for continuous variables as well as frequency and percentage for categorical variables. Logit/logistic regression analysis was used to predict the odds of patient-reported outcomes that were binary with physician-reported variables as the predictor. Linear regression analysis was used to assess the association between 2 continuous variables. All analyses were conducted using SPSS version 24 (IBM).20 Significance criterion was set at α of .05.
RESULTS Demographics
The final sample included data from 53 physicians and 3343 patients. The study sample mean age (SD) was 50.3 (9.9) years for PCPs (n=53) and 59.8 (16.9) years for patients (n=3343). The physician sample was 36% female and predominantly White (83%). Ninety-one percent of the PCPs had an MD (the remaining had a DO degree), and the mean (SD) years practicing was 21.8 (10.6) years. Seventeen percent of PCPs were trained in internal medicine, 4% in internal medicine and pediatrics, and 79% family medicine; 79% of PCPs had received prior training in dermatology. The patient sample was 58% female, predominantly White (84%), non-Hispanic/Latinx (95%), had completed high school (94%), and earned more than $40,000 annually (66%).
Physician- and Patient-Reported FBSEs
Physicians reported performing FBSEs with variable frequency. Among PCPs who conducted FBSEs with greater frequency, there was a modest increase in the odds that patients reported a particular body part was examined (back: odds ratio [OR], 24.5% [95% CI, 1.18-1.31; P<.001]; abdomen: OR, 23.3% [95% CI, 1.17-1.30; P<.001]; backs of legs: OR, 20.4% [95% CI, 1.13-1.28; P<.001])(Table 1). The patient-reported level of undress during examination was significantly associated with physician-reported FBSE (β=0.16 [95% CI, 0.13-0.18; P<.001])(Table 2).
Because of the bimodal distribution of scores in the physician-reported frequency of FBSEs, particularly pertaining to the extreme points of the scale, we further repeated analysis with only the never and almost always groups (Table 1). Primary care providers who reported almost always for FBSE had 29.6% increased odds of patient-reported back examination (95% CI, 1.00-1.68; P=.048) and 59.3% increased odds of patient-reported abdomen examination (95% CI, 1.23-2.06; P<.001). The raw percentages of patients who reported having their back, abdomen, and backs of legs examined when the PCP reported having never conducted an FBSE were 56%, 40%, and 26%, respectively. The raw percentages of patients who reported having their back, abdomen, and backs of legs examined when the PCP reported having almost always conducted an FBSE were 52%, 51%, and 30%, respectively. Raw percentages were calculated by dividing the number of "yes" responses by participants for each body part examined by thetotal number of participant responses (“yes” and “no”) for each respective body part. There was no significant change in odds of patient-reported backs of legs examined with PCP-reported never vs almost always conducting an FBSE. In addition, a greater patient-reported level of undress was associated with 20.2% increased odds of PCPs reporting almost always conducting an FBSE (95% CI, 1.08-1.34; P=.001).
FBSEs in Patient Medical Records
When comparing PCP-reported FBSE and report of FBSE in patient medical records, there was a 39.0% increased odds of the patient medical record indicating FBSE when physicians reported conducting an FBSE with greater frequency (95% CI, 1.30-1.48; P<.001)(eTable 1). When examining PCP-reported never vs almost always conducting an FBSE, a report of almost always was associated with 79.0% increased odds of the patient medical record indicating that an FBSE was conducted (95% CI, 1.28-2.49; P=.001). The raw percentage of the patient medical record indicating an FBSE was conducted when the PCP reported having never conducted an FBSE was 17% and 26% when the PCP reported having almost always conducted an FBSE.
When comparing the patient-reported body part examined with patient FBSE medical record documentation, an indication of yes for FBSE on the patient medical record was associated with a considerable increase in odds that patients reported a particular body part was examined (back: 91.4% [95% CI, 1.59-2.31; P<.001]; abdomen: 75.0% [95% CI, 1.45-2.11; P<.001]; backs of legs: 91.6% [95% CI, 1.56-2.36; P<.001])(eTable 2). The raw percentages of patients who reported having their back, abdomen, and backs of legs examined vs not examined when the patient medical record indicated an FBSE was completed were 24% vs 14%, 23% vs 15%, and 26% vs 16%, respectively. An increase in patient-reported level of undress was associated with a 57.0% increased odds of their medical record indicating an FBSE was conducted (95% CI, 1.45-1.70; P<.001).
COMMENT How PCPs Perform FBSEs Varies
We found that PCPs performed FBSEs with variable frequency, and among those who did, the patient report of their examination varied considerably (Table 1). There appears to be considerable ambiguity in each of these means of determining the extent to which the skin was inspected for skin cancer, which may render the task of improving such inspection more difficult. We asked patients whether their back, abdomen, and backs of legs were examined as an assessment of some of the variety of areas inspected during an FBSE. During a general well-visit appointment, a patient’s back and abdomen may be examined for multiple reasons. Patients may have misinterpreted elements of the pulmonary, cardiac, abdominal, or musculoskeletal examinations as being part of the FBSE. The back and abdomen—the least specific features of the FBSE—were reported by patients to be the most often examined. Conversely, the backs of the legs—the most specific feature of the FBSE—had the lowest odds of being examined (Table 1).
In addition to the potential limitations of patient awareness of physician activity, our results also could be explained by differences among PCPs in how they performed FBSEs. There is no standardized method of conducting an FBSE. Furthermore, not all medical students and residents are exposed to dermatology training. In our sample of 53 physicians, 79% had reported receiving dermatology training; however, we did not assess the extent to which they had been trained in conducting an FBSE and/or identifying malignant lesions. In an American survey of 659 medical students, more than two-thirds of students had never been trained or never examined a patient for skin cancer.21 In another American survey of 342 internal medicine, family medicine, pediatrics, and obstetrics/gynecology residents across 7 medical schools and 4 residency programs, more than three-quarters of residents had never been trained in skin cancer screening.22 Our findings reflect insufficient and inconsistent training in skin cancer screening and underscore the need for mandatory education to ensure quality FBSEs are performed in the primary care setting.
Frequency of PCPs Performing FBSEs
Similar to prior studies analyzing the frequency of FBSE performance in the primary care setting,16,19,23,24 more than half of our PCP sample reported sometimes to never conducting FBSEs. The percentage of physicians who reported conducting FBSEs in our sample was greater than the proportion reported by the National Health Interview Survey, in which only 8% of patients received an FBSE in the prior year by a PCP or obstetrician/gynecologist,16 but similar to a smaller patient study.19 In that study, 87% of patients, regardless of their skin cancer history, also reported that they would like their PCP to perform an FBSE regularly.19 Although some of our patient participants may have declined an FBSE, it is unlikely that that would have entirely accounted for the relatively low number of PCPs who reported frequently performing FBSEs.
Documentation in Medical Records of FBSEs
Compared to PCP self-reported performance of FBSEs, considerably fewer PCPs marked the patient medical record as having completed an FBSE. Among patients with medical records that indicated an FBSE had been conducted, they reported higher odds of all 3 body parts being examined, the highest being the backs of the legs. Also, when the patient medical record indicated an FBSE had been completed, the odds that the PCP reported an FBSE also were higher. The relatively low medical record documentation of FBSEs highlights the need for more rigorous enforcement of accurate documentation. However, among the cases that were recorded, it appeared that the content of the examinations was more consistent.
Benefits of PCP-Led FBSEs
Although the USPSTF issued an I rating for PCP-led FBSEs,14 multiple national medical societies, including the American Cancer Society,25 American Academy of Dermatology,26 and Skin Cancer Foundation,27 as well as international guidelines in Germany,28 Australia,29,30 and New Zealand,31 recommend regular FBSEs among the general or at-risk population; New Zealand and Australia have the highest incidence and prevalence of melanoma in the world.8 The benefits of physician-led FBSEs on detection of early-stage skin cancer, and in particular, melanoma detection, have been documented in numerous studies.30,32-38 However, the variability and often poor quality of skin screening may contribute in part to the just as numerous null results from prior skin screening studies,15 perpetuating the insufficient status of skin examinations by USPSTF standards.14 Our study underscores both the variability in frequency and content of PCP-administered FBSEs. It also highlights the need for standardization of screening examinations at the medical student, trainee, and physician level.
Study Limitations
The present study has several limitations. First, there was an unknown time lag between the FBSEs and physician self-reported surveys. Similarly, there was a variable time lag between the patient examination encounter and subsequent telephone survey. Both the physician and patient survey data may have been affected by recall bias. Second, patients were not asked directly whether an FBSE had been conducted. Furthermore, patients may not have appreciated whether the body part examined was part of the FBSE or another examination. Also, screenings often were not recorded in the medical record, assuming that the patient report and/or physician report was more accurate than the medical record.
Our study also was limited by demographics; our patient sample was largely comprised of White, educated, US adults, potentially limiting the generalizability of our findings. Conversely, a notable strength of our study was that our participants were recruited from 4 geographically diverse centers. Furthermore, we had a comparatively large sample size of patients and physicians. Also, the independent assessment of provider-reported examinations, objective assessment of medical records, and patient reports of their encounters provides a strong foundation for assessing the independent contributions of each data source.
CONCLUSION
Our study highlights the challenges future studies face in promoting skin cancer screening in the primary care setting. Our findings underscore the need for a standardized FBSE as well as clear clinical expectations regarding skin cancer screening that is expected of PCPs.
As long as skin cancer screening rates remain low in the United States, patients will be subject to potential delays and missed diagnoses, impacting morbidity and mortality.8 There are burgeoning resources and efforts in place to increase skin cancer screening. For example, free validated online training is available for early detection of melanoma and other skin cancers (https://www.visualdx.com/skin-cancer-education/).39-42 Future directions for bolstering screening numbers must focus on educating PCPs about skin cancer prevention and perhaps narrowing the screening population by age-appropriate risk assessments.
- Rogers HW, Weinstock MA, Feldman SR, et al. Incidence estimate of nonmelanoma skin cancer (keratinocyte carcinomas) in the U.S. population, 2012. JAMA Dermatol. 2015;151:1081-1086.
- Marzuka AG, Book SE. Basal cell carcinoma: pathogenesis, epidemiology, clinical features, diagnosis, histopathology, and management. Yale J Biol Med. 2015;88:167-179.
- Dourmishev LA, Rusinova D, Botev I. Clinical variants, stages, and management of basal cell carcinoma. Indian Dermatol Online J. 2013;4:12-17.
- Thompson AK, Kelley BF, Prokop LJ, et al. Risk factors for cutaneous squamous cell carcinoma outcomes: a systematic review and meta-analysis. JAMA Dermatol. 2016;152:419-428.
- Motaparthi K, Kapil JP, Velazquez EF. Cutaneous squamous cell carcinoma: review of the eighth edition of the American Joint Committee on Cancer Staging Guidelines, Prognostic Factors, and Histopathologic Variants. Adv Anat Pathol. 2017;24:171-194.
- Barton V, Armeson K, Hampras S, et al. Nonmelanoma skin cancer and risk of all-cause and cancer-related mortality: a systematic review. Arch Dermatol Res. 2017;309:243-251.
- Weinstock MA, Bogaars HA, Ashley M, et al. Nonmelanoma skin cancer mortality. a population-based study. Arch Dermatol. 1991;127:1194-1197.
- Matthews NH, Li W-Q, Qureshi AA, et al. Epidemiology of melanoma. In: Ward WH, Farma JM, eds. Cutaneous Melanoma: Etiology and Therapy. Codon Publications; 2017:3-22.
- Cakir BO, Adamson P, Cingi C. Epidemiology and economic burden of nonmelanoma skin cancer. Facial Plast Surg Clin North Am. 2012;20:419-422.
- Guy GP, Machlin SR, Ekwueme DU, et al. Prevalence and costs of skin cancer treatment in the U.S., 2002-2006 and 2007-2011. Am J Prev Med. 2015;48:183-187.
- Losina E, Walensky RP, Geller A, et al. Visual screening for malignant melanoma: a cost-effectiveness analysis. Arch Dermatol. 2007;143:21-28.
- Markova A, Weinstock MA, Risica P, et al. Effect of a web-based curriculum on primary care practice: basic skin cancer triage trial. Fam Med. 2013;45:558-568.
- Johnson MM, Leachman SA, Aspinwall LG, et al. Skin cancer screening: recommendations for data-driven screening guidelines and a review of the US Preventive Services Task Force controversy. Melanoma Manag. 2017;4:13-37.
- Agency for Healthcare Research and Quality. Screening for skin cancer in adults: an updated systematic evidence review for the U.S. Preventive Services Task Force. November 30, 2015. Accessed July 25, 2022. http://uspreventiveservicestaskforce.org/Page/Document/draft-evidence-review159/skin-cancer-screening2
- Wernli KJ, Henrikson NB, Morrison CC, et al. Screening for skin cancer in adults: updated evidence report and systematic review forthe US Preventive Services Task Force. JAMA. 2016;316:436-447.
- LeBlanc WG, Vidal L, Kirsner RS, et al. Reported skin cancer screening of US adult workers. J Am Acad Dermatol. 2008;59:55-63.
- Federman DG, Concato J, Caralis PV, et al. Screening for skin cancer in primary care settings. Arch Dermatol. 1997;133:1423-1425.
- Kirsner RS, Muhkerjee S, Federman DG. Skin cancer screening in primary care: prevalence and barriers. J Am Acad Dermatol. 1999;41:564-566.
- Federman DG, Kravetz JD, Tobin DG, et al. Full-body skin examinations: the patient’s perspective. Arch Dermatol. 2004;140:530-534.
- IBM. IBM SPSS Statistics for Windows. IBM Corp; 2015.
- Moore MM, Geller AC, Zhang Z, et al. Skin cancer examination teaching in US medical education. Arch Dermatol. 2006;142:439-444.
- Wise E, Singh D, Moore M, et al. Rates of skin cancer screening and prevention counseling by US medical residents. Arch Dermatol. 2009;145:1131-1136.
- Lakhani NA, Saraiya M, Thompson TD, et al. Total body skin examination for skin cancer screening among U.S. adults from 2000 to 2010. Prev Med. 2014;61:75-80.
- Coups EJ, Geller AC, Weinstock MA, et al. Prevalence and correlates of skin cancer screening among middle-aged and older white adults in the United States. Am J Med. 2010;123:439-445.
- American Cancer Society. Cancer facts & figures 2016. Accessed March 13, 2022. https://cancer.org/research/cancerfactsstatistics/cancerfactsfigures2016/
- American Academy of Dermatology. Skin cancer incidence rates. Updated April 22, 2022. Accessed August 1, 2022. https://www.aad.org/media/stats-skin-cancer
- Skin Cancer Foundation. Skin cancer prevention. Accessed July 25, 2022. http://skincancer.org/prevention/sun-protection/prevention-guidelines
- Katalinic A, Eisemann N, Waldmann A. Skin cancer screening in Germany. documenting melanoma incidence and mortality from 2008 to 2013. Dtsch Arztebl Int. 2015;112:629-634.
- Cancer Council Australia. Position statement: screening and early detection of skin cancer. Published July 2014. Accessed July 25, 2022. https://dermcoll.edu.au/wp-content/uploads/2014/05/PosStatEarlyDetectSkinCa.pdf
- Royal Australian College of General Practitioners. Guidelines for Preventive Activities in General Practice. 9th ed. The Royal Australian College of General Practitioners; 2016. Accessed July 27, 2022. https://www.racgp.org.au/download/Documents/Guidelines/Redbook9/17048-Red-Book-9th-Edition.pdf
- Cancer Council Australia and Australian Cancer Network and New Zealand Guidelines Group. Clinical Practice Guidelines for the Management of Melanoma in Australia and New Zealand. The Cancer Council Australia and Australian Cancer Network, Sydney and New Zealand Guidelines Group, Wellington; 2008. Accessed July 27, 2022. https://www.health.govt.nz/system/files/documents/publications/melanoma-guideline-nov08-v2.pdf
- Swetter SM, Pollitt RA, Johnson TM, et al. Behavioral determinants of successful early melanoma detection: role of self and physician skin examination. Cancer. 2012;118:3725-3734.
- Terushkin V, Halpern AC. Melanoma early detection. Hematol Oncol Clin North Am. 2009;23:481-500, viii.
- Aitken JF, Elwood M, Baade PD, et al. Clinical whole-body skin examination reduces the incidence of thick melanomas. Int J Cancer. 2010;126:450-458.
- Aitken JF, Elwood JM, Lowe JB, et al. A randomised trial of population screening for melanoma. J Med Screen. 2002;9:33-37.
- Breitbart EW, Waldmann A, Nolte S, et al. Systematic skin cancer screening in Northern Germany. J Am Acad Dermatol. 2012;66:201-211.
- Janda M, Lowe JB, Elwood M, et al. Do centralised skin screening clinics increase participation in melanoma screening (Australia)? Cancer Causes Control. 2006;17:161-168.
- Aitken JF, Janda M, Elwood M, et al. Clinical outcomes from skin screening clinics within a community-based melanoma screening program. J Am Acad Dermatol. 2006;54:105-114.
- Eide MJ, Asgari MM, Fletcher SW, et al. Effects on skills and practice from a web-based skin cancer course for primary care providers. J Am Board Fam Med. 2013;26:648-657.
- Weinstock MA, Ferris LK, Saul MI, et al. Downstream consequences of melanoma screening in a community practice setting: first results. Cancer. 2016;122:3152-3156.
- Matthews NH, Risica PM, Ferris LK, et al. Psychosocial impact of skin biopsies in the setting of melanoma screening: a cross-sectional survey. Br J Dermatol. 2019;180:664-665.
- Risica PM, Matthews NH, Dionne L, et al. Psychosocial consequences of skin cancer screening. Prev Med Rep. 2018;10:310-316.
- Rogers HW, Weinstock MA, Feldman SR, et al. Incidence estimate of nonmelanoma skin cancer (keratinocyte carcinomas) in the U.S. population, 2012. JAMA Dermatol. 2015;151:1081-1086.
- Marzuka AG, Book SE. Basal cell carcinoma: pathogenesis, epidemiology, clinical features, diagnosis, histopathology, and management. Yale J Biol Med. 2015;88:167-179.
- Dourmishev LA, Rusinova D, Botev I. Clinical variants, stages, and management of basal cell carcinoma. Indian Dermatol Online J. 2013;4:12-17.
- Thompson AK, Kelley BF, Prokop LJ, et al. Risk factors for cutaneous squamous cell carcinoma outcomes: a systematic review and meta-analysis. JAMA Dermatol. 2016;152:419-428.
- Motaparthi K, Kapil JP, Velazquez EF. Cutaneous squamous cell carcinoma: review of the eighth edition of the American Joint Committee on Cancer Staging Guidelines, Prognostic Factors, and Histopathologic Variants. Adv Anat Pathol. 2017;24:171-194.
- Barton V, Armeson K, Hampras S, et al. Nonmelanoma skin cancer and risk of all-cause and cancer-related mortality: a systematic review. Arch Dermatol Res. 2017;309:243-251.
- Weinstock MA, Bogaars HA, Ashley M, et al. Nonmelanoma skin cancer mortality. a population-based study. Arch Dermatol. 1991;127:1194-1197.
- Matthews NH, Li W-Q, Qureshi AA, et al. Epidemiology of melanoma. In: Ward WH, Farma JM, eds. Cutaneous Melanoma: Etiology and Therapy. Codon Publications; 2017:3-22.
- Cakir BO, Adamson P, Cingi C. Epidemiology and economic burden of nonmelanoma skin cancer. Facial Plast Surg Clin North Am. 2012;20:419-422.
- Guy GP, Machlin SR, Ekwueme DU, et al. Prevalence and costs of skin cancer treatment in the U.S., 2002-2006 and 2007-2011. Am J Prev Med. 2015;48:183-187.
- Losina E, Walensky RP, Geller A, et al. Visual screening for malignant melanoma: a cost-effectiveness analysis. Arch Dermatol. 2007;143:21-28.
- Markova A, Weinstock MA, Risica P, et al. Effect of a web-based curriculum on primary care practice: basic skin cancer triage trial. Fam Med. 2013;45:558-568.
- Johnson MM, Leachman SA, Aspinwall LG, et al. Skin cancer screening: recommendations for data-driven screening guidelines and a review of the US Preventive Services Task Force controversy. Melanoma Manag. 2017;4:13-37.
- Agency for Healthcare Research and Quality. Screening for skin cancer in adults: an updated systematic evidence review for the U.S. Preventive Services Task Force. November 30, 2015. Accessed July 25, 2022. http://uspreventiveservicestaskforce.org/Page/Document/draft-evidence-review159/skin-cancer-screening2
- Wernli KJ, Henrikson NB, Morrison CC, et al. Screening for skin cancer in adults: updated evidence report and systematic review forthe US Preventive Services Task Force. JAMA. 2016;316:436-447.
- LeBlanc WG, Vidal L, Kirsner RS, et al. Reported skin cancer screening of US adult workers. J Am Acad Dermatol. 2008;59:55-63.
- Federman DG, Concato J, Caralis PV, et al. Screening for skin cancer in primary care settings. Arch Dermatol. 1997;133:1423-1425.
- Kirsner RS, Muhkerjee S, Federman DG. Skin cancer screening in primary care: prevalence and barriers. J Am Acad Dermatol. 1999;41:564-566.
- Federman DG, Kravetz JD, Tobin DG, et al. Full-body skin examinations: the patient’s perspective. Arch Dermatol. 2004;140:530-534.
- IBM. IBM SPSS Statistics for Windows. IBM Corp; 2015.
- Moore MM, Geller AC, Zhang Z, et al. Skin cancer examination teaching in US medical education. Arch Dermatol. 2006;142:439-444.
- Wise E, Singh D, Moore M, et al. Rates of skin cancer screening and prevention counseling by US medical residents. Arch Dermatol. 2009;145:1131-1136.
- Lakhani NA, Saraiya M, Thompson TD, et al. Total body skin examination for skin cancer screening among U.S. adults from 2000 to 2010. Prev Med. 2014;61:75-80.
- Coups EJ, Geller AC, Weinstock MA, et al. Prevalence and correlates of skin cancer screening among middle-aged and older white adults in the United States. Am J Med. 2010;123:439-445.
- American Cancer Society. Cancer facts & figures 2016. Accessed March 13, 2022. https://cancer.org/research/cancerfactsstatistics/cancerfactsfigures2016/
- American Academy of Dermatology. Skin cancer incidence rates. Updated April 22, 2022. Accessed August 1, 2022. https://www.aad.org/media/stats-skin-cancer
- Skin Cancer Foundation. Skin cancer prevention. Accessed July 25, 2022. http://skincancer.org/prevention/sun-protection/prevention-guidelines
- Katalinic A, Eisemann N, Waldmann A. Skin cancer screening in Germany. documenting melanoma incidence and mortality from 2008 to 2013. Dtsch Arztebl Int. 2015;112:629-634.
- Cancer Council Australia. Position statement: screening and early detection of skin cancer. Published July 2014. Accessed July 25, 2022. https://dermcoll.edu.au/wp-content/uploads/2014/05/PosStatEarlyDetectSkinCa.pdf
- Royal Australian College of General Practitioners. Guidelines for Preventive Activities in General Practice. 9th ed. The Royal Australian College of General Practitioners; 2016. Accessed July 27, 2022. https://www.racgp.org.au/download/Documents/Guidelines/Redbook9/17048-Red-Book-9th-Edition.pdf
- Cancer Council Australia and Australian Cancer Network and New Zealand Guidelines Group. Clinical Practice Guidelines for the Management of Melanoma in Australia and New Zealand. The Cancer Council Australia and Australian Cancer Network, Sydney and New Zealand Guidelines Group, Wellington; 2008. Accessed July 27, 2022. https://www.health.govt.nz/system/files/documents/publications/melanoma-guideline-nov08-v2.pdf
- Swetter SM, Pollitt RA, Johnson TM, et al. Behavioral determinants of successful early melanoma detection: role of self and physician skin examination. Cancer. 2012;118:3725-3734.
- Terushkin V, Halpern AC. Melanoma early detection. Hematol Oncol Clin North Am. 2009;23:481-500, viii.
- Aitken JF, Elwood M, Baade PD, et al. Clinical whole-body skin examination reduces the incidence of thick melanomas. Int J Cancer. 2010;126:450-458.
- Aitken JF, Elwood JM, Lowe JB, et al. A randomised trial of population screening for melanoma. J Med Screen. 2002;9:33-37.
- Breitbart EW, Waldmann A, Nolte S, et al. Systematic skin cancer screening in Northern Germany. J Am Acad Dermatol. 2012;66:201-211.
- Janda M, Lowe JB, Elwood M, et al. Do centralised skin screening clinics increase participation in melanoma screening (Australia)? Cancer Causes Control. 2006;17:161-168.
- Aitken JF, Janda M, Elwood M, et al. Clinical outcomes from skin screening clinics within a community-based melanoma screening program. J Am Acad Dermatol. 2006;54:105-114.
- Eide MJ, Asgari MM, Fletcher SW, et al. Effects on skills and practice from a web-based skin cancer course for primary care providers. J Am Board Fam Med. 2013;26:648-657.
- Weinstock MA, Ferris LK, Saul MI, et al. Downstream consequences of melanoma screening in a community practice setting: first results. Cancer. 2016;122:3152-3156.
- Matthews NH, Risica PM, Ferris LK, et al. Psychosocial impact of skin biopsies in the setting of melanoma screening: a cross-sectional survey. Br J Dermatol. 2019;180:664-665.
- Risica PM, Matthews NH, Dionne L, et al. Psychosocial consequences of skin cancer screening. Prev Med Rep. 2018;10:310-316.
PRACTICE POINTS
- Dermatologists should be aware of the variability in practice and execution of full-body skin examinations (FBSEs) among primary care providers and offer comprehensive examinations for every patient.
- Variability in reporting and execution of FBSEs may impact the continued US Preventive Services Task Force I rating in their guidelines and promotion of skin cancer screening in the primary care setting.
Combatting Climate Change: 10 Interventions for Dermatologists to Consider for Sustainability
The impacts of anthropogenic climate change on human health are numerous and growing. The evidence that climate change is occurring due to the burning of fossil fuels is substantial, with a 2019 report elevating the data supporting anthropogenic climate change to a gold standard 5-sigma level of significance.1 In the peer-reviewed scientific literature, the consensus that humans are causing climate change is greater than 99%.2 Both the American Medical Association and the American College of Physicians have acknowledged the health impacts of climate change and importance for action. They encourage physicians to engage in environmentally sustainable practices and to advocate for effective climate change mitigation strategies.3,4 A survey of dermatologists also found that 99.3% (n=148) recognize climate change is occurring, and similarly high numbers are concerned about its health impacts.5
Notably, the health care industry must grapple not only with the health impacts of climate change but with the fact that the health care sector itself is responsible for a large amount of carbon emissions.6 The global health care industry as a whole produces enough carbon emissions to be ranked as the fifth largest emitting nation in the world.7 A quarter of these emissions are attributed to the US health care system.8,9 Climate science has shown we must limit CO2 emissions to avoid catastrophic climate change, with the sixth assessment report of the United Nations’ Intergovernmental Panel on Climate Change and the Paris Agreement targeting large emission reductions within the next decade.10 In August 2021, the US Department of Health and Human Services created the Office of Climate Change and Health Equity. Assistant Secretary for Health ADM Rachel L. Levine, MD, has committed to reducing the carbon emissions from the health care sector by 25% in the next decade, in line with scientific consensus regarding necessary changes.11
The dermatologic impacts of climate change are myriad. Rising temperatures, increasing air and water pollution, and stratospheric ozone depletion will lead to expanded geographic ranges of vector-borne diseases, worsening of chronic skin conditions such as atopic dermatitis/eczema and pemphigus, and increasing rates of skin cancer.12 For instance, warmer temperatures have allowed mosquitoes of the Aedes genus to infest new areas, leading to outbreaks of viral illnesses with cutaneous manifestations such as dengue, chikungunya, and Zika virus in previously nonindigenous regions.13 Rising temperatures also have been associated with an expanding geographic range of tick- and sandfly-borne illnesses such as Lyme disease, Rocky Mountain spotted fever, and cutaneous leishmaniasis.13,14 Additionally, short-term exposure to air pollution from wildfire smoke has been associated with an increased use of health care services by patients with atopic dermatitis.15 Increased levels of air pollutants also have been found to be associated with psoriasis flares as well as hyperpigmentation and wrinkle formation.16,17 Skin cancer incidence is predicted to rise due to increased UV radiation exposure secondary to stratospheric ozone depletion.18
Although the effects of climate change are significant and the magnitude of the climate crisis may feel overwhelming, it is essential to avoid doomerism and focus on meaningful impactful actions. Current CO2 emissions will remain in the atmosphere for hundreds to thousands of years, and the choices we make now commit future generations to live in a world shaped by our decisions. Importantly, there are impactful and low-cost, cost-effective, or cost-saving changes that can be made to mitigate the climate crisis. Herein, we provide 10 practical actionable interventions for dermatologists to help combat climate change.
10 Interventions for Dermatologists to Combat Climate Change
1. Consider switching to renewable sources of energy. Making this switch often is the most impactful decision a dermatologist can make to address climate change. The electricity sector is the largest source of greenhouse gas emissions in the US health care system, and dermatology outpatient practices in particular have been observed to have a higher peak energy consumption than most other specialties studied.19,20 Many dermatology practices—both privately owned and academic—can switch to renewable energy seamlessly through power purchase agreements (PPAs), which are contracts between power providers and private entities to install renewable energy equipment or source renewable energy from offsite sources at a fixed rate. Using PPAs instead of traditional fossil fuel energy can provide cost savings as well as protect buyers from electrical price volatility. Numerous health care systems utilize PPAs such as Kaiser Permanente, Cleveland Clinic, and Rochester Regional Health. Additionally, dermatologists can directly purchase renewable energy equipment and eventually receive a return on investment from substantially lowered electric bills. It is important to note that the cost of commercial solar energy systems has decreased 69% since 2010 with further cost reductions predicted.21,22
2. Reduce standby power consumption. This refers to the use of electricity by a device when it appears to be off or is not in use, which can lead to considerable energy consumption and subsequently a larger carbon footprint for your practice. Ensuring electronics such as phone chargers, light fixtures, television screens, and computers are switched off prior to the end of the workday can make a large difference; for instance, a single radiology department at the University of Maryland (College Park, Maryland) found that if clinical workstations were shut down when not in use after an 8-hour workday, it would save 83,866 kWh of energy and $9225.33 per year.23 Additionally, using power strips with an automatic shutoff feature to shut off power to devices not in use provides a more convenient way to reduce standby power.
3. Optimize thermostat settings. An analysis of energy consumption in 157,000 US health care facilities found that space heating and cooling accounted for 40% of their total energy consumption.24 Thus, ensuring your thermostat and heating/cooling systems are working efficiently can conserve a substantial amount of energy. For maximum efficiency, it is recommended to set air conditioners to 74 °F (24 °C) and heaters to 68 °F (20 °C) or employ smart thermostats to optimally adjust temperatures when the office is not in use.25 In addition, routinely replacing or cleaning air conditioner filters can lower energy consumption by 5% to 15%.26 Similarly, improving insulation and ruggedization of both homes and offices may reduce heating and cooling waste and limit costs and emissions as a result.
4. Offer bicycle racks and charging ports for electric vehicles. In the United States, transportation generates more greenhouse gas emissions than any other source, primarily due to the burning of fossil fuels to power automobiles, trains, and planes. Because bicycles do not consume any fossil fuels and the use of electric vehicles has been found to result in substantial air pollution health benefits, encouraging the use of both can make a considerable positive impact on our climate.27 Providing these resources not only allows those who already travel sustainably to continue to do so but also serves as a reminder to your patients that sustainability is important to you as their health care provider. As electric vehicle sales continue to climb, infrastructure to support their use, including charging stations, will grow in importance. A physician’s office that offers a car-charging station may soon have a competitive advantage over others in the area.
5. Ensure properly regulated medical waste management. Regulated medical waste (also known as infectious medical waste or red bag waste) refers to health care–generated waste unsuitable for disposal in municipal solid waste systems due to concern for the spread of infectious or pathogenic materials. This waste largely is disposed via incineration, which harms the environment in a multitude of ways—both through harmful byproducts and from the CO2 emissions required to ship the waste to special processing facilities.28 Incineration of regulated medical waste emits potent toxins such as dioxins and furans as well as particulate matter, which contribute to air pollution. Ensuring only materials with infectious potential (as defined by each state’s Environmental Protection Agency) are disposed in regulated medical waste containers can dramatically reduce the harmful effects of incineration. Additionally, limiting regulated medical waste can be very cost-effective, as its disposal is 5- to 10-times more expensive than that of unregulated medical waste.29 Simple nudge measures such as educating staff about what waste goes in which receptacle, placing signage over the red bag waste to prompt staff to pause to consider if use of that bin is required before utilizing, using weights or clasps to make opening red bag waste containers slightly harder, and positioning different trash receptacles in different parts of examination rooms may help reduce inappropriate use of red bag waste.
6. Consider virtual platforms when possible. Due to the COVID-19 pandemic, virtual meeting platforms saw a considerable increase in usage by dermatologists. Teledermatology for patient care became much more widely adopted, and traditionally in-person meetings turned virtual.30 The reduction in emissions from these changes was remarkable. A recent study looking at the environmental impact of 3 months of teledermatology visits early during the COVID-19 pandemic found that 1476 teledermatology appointments saved 55,737 miles of car travel, equivalent to 15.37 metric tons of CO2.31 Whether for patient care when appropriate, academic conferences and continuing medical education credit, or for interviews (eg, medical students, residents, other staff), use of virtual platforms can reduce unnecessary travel and therefore substantially reduce travel-related emissions. When travel is unavoidable, consider exploring validated vetted companies that offer carbon offsets to reduce the harmful environmental impact of high-emission flights.
7. Limit use of single-use disposable items. Although single-use items such as examination gloves or needles are necessary in a dermatology practice, there are many opportunities to incorporate reusable items in your workplace. For instance, you can replace plastic cutlery and single-use plates in kitchen or dining areas with reusable alternatives. Additionally, using reusable isolation gowns instead of their single-use counterparts can help reduce waste; a reusable isolation gown system for providers including laundering services was found to consume 28% less energy and emit 30% fewer greenhouse gases than a single-use isolation gown system.32 Similarly, opting for reusable instruments instead of single-use instruments when possible also can help reduce your practice’s carbon footprint. Carefully evaluating each part of your “dermatology visit supply chain” may offer opportunities to utilize additional cost-saving, environmentally friendly options; for example, an individually plastic-wrapped Dermablade vs a bulk-packaged blade for shave biopsies has a higher cost and worse environmental impact. A single gauze often is sufficient for shave biopsies, but many practices open a plastic container of bulk gauze, much of which results in waste that too often is inappropriately disposed of as regulated medical waste despite not being saturated in blood/body fluids.
8. Educate on the effects of climate change. Dermatologists and other physicians have the unique opportunity to teach members of their community every day through patient care. Physicians are trusted messengers, and appropriately counseling patients regarding the risks of climate change and its effects on their dermatologic health is in line with both American Medical Association and American College of Physicians guidelines.3,4 For instance, patients with Lyme disease in Canada or Maine were unheard of a few decades ago, but now they are common; flares of atopic dermatitis in regions adjacent to recent wildfires may be attributable to harmful particulate matter resulting from fossil-fueled climate change and record droughts. Educating medical trainees on the impacts of climate change is just as vital, as it is a topic that often is neglected in medical school and residency curricula.33
9. Install water-efficient toilets and faucets. Anthropogenic climate change has been shown to increase the duration and intensity of droughts throughout the world.34 Much of the western United States also is experiencing record droughts. One way in which dermatology practices can work to combat droughts is through the use of water-conserving toilets, faucets, and urinals. Using water fixtures with the US Environmental Protection Agency’s WaterSense label is a convenient way to do so. The WaterSense label helps identify water fixtures certified to use at least 20% less water as well as save energy and decrease water costs.
10. Advocate through local and national organizations. There are numerous ways in which dermatologists can advocate for action against climate change. Joining professional organizations focused on addressing the climate crisis can help you connect with fellow dermatologists and physicians. The Expert Resource Group on Climate Change and Environmental Issues affiliated with the American Academy of Dermatology (AAD) is one such organization with many opportunities to raise awareness within the field of dermatology. The AAD recently joined the Medical Society Consortium on Climate and Health, an organization providing opportunities for policy and media outreach as well as research on climate change. Advocacy also can mean joining your local chapter of Physicians for Social Responsibility or encouraging divestment from fossil fuel companies within your institution. Voicing support for climate change–focused lectures at events such as grand rounds and society meetings at the local, regional, and state-wide levels can help raise awareness. As the dermatologic effects of climate change grow, being knowledgeable of the views of future leaders in our specialty and country on this issue will become increasingly important.
Final Thoughts
In addition to the climate-friendly decisions one can make as a dermatologist, there are many personal lifestyle choices to consider. Small dietary changes such as limiting consumption of beef and minimizing food waste can have large downstream effects. Opting for transportation via train and limiting air travel are both impactful decisions in reducing CO2 emissions. Similarly, switching to an electric vehicle or vehicle with minimal emissions can work to reduce greenhouse gas accumulation. For additional resources, note the AAD has partnered with My Green Doctor, a nonprofit service for health care practices that includes practical cost-saving suggestions to support sustainability in physician practices.
A recent joint publication in more than 200 medical journals described climate change as the greatest threat to global public health.35 Climate change is having devastating effects on dermatologic health and will only continue to do so if not addressed now. Dermatologists have the opportunity to join with our colleagues in the house of medicine and to take action to fight climate change and mitigate the health impacts on our patients, the population, and future generations.
- Santer BD, Bonfils CJW, Fu Q, et al. Celebrating the anniversary of three key events in climate change science. Nat Clim Chang. 2019;9:180-182.
- Lynas M, Houlton BZ, Perry S. Greater than 99% consensus on human caused climate change in the peer-reviewed scientific literature. Environ Res Lett. 2021;16:114005.
- Crowley RA; Health and Public Policy Committee of the American College of Physicians. Climate change and health: a position paper of the American College of Physicians [published online April 19, 2016]. Ann Intern Med. 2016;164:608-610. doi:10.7326/M15-2766
- Global climate change and human health H-135.398. American Medical Association website. Updated 2019. Accessed July 13, 2022. https://policysearch.ama-assn.org/policyfinder/detail/climate%20change?uri=%2FAMADoc%2FHOD.xml-0-309.xml
- Mieczkowska K, Stringer T, Barbieri JS, et al. Surveying the attitudes of dermatologists regarding climate change. Br J Dermatol. 2022;186:748-750.
- Eckelman MJ, Sherman J. Environmental impacts of the U.S. health care system and effects on public health. PLoS One. 2016;11:e0157014. doi:10.1371/journal.pone.0157014
- Karliner J, Slotterback S, Boyd R, et al. Health care’s climate footprint: how the health sector contributes to the global climate crisis and opportunities for action. Health Care Without Harm website. Published September 2019. Accessed July 13, 2022. https://noharm-global.org/sites/default/files/documents-files/5961/HealthCaresClimateFootprint_090619.pdf
- Pichler PP, Jaccard IS, Weisz U, et al. International comparison of health care carbon footprints. Environ Res Lett. 2019;14:064004.
- Solomon CG, LaRocque RC. Climate change—a health emergency. N Engl J Med. 2019;380:209-211. doi:10.1056/NEJMp1817067
- IPCC, 2021: Summary for Policymakers. In: Masson-Delmotte V, Zhai P, Pirani A, et al, eds. Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press; 2021:3-32.
- Dzau VJ, Levine R, Barrett G, et al. Decarbonizing the U.S. Health Sector—a call to action [published online October 13, 2021]. N Engl J Med. 2021;385:2117-2119. doi:10.1056/NEJMp2115675
- Silva GS, Rosenbach M. Climate change and dermatology: an introduction to a special topic, for this special issue. Int J Womens Dermatol 2021;7:3-7.
- Coates SJ, Norton SA. The effects of climate change on infectious diseases with cutaneous manifestations. Int J Womens Dermatol. 2021;7:8-16. doi:10.1016/j.ijwd.2020.07.005
- Andersen LK, Davis MD. Climate change and the epidemiology of selected tick-borne and mosquito-borne diseases: update from the International Society of Dermatology Climate Change Task Force [published online October 1, 2016]. Int J Dermatol. 2017;56:252-259. doi:10.1111/ijd.13438
- Fadadu RP, Grimes B, Jewell NP, et al. Association of wildfire air pollution and health care use for atopic dermatitis and itch. JAMA Dermatol. 2021;157:658-666. doi:10.1001/jamadermatol.2021.0179
- Bellinato F, Adami G, Vaienti S, et al. Association between short-term exposure to environmental air pollution and psoriasis flare. JAMA Dermatol. 2022;158:375-381. doi:10.1001/jamadermatol.2021.6019
- Krutmann J, Bouloc A, Sore G, et al. The skin aging exposome [published online September 28, 2016]. J Dermatol Sci. 2017;85:152-161.
- Parker ER. The influence of climate change on skin cancer incidence—a review of the evidence. Int J Womens Dermatol. 2020;7:17-27. doi:10.1016/j.ijwd.2020.07.003
- Eckelman MJ, Huang K, Lagasse R, et al. Health care pollution and public health damage in the United States: an update. Health Aff (Millwood). 2020;39:2071-2079.
- Sheppy M, Pless S, Kung F. Healthcare energy end-use monitoring. US Department of Energy website. Published August 2014. Accessed July 13, 2022. https://www.energy.gov/sites/prod/files/2014/09/f18/61064.pdf
- Feldman D, Ramasamy V, Fu R, et al. U.S. solar photovoltaic system and energy storage cost benchmark: Q1 2020. Published January 2021. Accessed July 7, 2022. https://www.nrel.gov/docs/fy21osti/77324.pdf
- 22. Apostoleris H, Sgouridis S, Stefancich M, et al. Utility solar prices will continue to drop all over the world even without subsidies. Nat Energy. 2019;4:833-834.
- Prasanna PM, Siegel E, Kunce A. Greening radiology. J Am Coll Radiol. 2011;8:780-784. doi:10.1016/j.jacr.2011.07.017
- Bawaneh K, Nezami FG, Rasheduzzaman MD, et al. Energy consumption analysis and characterization of healthcare facilities in the United States. Energies. 2019;12:1-20. doi:10.3390/en12193775
- Blum S, Buckland M, Sack TL, et al. Greening the office: saving resources, saving money, and educating our patients [published online July 4, 2020]. Int J Womens Dermatol. 2020;7:112-116.
- Maintaining your air conditioner. US Department of Energy website. Accessed July 13, 2022. https://www.energy.gov/energysaver/maintaining-your-air-conditioner
- Choma EF, Evans JS, Hammitt JK, et al. Assessing the health impacts of electric vehicles through air pollution in the United States [published online August 25, 2020]. Environ Int. 2020;144:106015.
- Windfeld ES, Brooks MS. Medical waste management—a review [published online August 22, 2015]. J Environ Manage. 2015;1;163:98-108. doi:10.1016/j.jenvman.2015.08.013
- Fathy R, Nelson CA, Barbieri JS. Combating climate change in the clinic: cost-effective strategies to decrease the carbon footprint of outpatient dermatologic practice. Int J Womens Dermatol. 2020;7:107-111.
- Pulsipher KJ, Presley CL, Rundle CW, et al. Teledermatology application use in the COVID-19 era. Dermatol Online J. 2020;26:13030/qt1fs0m0tp.
- O’Connell G, O’Connor C, Murphy M. Every cloud has a silver lining: the environmental benefit of teledermatology during the COVID-19 pandemic [published online July 9, 2021]. Clin Exp Dermatol. 2021;46:1589-1590. doi:10.1111/ced.14795
- Vozzola E, Overcash M, Griffing E. Environmental considerations in the selection of isolation gowns: a life cycle assessment of reusable and disposable alternatives [published online April 11, 2018]. Am J Infect Control. 2018;46:881-886. doi:10.1016/j.ajic.2018.02.002
- Rabin BM, Laney EB, Philipsborn RP. The unique role of medical students in catalyzing climate change education [published online October 14, 2020]. J Med Educ Curric Dev. doi:10.1177/2382120520957653
- Chiang F, Mazdiyasni O, AghaKouchak A. Evidence of anthropogenic impacts on global drought frequency, duration, and intensity [published online May 12, 2021]. Nat Commun. 2021;12:2754. doi:10.1038/s41467-021-22314-w
- Atwoli L, Baqui AH, Benfield T, et al. Call for emergency action to limit global temperature increases, restore biodiversity, and protect health [published online September 5, 2021]. N Engl J Med. 2021;385:1134-1137. doi:10.1056/NEJMe2113200
The impacts of anthropogenic climate change on human health are numerous and growing. The evidence that climate change is occurring due to the burning of fossil fuels is substantial, with a 2019 report elevating the data supporting anthropogenic climate change to a gold standard 5-sigma level of significance.1 In the peer-reviewed scientific literature, the consensus that humans are causing climate change is greater than 99%.2 Both the American Medical Association and the American College of Physicians have acknowledged the health impacts of climate change and importance for action. They encourage physicians to engage in environmentally sustainable practices and to advocate for effective climate change mitigation strategies.3,4 A survey of dermatologists also found that 99.3% (n=148) recognize climate change is occurring, and similarly high numbers are concerned about its health impacts.5
Notably, the health care industry must grapple not only with the health impacts of climate change but with the fact that the health care sector itself is responsible for a large amount of carbon emissions.6 The global health care industry as a whole produces enough carbon emissions to be ranked as the fifth largest emitting nation in the world.7 A quarter of these emissions are attributed to the US health care system.8,9 Climate science has shown we must limit CO2 emissions to avoid catastrophic climate change, with the sixth assessment report of the United Nations’ Intergovernmental Panel on Climate Change and the Paris Agreement targeting large emission reductions within the next decade.10 In August 2021, the US Department of Health and Human Services created the Office of Climate Change and Health Equity. Assistant Secretary for Health ADM Rachel L. Levine, MD, has committed to reducing the carbon emissions from the health care sector by 25% in the next decade, in line with scientific consensus regarding necessary changes.11
The dermatologic impacts of climate change are myriad. Rising temperatures, increasing air and water pollution, and stratospheric ozone depletion will lead to expanded geographic ranges of vector-borne diseases, worsening of chronic skin conditions such as atopic dermatitis/eczema and pemphigus, and increasing rates of skin cancer.12 For instance, warmer temperatures have allowed mosquitoes of the Aedes genus to infest new areas, leading to outbreaks of viral illnesses with cutaneous manifestations such as dengue, chikungunya, and Zika virus in previously nonindigenous regions.13 Rising temperatures also have been associated with an expanding geographic range of tick- and sandfly-borne illnesses such as Lyme disease, Rocky Mountain spotted fever, and cutaneous leishmaniasis.13,14 Additionally, short-term exposure to air pollution from wildfire smoke has been associated with an increased use of health care services by patients with atopic dermatitis.15 Increased levels of air pollutants also have been found to be associated with psoriasis flares as well as hyperpigmentation and wrinkle formation.16,17 Skin cancer incidence is predicted to rise due to increased UV radiation exposure secondary to stratospheric ozone depletion.18
Although the effects of climate change are significant and the magnitude of the climate crisis may feel overwhelming, it is essential to avoid doomerism and focus on meaningful impactful actions. Current CO2 emissions will remain in the atmosphere for hundreds to thousands of years, and the choices we make now commit future generations to live in a world shaped by our decisions. Importantly, there are impactful and low-cost, cost-effective, or cost-saving changes that can be made to mitigate the climate crisis. Herein, we provide 10 practical actionable interventions for dermatologists to help combat climate change.
10 Interventions for Dermatologists to Combat Climate Change
1. Consider switching to renewable sources of energy. Making this switch often is the most impactful decision a dermatologist can make to address climate change. The electricity sector is the largest source of greenhouse gas emissions in the US health care system, and dermatology outpatient practices in particular have been observed to have a higher peak energy consumption than most other specialties studied.19,20 Many dermatology practices—both privately owned and academic—can switch to renewable energy seamlessly through power purchase agreements (PPAs), which are contracts between power providers and private entities to install renewable energy equipment or source renewable energy from offsite sources at a fixed rate. Using PPAs instead of traditional fossil fuel energy can provide cost savings as well as protect buyers from electrical price volatility. Numerous health care systems utilize PPAs such as Kaiser Permanente, Cleveland Clinic, and Rochester Regional Health. Additionally, dermatologists can directly purchase renewable energy equipment and eventually receive a return on investment from substantially lowered electric bills. It is important to note that the cost of commercial solar energy systems has decreased 69% since 2010 with further cost reductions predicted.21,22
2. Reduce standby power consumption. This refers to the use of electricity by a device when it appears to be off or is not in use, which can lead to considerable energy consumption and subsequently a larger carbon footprint for your practice. Ensuring electronics such as phone chargers, light fixtures, television screens, and computers are switched off prior to the end of the workday can make a large difference; for instance, a single radiology department at the University of Maryland (College Park, Maryland) found that if clinical workstations were shut down when not in use after an 8-hour workday, it would save 83,866 kWh of energy and $9225.33 per year.23 Additionally, using power strips with an automatic shutoff feature to shut off power to devices not in use provides a more convenient way to reduce standby power.
3. Optimize thermostat settings. An analysis of energy consumption in 157,000 US health care facilities found that space heating and cooling accounted for 40% of their total energy consumption.24 Thus, ensuring your thermostat and heating/cooling systems are working efficiently can conserve a substantial amount of energy. For maximum efficiency, it is recommended to set air conditioners to 74 °F (24 °C) and heaters to 68 °F (20 °C) or employ smart thermostats to optimally adjust temperatures when the office is not in use.25 In addition, routinely replacing or cleaning air conditioner filters can lower energy consumption by 5% to 15%.26 Similarly, improving insulation and ruggedization of both homes and offices may reduce heating and cooling waste and limit costs and emissions as a result.
4. Offer bicycle racks and charging ports for electric vehicles. In the United States, transportation generates more greenhouse gas emissions than any other source, primarily due to the burning of fossil fuels to power automobiles, trains, and planes. Because bicycles do not consume any fossil fuels and the use of electric vehicles has been found to result in substantial air pollution health benefits, encouraging the use of both can make a considerable positive impact on our climate.27 Providing these resources not only allows those who already travel sustainably to continue to do so but also serves as a reminder to your patients that sustainability is important to you as their health care provider. As electric vehicle sales continue to climb, infrastructure to support their use, including charging stations, will grow in importance. A physician’s office that offers a car-charging station may soon have a competitive advantage over others in the area.
5. Ensure properly regulated medical waste management. Regulated medical waste (also known as infectious medical waste or red bag waste) refers to health care–generated waste unsuitable for disposal in municipal solid waste systems due to concern for the spread of infectious or pathogenic materials. This waste largely is disposed via incineration, which harms the environment in a multitude of ways—both through harmful byproducts and from the CO2 emissions required to ship the waste to special processing facilities.28 Incineration of regulated medical waste emits potent toxins such as dioxins and furans as well as particulate matter, which contribute to air pollution. Ensuring only materials with infectious potential (as defined by each state’s Environmental Protection Agency) are disposed in regulated medical waste containers can dramatically reduce the harmful effects of incineration. Additionally, limiting regulated medical waste can be very cost-effective, as its disposal is 5- to 10-times more expensive than that of unregulated medical waste.29 Simple nudge measures such as educating staff about what waste goes in which receptacle, placing signage over the red bag waste to prompt staff to pause to consider if use of that bin is required before utilizing, using weights or clasps to make opening red bag waste containers slightly harder, and positioning different trash receptacles in different parts of examination rooms may help reduce inappropriate use of red bag waste.
6. Consider virtual platforms when possible. Due to the COVID-19 pandemic, virtual meeting platforms saw a considerable increase in usage by dermatologists. Teledermatology for patient care became much more widely adopted, and traditionally in-person meetings turned virtual.30 The reduction in emissions from these changes was remarkable. A recent study looking at the environmental impact of 3 months of teledermatology visits early during the COVID-19 pandemic found that 1476 teledermatology appointments saved 55,737 miles of car travel, equivalent to 15.37 metric tons of CO2.31 Whether for patient care when appropriate, academic conferences and continuing medical education credit, or for interviews (eg, medical students, residents, other staff), use of virtual platforms can reduce unnecessary travel and therefore substantially reduce travel-related emissions. When travel is unavoidable, consider exploring validated vetted companies that offer carbon offsets to reduce the harmful environmental impact of high-emission flights.
7. Limit use of single-use disposable items. Although single-use items such as examination gloves or needles are necessary in a dermatology practice, there are many opportunities to incorporate reusable items in your workplace. For instance, you can replace plastic cutlery and single-use plates in kitchen or dining areas with reusable alternatives. Additionally, using reusable isolation gowns instead of their single-use counterparts can help reduce waste; a reusable isolation gown system for providers including laundering services was found to consume 28% less energy and emit 30% fewer greenhouse gases than a single-use isolation gown system.32 Similarly, opting for reusable instruments instead of single-use instruments when possible also can help reduce your practice’s carbon footprint. Carefully evaluating each part of your “dermatology visit supply chain” may offer opportunities to utilize additional cost-saving, environmentally friendly options; for example, an individually plastic-wrapped Dermablade vs a bulk-packaged blade for shave biopsies has a higher cost and worse environmental impact. A single gauze often is sufficient for shave biopsies, but many practices open a plastic container of bulk gauze, much of which results in waste that too often is inappropriately disposed of as regulated medical waste despite not being saturated in blood/body fluids.
8. Educate on the effects of climate change. Dermatologists and other physicians have the unique opportunity to teach members of their community every day through patient care. Physicians are trusted messengers, and appropriately counseling patients regarding the risks of climate change and its effects on their dermatologic health is in line with both American Medical Association and American College of Physicians guidelines.3,4 For instance, patients with Lyme disease in Canada or Maine were unheard of a few decades ago, but now they are common; flares of atopic dermatitis in regions adjacent to recent wildfires may be attributable to harmful particulate matter resulting from fossil-fueled climate change and record droughts. Educating medical trainees on the impacts of climate change is just as vital, as it is a topic that often is neglected in medical school and residency curricula.33
9. Install water-efficient toilets and faucets. Anthropogenic climate change has been shown to increase the duration and intensity of droughts throughout the world.34 Much of the western United States also is experiencing record droughts. One way in which dermatology practices can work to combat droughts is through the use of water-conserving toilets, faucets, and urinals. Using water fixtures with the US Environmental Protection Agency’s WaterSense label is a convenient way to do so. The WaterSense label helps identify water fixtures certified to use at least 20% less water as well as save energy and decrease water costs.
10. Advocate through local and national organizations. There are numerous ways in which dermatologists can advocate for action against climate change. Joining professional organizations focused on addressing the climate crisis can help you connect with fellow dermatologists and physicians. The Expert Resource Group on Climate Change and Environmental Issues affiliated with the American Academy of Dermatology (AAD) is one such organization with many opportunities to raise awareness within the field of dermatology. The AAD recently joined the Medical Society Consortium on Climate and Health, an organization providing opportunities for policy and media outreach as well as research on climate change. Advocacy also can mean joining your local chapter of Physicians for Social Responsibility or encouraging divestment from fossil fuel companies within your institution. Voicing support for climate change–focused lectures at events such as grand rounds and society meetings at the local, regional, and state-wide levels can help raise awareness. As the dermatologic effects of climate change grow, being knowledgeable of the views of future leaders in our specialty and country on this issue will become increasingly important.
Final Thoughts
In addition to the climate-friendly decisions one can make as a dermatologist, there are many personal lifestyle choices to consider. Small dietary changes such as limiting consumption of beef and minimizing food waste can have large downstream effects. Opting for transportation via train and limiting air travel are both impactful decisions in reducing CO2 emissions. Similarly, switching to an electric vehicle or vehicle with minimal emissions can work to reduce greenhouse gas accumulation. For additional resources, note the AAD has partnered with My Green Doctor, a nonprofit service for health care practices that includes practical cost-saving suggestions to support sustainability in physician practices.
A recent joint publication in more than 200 medical journals described climate change as the greatest threat to global public health.35 Climate change is having devastating effects on dermatologic health and will only continue to do so if not addressed now. Dermatologists have the opportunity to join with our colleagues in the house of medicine and to take action to fight climate change and mitigate the health impacts on our patients, the population, and future generations.
The impacts of anthropogenic climate change on human health are numerous and growing. The evidence that climate change is occurring due to the burning of fossil fuels is substantial, with a 2019 report elevating the data supporting anthropogenic climate change to a gold standard 5-sigma level of significance.1 In the peer-reviewed scientific literature, the consensus that humans are causing climate change is greater than 99%.2 Both the American Medical Association and the American College of Physicians have acknowledged the health impacts of climate change and importance for action. They encourage physicians to engage in environmentally sustainable practices and to advocate for effective climate change mitigation strategies.3,4 A survey of dermatologists also found that 99.3% (n=148) recognize climate change is occurring, and similarly high numbers are concerned about its health impacts.5
Notably, the health care industry must grapple not only with the health impacts of climate change but with the fact that the health care sector itself is responsible for a large amount of carbon emissions.6 The global health care industry as a whole produces enough carbon emissions to be ranked as the fifth largest emitting nation in the world.7 A quarter of these emissions are attributed to the US health care system.8,9 Climate science has shown we must limit CO2 emissions to avoid catastrophic climate change, with the sixth assessment report of the United Nations’ Intergovernmental Panel on Climate Change and the Paris Agreement targeting large emission reductions within the next decade.10 In August 2021, the US Department of Health and Human Services created the Office of Climate Change and Health Equity. Assistant Secretary for Health ADM Rachel L. Levine, MD, has committed to reducing the carbon emissions from the health care sector by 25% in the next decade, in line with scientific consensus regarding necessary changes.11
The dermatologic impacts of climate change are myriad. Rising temperatures, increasing air and water pollution, and stratospheric ozone depletion will lead to expanded geographic ranges of vector-borne diseases, worsening of chronic skin conditions such as atopic dermatitis/eczema and pemphigus, and increasing rates of skin cancer.12 For instance, warmer temperatures have allowed mosquitoes of the Aedes genus to infest new areas, leading to outbreaks of viral illnesses with cutaneous manifestations such as dengue, chikungunya, and Zika virus in previously nonindigenous regions.13 Rising temperatures also have been associated with an expanding geographic range of tick- and sandfly-borne illnesses such as Lyme disease, Rocky Mountain spotted fever, and cutaneous leishmaniasis.13,14 Additionally, short-term exposure to air pollution from wildfire smoke has been associated with an increased use of health care services by patients with atopic dermatitis.15 Increased levels of air pollutants also have been found to be associated with psoriasis flares as well as hyperpigmentation and wrinkle formation.16,17 Skin cancer incidence is predicted to rise due to increased UV radiation exposure secondary to stratospheric ozone depletion.18
Although the effects of climate change are significant and the magnitude of the climate crisis may feel overwhelming, it is essential to avoid doomerism and focus on meaningful impactful actions. Current CO2 emissions will remain in the atmosphere for hundreds to thousands of years, and the choices we make now commit future generations to live in a world shaped by our decisions. Importantly, there are impactful and low-cost, cost-effective, or cost-saving changes that can be made to mitigate the climate crisis. Herein, we provide 10 practical actionable interventions for dermatologists to help combat climate change.
10 Interventions for Dermatologists to Combat Climate Change
1. Consider switching to renewable sources of energy. Making this switch often is the most impactful decision a dermatologist can make to address climate change. The electricity sector is the largest source of greenhouse gas emissions in the US health care system, and dermatology outpatient practices in particular have been observed to have a higher peak energy consumption than most other specialties studied.19,20 Many dermatology practices—both privately owned and academic—can switch to renewable energy seamlessly through power purchase agreements (PPAs), which are contracts between power providers and private entities to install renewable energy equipment or source renewable energy from offsite sources at a fixed rate. Using PPAs instead of traditional fossil fuel energy can provide cost savings as well as protect buyers from electrical price volatility. Numerous health care systems utilize PPAs such as Kaiser Permanente, Cleveland Clinic, and Rochester Regional Health. Additionally, dermatologists can directly purchase renewable energy equipment and eventually receive a return on investment from substantially lowered electric bills. It is important to note that the cost of commercial solar energy systems has decreased 69% since 2010 with further cost reductions predicted.21,22
2. Reduce standby power consumption. This refers to the use of electricity by a device when it appears to be off or is not in use, which can lead to considerable energy consumption and subsequently a larger carbon footprint for your practice. Ensuring electronics such as phone chargers, light fixtures, television screens, and computers are switched off prior to the end of the workday can make a large difference; for instance, a single radiology department at the University of Maryland (College Park, Maryland) found that if clinical workstations were shut down when not in use after an 8-hour workday, it would save 83,866 kWh of energy and $9225.33 per year.23 Additionally, using power strips with an automatic shutoff feature to shut off power to devices not in use provides a more convenient way to reduce standby power.
3. Optimize thermostat settings. An analysis of energy consumption in 157,000 US health care facilities found that space heating and cooling accounted for 40% of their total energy consumption.24 Thus, ensuring your thermostat and heating/cooling systems are working efficiently can conserve a substantial amount of energy. For maximum efficiency, it is recommended to set air conditioners to 74 °F (24 °C) and heaters to 68 °F (20 °C) or employ smart thermostats to optimally adjust temperatures when the office is not in use.25 In addition, routinely replacing or cleaning air conditioner filters can lower energy consumption by 5% to 15%.26 Similarly, improving insulation and ruggedization of both homes and offices may reduce heating and cooling waste and limit costs and emissions as a result.
4. Offer bicycle racks and charging ports for electric vehicles. In the United States, transportation generates more greenhouse gas emissions than any other source, primarily due to the burning of fossil fuels to power automobiles, trains, and planes. Because bicycles do not consume any fossil fuels and the use of electric vehicles has been found to result in substantial air pollution health benefits, encouraging the use of both can make a considerable positive impact on our climate.27 Providing these resources not only allows those who already travel sustainably to continue to do so but also serves as a reminder to your patients that sustainability is important to you as their health care provider. As electric vehicle sales continue to climb, infrastructure to support their use, including charging stations, will grow in importance. A physician’s office that offers a car-charging station may soon have a competitive advantage over others in the area.
5. Ensure properly regulated medical waste management. Regulated medical waste (also known as infectious medical waste or red bag waste) refers to health care–generated waste unsuitable for disposal in municipal solid waste systems due to concern for the spread of infectious or pathogenic materials. This waste largely is disposed via incineration, which harms the environment in a multitude of ways—both through harmful byproducts and from the CO2 emissions required to ship the waste to special processing facilities.28 Incineration of regulated medical waste emits potent toxins such as dioxins and furans as well as particulate matter, which contribute to air pollution. Ensuring only materials with infectious potential (as defined by each state’s Environmental Protection Agency) are disposed in regulated medical waste containers can dramatically reduce the harmful effects of incineration. Additionally, limiting regulated medical waste can be very cost-effective, as its disposal is 5- to 10-times more expensive than that of unregulated medical waste.29 Simple nudge measures such as educating staff about what waste goes in which receptacle, placing signage over the red bag waste to prompt staff to pause to consider if use of that bin is required before utilizing, using weights or clasps to make opening red bag waste containers slightly harder, and positioning different trash receptacles in different parts of examination rooms may help reduce inappropriate use of red bag waste.
6. Consider virtual platforms when possible. Due to the COVID-19 pandemic, virtual meeting platforms saw a considerable increase in usage by dermatologists. Teledermatology for patient care became much more widely adopted, and traditionally in-person meetings turned virtual.30 The reduction in emissions from these changes was remarkable. A recent study looking at the environmental impact of 3 months of teledermatology visits early during the COVID-19 pandemic found that 1476 teledermatology appointments saved 55,737 miles of car travel, equivalent to 15.37 metric tons of CO2.31 Whether for patient care when appropriate, academic conferences and continuing medical education credit, or for interviews (eg, medical students, residents, other staff), use of virtual platforms can reduce unnecessary travel and therefore substantially reduce travel-related emissions. When travel is unavoidable, consider exploring validated vetted companies that offer carbon offsets to reduce the harmful environmental impact of high-emission flights.
7. Limit use of single-use disposable items. Although single-use items such as examination gloves or needles are necessary in a dermatology practice, there are many opportunities to incorporate reusable items in your workplace. For instance, you can replace plastic cutlery and single-use plates in kitchen or dining areas with reusable alternatives. Additionally, using reusable isolation gowns instead of their single-use counterparts can help reduce waste; a reusable isolation gown system for providers including laundering services was found to consume 28% less energy and emit 30% fewer greenhouse gases than a single-use isolation gown system.32 Similarly, opting for reusable instruments instead of single-use instruments when possible also can help reduce your practice’s carbon footprint. Carefully evaluating each part of your “dermatology visit supply chain” may offer opportunities to utilize additional cost-saving, environmentally friendly options; for example, an individually plastic-wrapped Dermablade vs a bulk-packaged blade for shave biopsies has a higher cost and worse environmental impact. A single gauze often is sufficient for shave biopsies, but many practices open a plastic container of bulk gauze, much of which results in waste that too often is inappropriately disposed of as regulated medical waste despite not being saturated in blood/body fluids.
8. Educate on the effects of climate change. Dermatologists and other physicians have the unique opportunity to teach members of their community every day through patient care. Physicians are trusted messengers, and appropriately counseling patients regarding the risks of climate change and its effects on their dermatologic health is in line with both American Medical Association and American College of Physicians guidelines.3,4 For instance, patients with Lyme disease in Canada or Maine were unheard of a few decades ago, but now they are common; flares of atopic dermatitis in regions adjacent to recent wildfires may be attributable to harmful particulate matter resulting from fossil-fueled climate change and record droughts. Educating medical trainees on the impacts of climate change is just as vital, as it is a topic that often is neglected in medical school and residency curricula.33
9. Install water-efficient toilets and faucets. Anthropogenic climate change has been shown to increase the duration and intensity of droughts throughout the world.34 Much of the western United States also is experiencing record droughts. One way in which dermatology practices can work to combat droughts is through the use of water-conserving toilets, faucets, and urinals. Using water fixtures with the US Environmental Protection Agency’s WaterSense label is a convenient way to do so. The WaterSense label helps identify water fixtures certified to use at least 20% less water as well as save energy and decrease water costs.
10. Advocate through local and national organizations. There are numerous ways in which dermatologists can advocate for action against climate change. Joining professional organizations focused on addressing the climate crisis can help you connect with fellow dermatologists and physicians. The Expert Resource Group on Climate Change and Environmental Issues affiliated with the American Academy of Dermatology (AAD) is one such organization with many opportunities to raise awareness within the field of dermatology. The AAD recently joined the Medical Society Consortium on Climate and Health, an organization providing opportunities for policy and media outreach as well as research on climate change. Advocacy also can mean joining your local chapter of Physicians for Social Responsibility or encouraging divestment from fossil fuel companies within your institution. Voicing support for climate change–focused lectures at events such as grand rounds and society meetings at the local, regional, and state-wide levels can help raise awareness. As the dermatologic effects of climate change grow, being knowledgeable of the views of future leaders in our specialty and country on this issue will become increasingly important.
Final Thoughts
In addition to the climate-friendly decisions one can make as a dermatologist, there are many personal lifestyle choices to consider. Small dietary changes such as limiting consumption of beef and minimizing food waste can have large downstream effects. Opting for transportation via train and limiting air travel are both impactful decisions in reducing CO2 emissions. Similarly, switching to an electric vehicle or vehicle with minimal emissions can work to reduce greenhouse gas accumulation. For additional resources, note the AAD has partnered with My Green Doctor, a nonprofit service for health care practices that includes practical cost-saving suggestions to support sustainability in physician practices.
A recent joint publication in more than 200 medical journals described climate change as the greatest threat to global public health.35 Climate change is having devastating effects on dermatologic health and will only continue to do so if not addressed now. Dermatologists have the opportunity to join with our colleagues in the house of medicine and to take action to fight climate change and mitigate the health impacts on our patients, the population, and future generations.
- Santer BD, Bonfils CJW, Fu Q, et al. Celebrating the anniversary of three key events in climate change science. Nat Clim Chang. 2019;9:180-182.
- Lynas M, Houlton BZ, Perry S. Greater than 99% consensus on human caused climate change in the peer-reviewed scientific literature. Environ Res Lett. 2021;16:114005.
- Crowley RA; Health and Public Policy Committee of the American College of Physicians. Climate change and health: a position paper of the American College of Physicians [published online April 19, 2016]. Ann Intern Med. 2016;164:608-610. doi:10.7326/M15-2766
- Global climate change and human health H-135.398. American Medical Association website. Updated 2019. Accessed July 13, 2022. https://policysearch.ama-assn.org/policyfinder/detail/climate%20change?uri=%2FAMADoc%2FHOD.xml-0-309.xml
- Mieczkowska K, Stringer T, Barbieri JS, et al. Surveying the attitudes of dermatologists regarding climate change. Br J Dermatol. 2022;186:748-750.
- Eckelman MJ, Sherman J. Environmental impacts of the U.S. health care system and effects on public health. PLoS One. 2016;11:e0157014. doi:10.1371/journal.pone.0157014
- Karliner J, Slotterback S, Boyd R, et al. Health care’s climate footprint: how the health sector contributes to the global climate crisis and opportunities for action. Health Care Without Harm website. Published September 2019. Accessed July 13, 2022. https://noharm-global.org/sites/default/files/documents-files/5961/HealthCaresClimateFootprint_090619.pdf
- Pichler PP, Jaccard IS, Weisz U, et al. International comparison of health care carbon footprints. Environ Res Lett. 2019;14:064004.
- Solomon CG, LaRocque RC. Climate change—a health emergency. N Engl J Med. 2019;380:209-211. doi:10.1056/NEJMp1817067
- IPCC, 2021: Summary for Policymakers. In: Masson-Delmotte V, Zhai P, Pirani A, et al, eds. Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press; 2021:3-32.
- Dzau VJ, Levine R, Barrett G, et al. Decarbonizing the U.S. Health Sector—a call to action [published online October 13, 2021]. N Engl J Med. 2021;385:2117-2119. doi:10.1056/NEJMp2115675
- Silva GS, Rosenbach M. Climate change and dermatology: an introduction to a special topic, for this special issue. Int J Womens Dermatol 2021;7:3-7.
- Coates SJ, Norton SA. The effects of climate change on infectious diseases with cutaneous manifestations. Int J Womens Dermatol. 2021;7:8-16. doi:10.1016/j.ijwd.2020.07.005
- Andersen LK, Davis MD. Climate change and the epidemiology of selected tick-borne and mosquito-borne diseases: update from the International Society of Dermatology Climate Change Task Force [published online October 1, 2016]. Int J Dermatol. 2017;56:252-259. doi:10.1111/ijd.13438
- Fadadu RP, Grimes B, Jewell NP, et al. Association of wildfire air pollution and health care use for atopic dermatitis and itch. JAMA Dermatol. 2021;157:658-666. doi:10.1001/jamadermatol.2021.0179
- Bellinato F, Adami G, Vaienti S, et al. Association between short-term exposure to environmental air pollution and psoriasis flare. JAMA Dermatol. 2022;158:375-381. doi:10.1001/jamadermatol.2021.6019
- Krutmann J, Bouloc A, Sore G, et al. The skin aging exposome [published online September 28, 2016]. J Dermatol Sci. 2017;85:152-161.
- Parker ER. The influence of climate change on skin cancer incidence—a review of the evidence. Int J Womens Dermatol. 2020;7:17-27. doi:10.1016/j.ijwd.2020.07.003
- Eckelman MJ, Huang K, Lagasse R, et al. Health care pollution and public health damage in the United States: an update. Health Aff (Millwood). 2020;39:2071-2079.
- Sheppy M, Pless S, Kung F. Healthcare energy end-use monitoring. US Department of Energy website. Published August 2014. Accessed July 13, 2022. https://www.energy.gov/sites/prod/files/2014/09/f18/61064.pdf
- Feldman D, Ramasamy V, Fu R, et al. U.S. solar photovoltaic system and energy storage cost benchmark: Q1 2020. Published January 2021. Accessed July 7, 2022. https://www.nrel.gov/docs/fy21osti/77324.pdf
- 22. Apostoleris H, Sgouridis S, Stefancich M, et al. Utility solar prices will continue to drop all over the world even without subsidies. Nat Energy. 2019;4:833-834.
- Prasanna PM, Siegel E, Kunce A. Greening radiology. J Am Coll Radiol. 2011;8:780-784. doi:10.1016/j.jacr.2011.07.017
- Bawaneh K, Nezami FG, Rasheduzzaman MD, et al. Energy consumption analysis and characterization of healthcare facilities in the United States. Energies. 2019;12:1-20. doi:10.3390/en12193775
- Blum S, Buckland M, Sack TL, et al. Greening the office: saving resources, saving money, and educating our patients [published online July 4, 2020]. Int J Womens Dermatol. 2020;7:112-116.
- Maintaining your air conditioner. US Department of Energy website. Accessed July 13, 2022. https://www.energy.gov/energysaver/maintaining-your-air-conditioner
- Choma EF, Evans JS, Hammitt JK, et al. Assessing the health impacts of electric vehicles through air pollution in the United States [published online August 25, 2020]. Environ Int. 2020;144:106015.
- Windfeld ES, Brooks MS. Medical waste management—a review [published online August 22, 2015]. J Environ Manage. 2015;1;163:98-108. doi:10.1016/j.jenvman.2015.08.013
- Fathy R, Nelson CA, Barbieri JS. Combating climate change in the clinic: cost-effective strategies to decrease the carbon footprint of outpatient dermatologic practice. Int J Womens Dermatol. 2020;7:107-111.
- Pulsipher KJ, Presley CL, Rundle CW, et al. Teledermatology application use in the COVID-19 era. Dermatol Online J. 2020;26:13030/qt1fs0m0tp.
- O’Connell G, O’Connor C, Murphy M. Every cloud has a silver lining: the environmental benefit of teledermatology during the COVID-19 pandemic [published online July 9, 2021]. Clin Exp Dermatol. 2021;46:1589-1590. doi:10.1111/ced.14795
- Vozzola E, Overcash M, Griffing E. Environmental considerations in the selection of isolation gowns: a life cycle assessment of reusable and disposable alternatives [published online April 11, 2018]. Am J Infect Control. 2018;46:881-886. doi:10.1016/j.ajic.2018.02.002
- Rabin BM, Laney EB, Philipsborn RP. The unique role of medical students in catalyzing climate change education [published online October 14, 2020]. J Med Educ Curric Dev. doi:10.1177/2382120520957653
- Chiang F, Mazdiyasni O, AghaKouchak A. Evidence of anthropogenic impacts on global drought frequency, duration, and intensity [published online May 12, 2021]. Nat Commun. 2021;12:2754. doi:10.1038/s41467-021-22314-w
- Atwoli L, Baqui AH, Benfield T, et al. Call for emergency action to limit global temperature increases, restore biodiversity, and protect health [published online September 5, 2021]. N Engl J Med. 2021;385:1134-1137. doi:10.1056/NEJMe2113200
- Santer BD, Bonfils CJW, Fu Q, et al. Celebrating the anniversary of three key events in climate change science. Nat Clim Chang. 2019;9:180-182.
- Lynas M, Houlton BZ, Perry S. Greater than 99% consensus on human caused climate change in the peer-reviewed scientific literature. Environ Res Lett. 2021;16:114005.
- Crowley RA; Health and Public Policy Committee of the American College of Physicians. Climate change and health: a position paper of the American College of Physicians [published online April 19, 2016]. Ann Intern Med. 2016;164:608-610. doi:10.7326/M15-2766
- Global climate change and human health H-135.398. American Medical Association website. Updated 2019. Accessed July 13, 2022. https://policysearch.ama-assn.org/policyfinder/detail/climate%20change?uri=%2FAMADoc%2FHOD.xml-0-309.xml
- Mieczkowska K, Stringer T, Barbieri JS, et al. Surveying the attitudes of dermatologists regarding climate change. Br J Dermatol. 2022;186:748-750.
- Eckelman MJ, Sherman J. Environmental impacts of the U.S. health care system and effects on public health. PLoS One. 2016;11:e0157014. doi:10.1371/journal.pone.0157014
- Karliner J, Slotterback S, Boyd R, et al. Health care’s climate footprint: how the health sector contributes to the global climate crisis and opportunities for action. Health Care Without Harm website. Published September 2019. Accessed July 13, 2022. https://noharm-global.org/sites/default/files/documents-files/5961/HealthCaresClimateFootprint_090619.pdf
- Pichler PP, Jaccard IS, Weisz U, et al. International comparison of health care carbon footprints. Environ Res Lett. 2019;14:064004.
- Solomon CG, LaRocque RC. Climate change—a health emergency. N Engl J Med. 2019;380:209-211. doi:10.1056/NEJMp1817067
- IPCC, 2021: Summary for Policymakers. In: Masson-Delmotte V, Zhai P, Pirani A, et al, eds. Climate Change 2021: The Physical Science Basis. Contribution of Working Group I to the Sixth Assessment Report of the Intergovernmental Panel on Climate Change. Cambridge University Press; 2021:3-32.
- Dzau VJ, Levine R, Barrett G, et al. Decarbonizing the U.S. Health Sector—a call to action [published online October 13, 2021]. N Engl J Med. 2021;385:2117-2119. doi:10.1056/NEJMp2115675
- Silva GS, Rosenbach M. Climate change and dermatology: an introduction to a special topic, for this special issue. Int J Womens Dermatol 2021;7:3-7.
- Coates SJ, Norton SA. The effects of climate change on infectious diseases with cutaneous manifestations. Int J Womens Dermatol. 2021;7:8-16. doi:10.1016/j.ijwd.2020.07.005
- Andersen LK, Davis MD. Climate change and the epidemiology of selected tick-borne and mosquito-borne diseases: update from the International Society of Dermatology Climate Change Task Force [published online October 1, 2016]. Int J Dermatol. 2017;56:252-259. doi:10.1111/ijd.13438
- Fadadu RP, Grimes B, Jewell NP, et al. Association of wildfire air pollution and health care use for atopic dermatitis and itch. JAMA Dermatol. 2021;157:658-666. doi:10.1001/jamadermatol.2021.0179
- Bellinato F, Adami G, Vaienti S, et al. Association between short-term exposure to environmental air pollution and psoriasis flare. JAMA Dermatol. 2022;158:375-381. doi:10.1001/jamadermatol.2021.6019
- Krutmann J, Bouloc A, Sore G, et al. The skin aging exposome [published online September 28, 2016]. J Dermatol Sci. 2017;85:152-161.
- Parker ER. The influence of climate change on skin cancer incidence—a review of the evidence. Int J Womens Dermatol. 2020;7:17-27. doi:10.1016/j.ijwd.2020.07.003
- Eckelman MJ, Huang K, Lagasse R, et al. Health care pollution and public health damage in the United States: an update. Health Aff (Millwood). 2020;39:2071-2079.
- Sheppy M, Pless S, Kung F. Healthcare energy end-use monitoring. US Department of Energy website. Published August 2014. Accessed July 13, 2022. https://www.energy.gov/sites/prod/files/2014/09/f18/61064.pdf
- Feldman D, Ramasamy V, Fu R, et al. U.S. solar photovoltaic system and energy storage cost benchmark: Q1 2020. Published January 2021. Accessed July 7, 2022. https://www.nrel.gov/docs/fy21osti/77324.pdf
- 22. Apostoleris H, Sgouridis S, Stefancich M, et al. Utility solar prices will continue to drop all over the world even without subsidies. Nat Energy. 2019;4:833-834.
- Prasanna PM, Siegel E, Kunce A. Greening radiology. J Am Coll Radiol. 2011;8:780-784. doi:10.1016/j.jacr.2011.07.017
- Bawaneh K, Nezami FG, Rasheduzzaman MD, et al. Energy consumption analysis and characterization of healthcare facilities in the United States. Energies. 2019;12:1-20. doi:10.3390/en12193775
- Blum S, Buckland M, Sack TL, et al. Greening the office: saving resources, saving money, and educating our patients [published online July 4, 2020]. Int J Womens Dermatol. 2020;7:112-116.
- Maintaining your air conditioner. US Department of Energy website. Accessed July 13, 2022. https://www.energy.gov/energysaver/maintaining-your-air-conditioner
- Choma EF, Evans JS, Hammitt JK, et al. Assessing the health impacts of electric vehicles through air pollution in the United States [published online August 25, 2020]. Environ Int. 2020;144:106015.
- Windfeld ES, Brooks MS. Medical waste management—a review [published online August 22, 2015]. J Environ Manage. 2015;1;163:98-108. doi:10.1016/j.jenvman.2015.08.013
- Fathy R, Nelson CA, Barbieri JS. Combating climate change in the clinic: cost-effective strategies to decrease the carbon footprint of outpatient dermatologic practice. Int J Womens Dermatol. 2020;7:107-111.
- Pulsipher KJ, Presley CL, Rundle CW, et al. Teledermatology application use in the COVID-19 era. Dermatol Online J. 2020;26:13030/qt1fs0m0tp.
- O’Connell G, O’Connor C, Murphy M. Every cloud has a silver lining: the environmental benefit of teledermatology during the COVID-19 pandemic [published online July 9, 2021]. Clin Exp Dermatol. 2021;46:1589-1590. doi:10.1111/ced.14795
- Vozzola E, Overcash M, Griffing E. Environmental considerations in the selection of isolation gowns: a life cycle assessment of reusable and disposable alternatives [published online April 11, 2018]. Am J Infect Control. 2018;46:881-886. doi:10.1016/j.ajic.2018.02.002
- Rabin BM, Laney EB, Philipsborn RP. The unique role of medical students in catalyzing climate change education [published online October 14, 2020]. J Med Educ Curric Dev. doi:10.1177/2382120520957653
- Chiang F, Mazdiyasni O, AghaKouchak A. Evidence of anthropogenic impacts on global drought frequency, duration, and intensity [published online May 12, 2021]. Nat Commun. 2021;12:2754. doi:10.1038/s41467-021-22314-w
- Atwoli L, Baqui AH, Benfield T, et al. Call for emergency action to limit global temperature increases, restore biodiversity, and protect health [published online September 5, 2021]. N Engl J Med. 2021;385:1134-1137. doi:10.1056/NEJMe2113200
White House declares monkeypox a public health emergency
There have been more than 6,600 reported cases of the disease in the United States, up from less than 5,000 cases reported last week.
“This public health emergency will allow us to explore additional strategies to get vaccines and treatments more quickly out in the affected communities. And it will allow us to get more data from jurisdictions so we can effectively track and attack this outbreak,” Robert Fenton, who was named as the national monkeypox response coordinator this week, said at a news briefing Aug. 4.
Those who catch the virus usually have fever-like symptoms, followed by red lesions on the body that can raise and develop pus. Those at highest risk of monkeypox are gay and bisexual men, as well as men who have sex with other men. There are between 1.6 million and 1.7 million Americans in this high-risk group, Health and Human Services Secretary Xavier Becerra said at the briefing.
The Jynneos vaccine is being distributed to protect against monkeypox and can prevent severe symptoms. It’s mostly going to those with the greatest risk of catching the virus.
Last week, the Biden administration made over 1.1 million doses of the Jynneos vaccine available – of which over 600,000 doses have already been distributed across the country – and have secured over 6.9 million Jynneos doses altogether.
Around 786,000 vaccines have already been allocated, and the first doses were shipped this week. States will be able to order more doses beginning Aug. 15. If a state has used 90% or more of its vaccine supply, it will be eligible to order more doses before Aug. 15, according to Dawn O’Connell, JD, assistant secretary for preparedness and response at the U.S. Department of Health and Human Services.
An additional 150,000 doses will be added to the national stockpile in September, with more doses to come later this year, Ms. O’Connell says.
The administration is also stressing the importance of monkeypox testing and says it can now distribute 80,000 monkeypox tests per week.
An antiviral drug – known as TPOXX – is also available to treat severe cases of monkeypox. Around 1,700,000 doses are available in the Strategic National Stockpile, public health officials say.
“We are prepared to take our response to the next level, and we urge every American to take this seriously and to take responsibility to help us tackle this virus,” Secretary Becerra told reporters.
The White House says it will continue reaching out to doctors, public health partners, LGBTQ advocates, and other impacted communities.
“The public health emergency further raises awareness about monkeypox, which will encourage clinicians to test for it,” Rochelle Walensky, MD, director of the Centers for Disease Control and Prevention, said at the briefing.
This week, President Joe Biden appointed a new White House monkeypox response team. Besides Mr. Fenton as the response coordinator, Demetre Daskalakis, MD, will serve as the White House national monkeypox response deputy coordinator. He is the director of the CDC’s Division of HIV Prevention.
“This virus is moving fast. This is a unique outbreak that is spreading faster than previous outbreaks,” Mr. Fenton told reporters Aug. 4. “That’s why the president asked me to explore everything we can do to combat monkeypox and protect communities at risk.”
This article was updated 8/4/22.
There have been more than 6,600 reported cases of the disease in the United States, up from less than 5,000 cases reported last week.
“This public health emergency will allow us to explore additional strategies to get vaccines and treatments more quickly out in the affected communities. And it will allow us to get more data from jurisdictions so we can effectively track and attack this outbreak,” Robert Fenton, who was named as the national monkeypox response coordinator this week, said at a news briefing Aug. 4.
Those who catch the virus usually have fever-like symptoms, followed by red lesions on the body that can raise and develop pus. Those at highest risk of monkeypox are gay and bisexual men, as well as men who have sex with other men. There are between 1.6 million and 1.7 million Americans in this high-risk group, Health and Human Services Secretary Xavier Becerra said at the briefing.
The Jynneos vaccine is being distributed to protect against monkeypox and can prevent severe symptoms. It’s mostly going to those with the greatest risk of catching the virus.
Last week, the Biden administration made over 1.1 million doses of the Jynneos vaccine available – of which over 600,000 doses have already been distributed across the country – and have secured over 6.9 million Jynneos doses altogether.
Around 786,000 vaccines have already been allocated, and the first doses were shipped this week. States will be able to order more doses beginning Aug. 15. If a state has used 90% or more of its vaccine supply, it will be eligible to order more doses before Aug. 15, according to Dawn O’Connell, JD, assistant secretary for preparedness and response at the U.S. Department of Health and Human Services.
An additional 150,000 doses will be added to the national stockpile in September, with more doses to come later this year, Ms. O’Connell says.
The administration is also stressing the importance of monkeypox testing and says it can now distribute 80,000 monkeypox tests per week.
An antiviral drug – known as TPOXX – is also available to treat severe cases of monkeypox. Around 1,700,000 doses are available in the Strategic National Stockpile, public health officials say.
“We are prepared to take our response to the next level, and we urge every American to take this seriously and to take responsibility to help us tackle this virus,” Secretary Becerra told reporters.
The White House says it will continue reaching out to doctors, public health partners, LGBTQ advocates, and other impacted communities.
“The public health emergency further raises awareness about monkeypox, which will encourage clinicians to test for it,” Rochelle Walensky, MD, director of the Centers for Disease Control and Prevention, said at the briefing.
This week, President Joe Biden appointed a new White House monkeypox response team. Besides Mr. Fenton as the response coordinator, Demetre Daskalakis, MD, will serve as the White House national monkeypox response deputy coordinator. He is the director of the CDC’s Division of HIV Prevention.
“This virus is moving fast. This is a unique outbreak that is spreading faster than previous outbreaks,” Mr. Fenton told reporters Aug. 4. “That’s why the president asked me to explore everything we can do to combat monkeypox and protect communities at risk.”
This article was updated 8/4/22.
There have been more than 6,600 reported cases of the disease in the United States, up from less than 5,000 cases reported last week.
“This public health emergency will allow us to explore additional strategies to get vaccines and treatments more quickly out in the affected communities. And it will allow us to get more data from jurisdictions so we can effectively track and attack this outbreak,” Robert Fenton, who was named as the national monkeypox response coordinator this week, said at a news briefing Aug. 4.
Those who catch the virus usually have fever-like symptoms, followed by red lesions on the body that can raise and develop pus. Those at highest risk of monkeypox are gay and bisexual men, as well as men who have sex with other men. There are between 1.6 million and 1.7 million Americans in this high-risk group, Health and Human Services Secretary Xavier Becerra said at the briefing.
The Jynneos vaccine is being distributed to protect against monkeypox and can prevent severe symptoms. It’s mostly going to those with the greatest risk of catching the virus.
Last week, the Biden administration made over 1.1 million doses of the Jynneos vaccine available – of which over 600,000 doses have already been distributed across the country – and have secured over 6.9 million Jynneos doses altogether.
Around 786,000 vaccines have already been allocated, and the first doses were shipped this week. States will be able to order more doses beginning Aug. 15. If a state has used 90% or more of its vaccine supply, it will be eligible to order more doses before Aug. 15, according to Dawn O’Connell, JD, assistant secretary for preparedness and response at the U.S. Department of Health and Human Services.
An additional 150,000 doses will be added to the national stockpile in September, with more doses to come later this year, Ms. O’Connell says.
The administration is also stressing the importance of monkeypox testing and says it can now distribute 80,000 monkeypox tests per week.
An antiviral drug – known as TPOXX – is also available to treat severe cases of monkeypox. Around 1,700,000 doses are available in the Strategic National Stockpile, public health officials say.
“We are prepared to take our response to the next level, and we urge every American to take this seriously and to take responsibility to help us tackle this virus,” Secretary Becerra told reporters.
The White House says it will continue reaching out to doctors, public health partners, LGBTQ advocates, and other impacted communities.
“The public health emergency further raises awareness about monkeypox, which will encourage clinicians to test for it,” Rochelle Walensky, MD, director of the Centers for Disease Control and Prevention, said at the briefing.
This week, President Joe Biden appointed a new White House monkeypox response team. Besides Mr. Fenton as the response coordinator, Demetre Daskalakis, MD, will serve as the White House national monkeypox response deputy coordinator. He is the director of the CDC’s Division of HIV Prevention.
“This virus is moving fast. This is a unique outbreak that is spreading faster than previous outbreaks,” Mr. Fenton told reporters Aug. 4. “That’s why the president asked me to explore everything we can do to combat monkeypox and protect communities at risk.”
This article was updated 8/4/22.