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In Case You Missed It: COVID
Life during COVID-19: A pandemic of silence
Our world has radically changed during the coronavirus disease 2019 (COVID-19) crisis, and this impact has quickly transformed many lives. Whether you’re on the front lines of the COVID-19 pandemic or waiting in eager anticipation to return to practice, there is no denying that a few months ago we could never have imagined the health care and humanitarian crisis that is now before us. While we are united in our longing for a better time, we couldn’t be further apart socially and emotionally … and I’m not just talking about 6 feet.
One thing that has been truly striking to me is the silence. While experts have suggested there is a “silent pandemic” of mental illness on the horizon,1 I’ve been struck by the actual silence that exists as we walk through our stores and neighborhoods. We’re not speaking to each other anymore; it’s almost as if we’re afraid to make eye contact with one another.
Humans are social creatures, and the isolation that many people are experiencing during this pandemic could have detrimental and lasting effects if we don’t take action. While I highly encourage and support efforts to employ social distancing and mitigate the spread of this illness, I’m increasingly concerned about another kind of truly silent pandemic brewing beneath the surface of the COVID-19 crisis. Even under the best conditions, many individuals with posttraumatic stress disorder, depression, anxiety, bipolar disorder, schizophrenia, and other psychiatric disorders may lack adequate social interaction and experience feelings of isolation. These individuals need connection—not silence.
What happens to people who already felt intense isolation before COVID-19 and may have had invaluable lifelines cut off during this time of social distancing? What about individuals with alcohol or substance use disorders, or families who are sheltered in place in unsafe or violent home conditions? How can they reach out in silence? How can we help?
Fostering human connection
To address this, we must actively work to engage our patients and communities. One simple way to help is to acknowledge the people you encounter. Yes, stay 6 feet apart, and wear appropriate personal protective equipment. However, it is still OK to smile and greet someone with a nod, a smile, or a “hello.” A genuine smile can still be seen in someone’s eyes. We need these types of human connection, perhaps now more than ever before. We need each other.
Most importantly, during this time, we need to be aware of individuals who are most at risk in this silent pandemic. We can offer our patients appointments via video conferencing. We can use texting, e-mail, social media, phone calls, and video conferencing to check in with our families, friends, and neighbors. We’re at war with a terrible foe, but let’s not let the human connection become collateral damage.
1. Galea S, Merchant RM, Lurie N, et al. The mental health consequences of COVID-19 and physical distancing: the need for prevention and early intervention [published online April 10, 2020]. JAMA Intern Med. 2020. doi: 10.1001/jamainternmed.2020.1562.
Our world has radically changed during the coronavirus disease 2019 (COVID-19) crisis, and this impact has quickly transformed many lives. Whether you’re on the front lines of the COVID-19 pandemic or waiting in eager anticipation to return to practice, there is no denying that a few months ago we could never have imagined the health care and humanitarian crisis that is now before us. While we are united in our longing for a better time, we couldn’t be further apart socially and emotionally … and I’m not just talking about 6 feet.
One thing that has been truly striking to me is the silence. While experts have suggested there is a “silent pandemic” of mental illness on the horizon,1 I’ve been struck by the actual silence that exists as we walk through our stores and neighborhoods. We’re not speaking to each other anymore; it’s almost as if we’re afraid to make eye contact with one another.
Humans are social creatures, and the isolation that many people are experiencing during this pandemic could have detrimental and lasting effects if we don’t take action. While I highly encourage and support efforts to employ social distancing and mitigate the spread of this illness, I’m increasingly concerned about another kind of truly silent pandemic brewing beneath the surface of the COVID-19 crisis. Even under the best conditions, many individuals with posttraumatic stress disorder, depression, anxiety, bipolar disorder, schizophrenia, and other psychiatric disorders may lack adequate social interaction and experience feelings of isolation. These individuals need connection—not silence.
What happens to people who already felt intense isolation before COVID-19 and may have had invaluable lifelines cut off during this time of social distancing? What about individuals with alcohol or substance use disorders, or families who are sheltered in place in unsafe or violent home conditions? How can they reach out in silence? How can we help?
Fostering human connection
To address this, we must actively work to engage our patients and communities. One simple way to help is to acknowledge the people you encounter. Yes, stay 6 feet apart, and wear appropriate personal protective equipment. However, it is still OK to smile and greet someone with a nod, a smile, or a “hello.” A genuine smile can still be seen in someone’s eyes. We need these types of human connection, perhaps now more than ever before. We need each other.
Most importantly, during this time, we need to be aware of individuals who are most at risk in this silent pandemic. We can offer our patients appointments via video conferencing. We can use texting, e-mail, social media, phone calls, and video conferencing to check in with our families, friends, and neighbors. We’re at war with a terrible foe, but let’s not let the human connection become collateral damage.
Our world has radically changed during the coronavirus disease 2019 (COVID-19) crisis, and this impact has quickly transformed many lives. Whether you’re on the front lines of the COVID-19 pandemic or waiting in eager anticipation to return to practice, there is no denying that a few months ago we could never have imagined the health care and humanitarian crisis that is now before us. While we are united in our longing for a better time, we couldn’t be further apart socially and emotionally … and I’m not just talking about 6 feet.
One thing that has been truly striking to me is the silence. While experts have suggested there is a “silent pandemic” of mental illness on the horizon,1 I’ve been struck by the actual silence that exists as we walk through our stores and neighborhoods. We’re not speaking to each other anymore; it’s almost as if we’re afraid to make eye contact with one another.
Humans are social creatures, and the isolation that many people are experiencing during this pandemic could have detrimental and lasting effects if we don’t take action. While I highly encourage and support efforts to employ social distancing and mitigate the spread of this illness, I’m increasingly concerned about another kind of truly silent pandemic brewing beneath the surface of the COVID-19 crisis. Even under the best conditions, many individuals with posttraumatic stress disorder, depression, anxiety, bipolar disorder, schizophrenia, and other psychiatric disorders may lack adequate social interaction and experience feelings of isolation. These individuals need connection—not silence.
What happens to people who already felt intense isolation before COVID-19 and may have had invaluable lifelines cut off during this time of social distancing? What about individuals with alcohol or substance use disorders, or families who are sheltered in place in unsafe or violent home conditions? How can they reach out in silence? How can we help?
Fostering human connection
To address this, we must actively work to engage our patients and communities. One simple way to help is to acknowledge the people you encounter. Yes, stay 6 feet apart, and wear appropriate personal protective equipment. However, it is still OK to smile and greet someone with a nod, a smile, or a “hello.” A genuine smile can still be seen in someone’s eyes. We need these types of human connection, perhaps now more than ever before. We need each other.
Most importantly, during this time, we need to be aware of individuals who are most at risk in this silent pandemic. We can offer our patients appointments via video conferencing. We can use texting, e-mail, social media, phone calls, and video conferencing to check in with our families, friends, and neighbors. We’re at war with a terrible foe, but let’s not let the human connection become collateral damage.
1. Galea S, Merchant RM, Lurie N, et al. The mental health consequences of COVID-19 and physical distancing: the need for prevention and early intervention [published online April 10, 2020]. JAMA Intern Med. 2020. doi: 10.1001/jamainternmed.2020.1562.
1. Galea S, Merchant RM, Lurie N, et al. The mental health consequences of COVID-19 and physical distancing: the need for prevention and early intervention [published online April 10, 2020]. JAMA Intern Med. 2020. doi: 10.1001/jamainternmed.2020.1562.
Neuropsychiatric manifestations of COVID-19
On March 11, 2020, the World Health Organization declared that coronavirus disease 2019 (COVID-19) was a pandemic.1 As of mid-May 2020, the illness had claimed more than 316,000 lives worldwide.2 The main symptoms of the respiratory illness caused by COVID-19 are fever, dry cough, and shortness of breath. However, disorders of consciousness also have been reported, especially in patients who succumb to the illness.3 In fact, approximately one-third of hospitalized COVID-19 patients experience neurologic symptoms.4 Although the most common of these symptoms are dizziness, headache, and loss of smell and taste, patients with more severe cases can experience acute cerebrovascular diseases and impaired consciousness.4 As such, psychiatrists assessing confusion should include COVID-19 in their differential diagnosis as a potential cause of altered mental status.
How COVID-19 might affect the CNS
Although primarily considered a respiratory illness, COVID-19 also may have neurotropic potential. The virus that causes COVID-19, severe acute respiratory syndrome-coronavirus-2 (SARS-CoV-2), is a beta-coronavirus. Two other highly pathogenic coronaviruses—SARS-CoV-1 and Middle East respiratory syndrome–related coronavirus (MERS-CoV)—are also beta-coronaviruses, and both have been reported to invade the CNS in some patients.5 These viruses are thought to invade cells via angiotensin-converting enzyme 2 (ACE2) receptors.6 These receptors are located on the epithelial cells of the respiratory and gastrointestinal (GI) tracts, but also are expressed in certain areas of the brain.7 Transmission to the brain could occur through various routes. However, the clinical symptom of loss of smell and taste hints to possible transmission of the virus from nasal cells to the olfactory bulb via trans-synaptic transmission in olfactory neurons.5,8,9
Immune injury via systemic inflammation is another proposed mechanism for nervous system damage.8,9 This has been described as “cytokine storm syndrome” and provides support to the role of immunotherapy in COVID-19 patients.10 Such inflammation has been long hypothesized as a contributor to psychiatric illnesses, especially neurocognitive disorders.11,12
Neuropsychiatric complications of COVID-19
Disorders of consciousness were identified early as a symptom of COVID-19.3 Subsequent studies and case reports have confirmed impaired consciousness as a possible symptom of COVID-19.4 The first case of encephalitis secondary to COVID-19 was reported by Chinese media on March 5, 2020 in Beijing, China.13 Subsequently, cases of encephalopathy secondary to COVID-19 have been reported in the United States. A 74-year-old man in Boca Raton, Florida who had recently returned from the Netherlands presented with altered mental status and was confirmed positive for COVID-19.14 A female airline worker in her late 50s who presented with altered mental status and tested positive for COVID-19 was found on imaging to have acute hemorrhagic necrotizing encephalopathy.15 There also have been cases of patients with confirmed COVID-19 who initially presented with complaints of seizures16 and Guillain-Barré syndrome.17 As such, neuropsychiatric complications of COVID-19 are being increasingly recognized and are important to consider during psychiatric assessments.
Consider COVID-19 when assessing altered mental status
Psychiatrists are often consulted to assess patients with impaired consciousness, mental status changes, or confusion. Acute changes to mentation raise concern for delirium. In fact, delirium should always be ruled out when assessing new psychiatric symptoms. The astute psychiatrist is aware of the myriad of medical contributors to delirium. However, because knowledge of COVID-19 is in its infancy, it can be easy to overlook this virus as a potential contributor to delirium. Even patients whose confusion seems to be more in line with a major neurocognitive disorder should be evaluated for COVID-19, because the sudden onset of cognitive impairment may be due to hypoxia, inflammatory damage, or cerebrovascular changes secondary to infection with the virus or its respiratory complications, such as acute respiratory distress syndrome (ARDS).18
The most obvious clues to the possible presence of COVID-19 in a patient who is confused would be fever, dry cough, and shortness of breath. Because ACE2 receptors are also located in the GI tract, nausea, vomiting, and diarrhea also are possible. However, patients who are confused may be poor historians, demonstrating behavioral symptoms that might make physical assessments challenging, or simply may be pre- or asymptomatic carriers of the virus. Hence, a thorough review of the patient’s history and collateral information is invaluable. A recent history of travel or contact with COVID-19–positive individuals should raise suspicion for viral infection. A patient who mentions a loss of taste or smell would also alert the psychiatrist to the possibility of COVID-19. A patient might not directly state this information, but may mention that he/she has been eating less or has not been disturbed by odors. Neuroimaging can be useful because patients with severe cases are at increased risk for acute cerebrovascular diseases.4 Also, ordering a chest CT may prove helpful because this testing is highly sensitive for COVID-19.19 If there is sufficient clinical evidence to suspect viral infection, testing for COVID-19 should be performed immediately.
It is important to be vigilant for the possibility of COVID-19 infection in patients who present with confusion. Because the virus is highly contagious, the threshold for COVID-19 testing should be low. Viral infection in patients can manifest in ways other than classic respiratory symptoms. Psychiatrists should be aware of COVID-19’s potential to invade the CNS and cause neuropsychiatric symptoms. When assessing confusion in any setting, the clinical and historical clues for COVID-19 should be kept in mind. This will allow patients with COVID-19 to be quickly diagnosed to initiate appropriate management and minimize progression of the illness. Additionally, this will allow for efficient quarantine of the patient to prevent the spread of the virus to others. As such, psychiatrists can play an important role in containing this virus and resolving the COVID-19 pandemic.
Continue to: Bottom Line
Bottom Line
Although primarily considered a respiratory illness, coronavirus disease 2019 (COVID-19) also may have the potential to invade the CNS and cause neuropsychiatric symptoms, such as impaired consciousness, encephalitis, or a loss of taste or smell. When assessing a patient who presents with confusion, be vigilant for the possibility of COVID-19.
Related Resources
- American Psychiatry Association. APA coronavirus resources. https://www.psychiatry.org/psychiatrists/covid-19-coronavirus#psych.
- Troyer EA, Kohn JN, Hong S. Are we facing a crashing wave of neuropsychiatric sequelae of COVID-19? Neuropsychiatric symptoms and potential immunologic mechanisms. Brain Behav Immun. 2020;S0889-1591(20)30489-X. doi: 10.1016/j.bbi.2020.04.027.
1. World Health Organization. Rolling updates on coronavirus disease (COVID-19). https://www.who.int/emergencies/diseases/novel-coronavirus-2019/events-as-they-happen. Updated May 1, 2020. Accessed May 4, 2020.
2. John Hopkins University. Coronavirus resource center. World map. https://coronavirus.jhu.edu/map.html. Accessed May 4, 2020.
3. Chen T, Wu D, Chen H, et al. Clinical characteristics of 113 deceased patients with coronavirus disease 2019: retrospective study. BMJ. 2020;368:m1091. doi: 10.1136/bmj.m1091.
4. Mao L, Wang M, Chen S, et al. Neurologic manifestations of hospitalized patients with COVID-19 in Wuhan, China: a retrospective case series study [published online February 25, 2020]. JAMA Neurol. 2020;e201127. doi: 10.1101/2020.02.22.20026500.
5. Li YC, Bai WZ, Hashikawa T. The neuroinvasive potential of SARS-CoV2 may play a role in the respiratory failure of COVID-19 patients [published online February 27, 2020]. J Med Virol. 2020;92(6). doi: 10.1002/jmv.25728.
6. Baig AM, Khaleeq A, Ali E, et al. Evidence of the COVID-19 virus targeting the CNS: tissue distribution, host-virus interaction, and proposed neurotropic mechanisms. ACS Chem Neurosci. 2020;11(7):995-998.
7. Xia H, Lazartigues E. Angiotensin-converting enzyme 2: central regulator for cardiovascular function. Curr Hypertens Rep. 2010;12(3):170-175.
8. Steardo L, Steardo L Jr, Zorec R, et al. Neuroinfection may contribute to pathophysiology and clinical manifestations of COVID-19 [published online March 29, 2020]. Acta Physiol (Oxf). 2020;e13473. doi: 10.1111/apha.13473.
9. Wu Y, Xu X, Chen Z, et al. Nervous system involvement after infection with COVID-19 and other coronaviruses [published online March 30, 2020]. Brain Behav Immun. 2020;S0889-1591(20)30357-3. doi: 10.1016/j.bbi.2020.03.031.
10. Mehta P, McAuley DF, Brown M, et al; HLH Across Specialty Collaboration, UK. COVID-19: consider cytokine storm syndromes and immunosuppression. Lancet. 2020;395(10229):1033-1034.
11. McNeil JB, Hughes CG, Girard T, et al. Plasma biomarkers of inflammation, coagulation, and brain injury as predictors of delirium duration in older hospitalized patients. PLoS One. 2019;14(12):e0226412. doi: 10.1371/journal.pone.0226412.
12. Heneka MT, Carson MJ, Khoury JE, et al. Neuroinflammation in Alzheimer’s disease. Lancet Neurol. 2015;14(4):388‐405.
13. Beijing hospital confirms nervous system infections by novel coronavirus. XINHUANET. http://www.xinhuanet.com/english/2020-03/05/c_138846529.htm. Published May 3, 2020. Accessed May 4, 2020.
14. Filatov A, Sharma P, Hindi F, et al. Neurological complications of coronavirus disease (COVID-19): encephalopathy. Cureus. 2020;12(3):e7352. doi: 10.7759/cureus.7352.
15. Poyiadji N, Shahin G, Noujaim D, et al. COVID-19-associated acute hemorrhagic necrotizing encephalopathy: CT and MRI features [published online March 31, 2020]. Radiology. 2020;201187. doi: 10.1148/radiol.2020201187.
16. Karimi N, Razavi AS, Rouhani N. Frequent convulsive seizures in an adult patient with COVID-19: a case report. Iran Red Crescent Med J. 2020;22(3):e102828. doi: 10.5812/ircmj.102828.
17. Zhao H, Shen D, Zhou H, et al. Guillain-Barré syndrome associated with SARS-CoV-2 infection: causality or coincidence? Lancet Neurol. 2020;19(5):383-384.
18. Sasannejad C, Ely EW, Lahiri S. Long-term cognitive impairment after acute respiratory distress syndrome: a review of clinical impact and pathophysiological mechanisms. Crit Care. 2019;23(1):352.
19. Fang Y, Zhang H, Xie J, et al. Sensitivity of chest CT for COVID-19: comparison to RT-PCR [published online February 19, 2020]. Radiology. 2020;200432. doi: 10.1148/radiol.2020200432.
On March 11, 2020, the World Health Organization declared that coronavirus disease 2019 (COVID-19) was a pandemic.1 As of mid-May 2020, the illness had claimed more than 316,000 lives worldwide.2 The main symptoms of the respiratory illness caused by COVID-19 are fever, dry cough, and shortness of breath. However, disorders of consciousness also have been reported, especially in patients who succumb to the illness.3 In fact, approximately one-third of hospitalized COVID-19 patients experience neurologic symptoms.4 Although the most common of these symptoms are dizziness, headache, and loss of smell and taste, patients with more severe cases can experience acute cerebrovascular diseases and impaired consciousness.4 As such, psychiatrists assessing confusion should include COVID-19 in their differential diagnosis as a potential cause of altered mental status.
How COVID-19 might affect the CNS
Although primarily considered a respiratory illness, COVID-19 also may have neurotropic potential. The virus that causes COVID-19, severe acute respiratory syndrome-coronavirus-2 (SARS-CoV-2), is a beta-coronavirus. Two other highly pathogenic coronaviruses—SARS-CoV-1 and Middle East respiratory syndrome–related coronavirus (MERS-CoV)—are also beta-coronaviruses, and both have been reported to invade the CNS in some patients.5 These viruses are thought to invade cells via angiotensin-converting enzyme 2 (ACE2) receptors.6 These receptors are located on the epithelial cells of the respiratory and gastrointestinal (GI) tracts, but also are expressed in certain areas of the brain.7 Transmission to the brain could occur through various routes. However, the clinical symptom of loss of smell and taste hints to possible transmission of the virus from nasal cells to the olfactory bulb via trans-synaptic transmission in olfactory neurons.5,8,9
Immune injury via systemic inflammation is another proposed mechanism for nervous system damage.8,9 This has been described as “cytokine storm syndrome” and provides support to the role of immunotherapy in COVID-19 patients.10 Such inflammation has been long hypothesized as a contributor to psychiatric illnesses, especially neurocognitive disorders.11,12
Neuropsychiatric complications of COVID-19
Disorders of consciousness were identified early as a symptom of COVID-19.3 Subsequent studies and case reports have confirmed impaired consciousness as a possible symptom of COVID-19.4 The first case of encephalitis secondary to COVID-19 was reported by Chinese media on March 5, 2020 in Beijing, China.13 Subsequently, cases of encephalopathy secondary to COVID-19 have been reported in the United States. A 74-year-old man in Boca Raton, Florida who had recently returned from the Netherlands presented with altered mental status and was confirmed positive for COVID-19.14 A female airline worker in her late 50s who presented with altered mental status and tested positive for COVID-19 was found on imaging to have acute hemorrhagic necrotizing encephalopathy.15 There also have been cases of patients with confirmed COVID-19 who initially presented with complaints of seizures16 and Guillain-Barré syndrome.17 As such, neuropsychiatric complications of COVID-19 are being increasingly recognized and are important to consider during psychiatric assessments.
Consider COVID-19 when assessing altered mental status
Psychiatrists are often consulted to assess patients with impaired consciousness, mental status changes, or confusion. Acute changes to mentation raise concern for delirium. In fact, delirium should always be ruled out when assessing new psychiatric symptoms. The astute psychiatrist is aware of the myriad of medical contributors to delirium. However, because knowledge of COVID-19 is in its infancy, it can be easy to overlook this virus as a potential contributor to delirium. Even patients whose confusion seems to be more in line with a major neurocognitive disorder should be evaluated for COVID-19, because the sudden onset of cognitive impairment may be due to hypoxia, inflammatory damage, or cerebrovascular changes secondary to infection with the virus or its respiratory complications, such as acute respiratory distress syndrome (ARDS).18
The most obvious clues to the possible presence of COVID-19 in a patient who is confused would be fever, dry cough, and shortness of breath. Because ACE2 receptors are also located in the GI tract, nausea, vomiting, and diarrhea also are possible. However, patients who are confused may be poor historians, demonstrating behavioral symptoms that might make physical assessments challenging, or simply may be pre- or asymptomatic carriers of the virus. Hence, a thorough review of the patient’s history and collateral information is invaluable. A recent history of travel or contact with COVID-19–positive individuals should raise suspicion for viral infection. A patient who mentions a loss of taste or smell would also alert the psychiatrist to the possibility of COVID-19. A patient might not directly state this information, but may mention that he/she has been eating less or has not been disturbed by odors. Neuroimaging can be useful because patients with severe cases are at increased risk for acute cerebrovascular diseases.4 Also, ordering a chest CT may prove helpful because this testing is highly sensitive for COVID-19.19 If there is sufficient clinical evidence to suspect viral infection, testing for COVID-19 should be performed immediately.
It is important to be vigilant for the possibility of COVID-19 infection in patients who present with confusion. Because the virus is highly contagious, the threshold for COVID-19 testing should be low. Viral infection in patients can manifest in ways other than classic respiratory symptoms. Psychiatrists should be aware of COVID-19’s potential to invade the CNS and cause neuropsychiatric symptoms. When assessing confusion in any setting, the clinical and historical clues for COVID-19 should be kept in mind. This will allow patients with COVID-19 to be quickly diagnosed to initiate appropriate management and minimize progression of the illness. Additionally, this will allow for efficient quarantine of the patient to prevent the spread of the virus to others. As such, psychiatrists can play an important role in containing this virus and resolving the COVID-19 pandemic.
Continue to: Bottom Line
Bottom Line
Although primarily considered a respiratory illness, coronavirus disease 2019 (COVID-19) also may have the potential to invade the CNS and cause neuropsychiatric symptoms, such as impaired consciousness, encephalitis, or a loss of taste or smell. When assessing a patient who presents with confusion, be vigilant for the possibility of COVID-19.
Related Resources
- American Psychiatry Association. APA coronavirus resources. https://www.psychiatry.org/psychiatrists/covid-19-coronavirus#psych.
- Troyer EA, Kohn JN, Hong S. Are we facing a crashing wave of neuropsychiatric sequelae of COVID-19? Neuropsychiatric symptoms and potential immunologic mechanisms. Brain Behav Immun. 2020;S0889-1591(20)30489-X. doi: 10.1016/j.bbi.2020.04.027.
On March 11, 2020, the World Health Organization declared that coronavirus disease 2019 (COVID-19) was a pandemic.1 As of mid-May 2020, the illness had claimed more than 316,000 lives worldwide.2 The main symptoms of the respiratory illness caused by COVID-19 are fever, dry cough, and shortness of breath. However, disorders of consciousness also have been reported, especially in patients who succumb to the illness.3 In fact, approximately one-third of hospitalized COVID-19 patients experience neurologic symptoms.4 Although the most common of these symptoms are dizziness, headache, and loss of smell and taste, patients with more severe cases can experience acute cerebrovascular diseases and impaired consciousness.4 As such, psychiatrists assessing confusion should include COVID-19 in their differential diagnosis as a potential cause of altered mental status.
How COVID-19 might affect the CNS
Although primarily considered a respiratory illness, COVID-19 also may have neurotropic potential. The virus that causes COVID-19, severe acute respiratory syndrome-coronavirus-2 (SARS-CoV-2), is a beta-coronavirus. Two other highly pathogenic coronaviruses—SARS-CoV-1 and Middle East respiratory syndrome–related coronavirus (MERS-CoV)—are also beta-coronaviruses, and both have been reported to invade the CNS in some patients.5 These viruses are thought to invade cells via angiotensin-converting enzyme 2 (ACE2) receptors.6 These receptors are located on the epithelial cells of the respiratory and gastrointestinal (GI) tracts, but also are expressed in certain areas of the brain.7 Transmission to the brain could occur through various routes. However, the clinical symptom of loss of smell and taste hints to possible transmission of the virus from nasal cells to the olfactory bulb via trans-synaptic transmission in olfactory neurons.5,8,9
Immune injury via systemic inflammation is another proposed mechanism for nervous system damage.8,9 This has been described as “cytokine storm syndrome” and provides support to the role of immunotherapy in COVID-19 patients.10 Such inflammation has been long hypothesized as a contributor to psychiatric illnesses, especially neurocognitive disorders.11,12
Neuropsychiatric complications of COVID-19
Disorders of consciousness were identified early as a symptom of COVID-19.3 Subsequent studies and case reports have confirmed impaired consciousness as a possible symptom of COVID-19.4 The first case of encephalitis secondary to COVID-19 was reported by Chinese media on March 5, 2020 in Beijing, China.13 Subsequently, cases of encephalopathy secondary to COVID-19 have been reported in the United States. A 74-year-old man in Boca Raton, Florida who had recently returned from the Netherlands presented with altered mental status and was confirmed positive for COVID-19.14 A female airline worker in her late 50s who presented with altered mental status and tested positive for COVID-19 was found on imaging to have acute hemorrhagic necrotizing encephalopathy.15 There also have been cases of patients with confirmed COVID-19 who initially presented with complaints of seizures16 and Guillain-Barré syndrome.17 As such, neuropsychiatric complications of COVID-19 are being increasingly recognized and are important to consider during psychiatric assessments.
Consider COVID-19 when assessing altered mental status
Psychiatrists are often consulted to assess patients with impaired consciousness, mental status changes, or confusion. Acute changes to mentation raise concern for delirium. In fact, delirium should always be ruled out when assessing new psychiatric symptoms. The astute psychiatrist is aware of the myriad of medical contributors to delirium. However, because knowledge of COVID-19 is in its infancy, it can be easy to overlook this virus as a potential contributor to delirium. Even patients whose confusion seems to be more in line with a major neurocognitive disorder should be evaluated for COVID-19, because the sudden onset of cognitive impairment may be due to hypoxia, inflammatory damage, or cerebrovascular changes secondary to infection with the virus or its respiratory complications, such as acute respiratory distress syndrome (ARDS).18
The most obvious clues to the possible presence of COVID-19 in a patient who is confused would be fever, dry cough, and shortness of breath. Because ACE2 receptors are also located in the GI tract, nausea, vomiting, and diarrhea also are possible. However, patients who are confused may be poor historians, demonstrating behavioral symptoms that might make physical assessments challenging, or simply may be pre- or asymptomatic carriers of the virus. Hence, a thorough review of the patient’s history and collateral information is invaluable. A recent history of travel or contact with COVID-19–positive individuals should raise suspicion for viral infection. A patient who mentions a loss of taste or smell would also alert the psychiatrist to the possibility of COVID-19. A patient might not directly state this information, but may mention that he/she has been eating less or has not been disturbed by odors. Neuroimaging can be useful because patients with severe cases are at increased risk for acute cerebrovascular diseases.4 Also, ordering a chest CT may prove helpful because this testing is highly sensitive for COVID-19.19 If there is sufficient clinical evidence to suspect viral infection, testing for COVID-19 should be performed immediately.
It is important to be vigilant for the possibility of COVID-19 infection in patients who present with confusion. Because the virus is highly contagious, the threshold for COVID-19 testing should be low. Viral infection in patients can manifest in ways other than classic respiratory symptoms. Psychiatrists should be aware of COVID-19’s potential to invade the CNS and cause neuropsychiatric symptoms. When assessing confusion in any setting, the clinical and historical clues for COVID-19 should be kept in mind. This will allow patients with COVID-19 to be quickly diagnosed to initiate appropriate management and minimize progression of the illness. Additionally, this will allow for efficient quarantine of the patient to prevent the spread of the virus to others. As such, psychiatrists can play an important role in containing this virus and resolving the COVID-19 pandemic.
Continue to: Bottom Line
Bottom Line
Although primarily considered a respiratory illness, coronavirus disease 2019 (COVID-19) also may have the potential to invade the CNS and cause neuropsychiatric symptoms, such as impaired consciousness, encephalitis, or a loss of taste or smell. When assessing a patient who presents with confusion, be vigilant for the possibility of COVID-19.
Related Resources
- American Psychiatry Association. APA coronavirus resources. https://www.psychiatry.org/psychiatrists/covid-19-coronavirus#psych.
- Troyer EA, Kohn JN, Hong S. Are we facing a crashing wave of neuropsychiatric sequelae of COVID-19? Neuropsychiatric symptoms and potential immunologic mechanisms. Brain Behav Immun. 2020;S0889-1591(20)30489-X. doi: 10.1016/j.bbi.2020.04.027.
1. World Health Organization. Rolling updates on coronavirus disease (COVID-19). https://www.who.int/emergencies/diseases/novel-coronavirus-2019/events-as-they-happen. Updated May 1, 2020. Accessed May 4, 2020.
2. John Hopkins University. Coronavirus resource center. World map. https://coronavirus.jhu.edu/map.html. Accessed May 4, 2020.
3. Chen T, Wu D, Chen H, et al. Clinical characteristics of 113 deceased patients with coronavirus disease 2019: retrospective study. BMJ. 2020;368:m1091. doi: 10.1136/bmj.m1091.
4. Mao L, Wang M, Chen S, et al. Neurologic manifestations of hospitalized patients with COVID-19 in Wuhan, China: a retrospective case series study [published online February 25, 2020]. JAMA Neurol. 2020;e201127. doi: 10.1101/2020.02.22.20026500.
5. Li YC, Bai WZ, Hashikawa T. The neuroinvasive potential of SARS-CoV2 may play a role in the respiratory failure of COVID-19 patients [published online February 27, 2020]. J Med Virol. 2020;92(6). doi: 10.1002/jmv.25728.
6. Baig AM, Khaleeq A, Ali E, et al. Evidence of the COVID-19 virus targeting the CNS: tissue distribution, host-virus interaction, and proposed neurotropic mechanisms. ACS Chem Neurosci. 2020;11(7):995-998.
7. Xia H, Lazartigues E. Angiotensin-converting enzyme 2: central regulator for cardiovascular function. Curr Hypertens Rep. 2010;12(3):170-175.
8. Steardo L, Steardo L Jr, Zorec R, et al. Neuroinfection may contribute to pathophysiology and clinical manifestations of COVID-19 [published online March 29, 2020]. Acta Physiol (Oxf). 2020;e13473. doi: 10.1111/apha.13473.
9. Wu Y, Xu X, Chen Z, et al. Nervous system involvement after infection with COVID-19 and other coronaviruses [published online March 30, 2020]. Brain Behav Immun. 2020;S0889-1591(20)30357-3. doi: 10.1016/j.bbi.2020.03.031.
10. Mehta P, McAuley DF, Brown M, et al; HLH Across Specialty Collaboration, UK. COVID-19: consider cytokine storm syndromes and immunosuppression. Lancet. 2020;395(10229):1033-1034.
11. McNeil JB, Hughes CG, Girard T, et al. Plasma biomarkers of inflammation, coagulation, and brain injury as predictors of delirium duration in older hospitalized patients. PLoS One. 2019;14(12):e0226412. doi: 10.1371/journal.pone.0226412.
12. Heneka MT, Carson MJ, Khoury JE, et al. Neuroinflammation in Alzheimer’s disease. Lancet Neurol. 2015;14(4):388‐405.
13. Beijing hospital confirms nervous system infections by novel coronavirus. XINHUANET. http://www.xinhuanet.com/english/2020-03/05/c_138846529.htm. Published May 3, 2020. Accessed May 4, 2020.
14. Filatov A, Sharma P, Hindi F, et al. Neurological complications of coronavirus disease (COVID-19): encephalopathy. Cureus. 2020;12(3):e7352. doi: 10.7759/cureus.7352.
15. Poyiadji N, Shahin G, Noujaim D, et al. COVID-19-associated acute hemorrhagic necrotizing encephalopathy: CT and MRI features [published online March 31, 2020]. Radiology. 2020;201187. doi: 10.1148/radiol.2020201187.
16. Karimi N, Razavi AS, Rouhani N. Frequent convulsive seizures in an adult patient with COVID-19: a case report. Iran Red Crescent Med J. 2020;22(3):e102828. doi: 10.5812/ircmj.102828.
17. Zhao H, Shen D, Zhou H, et al. Guillain-Barré syndrome associated with SARS-CoV-2 infection: causality or coincidence? Lancet Neurol. 2020;19(5):383-384.
18. Sasannejad C, Ely EW, Lahiri S. Long-term cognitive impairment after acute respiratory distress syndrome: a review of clinical impact and pathophysiological mechanisms. Crit Care. 2019;23(1):352.
19. Fang Y, Zhang H, Xie J, et al. Sensitivity of chest CT for COVID-19: comparison to RT-PCR [published online February 19, 2020]. Radiology. 2020;200432. doi: 10.1148/radiol.2020200432.
1. World Health Organization. Rolling updates on coronavirus disease (COVID-19). https://www.who.int/emergencies/diseases/novel-coronavirus-2019/events-as-they-happen. Updated May 1, 2020. Accessed May 4, 2020.
2. John Hopkins University. Coronavirus resource center. World map. https://coronavirus.jhu.edu/map.html. Accessed May 4, 2020.
3. Chen T, Wu D, Chen H, et al. Clinical characteristics of 113 deceased patients with coronavirus disease 2019: retrospective study. BMJ. 2020;368:m1091. doi: 10.1136/bmj.m1091.
4. Mao L, Wang M, Chen S, et al. Neurologic manifestations of hospitalized patients with COVID-19 in Wuhan, China: a retrospective case series study [published online February 25, 2020]. JAMA Neurol. 2020;e201127. doi: 10.1101/2020.02.22.20026500.
5. Li YC, Bai WZ, Hashikawa T. The neuroinvasive potential of SARS-CoV2 may play a role in the respiratory failure of COVID-19 patients [published online February 27, 2020]. J Med Virol. 2020;92(6). doi: 10.1002/jmv.25728.
6. Baig AM, Khaleeq A, Ali E, et al. Evidence of the COVID-19 virus targeting the CNS: tissue distribution, host-virus interaction, and proposed neurotropic mechanisms. ACS Chem Neurosci. 2020;11(7):995-998.
7. Xia H, Lazartigues E. Angiotensin-converting enzyme 2: central regulator for cardiovascular function. Curr Hypertens Rep. 2010;12(3):170-175.
8. Steardo L, Steardo L Jr, Zorec R, et al. Neuroinfection may contribute to pathophysiology and clinical manifestations of COVID-19 [published online March 29, 2020]. Acta Physiol (Oxf). 2020;e13473. doi: 10.1111/apha.13473.
9. Wu Y, Xu X, Chen Z, et al. Nervous system involvement after infection with COVID-19 and other coronaviruses [published online March 30, 2020]. Brain Behav Immun. 2020;S0889-1591(20)30357-3. doi: 10.1016/j.bbi.2020.03.031.
10. Mehta P, McAuley DF, Brown M, et al; HLH Across Specialty Collaboration, UK. COVID-19: consider cytokine storm syndromes and immunosuppression. Lancet. 2020;395(10229):1033-1034.
11. McNeil JB, Hughes CG, Girard T, et al. Plasma biomarkers of inflammation, coagulation, and brain injury as predictors of delirium duration in older hospitalized patients. PLoS One. 2019;14(12):e0226412. doi: 10.1371/journal.pone.0226412.
12. Heneka MT, Carson MJ, Khoury JE, et al. Neuroinflammation in Alzheimer’s disease. Lancet Neurol. 2015;14(4):388‐405.
13. Beijing hospital confirms nervous system infections by novel coronavirus. XINHUANET. http://www.xinhuanet.com/english/2020-03/05/c_138846529.htm. Published May 3, 2020. Accessed May 4, 2020.
14. Filatov A, Sharma P, Hindi F, et al. Neurological complications of coronavirus disease (COVID-19): encephalopathy. Cureus. 2020;12(3):e7352. doi: 10.7759/cureus.7352.
15. Poyiadji N, Shahin G, Noujaim D, et al. COVID-19-associated acute hemorrhagic necrotizing encephalopathy: CT and MRI features [published online March 31, 2020]. Radiology. 2020;201187. doi: 10.1148/radiol.2020201187.
16. Karimi N, Razavi AS, Rouhani N. Frequent convulsive seizures in an adult patient with COVID-19: a case report. Iran Red Crescent Med J. 2020;22(3):e102828. doi: 10.5812/ircmj.102828.
17. Zhao H, Shen D, Zhou H, et al. Guillain-Barré syndrome associated with SARS-CoV-2 infection: causality or coincidence? Lancet Neurol. 2020;19(5):383-384.
18. Sasannejad C, Ely EW, Lahiri S. Long-term cognitive impairment after acute respiratory distress syndrome: a review of clinical impact and pathophysiological mechanisms. Crit Care. 2019;23(1):352.
19. Fang Y, Zhang H, Xie J, et al. Sensitivity of chest CT for COVID-19: comparison to RT-PCR [published online February 19, 2020]. Radiology. 2020;200432. doi: 10.1148/radiol.2020200432.
Patient-focused precautions, testing help blunt pandemic effects on heme-onc unit
Keeping hematologic oncology patients on their treatment regimens and caring for inpatients with hematologic malignancies remained “manageable” during the first 2 months of the COVID-19 pandemic at Levine Cancer Institute in Charlotte, N.C.
That level of manageability has partly been because a surge in cases so far hasn’t arrived at Levine or in most of the surrounding North Carolina and South Carolina communities it serves. As of May 15, 2020, the total number of confirmed and reported COVID-19 cases had reached about 19,000 in North Carolina, and just under 9,000 in South Carolina, out of a total population in the two states of close to 16 million. What’s happened instead at Levine Cancer Institute (LCI) has been a steady but low drumbeat of cases that, by mid-May 2020, totaled fewer than 10 patients with hematologic malignancies diagnosed with COVID-19.
“For a large system with multiple sites throughout North and South Carolina that saw 17,200 new patients in 2019 – including solid tumor, benign hematology, and malignant hematology patients – with 198,000 total patient visits, it is safe to say that we are off to a good start. However, we remain in the early throes of the pandemic and we will need to remain vigilant going forward,” said Peter Voorhees, MD, professor of medicine and director of Medical Operations and Outreach Services in LCI’s Department of Hematologic Oncology and Blood Disorders.
The limited effects to date of COVID-19 at LCI has been thanks to a regimen of great caution for preventing infections that’s been consistently conveyed to LCI patients from before the pandemic’s onset, liberal testing that started early, a proactive plan to defer and temporarily replace infusion care when medically appropriate, a novel staffing approach designed to minimize and contain potential staff outbreaks, and an early pivot to virtual patient contact when feasible.
COVID-19 has had limited penetration into the LCI case load because patients have, in general, “been very careful,” said Dr. Voorhees.
“My impression is that the incidence has been low partly because our patients, especially those with hematologic malignancies including those on active chemotherapy, were already getting warned to be cautious even before the coronavirus using distancing, masking, and meticulous hand hygiene,” he said in an interview that reviewed the steps LCI took starting in March to confront and manage the effects of the then-nascent pandemic. “Since we started screening asymptomatic patients in the inpatient and outpatient settings we have identified only one patient with COVID-19 infection, which supports the low rate of infection in our patient population thus far.”
Another key step was the launch of “robust” testing for the COVID-19 virus starting on March 9, using an in-house assay from LCI’s parent health system, Atrium Health, that delivered results within 24 hours. Testing became available at LCI “earlier than at many other health systems.” At first, testing was limited to patients or staff presenting with symptoms, but in the following weeks, it expanded to more patients, including those without symptoms who were scheduled for treatment at the apheresis center, cell donors and cell recipients, patients arriving for inpatient chemotherapy or cellular therapy, patients arriving from a skilled nursing facility or similar environments, and more recently, outpatient chemotherapy patients. “We’re now doing a lot of screening,” Dr. Voorhees said. “In general, screening has been well received because patients recognize that it’s for their own safety.”
Another piece of COVID-19 preparedness was a move toward technology as an alternative to face-to-face encounters between patients and staff. “We adopted virtual technology early.” When medically appropriate, they provided either video consultations with more tech-savvy patients or telephone-based virtual visits for patients who preferred a more familiar interface. As LCI starts the process of reentry for patients whose face-to-face encounters were deferred, virtual visits will remain an important facet of maintaining care while limiting exposure for appropriate patients and facilitating adequate space for social distancing in the clinics and infusion centers.
Atrium Health also launched a “virtual hospital” geared to intensified remote management of COVID-19 patients who aren’t sick enough for hospitalization. “People who test positive automatically enter the virtual hospital and have regular interactions with their team of providers,” with LCI providing additional support for their patients who get infected. Patients receive an equipment kit that lets them monitor and transmit their vital signs. The virtual hospital program also helps expedite personal needs like delivery of prescriptions and food. “It helps patients manage at home, and has been incredibly useful,” said Dr. Voorhees.
Perhaps the most challenging step LCI clinicians took to preclude a potential COVID-19 case surge was to review all patients receiving infusional therapy or planned cellular therapy and triage those who could potentially tolerate a temporary change to either an oral, at-home regimen or to a brief hold on their treatment. Some patients on maintenance, outpatient infusion-therapy regimens “expressed concern about coming to the clinic. We looked at the patients scheduled to come for infusions and decided which visits were essential and which were deferrable without disrupting care by briefly using a noninfusional approach,” said Dr. Voorhees. The number of patients who had their regimens modified or held was “relatively small,” and with the recent recognition that a surge of infections has not occurred, “we’re now rolling out cautious reentry of those patients back to their originally prescribed chemotherapy.”
In addition to concerns of exposure at infusion clinics, there are concerns about the heightened susceptibility of immunosuppressed hematologic oncology patients to COVID-19 and their risk for more severe infection. “Our view is that, if patients tested positive, continuing immunosuppressive treatment would likely be detrimental,” so when possible treatment is temporarily suspended and then resumed when the infection has cleared. “When patients test positive for a prolonged period, a decision to resume treatment must be in the best interests of the patient and weigh the benefits of resuming therapy against the risks of incurring a more severe infection by restarting potentially immunosuppressive therapy,” Dr. Voorhees said.
The enhanced risk that cancer patients face if they develop COVID-19 was documented in a recent review of 218 cancer patients hospitalized for COVID-19 during parts of March and April in a large New York health system. The results showed an overall mortality rate of 28%, including a 37% rate among 54 patients with hematologic malignancies and a 25% rate among 164 patients with solid tumors. The mortality rate “may not be quite as high as they reported because that depends on how many patients you test, but there is no question that patients with more comorbidities are at higher risk. Patients with active cancer on chemotherapy are a particularly vulnerable population, and many have expressed concerns about their vulnerability,” he observed.
For the few LCI patients who developed COVID-19 infection, the medical staff has had several therapeutic options they could match to each patient’s needs, with help from the Atrium Health infectious disease team. LCI and Atrium Health are participating in several COVID-19 clinical treatment trials, including an investigational convalescent plasma protocol spearheaded by the Mayo Clinic. They have also opened a randomized, phase 2 trial evaluating the safety and efficacy of selinexor (Xpovio), an oral drug that’s Food and Drug Administration approved for patients with multiple myeloma, for treatment of moderate or severe COVID-19 infection. Additional studies evaluating blockade of granulocyte-macrophage colony-stimulating factor, as well as inhaled antiviral therapy, have recently launched, and several additional studies are poised to open in the coming weeks.
The LCI and Atrium Health team also has a supply of the antiviral agent remdesivir as part of the FDA’s expanded access protocol and emergency use authorization. They also have a supply of and experience administering the interleukin-6 receptor inhibitor tocilizumab (Actemra), which showed some suggestion of efficacy in limited experience treating patients with severe or critical COVID-19 infections. Clinicians at LCI have not used the investigational and unproven agents hydroxychloroquine, chloroquine, and azithromycin to either prevent or treat COVID-19.
LCI also instituted measures to try to minimize the risk that staff members could become infected and transmit the virus while asymptomatic. Following conversations held early on with COVID-19–experienced health authorities in China and Italy, the patient-facing LCI staff split into two teams starting on March 23 that alternated responsibility for direct patient interactions every 2 weeks. When one of these teams was off from direct patient contact they continued to care for patients remotely through virtual technologies. The concept was that, if a staffer became infected while remaining asymptomatic during their contact with patients, their status would either become diagnosable or resolve during their 2 weeks away from seeing any patients. Perhaps in part because of this approach infections among staff members “have not been a big issue. We’ve had an incredibly low infection rate among the LCI staff,” Dr. Voorhees noted.
By mid-May, with the imminent threat of a sudden CODIV-19 surge moderated, heme-onc operations at LCI began to cautiously revert to more normal operations. “We’re continuing patient screening for signs and symptoms of COVID-19 infection, testing for asymptomatic infections, and requiring masking and social distancing in the clinics and hospitals, but we’re starting to slowly restore the number of patients at our clinics [virtual and face to face[ and infusion centers,” and the staff’s division into two teams ended. “The idea was to get past a surge and make sure our system was not overwhelmed. We anticipated a local surge in late April, but then it kept getting pushed back. Current projections are for the infection rate among LCI patients to remain low provided that community spread remains stable or, ideally, decreases.” The LCI infectious disease staff is closely monitoring infection rates for early recognition of an outbreak, with plans to follow any new cases with contact tracing. So far, the COVID-19 pandemic at LCI “has been very manageable,” Dr. Voorhees concluded.
“We’re now better positioned to deal with a case surge if it were to happen. We could resume the two-team approach, hospital-wide plans are now in place for a future surge, and we are now up and running with robust testing and inpatient and outpatient virtual technology. The first time, we were all learning on the fly.”
The LCI biostatistics team has been prospectively collecting the Institutes’s COVID-19 patient data, with plans to report their findings.
Dr. Voorhees has had financial relationships with Bristol-Myers Squibb/Celgene, Janssen, Novartis, and Oncopeptides, none of which are relevant to this article.
Keeping hematologic oncology patients on their treatment regimens and caring for inpatients with hematologic malignancies remained “manageable” during the first 2 months of the COVID-19 pandemic at Levine Cancer Institute in Charlotte, N.C.
That level of manageability has partly been because a surge in cases so far hasn’t arrived at Levine or in most of the surrounding North Carolina and South Carolina communities it serves. As of May 15, 2020, the total number of confirmed and reported COVID-19 cases had reached about 19,000 in North Carolina, and just under 9,000 in South Carolina, out of a total population in the two states of close to 16 million. What’s happened instead at Levine Cancer Institute (LCI) has been a steady but low drumbeat of cases that, by mid-May 2020, totaled fewer than 10 patients with hematologic malignancies diagnosed with COVID-19.
“For a large system with multiple sites throughout North and South Carolina that saw 17,200 new patients in 2019 – including solid tumor, benign hematology, and malignant hematology patients – with 198,000 total patient visits, it is safe to say that we are off to a good start. However, we remain in the early throes of the pandemic and we will need to remain vigilant going forward,” said Peter Voorhees, MD, professor of medicine and director of Medical Operations and Outreach Services in LCI’s Department of Hematologic Oncology and Blood Disorders.
The limited effects to date of COVID-19 at LCI has been thanks to a regimen of great caution for preventing infections that’s been consistently conveyed to LCI patients from before the pandemic’s onset, liberal testing that started early, a proactive plan to defer and temporarily replace infusion care when medically appropriate, a novel staffing approach designed to minimize and contain potential staff outbreaks, and an early pivot to virtual patient contact when feasible.
COVID-19 has had limited penetration into the LCI case load because patients have, in general, “been very careful,” said Dr. Voorhees.
“My impression is that the incidence has been low partly because our patients, especially those with hematologic malignancies including those on active chemotherapy, were already getting warned to be cautious even before the coronavirus using distancing, masking, and meticulous hand hygiene,” he said in an interview that reviewed the steps LCI took starting in March to confront and manage the effects of the then-nascent pandemic. “Since we started screening asymptomatic patients in the inpatient and outpatient settings we have identified only one patient with COVID-19 infection, which supports the low rate of infection in our patient population thus far.”
Another key step was the launch of “robust” testing for the COVID-19 virus starting on March 9, using an in-house assay from LCI’s parent health system, Atrium Health, that delivered results within 24 hours. Testing became available at LCI “earlier than at many other health systems.” At first, testing was limited to patients or staff presenting with symptoms, but in the following weeks, it expanded to more patients, including those without symptoms who were scheduled for treatment at the apheresis center, cell donors and cell recipients, patients arriving for inpatient chemotherapy or cellular therapy, patients arriving from a skilled nursing facility or similar environments, and more recently, outpatient chemotherapy patients. “We’re now doing a lot of screening,” Dr. Voorhees said. “In general, screening has been well received because patients recognize that it’s for their own safety.”
Another piece of COVID-19 preparedness was a move toward technology as an alternative to face-to-face encounters between patients and staff. “We adopted virtual technology early.” When medically appropriate, they provided either video consultations with more tech-savvy patients or telephone-based virtual visits for patients who preferred a more familiar interface. As LCI starts the process of reentry for patients whose face-to-face encounters were deferred, virtual visits will remain an important facet of maintaining care while limiting exposure for appropriate patients and facilitating adequate space for social distancing in the clinics and infusion centers.
Atrium Health also launched a “virtual hospital” geared to intensified remote management of COVID-19 patients who aren’t sick enough for hospitalization. “People who test positive automatically enter the virtual hospital and have regular interactions with their team of providers,” with LCI providing additional support for their patients who get infected. Patients receive an equipment kit that lets them monitor and transmit their vital signs. The virtual hospital program also helps expedite personal needs like delivery of prescriptions and food. “It helps patients manage at home, and has been incredibly useful,” said Dr. Voorhees.
Perhaps the most challenging step LCI clinicians took to preclude a potential COVID-19 case surge was to review all patients receiving infusional therapy or planned cellular therapy and triage those who could potentially tolerate a temporary change to either an oral, at-home regimen or to a brief hold on their treatment. Some patients on maintenance, outpatient infusion-therapy regimens “expressed concern about coming to the clinic. We looked at the patients scheduled to come for infusions and decided which visits were essential and which were deferrable without disrupting care by briefly using a noninfusional approach,” said Dr. Voorhees. The number of patients who had their regimens modified or held was “relatively small,” and with the recent recognition that a surge of infections has not occurred, “we’re now rolling out cautious reentry of those patients back to their originally prescribed chemotherapy.”
In addition to concerns of exposure at infusion clinics, there are concerns about the heightened susceptibility of immunosuppressed hematologic oncology patients to COVID-19 and their risk for more severe infection. “Our view is that, if patients tested positive, continuing immunosuppressive treatment would likely be detrimental,” so when possible treatment is temporarily suspended and then resumed when the infection has cleared. “When patients test positive for a prolonged period, a decision to resume treatment must be in the best interests of the patient and weigh the benefits of resuming therapy against the risks of incurring a more severe infection by restarting potentially immunosuppressive therapy,” Dr. Voorhees said.
The enhanced risk that cancer patients face if they develop COVID-19 was documented in a recent review of 218 cancer patients hospitalized for COVID-19 during parts of March and April in a large New York health system. The results showed an overall mortality rate of 28%, including a 37% rate among 54 patients with hematologic malignancies and a 25% rate among 164 patients with solid tumors. The mortality rate “may not be quite as high as they reported because that depends on how many patients you test, but there is no question that patients with more comorbidities are at higher risk. Patients with active cancer on chemotherapy are a particularly vulnerable population, and many have expressed concerns about their vulnerability,” he observed.
For the few LCI patients who developed COVID-19 infection, the medical staff has had several therapeutic options they could match to each patient’s needs, with help from the Atrium Health infectious disease team. LCI and Atrium Health are participating in several COVID-19 clinical treatment trials, including an investigational convalescent plasma protocol spearheaded by the Mayo Clinic. They have also opened a randomized, phase 2 trial evaluating the safety and efficacy of selinexor (Xpovio), an oral drug that’s Food and Drug Administration approved for patients with multiple myeloma, for treatment of moderate or severe COVID-19 infection. Additional studies evaluating blockade of granulocyte-macrophage colony-stimulating factor, as well as inhaled antiviral therapy, have recently launched, and several additional studies are poised to open in the coming weeks.
The LCI and Atrium Health team also has a supply of the antiviral agent remdesivir as part of the FDA’s expanded access protocol and emergency use authorization. They also have a supply of and experience administering the interleukin-6 receptor inhibitor tocilizumab (Actemra), which showed some suggestion of efficacy in limited experience treating patients with severe or critical COVID-19 infections. Clinicians at LCI have not used the investigational and unproven agents hydroxychloroquine, chloroquine, and azithromycin to either prevent or treat COVID-19.
LCI also instituted measures to try to minimize the risk that staff members could become infected and transmit the virus while asymptomatic. Following conversations held early on with COVID-19–experienced health authorities in China and Italy, the patient-facing LCI staff split into two teams starting on March 23 that alternated responsibility for direct patient interactions every 2 weeks. When one of these teams was off from direct patient contact they continued to care for patients remotely through virtual technologies. The concept was that, if a staffer became infected while remaining asymptomatic during their contact with patients, their status would either become diagnosable or resolve during their 2 weeks away from seeing any patients. Perhaps in part because of this approach infections among staff members “have not been a big issue. We’ve had an incredibly low infection rate among the LCI staff,” Dr. Voorhees noted.
By mid-May, with the imminent threat of a sudden CODIV-19 surge moderated, heme-onc operations at LCI began to cautiously revert to more normal operations. “We’re continuing patient screening for signs and symptoms of COVID-19 infection, testing for asymptomatic infections, and requiring masking and social distancing in the clinics and hospitals, but we’re starting to slowly restore the number of patients at our clinics [virtual and face to face[ and infusion centers,” and the staff’s division into two teams ended. “The idea was to get past a surge and make sure our system was not overwhelmed. We anticipated a local surge in late April, but then it kept getting pushed back. Current projections are for the infection rate among LCI patients to remain low provided that community spread remains stable or, ideally, decreases.” The LCI infectious disease staff is closely monitoring infection rates for early recognition of an outbreak, with plans to follow any new cases with contact tracing. So far, the COVID-19 pandemic at LCI “has been very manageable,” Dr. Voorhees concluded.
“We’re now better positioned to deal with a case surge if it were to happen. We could resume the two-team approach, hospital-wide plans are now in place for a future surge, and we are now up and running with robust testing and inpatient and outpatient virtual technology. The first time, we were all learning on the fly.”
The LCI biostatistics team has been prospectively collecting the Institutes’s COVID-19 patient data, with plans to report their findings.
Dr. Voorhees has had financial relationships with Bristol-Myers Squibb/Celgene, Janssen, Novartis, and Oncopeptides, none of which are relevant to this article.
Keeping hematologic oncology patients on their treatment regimens and caring for inpatients with hematologic malignancies remained “manageable” during the first 2 months of the COVID-19 pandemic at Levine Cancer Institute in Charlotte, N.C.
That level of manageability has partly been because a surge in cases so far hasn’t arrived at Levine or in most of the surrounding North Carolina and South Carolina communities it serves. As of May 15, 2020, the total number of confirmed and reported COVID-19 cases had reached about 19,000 in North Carolina, and just under 9,000 in South Carolina, out of a total population in the two states of close to 16 million. What’s happened instead at Levine Cancer Institute (LCI) has been a steady but low drumbeat of cases that, by mid-May 2020, totaled fewer than 10 patients with hematologic malignancies diagnosed with COVID-19.
“For a large system with multiple sites throughout North and South Carolina that saw 17,200 new patients in 2019 – including solid tumor, benign hematology, and malignant hematology patients – with 198,000 total patient visits, it is safe to say that we are off to a good start. However, we remain in the early throes of the pandemic and we will need to remain vigilant going forward,” said Peter Voorhees, MD, professor of medicine and director of Medical Operations and Outreach Services in LCI’s Department of Hematologic Oncology and Blood Disorders.
The limited effects to date of COVID-19 at LCI has been thanks to a regimen of great caution for preventing infections that’s been consistently conveyed to LCI patients from before the pandemic’s onset, liberal testing that started early, a proactive plan to defer and temporarily replace infusion care when medically appropriate, a novel staffing approach designed to minimize and contain potential staff outbreaks, and an early pivot to virtual patient contact when feasible.
COVID-19 has had limited penetration into the LCI case load because patients have, in general, “been very careful,” said Dr. Voorhees.
“My impression is that the incidence has been low partly because our patients, especially those with hematologic malignancies including those on active chemotherapy, were already getting warned to be cautious even before the coronavirus using distancing, masking, and meticulous hand hygiene,” he said in an interview that reviewed the steps LCI took starting in March to confront and manage the effects of the then-nascent pandemic. “Since we started screening asymptomatic patients in the inpatient and outpatient settings we have identified only one patient with COVID-19 infection, which supports the low rate of infection in our patient population thus far.”
Another key step was the launch of “robust” testing for the COVID-19 virus starting on March 9, using an in-house assay from LCI’s parent health system, Atrium Health, that delivered results within 24 hours. Testing became available at LCI “earlier than at many other health systems.” At first, testing was limited to patients or staff presenting with symptoms, but in the following weeks, it expanded to more patients, including those without symptoms who were scheduled for treatment at the apheresis center, cell donors and cell recipients, patients arriving for inpatient chemotherapy or cellular therapy, patients arriving from a skilled nursing facility or similar environments, and more recently, outpatient chemotherapy patients. “We’re now doing a lot of screening,” Dr. Voorhees said. “In general, screening has been well received because patients recognize that it’s for their own safety.”
Another piece of COVID-19 preparedness was a move toward technology as an alternative to face-to-face encounters between patients and staff. “We adopted virtual technology early.” When medically appropriate, they provided either video consultations with more tech-savvy patients or telephone-based virtual visits for patients who preferred a more familiar interface. As LCI starts the process of reentry for patients whose face-to-face encounters were deferred, virtual visits will remain an important facet of maintaining care while limiting exposure for appropriate patients and facilitating adequate space for social distancing in the clinics and infusion centers.
Atrium Health also launched a “virtual hospital” geared to intensified remote management of COVID-19 patients who aren’t sick enough for hospitalization. “People who test positive automatically enter the virtual hospital and have regular interactions with their team of providers,” with LCI providing additional support for their patients who get infected. Patients receive an equipment kit that lets them monitor and transmit their vital signs. The virtual hospital program also helps expedite personal needs like delivery of prescriptions and food. “It helps patients manage at home, and has been incredibly useful,” said Dr. Voorhees.
Perhaps the most challenging step LCI clinicians took to preclude a potential COVID-19 case surge was to review all patients receiving infusional therapy or planned cellular therapy and triage those who could potentially tolerate a temporary change to either an oral, at-home regimen or to a brief hold on their treatment. Some patients on maintenance, outpatient infusion-therapy regimens “expressed concern about coming to the clinic. We looked at the patients scheduled to come for infusions and decided which visits were essential and which were deferrable without disrupting care by briefly using a noninfusional approach,” said Dr. Voorhees. The number of patients who had their regimens modified or held was “relatively small,” and with the recent recognition that a surge of infections has not occurred, “we’re now rolling out cautious reentry of those patients back to their originally prescribed chemotherapy.”
In addition to concerns of exposure at infusion clinics, there are concerns about the heightened susceptibility of immunosuppressed hematologic oncology patients to COVID-19 and their risk for more severe infection. “Our view is that, if patients tested positive, continuing immunosuppressive treatment would likely be detrimental,” so when possible treatment is temporarily suspended and then resumed when the infection has cleared. “When patients test positive for a prolonged period, a decision to resume treatment must be in the best interests of the patient and weigh the benefits of resuming therapy against the risks of incurring a more severe infection by restarting potentially immunosuppressive therapy,” Dr. Voorhees said.
The enhanced risk that cancer patients face if they develop COVID-19 was documented in a recent review of 218 cancer patients hospitalized for COVID-19 during parts of March and April in a large New York health system. The results showed an overall mortality rate of 28%, including a 37% rate among 54 patients with hematologic malignancies and a 25% rate among 164 patients with solid tumors. The mortality rate “may not be quite as high as they reported because that depends on how many patients you test, but there is no question that patients with more comorbidities are at higher risk. Patients with active cancer on chemotherapy are a particularly vulnerable population, and many have expressed concerns about their vulnerability,” he observed.
For the few LCI patients who developed COVID-19 infection, the medical staff has had several therapeutic options they could match to each patient’s needs, with help from the Atrium Health infectious disease team. LCI and Atrium Health are participating in several COVID-19 clinical treatment trials, including an investigational convalescent plasma protocol spearheaded by the Mayo Clinic. They have also opened a randomized, phase 2 trial evaluating the safety and efficacy of selinexor (Xpovio), an oral drug that’s Food and Drug Administration approved for patients with multiple myeloma, for treatment of moderate or severe COVID-19 infection. Additional studies evaluating blockade of granulocyte-macrophage colony-stimulating factor, as well as inhaled antiviral therapy, have recently launched, and several additional studies are poised to open in the coming weeks.
The LCI and Atrium Health team also has a supply of the antiviral agent remdesivir as part of the FDA’s expanded access protocol and emergency use authorization. They also have a supply of and experience administering the interleukin-6 receptor inhibitor tocilizumab (Actemra), which showed some suggestion of efficacy in limited experience treating patients with severe or critical COVID-19 infections. Clinicians at LCI have not used the investigational and unproven agents hydroxychloroquine, chloroquine, and azithromycin to either prevent or treat COVID-19.
LCI also instituted measures to try to minimize the risk that staff members could become infected and transmit the virus while asymptomatic. Following conversations held early on with COVID-19–experienced health authorities in China and Italy, the patient-facing LCI staff split into two teams starting on March 23 that alternated responsibility for direct patient interactions every 2 weeks. When one of these teams was off from direct patient contact they continued to care for patients remotely through virtual technologies. The concept was that, if a staffer became infected while remaining asymptomatic during their contact with patients, their status would either become diagnosable or resolve during their 2 weeks away from seeing any patients. Perhaps in part because of this approach infections among staff members “have not been a big issue. We’ve had an incredibly low infection rate among the LCI staff,” Dr. Voorhees noted.
By mid-May, with the imminent threat of a sudden CODIV-19 surge moderated, heme-onc operations at LCI began to cautiously revert to more normal operations. “We’re continuing patient screening for signs and symptoms of COVID-19 infection, testing for asymptomatic infections, and requiring masking and social distancing in the clinics and hospitals, but we’re starting to slowly restore the number of patients at our clinics [virtual and face to face[ and infusion centers,” and the staff’s division into two teams ended. “The idea was to get past a surge and make sure our system was not overwhelmed. We anticipated a local surge in late April, but then it kept getting pushed back. Current projections are for the infection rate among LCI patients to remain low provided that community spread remains stable or, ideally, decreases.” The LCI infectious disease staff is closely monitoring infection rates for early recognition of an outbreak, with plans to follow any new cases with contact tracing. So far, the COVID-19 pandemic at LCI “has been very manageable,” Dr. Voorhees concluded.
“We’re now better positioned to deal with a case surge if it were to happen. We could resume the two-team approach, hospital-wide plans are now in place for a future surge, and we are now up and running with robust testing and inpatient and outpatient virtual technology. The first time, we were all learning on the fly.”
The LCI biostatistics team has been prospectively collecting the Institutes’s COVID-19 patient data, with plans to report their findings.
Dr. Voorhees has had financial relationships with Bristol-Myers Squibb/Celgene, Janssen, Novartis, and Oncopeptides, none of which are relevant to this article.
Today’s top news highlights: ACE inhibitors in COVID patients, fewer AMI admissions, and more
Here are the stories our MDedge editors across specialties think you need to know about today:
Are ACE inhibitors protective in COVID-19?
Older patients with COVID-19 had a lower risk of developing severe illness if they were taking ACE inhibitors, according to a large observational U.S. study. ACE inhibitor use was associated with an almost 40% lower risk for COVID-19 hospitalization for older people enrolled in Medicare Advantage plans. Senior investigator Harlan M. Krumholz, MD, said that while he and his associates think this finding is worthy of further study, “We don’t believe this is enough info to change practice.” The study was published on the MedRxiv preprint server and has not yet been peer reviewed.
READ MORE.
AMI: Admissions drop, deaths rise
In Italy, sharp nationwide decreases in hospitalizations for acute myocardial infarctions (AMIs) during the height of COVID-19 were offset by higher mortality for patients who did present. The study counted AMIs at 54 hospitals nationwide for the week of March 12-19, 2020, and compared that with an equivalent week in 2019 – 319 vs. 618 AMIs, respectively, representing a 48% reduction in hospitalizations. Mortality for ST-segment elevation MI cases more than tripled to 14% during the outbreak, compared with 4% in 2019. “The concern is fewer MIs most likely means people are dying at home or presenting later as this study suggests,” commented Martha Gulati, MD, chief of cardiology at the University of Arizona, Phoenix, who was not involved with the study.
READ MORE.
Prenatal, postpartum screening for depression falls short
Health care providers fail to ask one in five prenatal patients and one in eight postpartum patients about depression, according to the Centers for Disease Control and Prevention. Researchers analyzed self-reported data on postpartum depressive symptoms collected in 2018 by the Pregnancy Risk Assessment Monitoring System. Mental health conditions play a role in approximately 9% of pregnancy-related deaths and not asking about depression represents “missed opportunities to potentially identify and treat women with depression,” said coauthor Jean Y. Ko, PhD, from the division of reproductive health at the National Center for Chronic Disease Prevention and Health Promotion.
For more on COVID-19, visit our Resource Center. All of our latest news is available on MDedge.com.
Here are the stories our MDedge editors across specialties think you need to know about today:
Are ACE inhibitors protective in COVID-19?
Older patients with COVID-19 had a lower risk of developing severe illness if they were taking ACE inhibitors, according to a large observational U.S. study. ACE inhibitor use was associated with an almost 40% lower risk for COVID-19 hospitalization for older people enrolled in Medicare Advantage plans. Senior investigator Harlan M. Krumholz, MD, said that while he and his associates think this finding is worthy of further study, “We don’t believe this is enough info to change practice.” The study was published on the MedRxiv preprint server and has not yet been peer reviewed.
READ MORE.
AMI: Admissions drop, deaths rise
In Italy, sharp nationwide decreases in hospitalizations for acute myocardial infarctions (AMIs) during the height of COVID-19 were offset by higher mortality for patients who did present. The study counted AMIs at 54 hospitals nationwide for the week of March 12-19, 2020, and compared that with an equivalent week in 2019 – 319 vs. 618 AMIs, respectively, representing a 48% reduction in hospitalizations. Mortality for ST-segment elevation MI cases more than tripled to 14% during the outbreak, compared with 4% in 2019. “The concern is fewer MIs most likely means people are dying at home or presenting later as this study suggests,” commented Martha Gulati, MD, chief of cardiology at the University of Arizona, Phoenix, who was not involved with the study.
READ MORE.
Prenatal, postpartum screening for depression falls short
Health care providers fail to ask one in five prenatal patients and one in eight postpartum patients about depression, according to the Centers for Disease Control and Prevention. Researchers analyzed self-reported data on postpartum depressive symptoms collected in 2018 by the Pregnancy Risk Assessment Monitoring System. Mental health conditions play a role in approximately 9% of pregnancy-related deaths and not asking about depression represents “missed opportunities to potentially identify and treat women with depression,” said coauthor Jean Y. Ko, PhD, from the division of reproductive health at the National Center for Chronic Disease Prevention and Health Promotion.
For more on COVID-19, visit our Resource Center. All of our latest news is available on MDedge.com.
Here are the stories our MDedge editors across specialties think you need to know about today:
Are ACE inhibitors protective in COVID-19?
Older patients with COVID-19 had a lower risk of developing severe illness if they were taking ACE inhibitors, according to a large observational U.S. study. ACE inhibitor use was associated with an almost 40% lower risk for COVID-19 hospitalization for older people enrolled in Medicare Advantage plans. Senior investigator Harlan M. Krumholz, MD, said that while he and his associates think this finding is worthy of further study, “We don’t believe this is enough info to change practice.” The study was published on the MedRxiv preprint server and has not yet been peer reviewed.
READ MORE.
AMI: Admissions drop, deaths rise
In Italy, sharp nationwide decreases in hospitalizations for acute myocardial infarctions (AMIs) during the height of COVID-19 were offset by higher mortality for patients who did present. The study counted AMIs at 54 hospitals nationwide for the week of March 12-19, 2020, and compared that with an equivalent week in 2019 – 319 vs. 618 AMIs, respectively, representing a 48% reduction in hospitalizations. Mortality for ST-segment elevation MI cases more than tripled to 14% during the outbreak, compared with 4% in 2019. “The concern is fewer MIs most likely means people are dying at home or presenting later as this study suggests,” commented Martha Gulati, MD, chief of cardiology at the University of Arizona, Phoenix, who was not involved with the study.
READ MORE.
Prenatal, postpartum screening for depression falls short
Health care providers fail to ask one in five prenatal patients and one in eight postpartum patients about depression, according to the Centers for Disease Control and Prevention. Researchers analyzed self-reported data on postpartum depressive symptoms collected in 2018 by the Pregnancy Risk Assessment Monitoring System. Mental health conditions play a role in approximately 9% of pregnancy-related deaths and not asking about depression represents “missed opportunities to potentially identify and treat women with depression,” said coauthor Jean Y. Ko, PhD, from the division of reproductive health at the National Center for Chronic Disease Prevention and Health Promotion.
For more on COVID-19, visit our Resource Center. All of our latest news is available on MDedge.com.
Out of the pipeline: Remdesivir
Although the US Food and Drug Administration (FDA) has granted emergency use authorization of remdesivir (Gilead Sciences, Inc., Foster City, California) to treat COVID-19, the disease caused by SARS-CoV-2, the drug is considered an investigational agent, not yet formally approved by the FDA and whose efficacy and safety has not yet been fully characterized. Remdesivir has been shown to be effective in reducing the time to recovery of people with COVID-19 disease. It has not been tested in a large controlled clinical trial of pregnant women with COVID-19; however, remdesivir has been given to pregnant women infected with COVID-19 in a compassionate use protocol. For pregnant women, the drug should only be used if the potential benefit justifies the potential risk to the mother and fetus.1
Pharmacology. Remdesivir is a nucleoside RNA polymerase inhibitor. It has a molecular formula of
C27H35N6O8P and a molecular weight of 602.6 g/mol.1
Mechanism of action. From FDA’s fact sheet: “Remdesivir is an adenosine nucleotide prodrug that distributes into cells where it is metabolized to form the pharmacologically active nucleoside triphosphate metabolite. Metabolism of remdesivir to remdesivir triphosphate has been demonstrated in multiple cell types. Remdesivir triphosphate acts as an analog of adenosine triphosphate (ATP) and competes with the natural ATP substrate for incorporation into nascent RNA chains by the SARS-CoV-2 RNA-dependent RNA polymerase, which results in chain termination during replication of the viral RNA. Remdesivir triphosphate is a weak inhibitor of mammalian DNA and RNA polymerases with low potential for mitochondrial toxicity.”1
Treatment protocols
Remdesivir is authorized for treatment of hospitalized patients with severe COVID-19 disease, defined as patients with an oxygen saturation ≤ 94% on room air or requiring supplemental oxygen or requiring mechanical ventilation or requiring extracorporeal membrane oxygenation (ECMO). The optimal dose and duration of treatment of COVID-19 with remdesivir is unknown.1
Prior to initiating treatment, the estimated glomerular filtration rate should be documented to be ≥ 30 mL/min. An excipient used in the remdesivir formulation—sulfobutylether-β-cylcodextrin sodium salt—is renally cleared and accumulates in patients with decreased renal function.
Baseline liver function tests should be performed prior to treatment and daily during the course of treatment. Remdesivir should not be initiated in patients with an alanine aminotransferase (ALT) level ≥ 5 times the upper limit of normal at baseline. Remdesivir should be discontinued in patients who develop an ALT level ≥ 5 times the upper limit of normal or in patients who develop elevated ALT levels and have increased bilirubin, alkaline phosphatase, or international normalized ratio.1
In one open-label study (GS-US-540-5773), remdesivir treatment was discontinued due to an adverse event in 5% of patients on a 5-day regimen and in 10% of patients on a 10-day regimen.1
Under the emergency use authorization, two treatment protocols have been proposed depending on the clinical severity of the COVID-19 infection1:
- Protocol 1: For people with COVID-19 requiring mechanical ventilation and/or ECMO, the duration of therapy is 10 days, beginning with a loading dose of remdesivir 200 mg infused intravenously for 30 to 120 minutes on day 1 followed by a once-daily dose of 100 mg for 9 days.
- Protocol 2: For people with COVID-19 disease not requiring mechanical ventilation and/or ECMO, the duration of therapy is 5 days, beginning with a loading dose of remdesivir 200 mg infused intravenously for 30 to 120 minutes on day 1 followed by a once-daily dose of 100 mg for 4 days. If the patient does not show clinical improvement, treatment may be extended for an additional 5 days.
Continue to: Randomized placebo-controlled trial results...
Randomized placebo-controlled trial results
The Adaptive COVID-19 Treatment Trial (ACTT), sponsored by the National Institute of Allergy and Infectious Diseases, is a randomized, double-blind, placebo-controlled trial conducted by Gilead Sciences. The study began in February and evaluated up to 10 days of remdesivir treatment—200 mg IV once daily for 1 day followed by 100 mg IV once daily for 9 days in hospitalized adult patients with COVID-19. Patients were enrolled in a 1:1 manner to remdesivir or placebo, and time to recovery within 28 days after randomization was the trial’s endpoint. According to preliminary analysis of 606 recovered patients, recovery took a median of 11 days in the remdesivir group and 15 days in the placebo group (hazard ratio, 1.31; 95% confidence interval (CI), 1.12‒1.54; P<.001). Mortality rates were 8.0% and 11.6% in the remdesivir and placebo groups, respectively (P=.059).1
5 vs 10 days of remdesivir treatment
The Gilead Sciences‒sponsored study GS-US-540-5773 was a randomized, open-label multicenter trial of patients with severe COVID-19. A total of 197 adult patients received 10-day remdesivir treatment (200 mg IV once daily for 1 day followed by 100 mg IV once daily for 9 days). An additional 200 adult patients received 5-day remdesivir treatment (200 mg IV once daily followed by 100 mg IV for 4 days). Both groups also received standard of care. Results suggested that patients receiving 10 days of remdesivir had similar improvement in clinical status compared with those receiving a 5-day treatment course (10-to-5 day odds ratio, 0.76; 95% CI, 0.51‒1.13] on day 14).1 Improvement in clinical status was defined as an improvement of 2 or more points from baseline on a predefined 7-point scale that ranged from hospital discharge to increasing levels of oxygen support to death. Clinical recovery was achieved if patients ceased the need for oxygen support or were discharged.1
The time to clinical improvement for 50% of patients was similar in each treatment group (10 days in the 5-day group versus 11 days in the 10-day group). By day 14, observed clinical improvement rates were 65% and 54% in the 5- and 10-day treatment groups, respectively. Clinical recovery rates were 70% and 59% in the 5- and 10-day treatment groups and mortality rates were 8% and 11%.1
Adverse events
The use of remdesivir is contraindicated in patients who are hypersensitive to the drug. Its infusion may cause hypotension, nausea, vomiting, diaphoresis, and shivering. If signs of a clinically significant infusion reaction are observed the infusion should be discontinued. As noted above, elevation in ALT levels occurs with remdesivir treatment.1
Reporting serious adverse events. If a serious and unexpected adverse event occurs and appears to be associated with the use of remdesivir, the prescribing health care provider and/or the provider’s designee should complete and submit a MedWatch form to the FDA using one of the following methods1:
- Complete and submit the report online: www.fda.gov/medwatch/report.htm
- Return form FDA 3500 (available at http://www.fda.gov/downloads/AboutFDA/ReportsManualsForms/Forms/UCM163919.pdf) to the FDA by mail (MedWatch, 5600 Fishers Lane, Rockville, MD 20852-9787) or fax (1-800-FDA-0178)
- Gilead requests that all FDA MedWatch forms also be returned to Gilead Pharmacovigilance and Epidemiology: fax: 1-650-522-5477 726; e-mail: Safety_fc@gilead.com
Continue to: Drug interactions...
Drug interactions
Remdesivir has not been evaluated for drug-drug interactions in humans. The clinical relevance of in vitro drug interactions also has not been established. According to the FDA, remdesivir is a substrate for the drug metabolizing enzymes CYP2C8, CYP2D6, and CYP3A4, and is a substrate for organic anion transporting polypeptides 1B1 (OAPT1B1) and P-glycoprotein (P-gp) transporters. In vitro, remdesivir inhibits CYP3A4, OATP1B1, OATP1B3, BSEP, MRP4, and NTCP.1
Pregnancy risk summary
Remdesivir has not been studied adequately in pregnant women and only should be used during pregnancy if the potential benefit of the drug justifies the potential risk to both mother and fetus.
Nonclinical animal studies that included systemic exposure of the predominant circulating metabolite of remdesivir in pregnant rats and rabbits (at 4 times the recommended dose of human exposure) demonstrated no adverse effect on embryofetal development.1
Breastfeeding
The only information regarding breastfeeding and remdesivir comes from animal studies. The drug and its metabolites were detected in the plasma of nursing rat pups whose mothers given intravenous remdesivir daily from gestation day 6 to lactation day 20. Measured on lactation day 10, remdesivir exposure in the pups was about 1% that of maternal exposure.1
“Because of the potential for viral transmission to SARS-CoV-2-negative infants and adverse reactions from the drug in breastfeeding infants, the developmental and health benefits of breastfeeding should be considered along with the mother’s clinical need for remdesivir and any potential adverse effects on the breastfed child from remdesivir or from the underlying maternal condition.”1
- US Food and Drug Administration. Fact Sheet for Health Care Providers Emergency Use Authorization (UA) of Remdesivir (GS-5734)TM. https://www.fda.gov/media/137566/download. Accessed May 19, 2020.
Although the US Food and Drug Administration (FDA) has granted emergency use authorization of remdesivir (Gilead Sciences, Inc., Foster City, California) to treat COVID-19, the disease caused by SARS-CoV-2, the drug is considered an investigational agent, not yet formally approved by the FDA and whose efficacy and safety has not yet been fully characterized. Remdesivir has been shown to be effective in reducing the time to recovery of people with COVID-19 disease. It has not been tested in a large controlled clinical trial of pregnant women with COVID-19; however, remdesivir has been given to pregnant women infected with COVID-19 in a compassionate use protocol. For pregnant women, the drug should only be used if the potential benefit justifies the potential risk to the mother and fetus.1
Pharmacology. Remdesivir is a nucleoside RNA polymerase inhibitor. It has a molecular formula of
C27H35N6O8P and a molecular weight of 602.6 g/mol.1
Mechanism of action. From FDA’s fact sheet: “Remdesivir is an adenosine nucleotide prodrug that distributes into cells where it is metabolized to form the pharmacologically active nucleoside triphosphate metabolite. Metabolism of remdesivir to remdesivir triphosphate has been demonstrated in multiple cell types. Remdesivir triphosphate acts as an analog of adenosine triphosphate (ATP) and competes with the natural ATP substrate for incorporation into nascent RNA chains by the SARS-CoV-2 RNA-dependent RNA polymerase, which results in chain termination during replication of the viral RNA. Remdesivir triphosphate is a weak inhibitor of mammalian DNA and RNA polymerases with low potential for mitochondrial toxicity.”1
Treatment protocols
Remdesivir is authorized for treatment of hospitalized patients with severe COVID-19 disease, defined as patients with an oxygen saturation ≤ 94% on room air or requiring supplemental oxygen or requiring mechanical ventilation or requiring extracorporeal membrane oxygenation (ECMO). The optimal dose and duration of treatment of COVID-19 with remdesivir is unknown.1
Prior to initiating treatment, the estimated glomerular filtration rate should be documented to be ≥ 30 mL/min. An excipient used in the remdesivir formulation—sulfobutylether-β-cylcodextrin sodium salt—is renally cleared and accumulates in patients with decreased renal function.
Baseline liver function tests should be performed prior to treatment and daily during the course of treatment. Remdesivir should not be initiated in patients with an alanine aminotransferase (ALT) level ≥ 5 times the upper limit of normal at baseline. Remdesivir should be discontinued in patients who develop an ALT level ≥ 5 times the upper limit of normal or in patients who develop elevated ALT levels and have increased bilirubin, alkaline phosphatase, or international normalized ratio.1
In one open-label study (GS-US-540-5773), remdesivir treatment was discontinued due to an adverse event in 5% of patients on a 5-day regimen and in 10% of patients on a 10-day regimen.1
Under the emergency use authorization, two treatment protocols have been proposed depending on the clinical severity of the COVID-19 infection1:
- Protocol 1: For people with COVID-19 requiring mechanical ventilation and/or ECMO, the duration of therapy is 10 days, beginning with a loading dose of remdesivir 200 mg infused intravenously for 30 to 120 minutes on day 1 followed by a once-daily dose of 100 mg for 9 days.
- Protocol 2: For people with COVID-19 disease not requiring mechanical ventilation and/or ECMO, the duration of therapy is 5 days, beginning with a loading dose of remdesivir 200 mg infused intravenously for 30 to 120 minutes on day 1 followed by a once-daily dose of 100 mg for 4 days. If the patient does not show clinical improvement, treatment may be extended for an additional 5 days.
Continue to: Randomized placebo-controlled trial results...
Randomized placebo-controlled trial results
The Adaptive COVID-19 Treatment Trial (ACTT), sponsored by the National Institute of Allergy and Infectious Diseases, is a randomized, double-blind, placebo-controlled trial conducted by Gilead Sciences. The study began in February and evaluated up to 10 days of remdesivir treatment—200 mg IV once daily for 1 day followed by 100 mg IV once daily for 9 days in hospitalized adult patients with COVID-19. Patients were enrolled in a 1:1 manner to remdesivir or placebo, and time to recovery within 28 days after randomization was the trial’s endpoint. According to preliminary analysis of 606 recovered patients, recovery took a median of 11 days in the remdesivir group and 15 days in the placebo group (hazard ratio, 1.31; 95% confidence interval (CI), 1.12‒1.54; P<.001). Mortality rates were 8.0% and 11.6% in the remdesivir and placebo groups, respectively (P=.059).1
5 vs 10 days of remdesivir treatment
The Gilead Sciences‒sponsored study GS-US-540-5773 was a randomized, open-label multicenter trial of patients with severe COVID-19. A total of 197 adult patients received 10-day remdesivir treatment (200 mg IV once daily for 1 day followed by 100 mg IV once daily for 9 days). An additional 200 adult patients received 5-day remdesivir treatment (200 mg IV once daily followed by 100 mg IV for 4 days). Both groups also received standard of care. Results suggested that patients receiving 10 days of remdesivir had similar improvement in clinical status compared with those receiving a 5-day treatment course (10-to-5 day odds ratio, 0.76; 95% CI, 0.51‒1.13] on day 14).1 Improvement in clinical status was defined as an improvement of 2 or more points from baseline on a predefined 7-point scale that ranged from hospital discharge to increasing levels of oxygen support to death. Clinical recovery was achieved if patients ceased the need for oxygen support or were discharged.1
The time to clinical improvement for 50% of patients was similar in each treatment group (10 days in the 5-day group versus 11 days in the 10-day group). By day 14, observed clinical improvement rates were 65% and 54% in the 5- and 10-day treatment groups, respectively. Clinical recovery rates were 70% and 59% in the 5- and 10-day treatment groups and mortality rates were 8% and 11%.1
Adverse events
The use of remdesivir is contraindicated in patients who are hypersensitive to the drug. Its infusion may cause hypotension, nausea, vomiting, diaphoresis, and shivering. If signs of a clinically significant infusion reaction are observed the infusion should be discontinued. As noted above, elevation in ALT levels occurs with remdesivir treatment.1
Reporting serious adverse events. If a serious and unexpected adverse event occurs and appears to be associated with the use of remdesivir, the prescribing health care provider and/or the provider’s designee should complete and submit a MedWatch form to the FDA using one of the following methods1:
- Complete and submit the report online: www.fda.gov/medwatch/report.htm
- Return form FDA 3500 (available at http://www.fda.gov/downloads/AboutFDA/ReportsManualsForms/Forms/UCM163919.pdf) to the FDA by mail (MedWatch, 5600 Fishers Lane, Rockville, MD 20852-9787) or fax (1-800-FDA-0178)
- Gilead requests that all FDA MedWatch forms also be returned to Gilead Pharmacovigilance and Epidemiology: fax: 1-650-522-5477 726; e-mail: Safety_fc@gilead.com
Continue to: Drug interactions...
Drug interactions
Remdesivir has not been evaluated for drug-drug interactions in humans. The clinical relevance of in vitro drug interactions also has not been established. According to the FDA, remdesivir is a substrate for the drug metabolizing enzymes CYP2C8, CYP2D6, and CYP3A4, and is a substrate for organic anion transporting polypeptides 1B1 (OAPT1B1) and P-glycoprotein (P-gp) transporters. In vitro, remdesivir inhibits CYP3A4, OATP1B1, OATP1B3, BSEP, MRP4, and NTCP.1
Pregnancy risk summary
Remdesivir has not been studied adequately in pregnant women and only should be used during pregnancy if the potential benefit of the drug justifies the potential risk to both mother and fetus.
Nonclinical animal studies that included systemic exposure of the predominant circulating metabolite of remdesivir in pregnant rats and rabbits (at 4 times the recommended dose of human exposure) demonstrated no adverse effect on embryofetal development.1
Breastfeeding
The only information regarding breastfeeding and remdesivir comes from animal studies. The drug and its metabolites were detected in the plasma of nursing rat pups whose mothers given intravenous remdesivir daily from gestation day 6 to lactation day 20. Measured on lactation day 10, remdesivir exposure in the pups was about 1% that of maternal exposure.1
“Because of the potential for viral transmission to SARS-CoV-2-negative infants and adverse reactions from the drug in breastfeeding infants, the developmental and health benefits of breastfeeding should be considered along with the mother’s clinical need for remdesivir and any potential adverse effects on the breastfed child from remdesivir or from the underlying maternal condition.”1
Although the US Food and Drug Administration (FDA) has granted emergency use authorization of remdesivir (Gilead Sciences, Inc., Foster City, California) to treat COVID-19, the disease caused by SARS-CoV-2, the drug is considered an investigational agent, not yet formally approved by the FDA and whose efficacy and safety has not yet been fully characterized. Remdesivir has been shown to be effective in reducing the time to recovery of people with COVID-19 disease. It has not been tested in a large controlled clinical trial of pregnant women with COVID-19; however, remdesivir has been given to pregnant women infected with COVID-19 in a compassionate use protocol. For pregnant women, the drug should only be used if the potential benefit justifies the potential risk to the mother and fetus.1
Pharmacology. Remdesivir is a nucleoside RNA polymerase inhibitor. It has a molecular formula of
C27H35N6O8P and a molecular weight of 602.6 g/mol.1
Mechanism of action. From FDA’s fact sheet: “Remdesivir is an adenosine nucleotide prodrug that distributes into cells where it is metabolized to form the pharmacologically active nucleoside triphosphate metabolite. Metabolism of remdesivir to remdesivir triphosphate has been demonstrated in multiple cell types. Remdesivir triphosphate acts as an analog of adenosine triphosphate (ATP) and competes with the natural ATP substrate for incorporation into nascent RNA chains by the SARS-CoV-2 RNA-dependent RNA polymerase, which results in chain termination during replication of the viral RNA. Remdesivir triphosphate is a weak inhibitor of mammalian DNA and RNA polymerases with low potential for mitochondrial toxicity.”1
Treatment protocols
Remdesivir is authorized for treatment of hospitalized patients with severe COVID-19 disease, defined as patients with an oxygen saturation ≤ 94% on room air or requiring supplemental oxygen or requiring mechanical ventilation or requiring extracorporeal membrane oxygenation (ECMO). The optimal dose and duration of treatment of COVID-19 with remdesivir is unknown.1
Prior to initiating treatment, the estimated glomerular filtration rate should be documented to be ≥ 30 mL/min. An excipient used in the remdesivir formulation—sulfobutylether-β-cylcodextrin sodium salt—is renally cleared and accumulates in patients with decreased renal function.
Baseline liver function tests should be performed prior to treatment and daily during the course of treatment. Remdesivir should not be initiated in patients with an alanine aminotransferase (ALT) level ≥ 5 times the upper limit of normal at baseline. Remdesivir should be discontinued in patients who develop an ALT level ≥ 5 times the upper limit of normal or in patients who develop elevated ALT levels and have increased bilirubin, alkaline phosphatase, or international normalized ratio.1
In one open-label study (GS-US-540-5773), remdesivir treatment was discontinued due to an adverse event in 5% of patients on a 5-day regimen and in 10% of patients on a 10-day regimen.1
Under the emergency use authorization, two treatment protocols have been proposed depending on the clinical severity of the COVID-19 infection1:
- Protocol 1: For people with COVID-19 requiring mechanical ventilation and/or ECMO, the duration of therapy is 10 days, beginning with a loading dose of remdesivir 200 mg infused intravenously for 30 to 120 minutes on day 1 followed by a once-daily dose of 100 mg for 9 days.
- Protocol 2: For people with COVID-19 disease not requiring mechanical ventilation and/or ECMO, the duration of therapy is 5 days, beginning with a loading dose of remdesivir 200 mg infused intravenously for 30 to 120 minutes on day 1 followed by a once-daily dose of 100 mg for 4 days. If the patient does not show clinical improvement, treatment may be extended for an additional 5 days.
Continue to: Randomized placebo-controlled trial results...
Randomized placebo-controlled trial results
The Adaptive COVID-19 Treatment Trial (ACTT), sponsored by the National Institute of Allergy and Infectious Diseases, is a randomized, double-blind, placebo-controlled trial conducted by Gilead Sciences. The study began in February and evaluated up to 10 days of remdesivir treatment—200 mg IV once daily for 1 day followed by 100 mg IV once daily for 9 days in hospitalized adult patients with COVID-19. Patients were enrolled in a 1:1 manner to remdesivir or placebo, and time to recovery within 28 days after randomization was the trial’s endpoint. According to preliminary analysis of 606 recovered patients, recovery took a median of 11 days in the remdesivir group and 15 days in the placebo group (hazard ratio, 1.31; 95% confidence interval (CI), 1.12‒1.54; P<.001). Mortality rates were 8.0% and 11.6% in the remdesivir and placebo groups, respectively (P=.059).1
5 vs 10 days of remdesivir treatment
The Gilead Sciences‒sponsored study GS-US-540-5773 was a randomized, open-label multicenter trial of patients with severe COVID-19. A total of 197 adult patients received 10-day remdesivir treatment (200 mg IV once daily for 1 day followed by 100 mg IV once daily for 9 days). An additional 200 adult patients received 5-day remdesivir treatment (200 mg IV once daily followed by 100 mg IV for 4 days). Both groups also received standard of care. Results suggested that patients receiving 10 days of remdesivir had similar improvement in clinical status compared with those receiving a 5-day treatment course (10-to-5 day odds ratio, 0.76; 95% CI, 0.51‒1.13] on day 14).1 Improvement in clinical status was defined as an improvement of 2 or more points from baseline on a predefined 7-point scale that ranged from hospital discharge to increasing levels of oxygen support to death. Clinical recovery was achieved if patients ceased the need for oxygen support or were discharged.1
The time to clinical improvement for 50% of patients was similar in each treatment group (10 days in the 5-day group versus 11 days in the 10-day group). By day 14, observed clinical improvement rates were 65% and 54% in the 5- and 10-day treatment groups, respectively. Clinical recovery rates were 70% and 59% in the 5- and 10-day treatment groups and mortality rates were 8% and 11%.1
Adverse events
The use of remdesivir is contraindicated in patients who are hypersensitive to the drug. Its infusion may cause hypotension, nausea, vomiting, diaphoresis, and shivering. If signs of a clinically significant infusion reaction are observed the infusion should be discontinued. As noted above, elevation in ALT levels occurs with remdesivir treatment.1
Reporting serious adverse events. If a serious and unexpected adverse event occurs and appears to be associated with the use of remdesivir, the prescribing health care provider and/or the provider’s designee should complete and submit a MedWatch form to the FDA using one of the following methods1:
- Complete and submit the report online: www.fda.gov/medwatch/report.htm
- Return form FDA 3500 (available at http://www.fda.gov/downloads/AboutFDA/ReportsManualsForms/Forms/UCM163919.pdf) to the FDA by mail (MedWatch, 5600 Fishers Lane, Rockville, MD 20852-9787) or fax (1-800-FDA-0178)
- Gilead requests that all FDA MedWatch forms also be returned to Gilead Pharmacovigilance and Epidemiology: fax: 1-650-522-5477 726; e-mail: Safety_fc@gilead.com
Continue to: Drug interactions...
Drug interactions
Remdesivir has not been evaluated for drug-drug interactions in humans. The clinical relevance of in vitro drug interactions also has not been established. According to the FDA, remdesivir is a substrate for the drug metabolizing enzymes CYP2C8, CYP2D6, and CYP3A4, and is a substrate for organic anion transporting polypeptides 1B1 (OAPT1B1) and P-glycoprotein (P-gp) transporters. In vitro, remdesivir inhibits CYP3A4, OATP1B1, OATP1B3, BSEP, MRP4, and NTCP.1
Pregnancy risk summary
Remdesivir has not been studied adequately in pregnant women and only should be used during pregnancy if the potential benefit of the drug justifies the potential risk to both mother and fetus.
Nonclinical animal studies that included systemic exposure of the predominant circulating metabolite of remdesivir in pregnant rats and rabbits (at 4 times the recommended dose of human exposure) demonstrated no adverse effect on embryofetal development.1
Breastfeeding
The only information regarding breastfeeding and remdesivir comes from animal studies. The drug and its metabolites were detected in the plasma of nursing rat pups whose mothers given intravenous remdesivir daily from gestation day 6 to lactation day 20. Measured on lactation day 10, remdesivir exposure in the pups was about 1% that of maternal exposure.1
“Because of the potential for viral transmission to SARS-CoV-2-negative infants and adverse reactions from the drug in breastfeeding infants, the developmental and health benefits of breastfeeding should be considered along with the mother’s clinical need for remdesivir and any potential adverse effects on the breastfed child from remdesivir or from the underlying maternal condition.”1
- US Food and Drug Administration. Fact Sheet for Health Care Providers Emergency Use Authorization (UA) of Remdesivir (GS-5734)TM. https://www.fda.gov/media/137566/download. Accessed May 19, 2020.
- US Food and Drug Administration. Fact Sheet for Health Care Providers Emergency Use Authorization (UA) of Remdesivir (GS-5734)TM. https://www.fda.gov/media/137566/download. Accessed May 19, 2020.
COVID-19 and Mental Health Awareness Month
#howareyoureally challenge seeks to increase access to care
We are months into the COVID-19 crisis, and mental health issues are proving to be rampant. In every crisis, there is opportunity, and this one is no different. The opportunity is clear. For Mental Health Awareness Month and beyond, we must convey a powerful message that mental health is key to our well-being and must be actively addressed. Because almost everyone has felt excess anxiety these last months, we have a unique chance to engage a wider audience.
To address the urgent need, the Mental Health Coalition was formed with the understanding that the mental health crisis is fueled by a pervasive and devastating stigma, preventing millions of individuals from being able to seek the critical treatment they need. Spearheaded by social activist and fashion designer, Kenneth Cole, it is a coalition of leading mental health organizations, brands, celebrities, and advocates who have joined forces to end the stigma surrounding mental health and to change the way people talk about, and care for, mental illness. The group’s mission listed on its website states: “We must increase the conversation around mental health. We must act to end silence, reduce stigma, and engage our community to inspire hope at this essential moment.”
As most of the United States has been under stay-at-home orders, our traditional relationships have been radically disrupted. New types of relationships are forming as we are relying even more on technology to connect us. Social media seems to be on the only “social” we can now safely engage in.
The coalition’s campaign, “#howareyoureally?” is harnessing the power of social media and creating a storytelling platform to allow users to more genuinely share their feelings in these unprecedented times. Celebrities include Whoopi Goldberg, Kendall Jenner, Chris Cuomo, Deepak Chopra, Kesha, and many more have already shared their stories.
“How Are You, Really?” challenges people to answer this question using social media in an open and honest fashion while still providing hope.
The second component of the initiative is to increase access to care, and they have a long list of collaborators, including leading mental health organizations such as the American Foundation for Suicide Prevention, Anxiety and Depression Association of America, Child Mind Institute, Depression and Bipolar Support Alliance, Didi Hirsch Mental Health Services, National Alliance on Mental Illness, and many more.
We have a unique opportunity this Mental Health Awareness Month, and As a community, we must be prepared to meet the escalating needs of our population.
Dr. Ritvo, a psychiatrist with more than 25 years’ experience, practices in Miami Beach, Fla. She is the author of “Bekindr – The Transformative Power of Kindness” (Hellertown, Pa.: Momosa Publishing, 2018) and is the founder of the Bekindr Global Initiative, a movement aimed at cultivating kindness in the world. Dr. Ritvo also is the cofounder of the Bold Beauty Project, a nonprofit group that pairs women with disabilities with photographers who create art exhibitions to raise awareness.
#howareyoureally challenge seeks to increase access to care
#howareyoureally challenge seeks to increase access to care
We are months into the COVID-19 crisis, and mental health issues are proving to be rampant. In every crisis, there is opportunity, and this one is no different. The opportunity is clear. For Mental Health Awareness Month and beyond, we must convey a powerful message that mental health is key to our well-being and must be actively addressed. Because almost everyone has felt excess anxiety these last months, we have a unique chance to engage a wider audience.
To address the urgent need, the Mental Health Coalition was formed with the understanding that the mental health crisis is fueled by a pervasive and devastating stigma, preventing millions of individuals from being able to seek the critical treatment they need. Spearheaded by social activist and fashion designer, Kenneth Cole, it is a coalition of leading mental health organizations, brands, celebrities, and advocates who have joined forces to end the stigma surrounding mental health and to change the way people talk about, and care for, mental illness. The group’s mission listed on its website states: “We must increase the conversation around mental health. We must act to end silence, reduce stigma, and engage our community to inspire hope at this essential moment.”
As most of the United States has been under stay-at-home orders, our traditional relationships have been radically disrupted. New types of relationships are forming as we are relying even more on technology to connect us. Social media seems to be on the only “social” we can now safely engage in.
The coalition’s campaign, “#howareyoureally?” is harnessing the power of social media and creating a storytelling platform to allow users to more genuinely share their feelings in these unprecedented times. Celebrities include Whoopi Goldberg, Kendall Jenner, Chris Cuomo, Deepak Chopra, Kesha, and many more have already shared their stories.
“How Are You, Really?” challenges people to answer this question using social media in an open and honest fashion while still providing hope.
The second component of the initiative is to increase access to care, and they have a long list of collaborators, including leading mental health organizations such as the American Foundation for Suicide Prevention, Anxiety and Depression Association of America, Child Mind Institute, Depression and Bipolar Support Alliance, Didi Hirsch Mental Health Services, National Alliance on Mental Illness, and many more.
We have a unique opportunity this Mental Health Awareness Month, and As a community, we must be prepared to meet the escalating needs of our population.
Dr. Ritvo, a psychiatrist with more than 25 years’ experience, practices in Miami Beach, Fla. She is the author of “Bekindr – The Transformative Power of Kindness” (Hellertown, Pa.: Momosa Publishing, 2018) and is the founder of the Bekindr Global Initiative, a movement aimed at cultivating kindness in the world. Dr. Ritvo also is the cofounder of the Bold Beauty Project, a nonprofit group that pairs women with disabilities with photographers who create art exhibitions to raise awareness.
We are months into the COVID-19 crisis, and mental health issues are proving to be rampant. In every crisis, there is opportunity, and this one is no different. The opportunity is clear. For Mental Health Awareness Month and beyond, we must convey a powerful message that mental health is key to our well-being and must be actively addressed. Because almost everyone has felt excess anxiety these last months, we have a unique chance to engage a wider audience.
To address the urgent need, the Mental Health Coalition was formed with the understanding that the mental health crisis is fueled by a pervasive and devastating stigma, preventing millions of individuals from being able to seek the critical treatment they need. Spearheaded by social activist and fashion designer, Kenneth Cole, it is a coalition of leading mental health organizations, brands, celebrities, and advocates who have joined forces to end the stigma surrounding mental health and to change the way people talk about, and care for, mental illness. The group’s mission listed on its website states: “We must increase the conversation around mental health. We must act to end silence, reduce stigma, and engage our community to inspire hope at this essential moment.”
As most of the United States has been under stay-at-home orders, our traditional relationships have been radically disrupted. New types of relationships are forming as we are relying even more on technology to connect us. Social media seems to be on the only “social” we can now safely engage in.
The coalition’s campaign, “#howareyoureally?” is harnessing the power of social media and creating a storytelling platform to allow users to more genuinely share their feelings in these unprecedented times. Celebrities include Whoopi Goldberg, Kendall Jenner, Chris Cuomo, Deepak Chopra, Kesha, and many more have already shared their stories.
“How Are You, Really?” challenges people to answer this question using social media in an open and honest fashion while still providing hope.
The second component of the initiative is to increase access to care, and they have a long list of collaborators, including leading mental health organizations such as the American Foundation for Suicide Prevention, Anxiety and Depression Association of America, Child Mind Institute, Depression and Bipolar Support Alliance, Didi Hirsch Mental Health Services, National Alliance on Mental Illness, and many more.
We have a unique opportunity this Mental Health Awareness Month, and As a community, we must be prepared to meet the escalating needs of our population.
Dr. Ritvo, a psychiatrist with more than 25 years’ experience, practices in Miami Beach, Fla. She is the author of “Bekindr – The Transformative Power of Kindness” (Hellertown, Pa.: Momosa Publishing, 2018) and is the founder of the Bekindr Global Initiative, a movement aimed at cultivating kindness in the world. Dr. Ritvo also is the cofounder of the Bold Beauty Project, a nonprofit group that pairs women with disabilities with photographers who create art exhibitions to raise awareness.
ACE inhibitors and severe COVID-19: Protective in older patients?
.
In addition, a new meta-analysis of all the available data on the use of ACE inhibitors and angiotensin-receptor blockers (ARBs) in COVID-19–infected patients has concluded that these drugs are not associated with more severe disease and do not increase susceptibility to infection.
The observational study, which was published on the MedRxiv preprint server on May 19 and has not yet been peer reviewed, was conducted by the health insurance company United Heath Group and by Yale University, New Haven, Conn.
The investigators analyzed data from 10,000 patients from across the United States who had tested positive for COVID-19, who were enrolled in Medicare Advantage insurance plans or were commercially insured, and who had received a prescription for one or more antihypertensive medications.
Results showed that the use of ACE inhibitors was associated with an almost 40% lower risk for COVID-19 hospitalization for older people enrolled in Medicare Advantage plans. No such benefit was seen in the younger commercially insured patients or in either group with ARBs.
At a telephone media briefing on the study, senior investigator Harlan M. Krumholz, MD, said: “We don’t believe this is enough info to change practice, but we do think this is an interesting and intriguing result.
“These findings merit a clinical trial to formally test whether ACE inhibitors – which are cheap, widely available, and well-tolerated drugs – can reduce hospitalization of patients infected with COVID-19,” added Dr. Krumholz, professor of medicine at Yale and director of the Yale New Haven Hospital Center for Outcomes Research.
A pragmatic clinical trial is now being planned. In this trial, 10,000 older people who test positive for COVID-19 will be randomly assigned to receive either a low dose of an ACE inhibitor or placebo. It is hoped that recruitment for the trial will begin in June of 2020. It is open to all eligible Americans who are older than 50 years, who test negative for COVID-19, and who are not taking medications for hypertension. Prospective patients can sign up at a dedicated website.
The randomized trial, also conducted by United Health Group and Yale, is said to be “one of the first virtual COVID-19 clinical trials to be launched at scale.”
For the observational study, the researchers identified 2,263 people who were receiving medication for hypertension and who tested positive for COVID-19. Of these, approximately two-thirds were older, Medicare Advantage enrollees; one-third were younger, commercially insured individuals.
In a propensity score–matched analysis, the investigators matched 441 patients who were taking ACE inhibitors to 441 patients who were taking other antihypertensive agents; and 412 patients who were receiving an ARB to 412 patients who were receiving other antihypertensive agents.
Results showed that during a median of 30 days after testing positive, 12.7% of the cohort were hospitalized for COVID-19. In propensity score–matched analyses, neither ACE inhibitors (hazard ratio [HR], 0.77; P = .18) nor ARBs (HR, 0.88; P =.48) were significantly associated with risk for hospitalization.
However, in analyses stratified by the insurance group, ACE inhibitors (but not ARBs) were associated with a significant lower risk for hospitalization among the Medicare group (HR, 0.61; P = .02) but not among the commercially insured group (HR, 2.14; P = .12).
A second study examined outcomes of 7,933 individuals with hypertension who were hospitalized with COVID-19 (92% of these patients were Medicare Advantage enrollees). Of these, 14.2% died, 59.5% survived to discharge, and 26.3% underwent ongoing hospitalization. In propensity score–matched analyses, use of neither an ACE inhibitor (HR, 0.97; P = .74) nor an ARB (HR, 1.15; P = .15) was associated with risk of in-hospital mortality.
The researchers said their findings are consistent with prior evidence from randomized clinical trials suggesting a reduced risk for pneumonia with ACE inhibitors that is not observed with ARBs.
They also cited some preclinical evidence that they said suggests a possible protective role for ACE inhibitors in COVID-19: that ACE inhibitors, but not ARBs, are associated with the upregulation of ACE2 receptors, which modulate the local interactions of the renin-angiotensin-aldosterone system in the lung tissue.
“The presence of ACE2 receptors, therefore, exerts a protective effect against the development of acute lung injury in infections with SARS coronaviruses, which lead to dysregulation of these mechanisms and endothelial damage,” they added. “Further, our observations do not support theoretical concerns of adverse outcomes due to enhanced virulence of SARS coronaviruses due to overexpression of ACE2 receptors in cell cultures – an indirect binding site for these viruses.”
The authors also noted that their findings have “important implications” for four ongoing randomized trials of ACE inhibitors/ARBs in COVID-19, “as none of them align with the observations of our study.”
They pointed out that of the four ongoing trials, three are testing the use of ACE inhibitors or ARBs in the treatment of hospitalized COVID-19 patients, and one is testing the use of a 10-day course of ARBs after a positive SARS-CoV-2 test to prevent hospitalization.
Experts cautious
However, two cardiovascular experts who were asked to comment on this latest study were not overly optimistic about the data.
Michael A. Weber, MD, professor of medicine at the State University of New York, Brooklyn, said: “This report adds to the growing number of observational studies that show varying effects of ACE inhibitors and ARBs in increasing or decreasing hospitalizations for COVID-19 and the likelihood of in-hospital mortality. Overall, this new report differs from others in the remarkable effects of insurance coverage: In particular, for ACE inhibitors, there was a 40% reduction in fatal events in Medicare patients but a twofold increase in patients using commercial insurance – albeit the test for heterogeneity when comparing the two groups did not quite reach statistical significance.
“In essence, these authors are saying that ACE inhibitors are highly protective in patients aged 65 or older but bordering on harmful in patients aged below 65. I agree that it’s worthwhile to check this finding in a prospective trial ... but this hypothesis does seem to be a reach.”
Dr. Weber noted that both ACE inhibitors and ARBs increase the level of the ACE2 enzyme to which the COVID-19 virus binds in the lungs.
“The ACE inhibitors do so by inhibiting the enzyme’s action and thus stimulate further enzyme production; the ARBs block the effects of angiotensin II, which results in high angiotensin II levels that also upregulate ACE2 production,” he said. “Perhaps the ACE inhibitors, by binding to the ACE enzyme, can in some way interfere with the enzyme’s uptake of the COVID virus and thus provide some measure of clinical protection. This is possible, but why would this effect be apparent only in older people?”
John McMurray, MD, professor of medical cardiology at the University of Glasgow, Scotland, added: “This looks like a subgroup of a subgroup type analysis based on small numbers of events – I think there were only 77 hospitalizations among the 722 patients treated with an ACE inhibitor, and the Medicare Advantage subgroup was only 581 of those 722 patients.
“The hazard ratio had wide 95% CI [confidence interval] and a modest P value,” Dr. McMurray added. “So yes, interesting and hypothesis-generating, but not definitive.”
New meta-analysis
The new meta-analysis of all data so far available on ACE inhibitor and ARB use for patients with COVID-19 was published online in Annals of Internal Medicine on May 15.
The analysis is a living, systematic review with ongoing literature surveillance and critical appraisal, which will be updated as new data become available. It included 14 observational studies.
The authors, led by Katherine M. Mackey, MD, VA Portland Health Care System, Oregon, concluded: “High-certainty evidence suggests that ACE-inhibitor or ARB use is not associated with more severe COVID-19 disease, and moderate certainty evidence suggested no association between use of these medications and positive SARS-CoV-2 test results among symptomatic patients. Whether these medications increase the risk for mild or asymptomatic disease or are beneficial in COVID-19 treatment remains uncertain.”
In an accompanying editorial, William G. Kussmaul III, MD, Drexel University, Philadelphia, said that initial fears that these drugs may be harmful for patients with COVID-19 now seem to have been unfounded.
“We now have reasonable reassurance that drugs that alter the renin-angiotensin system do not pose substantial threats as either COVID-19 risk factors or severity multipliers,” he wrote.
A version of this article originally appeared on Medscape.com.
.
In addition, a new meta-analysis of all the available data on the use of ACE inhibitors and angiotensin-receptor blockers (ARBs) in COVID-19–infected patients has concluded that these drugs are not associated with more severe disease and do not increase susceptibility to infection.
The observational study, which was published on the MedRxiv preprint server on May 19 and has not yet been peer reviewed, was conducted by the health insurance company United Heath Group and by Yale University, New Haven, Conn.
The investigators analyzed data from 10,000 patients from across the United States who had tested positive for COVID-19, who were enrolled in Medicare Advantage insurance plans or were commercially insured, and who had received a prescription for one or more antihypertensive medications.
Results showed that the use of ACE inhibitors was associated with an almost 40% lower risk for COVID-19 hospitalization for older people enrolled in Medicare Advantage plans. No such benefit was seen in the younger commercially insured patients or in either group with ARBs.
At a telephone media briefing on the study, senior investigator Harlan M. Krumholz, MD, said: “We don’t believe this is enough info to change practice, but we do think this is an interesting and intriguing result.
“These findings merit a clinical trial to formally test whether ACE inhibitors – which are cheap, widely available, and well-tolerated drugs – can reduce hospitalization of patients infected with COVID-19,” added Dr. Krumholz, professor of medicine at Yale and director of the Yale New Haven Hospital Center for Outcomes Research.
A pragmatic clinical trial is now being planned. In this trial, 10,000 older people who test positive for COVID-19 will be randomly assigned to receive either a low dose of an ACE inhibitor or placebo. It is hoped that recruitment for the trial will begin in June of 2020. It is open to all eligible Americans who are older than 50 years, who test negative for COVID-19, and who are not taking medications for hypertension. Prospective patients can sign up at a dedicated website.
The randomized trial, also conducted by United Health Group and Yale, is said to be “one of the first virtual COVID-19 clinical trials to be launched at scale.”
For the observational study, the researchers identified 2,263 people who were receiving medication for hypertension and who tested positive for COVID-19. Of these, approximately two-thirds were older, Medicare Advantage enrollees; one-third were younger, commercially insured individuals.
In a propensity score–matched analysis, the investigators matched 441 patients who were taking ACE inhibitors to 441 patients who were taking other antihypertensive agents; and 412 patients who were receiving an ARB to 412 patients who were receiving other antihypertensive agents.
Results showed that during a median of 30 days after testing positive, 12.7% of the cohort were hospitalized for COVID-19. In propensity score–matched analyses, neither ACE inhibitors (hazard ratio [HR], 0.77; P = .18) nor ARBs (HR, 0.88; P =.48) were significantly associated with risk for hospitalization.
However, in analyses stratified by the insurance group, ACE inhibitors (but not ARBs) were associated with a significant lower risk for hospitalization among the Medicare group (HR, 0.61; P = .02) but not among the commercially insured group (HR, 2.14; P = .12).
A second study examined outcomes of 7,933 individuals with hypertension who were hospitalized with COVID-19 (92% of these patients were Medicare Advantage enrollees). Of these, 14.2% died, 59.5% survived to discharge, and 26.3% underwent ongoing hospitalization. In propensity score–matched analyses, use of neither an ACE inhibitor (HR, 0.97; P = .74) nor an ARB (HR, 1.15; P = .15) was associated with risk of in-hospital mortality.
The researchers said their findings are consistent with prior evidence from randomized clinical trials suggesting a reduced risk for pneumonia with ACE inhibitors that is not observed with ARBs.
They also cited some preclinical evidence that they said suggests a possible protective role for ACE inhibitors in COVID-19: that ACE inhibitors, but not ARBs, are associated with the upregulation of ACE2 receptors, which modulate the local interactions of the renin-angiotensin-aldosterone system in the lung tissue.
“The presence of ACE2 receptors, therefore, exerts a protective effect against the development of acute lung injury in infections with SARS coronaviruses, which lead to dysregulation of these mechanisms and endothelial damage,” they added. “Further, our observations do not support theoretical concerns of adverse outcomes due to enhanced virulence of SARS coronaviruses due to overexpression of ACE2 receptors in cell cultures – an indirect binding site for these viruses.”
The authors also noted that their findings have “important implications” for four ongoing randomized trials of ACE inhibitors/ARBs in COVID-19, “as none of them align with the observations of our study.”
They pointed out that of the four ongoing trials, three are testing the use of ACE inhibitors or ARBs in the treatment of hospitalized COVID-19 patients, and one is testing the use of a 10-day course of ARBs after a positive SARS-CoV-2 test to prevent hospitalization.
Experts cautious
However, two cardiovascular experts who were asked to comment on this latest study were not overly optimistic about the data.
Michael A. Weber, MD, professor of medicine at the State University of New York, Brooklyn, said: “This report adds to the growing number of observational studies that show varying effects of ACE inhibitors and ARBs in increasing or decreasing hospitalizations for COVID-19 and the likelihood of in-hospital mortality. Overall, this new report differs from others in the remarkable effects of insurance coverage: In particular, for ACE inhibitors, there was a 40% reduction in fatal events in Medicare patients but a twofold increase in patients using commercial insurance – albeit the test for heterogeneity when comparing the two groups did not quite reach statistical significance.
“In essence, these authors are saying that ACE inhibitors are highly protective in patients aged 65 or older but bordering on harmful in patients aged below 65. I agree that it’s worthwhile to check this finding in a prospective trial ... but this hypothesis does seem to be a reach.”
Dr. Weber noted that both ACE inhibitors and ARBs increase the level of the ACE2 enzyme to which the COVID-19 virus binds in the lungs.
“The ACE inhibitors do so by inhibiting the enzyme’s action and thus stimulate further enzyme production; the ARBs block the effects of angiotensin II, which results in high angiotensin II levels that also upregulate ACE2 production,” he said. “Perhaps the ACE inhibitors, by binding to the ACE enzyme, can in some way interfere with the enzyme’s uptake of the COVID virus and thus provide some measure of clinical protection. This is possible, but why would this effect be apparent only in older people?”
John McMurray, MD, professor of medical cardiology at the University of Glasgow, Scotland, added: “This looks like a subgroup of a subgroup type analysis based on small numbers of events – I think there were only 77 hospitalizations among the 722 patients treated with an ACE inhibitor, and the Medicare Advantage subgroup was only 581 of those 722 patients.
“The hazard ratio had wide 95% CI [confidence interval] and a modest P value,” Dr. McMurray added. “So yes, interesting and hypothesis-generating, but not definitive.”
New meta-analysis
The new meta-analysis of all data so far available on ACE inhibitor and ARB use for patients with COVID-19 was published online in Annals of Internal Medicine on May 15.
The analysis is a living, systematic review with ongoing literature surveillance and critical appraisal, which will be updated as new data become available. It included 14 observational studies.
The authors, led by Katherine M. Mackey, MD, VA Portland Health Care System, Oregon, concluded: “High-certainty evidence suggests that ACE-inhibitor or ARB use is not associated with more severe COVID-19 disease, and moderate certainty evidence suggested no association between use of these medications and positive SARS-CoV-2 test results among symptomatic patients. Whether these medications increase the risk for mild or asymptomatic disease or are beneficial in COVID-19 treatment remains uncertain.”
In an accompanying editorial, William G. Kussmaul III, MD, Drexel University, Philadelphia, said that initial fears that these drugs may be harmful for patients with COVID-19 now seem to have been unfounded.
“We now have reasonable reassurance that drugs that alter the renin-angiotensin system do not pose substantial threats as either COVID-19 risk factors or severity multipliers,” he wrote.
A version of this article originally appeared on Medscape.com.
.
In addition, a new meta-analysis of all the available data on the use of ACE inhibitors and angiotensin-receptor blockers (ARBs) in COVID-19–infected patients has concluded that these drugs are not associated with more severe disease and do not increase susceptibility to infection.
The observational study, which was published on the MedRxiv preprint server on May 19 and has not yet been peer reviewed, was conducted by the health insurance company United Heath Group and by Yale University, New Haven, Conn.
The investigators analyzed data from 10,000 patients from across the United States who had tested positive for COVID-19, who were enrolled in Medicare Advantage insurance plans or were commercially insured, and who had received a prescription for one or more antihypertensive medications.
Results showed that the use of ACE inhibitors was associated with an almost 40% lower risk for COVID-19 hospitalization for older people enrolled in Medicare Advantage plans. No such benefit was seen in the younger commercially insured patients or in either group with ARBs.
At a telephone media briefing on the study, senior investigator Harlan M. Krumholz, MD, said: “We don’t believe this is enough info to change practice, but we do think this is an interesting and intriguing result.
“These findings merit a clinical trial to formally test whether ACE inhibitors – which are cheap, widely available, and well-tolerated drugs – can reduce hospitalization of patients infected with COVID-19,” added Dr. Krumholz, professor of medicine at Yale and director of the Yale New Haven Hospital Center for Outcomes Research.
A pragmatic clinical trial is now being planned. In this trial, 10,000 older people who test positive for COVID-19 will be randomly assigned to receive either a low dose of an ACE inhibitor or placebo. It is hoped that recruitment for the trial will begin in June of 2020. It is open to all eligible Americans who are older than 50 years, who test negative for COVID-19, and who are not taking medications for hypertension. Prospective patients can sign up at a dedicated website.
The randomized trial, also conducted by United Health Group and Yale, is said to be “one of the first virtual COVID-19 clinical trials to be launched at scale.”
For the observational study, the researchers identified 2,263 people who were receiving medication for hypertension and who tested positive for COVID-19. Of these, approximately two-thirds were older, Medicare Advantage enrollees; one-third were younger, commercially insured individuals.
In a propensity score–matched analysis, the investigators matched 441 patients who were taking ACE inhibitors to 441 patients who were taking other antihypertensive agents; and 412 patients who were receiving an ARB to 412 patients who were receiving other antihypertensive agents.
Results showed that during a median of 30 days after testing positive, 12.7% of the cohort were hospitalized for COVID-19. In propensity score–matched analyses, neither ACE inhibitors (hazard ratio [HR], 0.77; P = .18) nor ARBs (HR, 0.88; P =.48) were significantly associated with risk for hospitalization.
However, in analyses stratified by the insurance group, ACE inhibitors (but not ARBs) were associated with a significant lower risk for hospitalization among the Medicare group (HR, 0.61; P = .02) but not among the commercially insured group (HR, 2.14; P = .12).
A second study examined outcomes of 7,933 individuals with hypertension who were hospitalized with COVID-19 (92% of these patients were Medicare Advantage enrollees). Of these, 14.2% died, 59.5% survived to discharge, and 26.3% underwent ongoing hospitalization. In propensity score–matched analyses, use of neither an ACE inhibitor (HR, 0.97; P = .74) nor an ARB (HR, 1.15; P = .15) was associated with risk of in-hospital mortality.
The researchers said their findings are consistent with prior evidence from randomized clinical trials suggesting a reduced risk for pneumonia with ACE inhibitors that is not observed with ARBs.
They also cited some preclinical evidence that they said suggests a possible protective role for ACE inhibitors in COVID-19: that ACE inhibitors, but not ARBs, are associated with the upregulation of ACE2 receptors, which modulate the local interactions of the renin-angiotensin-aldosterone system in the lung tissue.
“The presence of ACE2 receptors, therefore, exerts a protective effect against the development of acute lung injury in infections with SARS coronaviruses, which lead to dysregulation of these mechanisms and endothelial damage,” they added. “Further, our observations do not support theoretical concerns of adverse outcomes due to enhanced virulence of SARS coronaviruses due to overexpression of ACE2 receptors in cell cultures – an indirect binding site for these viruses.”
The authors also noted that their findings have “important implications” for four ongoing randomized trials of ACE inhibitors/ARBs in COVID-19, “as none of them align with the observations of our study.”
They pointed out that of the four ongoing trials, three are testing the use of ACE inhibitors or ARBs in the treatment of hospitalized COVID-19 patients, and one is testing the use of a 10-day course of ARBs after a positive SARS-CoV-2 test to prevent hospitalization.
Experts cautious
However, two cardiovascular experts who were asked to comment on this latest study were not overly optimistic about the data.
Michael A. Weber, MD, professor of medicine at the State University of New York, Brooklyn, said: “This report adds to the growing number of observational studies that show varying effects of ACE inhibitors and ARBs in increasing or decreasing hospitalizations for COVID-19 and the likelihood of in-hospital mortality. Overall, this new report differs from others in the remarkable effects of insurance coverage: In particular, for ACE inhibitors, there was a 40% reduction in fatal events in Medicare patients but a twofold increase in patients using commercial insurance – albeit the test for heterogeneity when comparing the two groups did not quite reach statistical significance.
“In essence, these authors are saying that ACE inhibitors are highly protective in patients aged 65 or older but bordering on harmful in patients aged below 65. I agree that it’s worthwhile to check this finding in a prospective trial ... but this hypothesis does seem to be a reach.”
Dr. Weber noted that both ACE inhibitors and ARBs increase the level of the ACE2 enzyme to which the COVID-19 virus binds in the lungs.
“The ACE inhibitors do so by inhibiting the enzyme’s action and thus stimulate further enzyme production; the ARBs block the effects of angiotensin II, which results in high angiotensin II levels that also upregulate ACE2 production,” he said. “Perhaps the ACE inhibitors, by binding to the ACE enzyme, can in some way interfere with the enzyme’s uptake of the COVID virus and thus provide some measure of clinical protection. This is possible, but why would this effect be apparent only in older people?”
John McMurray, MD, professor of medical cardiology at the University of Glasgow, Scotland, added: “This looks like a subgroup of a subgroup type analysis based on small numbers of events – I think there were only 77 hospitalizations among the 722 patients treated with an ACE inhibitor, and the Medicare Advantage subgroup was only 581 of those 722 patients.
“The hazard ratio had wide 95% CI [confidence interval] and a modest P value,” Dr. McMurray added. “So yes, interesting and hypothesis-generating, but not definitive.”
New meta-analysis
The new meta-analysis of all data so far available on ACE inhibitor and ARB use for patients with COVID-19 was published online in Annals of Internal Medicine on May 15.
The analysis is a living, systematic review with ongoing literature surveillance and critical appraisal, which will be updated as new data become available. It included 14 observational studies.
The authors, led by Katherine M. Mackey, MD, VA Portland Health Care System, Oregon, concluded: “High-certainty evidence suggests that ACE-inhibitor or ARB use is not associated with more severe COVID-19 disease, and moderate certainty evidence suggested no association between use of these medications and positive SARS-CoV-2 test results among symptomatic patients. Whether these medications increase the risk for mild or asymptomatic disease or are beneficial in COVID-19 treatment remains uncertain.”
In an accompanying editorial, William G. Kussmaul III, MD, Drexel University, Philadelphia, said that initial fears that these drugs may be harmful for patients with COVID-19 now seem to have been unfounded.
“We now have reasonable reassurance that drugs that alter the renin-angiotensin system do not pose substantial threats as either COVID-19 risk factors or severity multipliers,” he wrote.
A version of this article originally appeared on Medscape.com.
As visits for AMI drop during pandemic, deaths rise
The drastic drop in admissions for acute myocardial infarctions (AMI) during the COVID-19 pandemic in Italy has seen a parallel rise in MI fatality rates in those who do present to hospitals, according to a new report. This gives credence to suggestions that people have avoided hospitals during the pandemic despite life-threatening emergencies.
Salvatore De Rosa, MD, PhD, and colleagues reported their results in the European Heart Journal.
“These data return a frightening picture of about half of AMI patients not reaching out to the hospital at all, which will probably significantly increase mortality for AMI and bring with it a number of patients with post-MI heart failure, despite the fact that acute coronary syndrome management protocols were promptly implemented,” Dr. De Rosa, of Magna Graecia University in Catanzaro, Italy, and associates wrote.
Hospitalizations down
The study counted AMIs at 54 hospital coronary care units nationwide for the week of March 12-19, 2020, at the height of the coronavirus outbreak in northern Italy, and compared that with an equivalent week in 2019. The researchers reported 319 AMIs during the week in 2020, compared with 618 in the equivalent 2019 week, a 48% reduction (P < .001). Although the outbreak was worst in northern Italy, the decline in admissions occurred throughout the country.
An analysis of subtype determined the decline in the incidence of ST-segment elevation MI lagged significantly behind that of non-STEMI. STEMI declined from 268 in 2019 to 197 in 2020, a 27% reduction, while hospitalizations for non-STEMI went from 350 to 122, a 65% reduction.
The researchers also found substantial reductions in hospitalizations for heart failure, by 47%, and atrial fibrillation, by 53%. Incidentally, the mean age of atrial fibrillation patients was considerably younger in 2020: 64.6 vs. 70 years.
Death, complications up
AMI patients who managed to get to the hospital during the pandemic also had worse outcomes. Mortality for STEMI cases more than tripled, to 14% during the outbreak, compared with 4% in 2019 (P < .001) and complication rates increased by 80% to 19% (P = .025). Twenty-one STEMI patients were positive for COVID-19 and more than a quarter (29%) died, which was more than two and a half times the 12% death rate in non–COVID-19 STEMI patients.
Analysis of the STEMI group also found that the care gap for women with heart disease worsened significantly during the pandemic, as they comprised 20.3% of cases this year, compared with 25.4% before the pandemic. Also, the reduction in admissions for STEMI during the pandemic was statistically significant at 41% for women, but not for men at 18%.
Non-STEMI patients fared better overall than STEMI patients, but their outcomes also worsened during the pandemic. Non-STEMI patients were significantly less likely to have percutaneous coronary intervention during the pandemic than previously; the rate declined by 13%, from 77% to 66%. The non-STEMI mortality rate nearly doubled, although not statistically significantly, from 1.7% to 3.3%, whereas complication rates actually more than doubled, from 5.1% to 10.7%, a significant difference. Twelve (9.8%) of the non-STEMI patients were COVID-19 positive, but none died.
Trend extends beyond borders
Dr. De Rosa and colleagues noted that their findings are in line with studies that reported similar declines for STEMI interventions in the United States and Spain during the pandemic (J Am Coll Cardiol. 2020. doi: 10.1016/j.jacc.2020.04.011; REC Interv Cardiol. 2020. doi: 10.24875/RECIC.M20000120).
Additionally, a group at Kaiser Permanente in Northern California also reported a 50% decline in the incidence of AMI hospitalizations during the pandemic (N Engl J Med. 2020 May 19. doi: 10.1056/NEJMc2015630). Likewise, a study of aortic dissections in New York reported a sharp decline in procedures during the pandemic in the city, from 13 to 3 a month (J Am Coll Cardiol. 2020 May 15. doi: 10.1016/j.jacc.2020.05.022)
The researchers in Italy didn’t aim to determine the reasons for the decline in AMI hospitalizations, but Dr. De Rosa and colleagues speculated on the following explanations: Fear of contagion in response to media reports, concentration of resources to address COVID-19 may have engendered a sense to defer less urgent care among patients and health care systems, and a true reduction in acute cardiovascular disease because people under stay-at-home orders had low physical stress.
“The concern is fewer MIs most likely means people are dying at home or presenting later as this study suggests,” said Martha Gulati, MD, chief of cardiology at the University of Arizona, Phoenix, in interpreting the results of the Italian study.
That could be a result of a mixed message from the media about accessing health care during the pandemic. “What it suggests to a lot of us is that the media has transmitted this notion that hospitals are busy taking care of COVID-19 patients, but we never said don’t come to hospital if you’re having a heart attack,” Dr. Gulati said. “I think we created some sort of fear that patients if they didn’t have COVID-19 they didn’t want to bother physicians.”
Dr. Gulati, whose practice focuses on women with CVD, said the study’s findings that interventions in women dropped more precipitously than men were concerning. “We know already that women don’t do as well after a heart attack, compared to men, and now we see it worsen it even further when women aren’t presenting,” she said. “We’re worried that this is going to increase the gap.”
Dr. DeRosa and colleagues have no relevant financial relationships to disclose.
SOURCE: De Rosa S et al. Euro Heart J. 2020 May 15. doi: 10.1093/eurheartj/ehaa409.
The drastic drop in admissions for acute myocardial infarctions (AMI) during the COVID-19 pandemic in Italy has seen a parallel rise in MI fatality rates in those who do present to hospitals, according to a new report. This gives credence to suggestions that people have avoided hospitals during the pandemic despite life-threatening emergencies.
Salvatore De Rosa, MD, PhD, and colleagues reported their results in the European Heart Journal.
“These data return a frightening picture of about half of AMI patients not reaching out to the hospital at all, which will probably significantly increase mortality for AMI and bring with it a number of patients with post-MI heart failure, despite the fact that acute coronary syndrome management protocols were promptly implemented,” Dr. De Rosa, of Magna Graecia University in Catanzaro, Italy, and associates wrote.
Hospitalizations down
The study counted AMIs at 54 hospital coronary care units nationwide for the week of March 12-19, 2020, at the height of the coronavirus outbreak in northern Italy, and compared that with an equivalent week in 2019. The researchers reported 319 AMIs during the week in 2020, compared with 618 in the equivalent 2019 week, a 48% reduction (P < .001). Although the outbreak was worst in northern Italy, the decline in admissions occurred throughout the country.
An analysis of subtype determined the decline in the incidence of ST-segment elevation MI lagged significantly behind that of non-STEMI. STEMI declined from 268 in 2019 to 197 in 2020, a 27% reduction, while hospitalizations for non-STEMI went from 350 to 122, a 65% reduction.
The researchers also found substantial reductions in hospitalizations for heart failure, by 47%, and atrial fibrillation, by 53%. Incidentally, the mean age of atrial fibrillation patients was considerably younger in 2020: 64.6 vs. 70 years.
Death, complications up
AMI patients who managed to get to the hospital during the pandemic also had worse outcomes. Mortality for STEMI cases more than tripled, to 14% during the outbreak, compared with 4% in 2019 (P < .001) and complication rates increased by 80% to 19% (P = .025). Twenty-one STEMI patients were positive for COVID-19 and more than a quarter (29%) died, which was more than two and a half times the 12% death rate in non–COVID-19 STEMI patients.
Analysis of the STEMI group also found that the care gap for women with heart disease worsened significantly during the pandemic, as they comprised 20.3% of cases this year, compared with 25.4% before the pandemic. Also, the reduction in admissions for STEMI during the pandemic was statistically significant at 41% for women, but not for men at 18%.
Non-STEMI patients fared better overall than STEMI patients, but their outcomes also worsened during the pandemic. Non-STEMI patients were significantly less likely to have percutaneous coronary intervention during the pandemic than previously; the rate declined by 13%, from 77% to 66%. The non-STEMI mortality rate nearly doubled, although not statistically significantly, from 1.7% to 3.3%, whereas complication rates actually more than doubled, from 5.1% to 10.7%, a significant difference. Twelve (9.8%) of the non-STEMI patients were COVID-19 positive, but none died.
Trend extends beyond borders
Dr. De Rosa and colleagues noted that their findings are in line with studies that reported similar declines for STEMI interventions in the United States and Spain during the pandemic (J Am Coll Cardiol. 2020. doi: 10.1016/j.jacc.2020.04.011; REC Interv Cardiol. 2020. doi: 10.24875/RECIC.M20000120).
Additionally, a group at Kaiser Permanente in Northern California also reported a 50% decline in the incidence of AMI hospitalizations during the pandemic (N Engl J Med. 2020 May 19. doi: 10.1056/NEJMc2015630). Likewise, a study of aortic dissections in New York reported a sharp decline in procedures during the pandemic in the city, from 13 to 3 a month (J Am Coll Cardiol. 2020 May 15. doi: 10.1016/j.jacc.2020.05.022)
The researchers in Italy didn’t aim to determine the reasons for the decline in AMI hospitalizations, but Dr. De Rosa and colleagues speculated on the following explanations: Fear of contagion in response to media reports, concentration of resources to address COVID-19 may have engendered a sense to defer less urgent care among patients and health care systems, and a true reduction in acute cardiovascular disease because people under stay-at-home orders had low physical stress.
“The concern is fewer MIs most likely means people are dying at home or presenting later as this study suggests,” said Martha Gulati, MD, chief of cardiology at the University of Arizona, Phoenix, in interpreting the results of the Italian study.
That could be a result of a mixed message from the media about accessing health care during the pandemic. “What it suggests to a lot of us is that the media has transmitted this notion that hospitals are busy taking care of COVID-19 patients, but we never said don’t come to hospital if you’re having a heart attack,” Dr. Gulati said. “I think we created some sort of fear that patients if they didn’t have COVID-19 they didn’t want to bother physicians.”
Dr. Gulati, whose practice focuses on women with CVD, said the study’s findings that interventions in women dropped more precipitously than men were concerning. “We know already that women don’t do as well after a heart attack, compared to men, and now we see it worsen it even further when women aren’t presenting,” she said. “We’re worried that this is going to increase the gap.”
Dr. DeRosa and colleagues have no relevant financial relationships to disclose.
SOURCE: De Rosa S et al. Euro Heart J. 2020 May 15. doi: 10.1093/eurheartj/ehaa409.
The drastic drop in admissions for acute myocardial infarctions (AMI) during the COVID-19 pandemic in Italy has seen a parallel rise in MI fatality rates in those who do present to hospitals, according to a new report. This gives credence to suggestions that people have avoided hospitals during the pandemic despite life-threatening emergencies.
Salvatore De Rosa, MD, PhD, and colleagues reported their results in the European Heart Journal.
“These data return a frightening picture of about half of AMI patients not reaching out to the hospital at all, which will probably significantly increase mortality for AMI and bring with it a number of patients with post-MI heart failure, despite the fact that acute coronary syndrome management protocols were promptly implemented,” Dr. De Rosa, of Magna Graecia University in Catanzaro, Italy, and associates wrote.
Hospitalizations down
The study counted AMIs at 54 hospital coronary care units nationwide for the week of March 12-19, 2020, at the height of the coronavirus outbreak in northern Italy, and compared that with an equivalent week in 2019. The researchers reported 319 AMIs during the week in 2020, compared with 618 in the equivalent 2019 week, a 48% reduction (P < .001). Although the outbreak was worst in northern Italy, the decline in admissions occurred throughout the country.
An analysis of subtype determined the decline in the incidence of ST-segment elevation MI lagged significantly behind that of non-STEMI. STEMI declined from 268 in 2019 to 197 in 2020, a 27% reduction, while hospitalizations for non-STEMI went from 350 to 122, a 65% reduction.
The researchers also found substantial reductions in hospitalizations for heart failure, by 47%, and atrial fibrillation, by 53%. Incidentally, the mean age of atrial fibrillation patients was considerably younger in 2020: 64.6 vs. 70 years.
Death, complications up
AMI patients who managed to get to the hospital during the pandemic also had worse outcomes. Mortality for STEMI cases more than tripled, to 14% during the outbreak, compared with 4% in 2019 (P < .001) and complication rates increased by 80% to 19% (P = .025). Twenty-one STEMI patients were positive for COVID-19 and more than a quarter (29%) died, which was more than two and a half times the 12% death rate in non–COVID-19 STEMI patients.
Analysis of the STEMI group also found that the care gap for women with heart disease worsened significantly during the pandemic, as they comprised 20.3% of cases this year, compared with 25.4% before the pandemic. Also, the reduction in admissions for STEMI during the pandemic was statistically significant at 41% for women, but not for men at 18%.
Non-STEMI patients fared better overall than STEMI patients, but their outcomes also worsened during the pandemic. Non-STEMI patients were significantly less likely to have percutaneous coronary intervention during the pandemic than previously; the rate declined by 13%, from 77% to 66%. The non-STEMI mortality rate nearly doubled, although not statistically significantly, from 1.7% to 3.3%, whereas complication rates actually more than doubled, from 5.1% to 10.7%, a significant difference. Twelve (9.8%) of the non-STEMI patients were COVID-19 positive, but none died.
Trend extends beyond borders
Dr. De Rosa and colleagues noted that their findings are in line with studies that reported similar declines for STEMI interventions in the United States and Spain during the pandemic (J Am Coll Cardiol. 2020. doi: 10.1016/j.jacc.2020.04.011; REC Interv Cardiol. 2020. doi: 10.24875/RECIC.M20000120).
Additionally, a group at Kaiser Permanente in Northern California also reported a 50% decline in the incidence of AMI hospitalizations during the pandemic (N Engl J Med. 2020 May 19. doi: 10.1056/NEJMc2015630). Likewise, a study of aortic dissections in New York reported a sharp decline in procedures during the pandemic in the city, from 13 to 3 a month (J Am Coll Cardiol. 2020 May 15. doi: 10.1016/j.jacc.2020.05.022)
The researchers in Italy didn’t aim to determine the reasons for the decline in AMI hospitalizations, but Dr. De Rosa and colleagues speculated on the following explanations: Fear of contagion in response to media reports, concentration of resources to address COVID-19 may have engendered a sense to defer less urgent care among patients and health care systems, and a true reduction in acute cardiovascular disease because people under stay-at-home orders had low physical stress.
“The concern is fewer MIs most likely means people are dying at home or presenting later as this study suggests,” said Martha Gulati, MD, chief of cardiology at the University of Arizona, Phoenix, in interpreting the results of the Italian study.
That could be a result of a mixed message from the media about accessing health care during the pandemic. “What it suggests to a lot of us is that the media has transmitted this notion that hospitals are busy taking care of COVID-19 patients, but we never said don’t come to hospital if you’re having a heart attack,” Dr. Gulati said. “I think we created some sort of fear that patients if they didn’t have COVID-19 they didn’t want to bother physicians.”
Dr. Gulati, whose practice focuses on women with CVD, said the study’s findings that interventions in women dropped more precipitously than men were concerning. “We know already that women don’t do as well after a heart attack, compared to men, and now we see it worsen it even further when women aren’t presenting,” she said. “We’re worried that this is going to increase the gap.”
Dr. DeRosa and colleagues have no relevant financial relationships to disclose.
SOURCE: De Rosa S et al. Euro Heart J. 2020 May 15. doi: 10.1093/eurheartj/ehaa409.
FROM THE EUROPEAN HEART JOURNAL
Today’s top news highlights: COVID-19 vaccine hurdles, new options in prostate cancer
Here are the stories our MDedge editors across specialties think you need to know about today:
COVID-19 vaccines face tough road
Vaccine-induced neutralizing antibodies may not be sufficient to reliably provide sustained protection against SARS-CoV-2 infection. Rather, a successful vaccine against coronavirus will likely need to incorporate T-cell epitopes to induce a long-term memory T-cell immune response to the virus, Mehrdad Matloubian, MD, PhD, predicted at the virtual edition of the American College of Rheumatology’s 2020 State-of-the-Art Clinical Symposium. “In one study, 20 of 26 patients with SARS had lost their antibody response by 6 years post infection. And they had no B-cell immunity against the SARS antigens. The good news is they did have T-cell memory against SARS virus, and people with more severe disease tended to have more T-cell memory against SARS. All of this has really important implications for vaccine development,” observed Dr. Matloubian, a rheumatologist at the University of California, San Francisco. READ MORE
Chilblain-like lesions in children with suspected COVID-19
Reports are growing of cases of children with suspected COVID-19 and chilblain-like lesions. Most recently, there were two reports in Spain and Italy. These symptoms should be considered a sign of infection with the virus, but the symptoms themselves typically don’t require treatment, according to the authors of the two new reports, which were published in Pediatric Dermatology. READ MORE
FDA approves olaparib in metastatic prostate cancer
The Food and Drug Administration approved olaparib (Lynparza) for deleterious or suspected deleterious germline or somatic homologous recombination repair (HRR) gene-mutated metastatic castration-resistant prostate cancer (mCRPC). The drug is limited to use in men who have progressed following prior treatment with enzalutamide or abiraterone. The agency also recently approved rucaparib (Rubraca) for use in patients with mCRPC that harbor deleterious BRCA mutations (germline and/or somatic). READ MORE
Drugs, alcohol, suicide
Deaths from drugs, alcohol, and suicide are on the rise, despite recent decreases in opioid overdose deaths. A report released May 21 by the Trust for America’s Health (TFAH) and the Well Being Trust shows that 151,964 Americans died in 2018 from alcohol, drugs, and suicide. Experts warn that these deaths may increase in the wake of COVID-19. “We know what works to address deaths of despair but progress has been uneven and death rates continue to climb, with communities of color experiencing higher rates of increases in drug-induced and alcohol deaths,” said TFAH President and CEO John Auerbach. READ MORE
Guidance on managing suspected stroke during COVID-19
The American Heart Association/American Stroke Association has developed a “conceptual framework” to assist emergency medical service providers and in-hospital triage teams handle suspected cases of acute stroke during the ongoing COVID-19 crisis and future pandemics. The main factors to guide the triage decision are the likelihood of a large vessel occlusion; the magnitude of additional delays because of inter-hospital transfer and work flow efficiency at the primary stroke center or acute stroke ready hospital; the need for advanced critical care resources; and the availability of bed, staff, and PPE resources at the hospitals. READ MORE
For more on COVID-19, visit our Resource Center. All of our latest news is available on MDedge.com.
Here are the stories our MDedge editors across specialties think you need to know about today:
COVID-19 vaccines face tough road
Vaccine-induced neutralizing antibodies may not be sufficient to reliably provide sustained protection against SARS-CoV-2 infection. Rather, a successful vaccine against coronavirus will likely need to incorporate T-cell epitopes to induce a long-term memory T-cell immune response to the virus, Mehrdad Matloubian, MD, PhD, predicted at the virtual edition of the American College of Rheumatology’s 2020 State-of-the-Art Clinical Symposium. “In one study, 20 of 26 patients with SARS had lost their antibody response by 6 years post infection. And they had no B-cell immunity against the SARS antigens. The good news is they did have T-cell memory against SARS virus, and people with more severe disease tended to have more T-cell memory against SARS. All of this has really important implications for vaccine development,” observed Dr. Matloubian, a rheumatologist at the University of California, San Francisco. READ MORE
Chilblain-like lesions in children with suspected COVID-19
Reports are growing of cases of children with suspected COVID-19 and chilblain-like lesions. Most recently, there were two reports in Spain and Italy. These symptoms should be considered a sign of infection with the virus, but the symptoms themselves typically don’t require treatment, according to the authors of the two new reports, which were published in Pediatric Dermatology. READ MORE
FDA approves olaparib in metastatic prostate cancer
The Food and Drug Administration approved olaparib (Lynparza) for deleterious or suspected deleterious germline or somatic homologous recombination repair (HRR) gene-mutated metastatic castration-resistant prostate cancer (mCRPC). The drug is limited to use in men who have progressed following prior treatment with enzalutamide or abiraterone. The agency also recently approved rucaparib (Rubraca) for use in patients with mCRPC that harbor deleterious BRCA mutations (germline and/or somatic). READ MORE
Drugs, alcohol, suicide
Deaths from drugs, alcohol, and suicide are on the rise, despite recent decreases in opioid overdose deaths. A report released May 21 by the Trust for America’s Health (TFAH) and the Well Being Trust shows that 151,964 Americans died in 2018 from alcohol, drugs, and suicide. Experts warn that these deaths may increase in the wake of COVID-19. “We know what works to address deaths of despair but progress has been uneven and death rates continue to climb, with communities of color experiencing higher rates of increases in drug-induced and alcohol deaths,” said TFAH President and CEO John Auerbach. READ MORE
Guidance on managing suspected stroke during COVID-19
The American Heart Association/American Stroke Association has developed a “conceptual framework” to assist emergency medical service providers and in-hospital triage teams handle suspected cases of acute stroke during the ongoing COVID-19 crisis and future pandemics. The main factors to guide the triage decision are the likelihood of a large vessel occlusion; the magnitude of additional delays because of inter-hospital transfer and work flow efficiency at the primary stroke center or acute stroke ready hospital; the need for advanced critical care resources; and the availability of bed, staff, and PPE resources at the hospitals. READ MORE
For more on COVID-19, visit our Resource Center. All of our latest news is available on MDedge.com.
Here are the stories our MDedge editors across specialties think you need to know about today:
COVID-19 vaccines face tough road
Vaccine-induced neutralizing antibodies may not be sufficient to reliably provide sustained protection against SARS-CoV-2 infection. Rather, a successful vaccine against coronavirus will likely need to incorporate T-cell epitopes to induce a long-term memory T-cell immune response to the virus, Mehrdad Matloubian, MD, PhD, predicted at the virtual edition of the American College of Rheumatology’s 2020 State-of-the-Art Clinical Symposium. “In one study, 20 of 26 patients with SARS had lost their antibody response by 6 years post infection. And they had no B-cell immunity against the SARS antigens. The good news is they did have T-cell memory against SARS virus, and people with more severe disease tended to have more T-cell memory against SARS. All of this has really important implications for vaccine development,” observed Dr. Matloubian, a rheumatologist at the University of California, San Francisco. READ MORE
Chilblain-like lesions in children with suspected COVID-19
Reports are growing of cases of children with suspected COVID-19 and chilblain-like lesions. Most recently, there were two reports in Spain and Italy. These symptoms should be considered a sign of infection with the virus, but the symptoms themselves typically don’t require treatment, according to the authors of the two new reports, which were published in Pediatric Dermatology. READ MORE
FDA approves olaparib in metastatic prostate cancer
The Food and Drug Administration approved olaparib (Lynparza) for deleterious or suspected deleterious germline or somatic homologous recombination repair (HRR) gene-mutated metastatic castration-resistant prostate cancer (mCRPC). The drug is limited to use in men who have progressed following prior treatment with enzalutamide or abiraterone. The agency also recently approved rucaparib (Rubraca) for use in patients with mCRPC that harbor deleterious BRCA mutations (germline and/or somatic). READ MORE
Drugs, alcohol, suicide
Deaths from drugs, alcohol, and suicide are on the rise, despite recent decreases in opioid overdose deaths. A report released May 21 by the Trust for America’s Health (TFAH) and the Well Being Trust shows that 151,964 Americans died in 2018 from alcohol, drugs, and suicide. Experts warn that these deaths may increase in the wake of COVID-19. “We know what works to address deaths of despair but progress has been uneven and death rates continue to climb, with communities of color experiencing higher rates of increases in drug-induced and alcohol deaths,” said TFAH President and CEO John Auerbach. READ MORE
Guidance on managing suspected stroke during COVID-19
The American Heart Association/American Stroke Association has developed a “conceptual framework” to assist emergency medical service providers and in-hospital triage teams handle suspected cases of acute stroke during the ongoing COVID-19 crisis and future pandemics. The main factors to guide the triage decision are the likelihood of a large vessel occlusion; the magnitude of additional delays because of inter-hospital transfer and work flow efficiency at the primary stroke center or acute stroke ready hospital; the need for advanced critical care resources; and the availability of bed, staff, and PPE resources at the hospitals. READ MORE
For more on COVID-19, visit our Resource Center. All of our latest news is available on MDedge.com.
COVID-19 may cause subacute thyroiditis
Coronavirus disease of 2019 (COVID-19) may lead to subacute thyroiditis in some patients, which is suspected to have viral or postviral origin, especially with upper respiratory tract infections, according to a case study in the Journal of Clinical Endocrinology & Metabolism.
Alessandro Brancatella, a PhD student at the University Hospital Pisa (Italy), and colleagues described the case of an 18-year-old woman who was tested Feb. 21 for SARS-CoV-2 infection after her father was hospitalized because of COVID-19. Her results were positive for the virus, and not long after, she developed mild symptoms. By March 13 and again on March 14, test swabs for SARS-CoV-2 were both negative.
On March 17, she presented with fever, fatigue, palpitations, and neck pain that radiated to her jaw. Testing and physical examination pointed to subacute thyroiditis, and she was soon diagnosed and treated with prednisone. Her neck pain and fever disappeared within 2 days, and the remaining symptoms went away within a week.
The authors noted that the woman’s thyroid had been evaluated before she tested positive for SARS-CoV-2, and at that time, thyroid disease was ruled out. They also pointed out that, although the exact etiology for subacute thyroiditis is unknown, “it is common opinion that the disease is due to a viral infection or to a post-viral inflammatory reaction in genetically predisposed subjects.” They cited examples of viruses with suspected causal associations, including mumps, Epstein-Barr virus, and HIV, and they suggested that, based on the timing of the woman’s subacute thyroiditis and the normal results of her thyroid evaluation before developing COVID-19, SARS-CoV-2 be added to that list.
“To our knowledge, this is the first case of [subacute thyroiditis] related to SARS-CoV-2,” they concluded. “We therefore believe that physicians should be alerted about the possibility of this additional clinical manifestation related to SARS-CoV-2 infection.”
One author reported funding from the University of Pisa.
SOURCE: Brancatella A et al. J Clin Endocrinol Metab. 2020 May 21. doi: 10.1210/clinem/dgaa276.
Coronavirus disease of 2019 (COVID-19) may lead to subacute thyroiditis in some patients, which is suspected to have viral or postviral origin, especially with upper respiratory tract infections, according to a case study in the Journal of Clinical Endocrinology & Metabolism.
Alessandro Brancatella, a PhD student at the University Hospital Pisa (Italy), and colleagues described the case of an 18-year-old woman who was tested Feb. 21 for SARS-CoV-2 infection after her father was hospitalized because of COVID-19. Her results were positive for the virus, and not long after, she developed mild symptoms. By March 13 and again on March 14, test swabs for SARS-CoV-2 were both negative.
On March 17, she presented with fever, fatigue, palpitations, and neck pain that radiated to her jaw. Testing and physical examination pointed to subacute thyroiditis, and she was soon diagnosed and treated with prednisone. Her neck pain and fever disappeared within 2 days, and the remaining symptoms went away within a week.
The authors noted that the woman’s thyroid had been evaluated before she tested positive for SARS-CoV-2, and at that time, thyroid disease was ruled out. They also pointed out that, although the exact etiology for subacute thyroiditis is unknown, “it is common opinion that the disease is due to a viral infection or to a post-viral inflammatory reaction in genetically predisposed subjects.” They cited examples of viruses with suspected causal associations, including mumps, Epstein-Barr virus, and HIV, and they suggested that, based on the timing of the woman’s subacute thyroiditis and the normal results of her thyroid evaluation before developing COVID-19, SARS-CoV-2 be added to that list.
“To our knowledge, this is the first case of [subacute thyroiditis] related to SARS-CoV-2,” they concluded. “We therefore believe that physicians should be alerted about the possibility of this additional clinical manifestation related to SARS-CoV-2 infection.”
One author reported funding from the University of Pisa.
SOURCE: Brancatella A et al. J Clin Endocrinol Metab. 2020 May 21. doi: 10.1210/clinem/dgaa276.
Coronavirus disease of 2019 (COVID-19) may lead to subacute thyroiditis in some patients, which is suspected to have viral or postviral origin, especially with upper respiratory tract infections, according to a case study in the Journal of Clinical Endocrinology & Metabolism.
Alessandro Brancatella, a PhD student at the University Hospital Pisa (Italy), and colleagues described the case of an 18-year-old woman who was tested Feb. 21 for SARS-CoV-2 infection after her father was hospitalized because of COVID-19. Her results were positive for the virus, and not long after, she developed mild symptoms. By March 13 and again on March 14, test swabs for SARS-CoV-2 were both negative.
On March 17, she presented with fever, fatigue, palpitations, and neck pain that radiated to her jaw. Testing and physical examination pointed to subacute thyroiditis, and she was soon diagnosed and treated with prednisone. Her neck pain and fever disappeared within 2 days, and the remaining symptoms went away within a week.
The authors noted that the woman’s thyroid had been evaluated before she tested positive for SARS-CoV-2, and at that time, thyroid disease was ruled out. They also pointed out that, although the exact etiology for subacute thyroiditis is unknown, “it is common opinion that the disease is due to a viral infection or to a post-viral inflammatory reaction in genetically predisposed subjects.” They cited examples of viruses with suspected causal associations, including mumps, Epstein-Barr virus, and HIV, and they suggested that, based on the timing of the woman’s subacute thyroiditis and the normal results of her thyroid evaluation before developing COVID-19, SARS-CoV-2 be added to that list.
“To our knowledge, this is the first case of [subacute thyroiditis] related to SARS-CoV-2,” they concluded. “We therefore believe that physicians should be alerted about the possibility of this additional clinical manifestation related to SARS-CoV-2 infection.”
One author reported funding from the University of Pisa.
SOURCE: Brancatella A et al. J Clin Endocrinol Metab. 2020 May 21. doi: 10.1210/clinem/dgaa276.
FROM THE JOURNAL OF CLINICAL ENDOCRINOLOGY & METABOLISM