Clinical Psychiatry News

More patients are surviving critical illnesses requiring ICU care but many emerge with physical debility that may or may not eventually resolve.

Over the past decade, functional status deterioration after critical illness has become more common and of greater magnitude, despite concurrent efforts to reduce post–intensive care syndrome, based on a retrospective analysis of more than 100,000 patients.

Almost one-third of patients who survived nonsurgical ICU admission had evidence of functional status decline, reported lead author Nicholas E. Ingraham, MD, of the University of Minnesota, Minneapolis, and colleagues.

“Increasing capacity and decreasing mortality have created an evolving and diverse population of ICU survivors,” the investigators wrote in Critical Care Medicine. “Today’s survivors of critical illness are increasingly burdened by extensive physical and psychological comorbidities, often resulting in reduced quality of life.”

To determine trends in post–intensive care syndrome from 2008 to 2016, Dr. Ingraham and colleagues analyzed data from the Cerner Acute Physiology and Chronic Health Evaluation outcomes database, a national prospective cohort. Out of 202,786 adult patients admitted to the ICU, 129,917 were eligible for the study. Patients were excluded because of surgical admission, death, lack of functional status documentation, or inadequate hospital size or duration of participation. The final dataset had a median age of 63 years, with a slight predominance of male patients (54.0%). Most patients (80.9%) were White.

The primary outcome was defined as presence or absence of functional status deterioration, based on functional status at admission versus time of discharge. The secondary outcome was magnitude of deterioration over time.

The analysis, which controlled for age and severity of illness, revealed concerning trends for both outcomes.

Across the entire cohort 38,116 patients (29.3%) had functional status deterioration, with a 15% increase in prevalence over the course of the decade that spanned all disease categories (prevalence rate ratio, 1.15; 95% confidence interval, 1.13-1.17; P < .001). The magnitude of functional status decline also increased by 4% (odds ratio, 1.04; P < .001), with all but nonsurgical trauma patients showing greater deterioration over time.

“However, despite the decreasing magnitude of functional status deterioration in nonsurgical trauma, many admission diagnoses in this category remain in the top quartile of higher risk for functional status deterioration,” the investigators noted.

Functional status decline was most common among patients with head and polytrauma (OR, 3.39), followed closely by chest and spine trauma (OR, 3.38), and spine trauma (OR, 3.19). The top quartile of categories for prevalence of deterioration included nonsurgical trauma, neurologic, pulmonary, and gastrointestinal diseases.

Functional status decline was least common among patients diagnosed with diabetic ketoacidosis (OR, 0.27) or asthma (OR, 0.35).

“We believe our study provides important information that can be used in beginning to identify patients at high risk of functional status decline,” the investigators concluded. “Improving the identification of these patients and targeting appropriate interventions to mitigate this decline will be important directions for future studies in this area.”

According to David L. Bowton, MD, FCCP, professor emeritus, section on critical care, Wake Forest Baptist Health, Winston-Salem, N.C., the findings show just how common functional decline is after critical illness, and may actually underestimate prevalence.

“Because the authors employed a course evaluation tool employing only three categories of ability/disability and abstracted the level of disability from the medical record, they likely underestimated the frequency of clinically important, though not detected, disability at the time of hospital discharge,” Dr. Bowton said. “The study did not address cognitive impairment which can be detected in half of patients at 3 months following critical illness, and which significantly affects patients’ quality of life (Am J Respir Crit Care Med. 2020;202[2]:193-201).”

Dr. Bowton suggested that evidence-based methods of preventing post–intensive care syndrome are limited.

“Current efforts to improve post-ICU functional and cognitive outcomes suffer from the lack of proven effective interventions (Crit Care Med. 2019;47[11]:1607-18),” he said. “Observational data indicates that compliance with the ABCDEF bundle decreases the duration and incidence of delirium, ICU length of stay, duration of mechanical ventilation, and mortality (Crit Care Med. 2019;47[1]:3-14). However, the implications of these improvements on postdischarge functional outcomes are unknown as area the relative importance of individual elements of the bundle. Early mobility and patient and family diaries appear to improve functional status at discharge and postdischarge anxiety and depression, though the evidence supporting this is thin.”

Appropriate intervention may be especially challenging during the COVID-19 pandemic, he added.

“The impact of COVID on ICU staffing adequacy and stress is significant and the impact on quality bundle compliance and the availability of support services is currently not clear, but likely to be detrimental, especially to support services such as physical therapy that are already commonly understaffed,” Dr. Bowton said.

The study was supported by grants from the University of Minnesota’s Critical Care Research and Programmatic Development Program; the National Heart, Lung, and Blood Institute; and the University of Minnesota Clinical and Translational Science via the National Center for Advancing Translational Sciences. The investigators reported financial relationships with no other relevant organizations. Dr. Bowton reported no conflicts of interest.

SOURCE: Ingraham NE et al. Crit Care Med. 2020 Nov. doi: 10.1097/CCM.0000000000004524.

More patients are surviving critical illnesses requiring ICU care but many emerge with physical debility that may or may not eventually resolve.

Over the past decade, functional status deterioration after critical illness has become more common and of greater magnitude, despite concurrent efforts to reduce post–intensive care syndrome, based on a retrospective analysis of more than 100,000 patients.

Almost one-third of patients who survived nonsurgical ICU admission had evidence of functional status decline, reported lead author Nicholas E. Ingraham, MD, of the University of Minnesota, Minneapolis, and colleagues.

“Increasing capacity and decreasing mortality have created an evolving and diverse population of ICU survivors,” the investigators wrote in Critical Care Medicine. “Today’s survivors of critical illness are increasingly burdened by extensive physical and psychological comorbidities, often resulting in reduced quality of life.”

To determine trends in post–intensive care syndrome from 2008 to 2016, Dr. Ingraham and colleagues analyzed data from the Cerner Acute Physiology and Chronic Health Evaluation outcomes database, a national prospective cohort. Out of 202,786 adult patients admitted to the ICU, 129,917 were eligible for the study. Patients were excluded because of surgical admission, death, lack of functional status documentation, or inadequate hospital size or duration of participation. The final dataset had a median age of 63 years, with a slight predominance of male patients (54.0%). Most patients (80.9%) were White.

The primary outcome was defined as presence or absence of functional status deterioration, based on functional status at admission versus time of discharge. The secondary outcome was magnitude of deterioration over time.

The analysis, which controlled for age and severity of illness, revealed concerning trends for both outcomes.

Across the entire cohort 38,116 patients (29.3%) had functional status deterioration, with a 15% increase in prevalence over the course of the decade that spanned all disease categories (prevalence rate ratio, 1.15; 95% confidence interval, 1.13-1.17; P < .001). The magnitude of functional status decline also increased by 4% (odds ratio, 1.04; P < .001), with all but nonsurgical trauma patients showing greater deterioration over time.

“However, despite the decreasing magnitude of functional status deterioration in nonsurgical trauma, many admission diagnoses in this category remain in the top quartile of higher risk for functional status deterioration,” the investigators noted.

Functional status decline was most common among patients with head and polytrauma (OR, 3.39), followed closely by chest and spine trauma (OR, 3.38), and spine trauma (OR, 3.19). The top quartile of categories for prevalence of deterioration included nonsurgical trauma, neurologic, pulmonary, and gastrointestinal diseases.

Functional status decline was least common among patients diagnosed with diabetic ketoacidosis (OR, 0.27) or asthma (OR, 0.35).

“We believe our study provides important information that can be used in beginning to identify patients at high risk of functional status decline,” the investigators concluded. “Improving the identification of these patients and targeting appropriate interventions to mitigate this decline will be important directions for future studies in this area.”

According to David L. Bowton, MD, FCCP, professor emeritus, section on critical care, Wake Forest Baptist Health, Winston-Salem, N.C., the findings show just how common functional decline is after critical illness, and may actually underestimate prevalence.

“Because the authors employed a course evaluation tool employing only three categories of ability/disability and abstracted the level of disability from the medical record, they likely underestimated the frequency of clinically important, though not detected, disability at the time of hospital discharge,” Dr. Bowton said. “The study did not address cognitive impairment which can be detected in half of patients at 3 months following critical illness, and which significantly affects patients’ quality of life (Am J Respir Crit Care Med. 2020;202[2]:193-201).”

Dr. Bowton suggested that evidence-based methods of preventing post–intensive care syndrome are limited.

“Current efforts to improve post-ICU functional and cognitive outcomes suffer from the lack of proven effective interventions (Crit Care Med. 2019;47[11]:1607-18),” he said. “Observational data indicates that compliance with the ABCDEF bundle decreases the duration and incidence of delirium, ICU length of stay, duration of mechanical ventilation, and mortality (Crit Care Med. 2019;47[1]:3-14). However, the implications of these improvements on postdischarge functional outcomes are unknown as area the relative importance of individual elements of the bundle. Early mobility and patient and family diaries appear to improve functional status at discharge and postdischarge anxiety and depression, though the evidence supporting this is thin.”

Appropriate intervention may be especially challenging during the COVID-19 pandemic, he added.

“The impact of COVID on ICU staffing adequacy and stress is significant and the impact on quality bundle compliance and the availability of support services is currently not clear, but likely to be detrimental, especially to support services such as physical therapy that are already commonly understaffed,” Dr. Bowton said.

The study was supported by grants from the University of Minnesota’s Critical Care Research and Programmatic Development Program; the National Heart, Lung, and Blood Institute; and the University of Minnesota Clinical and Translational Science via the National Center for Advancing Translational Sciences. The investigators reported financial relationships with no other relevant organizations. Dr. Bowton reported no conflicts of interest.

SOURCE: Ingraham NE et al. Crit Care Med. 2020 Nov. doi: 10.1097/CCM.0000000000004524.

More patients are surviving critical illnesses requiring ICU care but many emerge with physical debility that may or may not eventually resolve.

Over the past decade, functional status deterioration after critical illness has become more common and of greater magnitude, despite concurrent efforts to reduce post–intensive care syndrome, based on a retrospective analysis of more than 100,000 patients.

Almost one-third of patients who survived nonsurgical ICU admission had evidence of functional status decline, reported lead author Nicholas E. Ingraham, MD, of the University of Minnesota, Minneapolis, and colleagues.

“Increasing capacity and decreasing mortality have created an evolving and diverse population of ICU survivors,” the investigators wrote in Critical Care Medicine. “Today’s survivors of critical illness are increasingly burdened by extensive physical and psychological comorbidities, often resulting in reduced quality of life.”

To determine trends in post–intensive care syndrome from 2008 to 2016, Dr. Ingraham and colleagues analyzed data from the Cerner Acute Physiology and Chronic Health Evaluation outcomes database, a national prospective cohort. Out of 202,786 adult patients admitted to the ICU, 129,917 were eligible for the study. Patients were excluded because of surgical admission, death, lack of functional status documentation, or inadequate hospital size or duration of participation. The final dataset had a median age of 63 years, with a slight predominance of male patients (54.0%). Most patients (80.9%) were White.

The primary outcome was defined as presence or absence of functional status deterioration, based on functional status at admission versus time of discharge. The secondary outcome was magnitude of deterioration over time.

The analysis, which controlled for age and severity of illness, revealed concerning trends for both outcomes.

Across the entire cohort 38,116 patients (29.3%) had functional status deterioration, with a 15% increase in prevalence over the course of the decade that spanned all disease categories (prevalence rate ratio, 1.15; 95% confidence interval, 1.13-1.17; P < .001). The magnitude of functional status decline also increased by 4% (odds ratio, 1.04; P < .001), with all but nonsurgical trauma patients showing greater deterioration over time.

“However, despite the decreasing magnitude of functional status deterioration in nonsurgical trauma, many admission diagnoses in this category remain in the top quartile of higher risk for functional status deterioration,” the investigators noted.

Functional status decline was most common among patients with head and polytrauma (OR, 3.39), followed closely by chest and spine trauma (OR, 3.38), and spine trauma (OR, 3.19). The top quartile of categories for prevalence of deterioration included nonsurgical trauma, neurologic, pulmonary, and gastrointestinal diseases.

Functional status decline was least common among patients diagnosed with diabetic ketoacidosis (OR, 0.27) or asthma (OR, 0.35).

“We believe our study provides important information that can be used in beginning to identify patients at high risk of functional status decline,” the investigators concluded. “Improving the identification of these patients and targeting appropriate interventions to mitigate this decline will be important directions for future studies in this area.”

According to David L. Bowton, MD, FCCP, professor emeritus, section on critical care, Wake Forest Baptist Health, Winston-Salem, N.C., the findings show just how common functional decline is after critical illness, and may actually underestimate prevalence.

“Because the authors employed a course evaluation tool employing only three categories of ability/disability and abstracted the level of disability from the medical record, they likely underestimated the frequency of clinically important, though not detected, disability at the time of hospital discharge,” Dr. Bowton said. “The study did not address cognitive impairment which can be detected in half of patients at 3 months following critical illness, and which significantly affects patients’ quality of life (Am J Respir Crit Care Med. 2020;202[2]:193-201).”

Dr. Bowton suggested that evidence-based methods of preventing post–intensive care syndrome are limited.

“Current efforts to improve post-ICU functional and cognitive outcomes suffer from the lack of proven effective interventions (Crit Care Med. 2019;47[11]:1607-18),” he said. “Observational data indicates that compliance with the ABCDEF bundle decreases the duration and incidence of delirium, ICU length of stay, duration of mechanical ventilation, and mortality (Crit Care Med. 2019;47[1]:3-14). However, the implications of these improvements on postdischarge functional outcomes are unknown as area the relative importance of individual elements of the bundle. Early mobility and patient and family diaries appear to improve functional status at discharge and postdischarge anxiety and depression, though the evidence supporting this is thin.”

Appropriate intervention may be especially challenging during the COVID-19 pandemic, he added.

“The impact of COVID on ICU staffing adequacy and stress is significant and the impact on quality bundle compliance and the availability of support services is currently not clear, but likely to be detrimental, especially to support services such as physical therapy that are already commonly understaffed,” Dr. Bowton said.

The study was supported by grants from the University of Minnesota’s Critical Care Research and Programmatic Development Program; the National Heart, Lung, and Blood Institute; and the University of Minnesota Clinical and Translational Science via the National Center for Advancing Translational Sciences. The investigators reported financial relationships with no other relevant organizations. Dr. Bowton reported no conflicts of interest.

SOURCE: Ingraham NE et al. Crit Care Med. 2020 Nov. doi: 10.1097/CCM.0000000000004524.

COVID-19 patients who survive their hospitalization don’t leave the disease behind upon discharge, as a significant percentage died within 60 days of discharge, with an ICU admission heightening the risk, according to an observational study of 38 Michigan hospitals. What’s more, many of them were burdened with health and emotional challenges ranging from hospital readmission to job loss and financial problems.

“These data confirm that the toll of COVID-19 extends well beyond hospitalization, a finding consistent with long-term sequelae from sepsis and other severe respiratory viral illnesses,” wrote lead author Vineet Chopra, MBBS, of the University of Michigan, Ann Arbor, and colleagues (Ann Intern Med. 2020 Nov 11: doi: 10.7326/M20-5661)

The researchers found that 29.2% of all patients hospitalized for COVID-19 from March 16 to July 1 died. The observational cohort study included 1,648 COVID-19 patients hospitalized at 38 Michigan hospitals participating in a statewide collaborative.

The bulk of those deaths occurred during hospitalization: 24.2% of patients (n = 398). Of the 1,250 patients discharged, 78% (n = 975) went home and 12.6% (n = 158) went to a skilled nursing facility, with the remainder unaccounted for. Within 60 days of discharge, 6.7% (n = 84) of hospitalized survivors had died and 15.2% (n = 189) were readmitted. The researchers gathered 60-day postdischarge data via a telephone survey, contacting 41.8% (n = 488) of discharged patients.

Outcomes were even worse for discharged patients who spent time in the ICU. The death rate among this group was 10.4% (17 of 165) after discharge. That resulted in an overall study death rate of 63.5% (n = 257) for the 405 patients who were in the ICU.

While the study data were in the first wave of the novel coronavirus, the findings have relevance today, said Mary Jo Farmer, MD, PhD, FCCP, directory of pulmonary hypertension services at Baystate Health in Springfield, Mass.

“This is the best information we have to date,” she said. “We have to continue to have an open mind and expect that this information may change as the virus possibly mutates as it spreads, and we should continue doing these types of outcomes studies at 90 days, 120 days, etc.”

The median age of study patients was 62, with a range of 50-72. The three leading comorbidities among discharged patients were hypertension (n = 800, 64%), diabetes (34.9%, n = 436), and cardiovascular disease (24.1%, n = 301).

Poor postdischarge outcomes weren’t limited to mortality and readmission. Almost 19% (n = 92) reported new or worsening cardiopulmonary symptoms such as cough and dyspnea, 13.3% had a persistent loss of taste or smell, and 12% (n = 58) reported more difficulty with daily living tasks.

The after-effects were not only physical. Nearly half of discharged patients (48.7%, n = 238) reported emotional effects and almost 6% (n = 28) sought mental health care. Among the 40% (n = 195) employed before they were hospitalized, 36% (n = 78) couldn’t return to work because of health issues or layoffs. Sixty percent (n = 117) of the pre-employed discharged patients did return to work, but 25% (n = 30) did so with reduced hours or modified job duties because of health problems.

Financial problems were also a burden. More than a third, 36.7% (n = 179), reported some financial impact from their hospitalization. About 10% (n = 47) said they used most or all of their savings, and 7% (n = 35) said they resorted to rationing necessities such as food or medications.

The researchers noted that one in five patients had no primary care follow-up at 2 months post discharge. “Collectively, these findings suggest that better models to support COVID-19 survivors are necessary,” said Dr. Chopra and colleagues.

The postdischarge course for patients involves two humps, said Sachin Gupta, MD, FCCP a pulmonary and critical care specialist at Alameda Health System in Oakland, Calif.: Getting over the hospitalization itself and the recovery phase. “As you look at the median age of the survivors, elderly patients who survive a hospital stay are still going to have a period of recovery, and like any viral illness that leads to someone being hospitalized, when you have an elderly patient with comorbidities, not all of them can make it over that final hump.”

SOURCE: Chopra V et al. Ann Intern Med. 2020 Nov 11. doi: 10.7326/M20-5661.

COVID-19 patients who survive their hospitalization don’t leave the disease behind upon discharge, as a significant percentage died within 60 days of discharge, with an ICU admission heightening the risk, according to an observational study of 38 Michigan hospitals. What’s more, many of them were burdened with health and emotional challenges ranging from hospital readmission to job loss and financial problems.

“These data confirm that the toll of COVID-19 extends well beyond hospitalization, a finding consistent with long-term sequelae from sepsis and other severe respiratory viral illnesses,” wrote lead author Vineet Chopra, MBBS, of the University of Michigan, Ann Arbor, and colleagues (Ann Intern Med. 2020 Nov 11: doi: 10.7326/M20-5661)

The researchers found that 29.2% of all patients hospitalized for COVID-19 from March 16 to July 1 died. The observational cohort study included 1,648 COVID-19 patients hospitalized at 38 Michigan hospitals participating in a statewide collaborative.

The bulk of those deaths occurred during hospitalization: 24.2% of patients (n = 398). Of the 1,250 patients discharged, 78% (n = 975) went home and 12.6% (n = 158) went to a skilled nursing facility, with the remainder unaccounted for. Within 60 days of discharge, 6.7% (n = 84) of hospitalized survivors had died and 15.2% (n = 189) were readmitted. The researchers gathered 60-day postdischarge data via a telephone survey, contacting 41.8% (n = 488) of discharged patients.

Outcomes were even worse for discharged patients who spent time in the ICU. The death rate among this group was 10.4% (17 of 165) after discharge. That resulted in an overall study death rate of 63.5% (n = 257) for the 405 patients who were in the ICU.

While the study data were in the first wave of the novel coronavirus, the findings have relevance today, said Mary Jo Farmer, MD, PhD, FCCP, directory of pulmonary hypertension services at Baystate Health in Springfield, Mass.

“This is the best information we have to date,” she said. “We have to continue to have an open mind and expect that this information may change as the virus possibly mutates as it spreads, and we should continue doing these types of outcomes studies at 90 days, 120 days, etc.”

The median age of study patients was 62, with a range of 50-72. The three leading comorbidities among discharged patients were hypertension (n = 800, 64%), diabetes (34.9%, n = 436), and cardiovascular disease (24.1%, n = 301).

Poor postdischarge outcomes weren’t limited to mortality and readmission. Almost 19% (n = 92) reported new or worsening cardiopulmonary symptoms such as cough and dyspnea, 13.3% had a persistent loss of taste or smell, and 12% (n = 58) reported more difficulty with daily living tasks.

The after-effects were not only physical. Nearly half of discharged patients (48.7%, n = 238) reported emotional effects and almost 6% (n = 28) sought mental health care. Among the 40% (n = 195) employed before they were hospitalized, 36% (n = 78) couldn’t return to work because of health issues or layoffs. Sixty percent (n = 117) of the pre-employed discharged patients did return to work, but 25% (n = 30) did so with reduced hours or modified job duties because of health problems.

Financial problems were also a burden. More than a third, 36.7% (n = 179), reported some financial impact from their hospitalization. About 10% (n = 47) said they used most or all of their savings, and 7% (n = 35) said they resorted to rationing necessities such as food or medications.

The researchers noted that one in five patients had no primary care follow-up at 2 months post discharge. “Collectively, these findings suggest that better models to support COVID-19 survivors are necessary,” said Dr. Chopra and colleagues.

The postdischarge course for patients involves two humps, said Sachin Gupta, MD, FCCP a pulmonary and critical care specialist at Alameda Health System in Oakland, Calif.: Getting over the hospitalization itself and the recovery phase. “As you look at the median age of the survivors, elderly patients who survive a hospital stay are still going to have a period of recovery, and like any viral illness that leads to someone being hospitalized, when you have an elderly patient with comorbidities, not all of them can make it over that final hump.”

SOURCE: Chopra V et al. Ann Intern Med. 2020 Nov 11. doi: 10.7326/M20-5661.

COVID-19 patients who survive their hospitalization don’t leave the disease behind upon discharge, as a significant percentage died within 60 days of discharge, with an ICU admission heightening the risk, according to an observational study of 38 Michigan hospitals. What’s more, many of them were burdened with health and emotional challenges ranging from hospital readmission to job loss and financial problems.

“These data confirm that the toll of COVID-19 extends well beyond hospitalization, a finding consistent with long-term sequelae from sepsis and other severe respiratory viral illnesses,” wrote lead author Vineet Chopra, MBBS, of the University of Michigan, Ann Arbor, and colleagues (Ann Intern Med. 2020 Nov 11: doi: 10.7326/M20-5661)

The researchers found that 29.2% of all patients hospitalized for COVID-19 from March 16 to July 1 died. The observational cohort study included 1,648 COVID-19 patients hospitalized at 38 Michigan hospitals participating in a statewide collaborative.

The bulk of those deaths occurred during hospitalization: 24.2% of patients (n = 398). Of the 1,250 patients discharged, 78% (n = 975) went home and 12.6% (n = 158) went to a skilled nursing facility, with the remainder unaccounted for. Within 60 days of discharge, 6.7% (n = 84) of hospitalized survivors had died and 15.2% (n = 189) were readmitted. The researchers gathered 60-day postdischarge data via a telephone survey, contacting 41.8% (n = 488) of discharged patients.

Outcomes were even worse for discharged patients who spent time in the ICU. The death rate among this group was 10.4% (17 of 165) after discharge. That resulted in an overall study death rate of 63.5% (n = 257) for the 405 patients who were in the ICU.

While the study data were in the first wave of the novel coronavirus, the findings have relevance today, said Mary Jo Farmer, MD, PhD, FCCP, directory of pulmonary hypertension services at Baystate Health in Springfield, Mass.

“This is the best information we have to date,” she said. “We have to continue to have an open mind and expect that this information may change as the virus possibly mutates as it spreads, and we should continue doing these types of outcomes studies at 90 days, 120 days, etc.”

The median age of study patients was 62, with a range of 50-72. The three leading comorbidities among discharged patients were hypertension (n = 800, 64%), diabetes (34.9%, n = 436), and cardiovascular disease (24.1%, n = 301).

Poor postdischarge outcomes weren’t limited to mortality and readmission. Almost 19% (n = 92) reported new or worsening cardiopulmonary symptoms such as cough and dyspnea, 13.3% had a persistent loss of taste or smell, and 12% (n = 58) reported more difficulty with daily living tasks.

The after-effects were not only physical. Nearly half of discharged patients (48.7%, n = 238) reported emotional effects and almost 6% (n = 28) sought mental health care. Among the 40% (n = 195) employed before they were hospitalized, 36% (n = 78) couldn’t return to work because of health issues or layoffs. Sixty percent (n = 117) of the pre-employed discharged patients did return to work, but 25% (n = 30) did so with reduced hours or modified job duties because of health problems.

Financial problems were also a burden. More than a third, 36.7% (n = 179), reported some financial impact from their hospitalization. About 10% (n = 47) said they used most or all of their savings, and 7% (n = 35) said they resorted to rationing necessities such as food or medications.

The researchers noted that one in five patients had no primary care follow-up at 2 months post discharge. “Collectively, these findings suggest that better models to support COVID-19 survivors are necessary,” said Dr. Chopra and colleagues.

The postdischarge course for patients involves two humps, said Sachin Gupta, MD, FCCP a pulmonary and critical care specialist at Alameda Health System in Oakland, Calif.: Getting over the hospitalization itself and the recovery phase. “As you look at the median age of the survivors, elderly patients who survive a hospital stay are still going to have a period of recovery, and like any viral illness that leads to someone being hospitalized, when you have an elderly patient with comorbidities, not all of them can make it over that final hump.”

SOURCE: Chopra V et al. Ann Intern Med. 2020 Nov 11. doi: 10.7326/M20-5661.

The Moderna mRNA-1273 vaccine, in development to prevent COVID-19, yielded 94.5% efficacy in early results and is generally well tolerated, the company announced early Monday. The product can be stored at refrigeration temperatures common to many physician offices, pharmacies, and hospitals.

The first interim results of the phase 3 COVE trial included 95 participants with confirmed COVID-19. An independent data safety monitoring board, which was appointed by the National Institutes of Health, informed Moderna that 90 of the patients who were positive for COVID-19 were in a placebo group and that 5 patients were in the mRNA-1273 vaccine group, resulting in a vaccine efficacy of 94.5% (P < .0001).

Interim data included 11 patients with severe COVID-19, all of whom were in the placebo group.

“This positive interim analysis from our phase 3 study has given us the first clinical validation that our vaccine can prevent COVID-19 disease, including severe disease,” said Stéphane Bancel, CEO of Moderna, said in a statement.

The vaccine met its primary study endpoint, which was based on adjudicated data that were collected starting 2 weeks after the second dose of mRNA-1273. The interim study population included people who could be at higher risk for COVID-19, including 15 adults aged 65 years and older and 20 participants from diverse communities.
 

Safety data

The DSMB also reviewed safety data for the COVE study interim results. The vaccine was generally safe and well tolerated, as determined on the basis of solicited adverse events. Most adverse events were mild to moderate and were generally short-lived, according to a company news release.

Injection-site pain was reported in 2.7% of participants after the first dose. After the second dose, 9.7% of participants reported fatigue, 8.9% reported myalgia, 5.2% reported arthralgia, 4.5% reported headache, 4.1% reported pain, and 2.0% reported erythema or redness at the injection site.

Moderna plans to request emergency-use authorization (EUA) from the Food and Drug Administration in the coming weeks. The company expects that the EUA will be based on more data from the COVE study, including a final analysis of 151 patients with a median follow-up of more than 2 months. Moderna also plans to seek authorizations from global regulatory agencies.

The company expects to have approximately 20 million doses of mRNA-1273 ready to ship in the United States by the end of the year. In addition, the company says it remains on track to manufacture between 500 million and 1 billion doses globally in 2021.

Moderna is developing distribution plans in conjunction with the Centers for Disease Control and Prevention, the federal government’s Operation Warp Speed, and McKesson, a COVID-19 vaccine distributor contracted by the U.S. government.
 

Refrigeration requirements

The mRNA-1273 vaccine can be shipped and stored for up to 6 months at –20° C (about –4° F), a temperature maintained in most home or medical freezers, according to Moderna. The company expects that, after the product thaws, it will remain stable at standard refrigerator temperatures of 2°-8° C (36°-46° F) for up to 30 days within the 6-month shelf life.

Because the mRNA-1273 vaccine is stable at these refrigerator temperatures, it can be stored at most physicians’ offices, pharmacies, and hospitals, the company noted. In contrast, the similar Pfizer BTN162b2 vaccine – early results for which showed a 90% efficacy rate – requires shipment and storage at “deep-freeze” conditions of –70° C or –80° C, which is more challenging from a logistic point of view.

Moderna’s mRNA-1273 can be kept at room temperature for up to 12 hours after removal from a refrigerator for patient administration. The vaccine will not require dilution prior to use.

More than 30,000 people aged older than 18 years in the United States are enrolled in the COVE study. The research is being conducted in collaboration with the National Institute of Allergy and Infectious Diseases and the Biomedical Advanced Research and Development Authority, part of the Office of the Assistant Secretary for Preparedness and Response at the Department of Health & Human Services.

A version of this article originally appeared on Medscape.com.

The Moderna mRNA-1273 vaccine, in development to prevent COVID-19, yielded 94.5% efficacy in early results and is generally well tolerated, the company announced early Monday. The product can be stored at refrigeration temperatures common to many physician offices, pharmacies, and hospitals.

The first interim results of the phase 3 COVE trial included 95 participants with confirmed COVID-19. An independent data safety monitoring board, which was appointed by the National Institutes of Health, informed Moderna that 90 of the patients who were positive for COVID-19 were in a placebo group and that 5 patients were in the mRNA-1273 vaccine group, resulting in a vaccine efficacy of 94.5% (P < .0001).

Interim data included 11 patients with severe COVID-19, all of whom were in the placebo group.

“This positive interim analysis from our phase 3 study has given us the first clinical validation that our vaccine can prevent COVID-19 disease, including severe disease,” said Stéphane Bancel, CEO of Moderna, said in a statement.

The vaccine met its primary study endpoint, which was based on adjudicated data that were collected starting 2 weeks after the second dose of mRNA-1273. The interim study population included people who could be at higher risk for COVID-19, including 15 adults aged 65 years and older and 20 participants from diverse communities.
 

Safety data

The DSMB also reviewed safety data for the COVE study interim results. The vaccine was generally safe and well tolerated, as determined on the basis of solicited adverse events. Most adverse events were mild to moderate and were generally short-lived, according to a company news release.

Injection-site pain was reported in 2.7% of participants after the first dose. After the second dose, 9.7% of participants reported fatigue, 8.9% reported myalgia, 5.2% reported arthralgia, 4.5% reported headache, 4.1% reported pain, and 2.0% reported erythema or redness at the injection site.

Moderna plans to request emergency-use authorization (EUA) from the Food and Drug Administration in the coming weeks. The company expects that the EUA will be based on more data from the COVE study, including a final analysis of 151 patients with a median follow-up of more than 2 months. Moderna also plans to seek authorizations from global regulatory agencies.

The company expects to have approximately 20 million doses of mRNA-1273 ready to ship in the United States by the end of the year. In addition, the company says it remains on track to manufacture between 500 million and 1 billion doses globally in 2021.

Moderna is developing distribution plans in conjunction with the Centers for Disease Control and Prevention, the federal government’s Operation Warp Speed, and McKesson, a COVID-19 vaccine distributor contracted by the U.S. government.
 

Refrigeration requirements

The mRNA-1273 vaccine can be shipped and stored for up to 6 months at –20° C (about –4° F), a temperature maintained in most home or medical freezers, according to Moderna. The company expects that, after the product thaws, it will remain stable at standard refrigerator temperatures of 2°-8° C (36°-46° F) for up to 30 days within the 6-month shelf life.

Because the mRNA-1273 vaccine is stable at these refrigerator temperatures, it can be stored at most physicians’ offices, pharmacies, and hospitals, the company noted. In contrast, the similar Pfizer BTN162b2 vaccine – early results for which showed a 90% efficacy rate – requires shipment and storage at “deep-freeze” conditions of –70° C or –80° C, which is more challenging from a logistic point of view.

Moderna’s mRNA-1273 can be kept at room temperature for up to 12 hours after removal from a refrigerator for patient administration. The vaccine will not require dilution prior to use.

More than 30,000 people aged older than 18 years in the United States are enrolled in the COVE study. The research is being conducted in collaboration with the National Institute of Allergy and Infectious Diseases and the Biomedical Advanced Research and Development Authority, part of the Office of the Assistant Secretary for Preparedness and Response at the Department of Health & Human Services.

A version of this article originally appeared on Medscape.com.

The Moderna mRNA-1273 vaccine, in development to prevent COVID-19, yielded 94.5% efficacy in early results and is generally well tolerated, the company announced early Monday. The product can be stored at refrigeration temperatures common to many physician offices, pharmacies, and hospitals.

The first interim results of the phase 3 COVE trial included 95 participants with confirmed COVID-19. An independent data safety monitoring board, which was appointed by the National Institutes of Health, informed Moderna that 90 of the patients who were positive for COVID-19 were in a placebo group and that 5 patients were in the mRNA-1273 vaccine group, resulting in a vaccine efficacy of 94.5% (P < .0001).

Interim data included 11 patients with severe COVID-19, all of whom were in the placebo group.

“This positive interim analysis from our phase 3 study has given us the first clinical validation that our vaccine can prevent COVID-19 disease, including severe disease,” said Stéphane Bancel, CEO of Moderna, said in a statement.

The vaccine met its primary study endpoint, which was based on adjudicated data that were collected starting 2 weeks after the second dose of mRNA-1273. The interim study population included people who could be at higher risk for COVID-19, including 15 adults aged 65 years and older and 20 participants from diverse communities.
 

Safety data

The DSMB also reviewed safety data for the COVE study interim results. The vaccine was generally safe and well tolerated, as determined on the basis of solicited adverse events. Most adverse events were mild to moderate and were generally short-lived, according to a company news release.

Injection-site pain was reported in 2.7% of participants after the first dose. After the second dose, 9.7% of participants reported fatigue, 8.9% reported myalgia, 5.2% reported arthralgia, 4.5% reported headache, 4.1% reported pain, and 2.0% reported erythema or redness at the injection site.

Moderna plans to request emergency-use authorization (EUA) from the Food and Drug Administration in the coming weeks. The company expects that the EUA will be based on more data from the COVE study, including a final analysis of 151 patients with a median follow-up of more than 2 months. Moderna also plans to seek authorizations from global regulatory agencies.

The company expects to have approximately 20 million doses of mRNA-1273 ready to ship in the United States by the end of the year. In addition, the company says it remains on track to manufacture between 500 million and 1 billion doses globally in 2021.

Moderna is developing distribution plans in conjunction with the Centers for Disease Control and Prevention, the federal government’s Operation Warp Speed, and McKesson, a COVID-19 vaccine distributor contracted by the U.S. government.
 

Refrigeration requirements

The mRNA-1273 vaccine can be shipped and stored for up to 6 months at –20° C (about –4° F), a temperature maintained in most home or medical freezers, according to Moderna. The company expects that, after the product thaws, it will remain stable at standard refrigerator temperatures of 2°-8° C (36°-46° F) for up to 30 days within the 6-month shelf life.

Because the mRNA-1273 vaccine is stable at these refrigerator temperatures, it can be stored at most physicians’ offices, pharmacies, and hospitals, the company noted. In contrast, the similar Pfizer BTN162b2 vaccine – early results for which showed a 90% efficacy rate – requires shipment and storage at “deep-freeze” conditions of –70° C or –80° C, which is more challenging from a logistic point of view.

Moderna’s mRNA-1273 can be kept at room temperature for up to 12 hours after removal from a refrigerator for patient administration. The vaccine will not require dilution prior to use.

More than 30,000 people aged older than 18 years in the United States are enrolled in the COVE study. The research is being conducted in collaboration with the National Institute of Allergy and Infectious Diseases and the Biomedical Advanced Research and Development Authority, part of the Office of the Assistant Secretary for Preparedness and Response at the Department of Health & Human Services.

A version of this article originally appeared on Medscape.com.

"The writing is on the wall” that virtual care is not meeting the needs of people with HIV who struggled with viral suppression even before the COVID-19 pandemic, said Jason Farley, PhD, ANP-BC, AACRN, associate professor of nursing at Johns Hopkins University, Baltimore. So it’s time for HIV care teams, especially clinics in the Ryan White HIV/AIDS Program, to get creative in bringing wraparound services to patients.

That may mean reallocating the workforce so that one person serves as a community health worker. Or it could mean increasing texts and video calls; helping patients find online support groups to address problems with alcohol or drug use; and conducting an overall assessment of patients’ needs as the pandemic continues.

“The virtual patient-centered medical home may be the new normal after COVID-19, and we have to be thinking about how we use this model with patients for whom it works, but supplement this model in patients that it does not,” Farley said at the virtual Association of Nurses in AIDS Care (ANAC) 2020 Annual Meeting. That work “is essential to our being able to facilitate the best patient outcomes possible.”
 

Early data, tiered interventions

Farley referred to an article published in September in the Journal AIDS that confirmed unpublished data mentioned at the International AIDS Conference 2020. The article reported that viral suppression rates among people with HIV who attended San Francisco’s Ward 86 HIV clinic dropped by 31% from pre-COVID levels.

Of the 1766 people who attended the clinic, about 1 in 5 had detectable HIV viral loads at any point in 2019. But that rate was 31% higher after shelter-in-place orders were issued. And although patients participated in telemedicine visits at more or less the same rate before and after the pandemic (31% vs. 30% no-shows), viral suppression rates dropped. The impact was especially acute for homeless individuals.

“This destabilization occurred despite our population attending telemedicine visits at a higher rate than expected, given the 60% drop in ambulatory care visit volume nationwide,” the authors stated in their article. “Telehealth visits, while offering greater patient convenience, may lead to less access to clinic-based social support services essential to achieving viral suppression among vulnerable groups.”

That’s the challenge HIV clinics now face, Farley said at the ANAC meeting.

He suggested a differentiated care approach in which there are four tiers of care, starting with the standard level of outreach, which may include email, electronic health record blasts, and robo-calls to remind people of their appointments and to refill their medications. Those with sustained viral suppression may only need 90-day automatic refills of their medications. Those who are vulnerable to nonadherence may need to be contacted weekly or more often by the clinic. Such contact could be made by a social worker, a community health worker, or through some form of virtual support.

Patients at tier 4, who have labile viral suppression, need far more than that. These are the 15% of patients with HIV who struggled with viral suppression before the pandemic. They are the patients that Farley’s team focuses on at Baltimore’s John G. Bartlett Specialty Clinic for Infectious Disease.

“We’ve completely deconstructed the patient-centered medical home,” he said of the early move to virtual care. He suggested that clinicians assess their services and ask themselves some questions:

• Has someone on the team reached out to every patient and checked in to see what their biggest needs are, medical or not, during the pandemic? Have they assessed the patient’s ability to receive video calls or text messages?
• How have group-support programs that address stigma or the social determinants of health fared in the transition to virtual medicine?
• Are patients who are in recovery being supported in order that they may engage with recovery programs online?
• How well have counseling services done in engaging people in virtual care? Currently, given the overall increase in mental health challenges during the pandemic, one would expect that the use of mental health counseling is increasing. “If they’re stagnant or going down, someone needs to be reflecting on that issue internally in the clinic,” he said.
• Are patients being contacted regarding the effects that isolation is having on their lives? “The things that would normally allow us to self-mitigate and self-manage these conditions, like going to the gym, meeting with friends, religious services – all of those are being cut,” he said.
• Is there an early alert from an in-person pharmacy to trigger outreach via a community health worker for patients who haven’t picked up their medications in a week or more?

Farley pointed to a 2015 model for an enhanced e-health approach to chronic care management that called for e-support from the community and that was enhanced through virtual communities.

These are some of the approaches Farley has taken at his clinic. He leads a team that focuses specifically on patients who struggled with engagement before the pandemic. Through a grant from the US Department of Health & Human Services’ Health Resources and Services Administration – even before the pandemic – that team has been funding community health workers who have multiple contacts with patients online and virtually and are able to offer what he calls “unapologetically enabling” support for patients so that they are able to focus on their health.

He gave the following example. Before the pandemic, a community health worker on the team had been working with a patient who showed up at every scheduled visit and swore that she was taking her medications, although clearly she was not. A community health worker, who was made available through the grant, was able to recognize that the patient’s biggest challenge in her life was providing childcare for her special-needs child. The community health worker worked with the patient for months to find stable childcare for the child, paid 2 months of rent for the patient so that she would not become homeless, and helped her find transitional housing. When the pandemic hit, the community health worker was already texting and conducting video calls with the patient regularly.

For the past 9 months, that patient has had an undetectable viral load, Farley said.

“Nine months during a pandemic,” Farley reiterated, “and the community health worker keeps working with her, keeps meeting with her.”
 

Stigma on stigma

The need for this level of support from the clinic may be even more important for people with HIV who acquire COVID-19, said Orlando Harris, PhD, assistant professor of community health systems at the University of California, San Francisco, (UCSF) School of Nursing. HIV-related stigma is a well-known deterrent to care for people living with the virus. During the presentation, Harris asked Farley about the impact of COVID-19 stigma on people with both HIV and COVID-19.

Farley said that patients at his clinic have told him that they have “ostracized” friends who have tested positive for COVID-19. Harris remembered a person with HIV who participated in one of his trials telling the researchers that despite all his precautions – wearing a mask, staying socially distant – he still acquired COVID-19. There was nothing he could have done, Harris said, other than just not go to the grocery store.

The fear of contracting another disease that is associated with stigma, as well as the need to disclose it, can inflame memories of the trauma of being diagnosed with HIV, Harris said. And with patient-centered medical homes struggling to reconstitute their wraparound services via telehealth, he said he wonders whether clinicians should be doing more.

“I worry about people who have survived being diagnosed with HIV in the ‘80s and the ‘90s before antiretroviral therapy showed up on the scene,” he told Medscape Medical News. “I worry that the folks that survived one pandemic [may] be feeling fearful or living in that fear that this new pandemic might take them out. That’s why I’m stressing the need for us to really consider, as clinicians and also as researchers the support systems, the coping mechanisms, the counseling, or what have you to support those living with HIV and vulnerable to COVID-19.”

During telehealth visits, that can be achieved simply by asking people how they are really doing and what their coping mechanisms are.

For their part, the clinicians at San Francisco’s Ward 86 are not trying to provide that support through telehealth on the same level as they were at the beginning of the pandemic, said Matthew Spinelli, MD, assistant professor of medicine, and Monica Gandhi, MD, associate chief of the Division of HIV, Infectious Diseases and Global Medicine, who are both at UCSF and are coauthors of the study.

They still offer telemedicine appointments to patients who request them, said Spinelli. He said about one-third of his patients still prefer to receive their care virtually. The rest have gone back to face-to-face support.

“The analysis led us to promptly open up care as much as possible to our patients, with the idea that telehealth is not cutting it for vulnerable patients with HIV,” Gandhi told Medscape Medical News via email. “We don’t think it’s right for a population who relies on social support from the clinic.”
 

This article first appeared on Medscape.com.

"The writing is on the wall” that virtual care is not meeting the needs of people with HIV who struggled with viral suppression even before the COVID-19 pandemic, said Jason Farley, PhD, ANP-BC, AACRN, associate professor of nursing at Johns Hopkins University, Baltimore. So it’s time for HIV care teams, especially clinics in the Ryan White HIV/AIDS Program, to get creative in bringing wraparound services to patients.

That may mean reallocating the workforce so that one person serves as a community health worker. Or it could mean increasing texts and video calls; helping patients find online support groups to address problems with alcohol or drug use; and conducting an overall assessment of patients’ needs as the pandemic continues.

“The virtual patient-centered medical home may be the new normal after COVID-19, and we have to be thinking about how we use this model with patients for whom it works, but supplement this model in patients that it does not,” Farley said at the virtual Association of Nurses in AIDS Care (ANAC) 2020 Annual Meeting. That work “is essential to our being able to facilitate the best patient outcomes possible.”
 

Early data, tiered interventions

Farley referred to an article published in September in the Journal AIDS that confirmed unpublished data mentioned at the International AIDS Conference 2020. The article reported that viral suppression rates among people with HIV who attended San Francisco’s Ward 86 HIV clinic dropped by 31% from pre-COVID levels.

Of the 1766 people who attended the clinic, about 1 in 5 had detectable HIV viral loads at any point in 2019. But that rate was 31% higher after shelter-in-place orders were issued. And although patients participated in telemedicine visits at more or less the same rate before and after the pandemic (31% vs. 30% no-shows), viral suppression rates dropped. The impact was especially acute for homeless individuals.

“This destabilization occurred despite our population attending telemedicine visits at a higher rate than expected, given the 60% drop in ambulatory care visit volume nationwide,” the authors stated in their article. “Telehealth visits, while offering greater patient convenience, may lead to less access to clinic-based social support services essential to achieving viral suppression among vulnerable groups.”

That’s the challenge HIV clinics now face, Farley said at the ANAC meeting.

He suggested a differentiated care approach in which there are four tiers of care, starting with the standard level of outreach, which may include email, electronic health record blasts, and robo-calls to remind people of their appointments and to refill their medications. Those with sustained viral suppression may only need 90-day automatic refills of their medications. Those who are vulnerable to nonadherence may need to be contacted weekly or more often by the clinic. Such contact could be made by a social worker, a community health worker, or through some form of virtual support.

Patients at tier 4, who have labile viral suppression, need far more than that. These are the 15% of patients with HIV who struggled with viral suppression before the pandemic. They are the patients that Farley’s team focuses on at Baltimore’s John G. Bartlett Specialty Clinic for Infectious Disease.

“We’ve completely deconstructed the patient-centered medical home,” he said of the early move to virtual care. He suggested that clinicians assess their services and ask themselves some questions:

• Has someone on the team reached out to every patient and checked in to see what their biggest needs are, medical or not, during the pandemic? Have they assessed the patient’s ability to receive video calls or text messages?
• How have group-support programs that address stigma or the social determinants of health fared in the transition to virtual medicine?
• Are patients who are in recovery being supported in order that they may engage with recovery programs online?
• How well have counseling services done in engaging people in virtual care? Currently, given the overall increase in mental health challenges during the pandemic, one would expect that the use of mental health counseling is increasing. “If they’re stagnant or going down, someone needs to be reflecting on that issue internally in the clinic,” he said.
• Are patients being contacted regarding the effects that isolation is having on their lives? “The things that would normally allow us to self-mitigate and self-manage these conditions, like going to the gym, meeting with friends, religious services – all of those are being cut,” he said.
• Is there an early alert from an in-person pharmacy to trigger outreach via a community health worker for patients who haven’t picked up their medications in a week or more?

Farley pointed to a 2015 model for an enhanced e-health approach to chronic care management that called for e-support from the community and that was enhanced through virtual communities.

These are some of the approaches Farley has taken at his clinic. He leads a team that focuses specifically on patients who struggled with engagement before the pandemic. Through a grant from the US Department of Health & Human Services’ Health Resources and Services Administration – even before the pandemic – that team has been funding community health workers who have multiple contacts with patients online and virtually and are able to offer what he calls “unapologetically enabling” support for patients so that they are able to focus on their health.

He gave the following example. Before the pandemic, a community health worker on the team had been working with a patient who showed up at every scheduled visit and swore that she was taking her medications, although clearly she was not. A community health worker, who was made available through the grant, was able to recognize that the patient’s biggest challenge in her life was providing childcare for her special-needs child. The community health worker worked with the patient for months to find stable childcare for the child, paid 2 months of rent for the patient so that she would not become homeless, and helped her find transitional housing. When the pandemic hit, the community health worker was already texting and conducting video calls with the patient regularly.

For the past 9 months, that patient has had an undetectable viral load, Farley said.

“Nine months during a pandemic,” Farley reiterated, “and the community health worker keeps working with her, keeps meeting with her.”
 

Stigma on stigma

The need for this level of support from the clinic may be even more important for people with HIV who acquire COVID-19, said Orlando Harris, PhD, assistant professor of community health systems at the University of California, San Francisco, (UCSF) School of Nursing. HIV-related stigma is a well-known deterrent to care for people living with the virus. During the presentation, Harris asked Farley about the impact of COVID-19 stigma on people with both HIV and COVID-19.

Farley said that patients at his clinic have told him that they have “ostracized” friends who have tested positive for COVID-19. Harris remembered a person with HIV who participated in one of his trials telling the researchers that despite all his precautions – wearing a mask, staying socially distant – he still acquired COVID-19. There was nothing he could have done, Harris said, other than just not go to the grocery store.

The fear of contracting another disease that is associated with stigma, as well as the need to disclose it, can inflame memories of the trauma of being diagnosed with HIV, Harris said. And with patient-centered medical homes struggling to reconstitute their wraparound services via telehealth, he said he wonders whether clinicians should be doing more.

“I worry about people who have survived being diagnosed with HIV in the ‘80s and the ‘90s before antiretroviral therapy showed up on the scene,” he told Medscape Medical News. “I worry that the folks that survived one pandemic [may] be feeling fearful or living in that fear that this new pandemic might take them out. That’s why I’m stressing the need for us to really consider, as clinicians and also as researchers the support systems, the coping mechanisms, the counseling, or what have you to support those living with HIV and vulnerable to COVID-19.”

During telehealth visits, that can be achieved simply by asking people how they are really doing and what their coping mechanisms are.

For their part, the clinicians at San Francisco’s Ward 86 are not trying to provide that support through telehealth on the same level as they were at the beginning of the pandemic, said Matthew Spinelli, MD, assistant professor of medicine, and Monica Gandhi, MD, associate chief of the Division of HIV, Infectious Diseases and Global Medicine, who are both at UCSF and are coauthors of the study.

They still offer telemedicine appointments to patients who request them, said Spinelli. He said about one-third of his patients still prefer to receive their care virtually. The rest have gone back to face-to-face support.

“The analysis led us to promptly open up care as much as possible to our patients, with the idea that telehealth is not cutting it for vulnerable patients with HIV,” Gandhi told Medscape Medical News via email. “We don’t think it’s right for a population who relies on social support from the clinic.”
 

This article first appeared on Medscape.com.

"The writing is on the wall” that virtual care is not meeting the needs of people with HIV who struggled with viral suppression even before the COVID-19 pandemic, said Jason Farley, PhD, ANP-BC, AACRN, associate professor of nursing at Johns Hopkins University, Baltimore. So it’s time for HIV care teams, especially clinics in the Ryan White HIV/AIDS Program, to get creative in bringing wraparound services to patients.

That may mean reallocating the workforce so that one person serves as a community health worker. Or it could mean increasing texts and video calls; helping patients find online support groups to address problems with alcohol or drug use; and conducting an overall assessment of patients’ needs as the pandemic continues.

“The virtual patient-centered medical home may be the new normal after COVID-19, and we have to be thinking about how we use this model with patients for whom it works, but supplement this model in patients that it does not,” Farley said at the virtual Association of Nurses in AIDS Care (ANAC) 2020 Annual Meeting. That work “is essential to our being able to facilitate the best patient outcomes possible.”
 

Early data, tiered interventions

Farley referred to an article published in September in the Journal AIDS that confirmed unpublished data mentioned at the International AIDS Conference 2020. The article reported that viral suppression rates among people with HIV who attended San Francisco’s Ward 86 HIV clinic dropped by 31% from pre-COVID levels.

Of the 1766 people who attended the clinic, about 1 in 5 had detectable HIV viral loads at any point in 2019. But that rate was 31% higher after shelter-in-place orders were issued. And although patients participated in telemedicine visits at more or less the same rate before and after the pandemic (31% vs. 30% no-shows), viral suppression rates dropped. The impact was especially acute for homeless individuals.

“This destabilization occurred despite our population attending telemedicine visits at a higher rate than expected, given the 60% drop in ambulatory care visit volume nationwide,” the authors stated in their article. “Telehealth visits, while offering greater patient convenience, may lead to less access to clinic-based social support services essential to achieving viral suppression among vulnerable groups.”

That’s the challenge HIV clinics now face, Farley said at the ANAC meeting.

He suggested a differentiated care approach in which there are four tiers of care, starting with the standard level of outreach, which may include email, electronic health record blasts, and robo-calls to remind people of their appointments and to refill their medications. Those with sustained viral suppression may only need 90-day automatic refills of their medications. Those who are vulnerable to nonadherence may need to be contacted weekly or more often by the clinic. Such contact could be made by a social worker, a community health worker, or through some form of virtual support.

Patients at tier 4, who have labile viral suppression, need far more than that. These are the 15% of patients with HIV who struggled with viral suppression before the pandemic. They are the patients that Farley’s team focuses on at Baltimore’s John G. Bartlett Specialty Clinic for Infectious Disease.

“We’ve completely deconstructed the patient-centered medical home,” he said of the early move to virtual care. He suggested that clinicians assess their services and ask themselves some questions:

• Has someone on the team reached out to every patient and checked in to see what their biggest needs are, medical or not, during the pandemic? Have they assessed the patient’s ability to receive video calls or text messages?
• How have group-support programs that address stigma or the social determinants of health fared in the transition to virtual medicine?
• Are patients who are in recovery being supported in order that they may engage with recovery programs online?
• How well have counseling services done in engaging people in virtual care? Currently, given the overall increase in mental health challenges during the pandemic, one would expect that the use of mental health counseling is increasing. “If they’re stagnant or going down, someone needs to be reflecting on that issue internally in the clinic,” he said.
• Are patients being contacted regarding the effects that isolation is having on their lives? “The things that would normally allow us to self-mitigate and self-manage these conditions, like going to the gym, meeting with friends, religious services – all of those are being cut,” he said.
• Is there an early alert from an in-person pharmacy to trigger outreach via a community health worker for patients who haven’t picked up their medications in a week or more?

Farley pointed to a 2015 model for an enhanced e-health approach to chronic care management that called for e-support from the community and that was enhanced through virtual communities.

These are some of the approaches Farley has taken at his clinic. He leads a team that focuses specifically on patients who struggled with engagement before the pandemic. Through a grant from the US Department of Health & Human Services’ Health Resources and Services Administration – even before the pandemic – that team has been funding community health workers who have multiple contacts with patients online and virtually and are able to offer what he calls “unapologetically enabling” support for patients so that they are able to focus on their health.

He gave the following example. Before the pandemic, a community health worker on the team had been working with a patient who showed up at every scheduled visit and swore that she was taking her medications, although clearly she was not. A community health worker, who was made available through the grant, was able to recognize that the patient’s biggest challenge in her life was providing childcare for her special-needs child. The community health worker worked with the patient for months to find stable childcare for the child, paid 2 months of rent for the patient so that she would not become homeless, and helped her find transitional housing. When the pandemic hit, the community health worker was already texting and conducting video calls with the patient regularly.

For the past 9 months, that patient has had an undetectable viral load, Farley said.

“Nine months during a pandemic,” Farley reiterated, “and the community health worker keeps working with her, keeps meeting with her.”
 

Stigma on stigma

The need for this level of support from the clinic may be even more important for people with HIV who acquire COVID-19, said Orlando Harris, PhD, assistant professor of community health systems at the University of California, San Francisco, (UCSF) School of Nursing. HIV-related stigma is a well-known deterrent to care for people living with the virus. During the presentation, Harris asked Farley about the impact of COVID-19 stigma on people with both HIV and COVID-19.

Farley said that patients at his clinic have told him that they have “ostracized” friends who have tested positive for COVID-19. Harris remembered a person with HIV who participated in one of his trials telling the researchers that despite all his precautions – wearing a mask, staying socially distant – he still acquired COVID-19. There was nothing he could have done, Harris said, other than just not go to the grocery store.

The fear of contracting another disease that is associated with stigma, as well as the need to disclose it, can inflame memories of the trauma of being diagnosed with HIV, Harris said. And with patient-centered medical homes struggling to reconstitute their wraparound services via telehealth, he said he wonders whether clinicians should be doing more.

“I worry about people who have survived being diagnosed with HIV in the ‘80s and the ‘90s before antiretroviral therapy showed up on the scene,” he told Medscape Medical News. “I worry that the folks that survived one pandemic [may] be feeling fearful or living in that fear that this new pandemic might take them out. That’s why I’m stressing the need for us to really consider, as clinicians and also as researchers the support systems, the coping mechanisms, the counseling, or what have you to support those living with HIV and vulnerable to COVID-19.”

During telehealth visits, that can be achieved simply by asking people how they are really doing and what their coping mechanisms are.

For their part, the clinicians at San Francisco’s Ward 86 are not trying to provide that support through telehealth on the same level as they were at the beginning of the pandemic, said Matthew Spinelli, MD, assistant professor of medicine, and Monica Gandhi, MD, associate chief of the Division of HIV, Infectious Diseases and Global Medicine, who are both at UCSF and are coauthors of the study.

They still offer telemedicine appointments to patients who request them, said Spinelli. He said about one-third of his patients still prefer to receive their care virtually. The rest have gone back to face-to-face support.

“The analysis led us to promptly open up care as much as possible to our patients, with the idea that telehealth is not cutting it for vulnerable patients with HIV,” Gandhi told Medscape Medical News via email. “We don’t think it’s right for a population who relies on social support from the clinic.”
 

This article first appeared on Medscape.com.

Coronavirus infections are expected to continue to climb in the upper Midwest and intermountain West of the United States, which will strain an already-maxed-out system as increased hospitalizations and deaths follow, say infectious diseases specialists.

“I think the situation in 2 to 4 weeks is going to be grim,” said Andrew Pavia, MD, chief of the division of pediatric infectious diseases at the University of Utah School of Medicine in Salt Lake City, on a call yesterday with reporters, sponsored by the Infectious Diseases Society of America (IDSA).

Cases began rising in Utah in mid-September and have gone up steeply since, increasing from 450 cases per day to 2,650 reported on Nov. 8, according to the Johns Hopkins Coronavirus Resource Center. The New York Times reports that the 7-day rolling average for hospitalizations have gone up 34% and deaths have risen 93%, with 11 deaths this past Tuesday.

Other states in the west – Montana, Idaho, and Wyoming, which reported 1,232 cases on Tuesday and have been averaging 660 cases a day in the last week, according to the Times – are being equally hard hit. The same is true for states in the upper Midwest, including North Dakota, South Dakota, Minnesota, Wisconsin, and Iowa.

Most of the states being hit now have large swaths of rural countryside, which means health resources are limited and spread out, said Pavia.

“The situation really has to be described as dire,” said Pavia, noting that intensive care units in Utah are full, including contingency units that were purpose-built for the pandemic. Physicians and nurses are burned out and in short supply, he said. Instead of a 1:1 or 1:2 nurse-to-ICU patient ratio, the ratio is now 1:4, said Pavia. “Throughout the region, people are facing a crisis in staffing.”

The University of Utah hospital normally takes referrals from Idaho, Wyoming, and northern Arizona, but is prioritizing Utah residents for ICU admission, said Pavia.

Both Pavia and Daniel P. McQuillen, MD, president-elect of IDSA, also noted the shortage of infectious diseases specialists, which began at least a decade ago. McQuillen, senior infectious diseases physician at Beth Israel Lahey Health in Boston, said he and colleagues had done some research earlier this year anticipating the pandemic’s spread, and found that some 80% of counties – including the rural counties in the states now being hit – have one or zero infectious disease specialists.

Those specialists can help improve patient outcomes, explained McQuillen.
 

Colleges likely driving spike

Pavia said the reasons for sharp increases in the region vary, but there are several areas of commonality. Most of the states didn’t have many cases early in the pandemic, “so perhaps there was less fear of the virus.” There were fewer actions by government officials, driven perhaps by the reluctance to take on individuals who are distrustful of government, he said.

Cases started going up after some events – such as the August motorcycle rally in Sturgis, South Dakota – but the acceleration in September was likely driven by the reopening of colleges across the region, said Pavia.

“Most of the states have kept in-person schooling, and probably more importantly, they’ve kept extracurricular activities in sports,” he said, adding that in many of the areas the weather has turned cooler, driving people indoors.

McQuillen said it has been shown that a significant amount of transmission occurs within homes – and college students may be bringing the virus home and fueling spread, in addition to people not wearing masks while at small family gatherings.

Both he and Pavia said more emphasis needs to be placed on mitigation measures such as mask-wearing as well as on testing. IDSA is starting #MaskUpAmerica, a public service campaign aimed at getting people to wear masks in all community settings, including at work, in churches, at social gatherings, in gyms, and on public transportation.

Pavia said in some places people are refusing to be tested because they don’t want to be quarantined.

Utah Gov. Gary Herbert (R) issued a statewide mask mandate this past weekend and announced some other restrictions, including a 2-week pause on most, but not all, athletic events, according to CBS News. But local pushback could weaken those measures, said Pavia.

Many people are looking to vaccines to usher in a return to normal. But, said Pavia, “vaccines aren’t going to help us out much this winter,” noting that initial doses will be given mostly to first responders and healthcare workers.

“The only way we’re going to get out of this this winter is by doing the things that we’ve been talking about for months – wearing a mask, watching your social distance, and avoiding large gatherings,” he said.

There is an end in sight, said Pavia, but it won’t be in early 2021. “That end is next summer or fall,” he said. “And that’s a hard message to give but it’s really critical.”

McQuillen agreed: “Wearing masks and distancing are exactly all we have probably until middle of next year.”
 

This article first appeared on Medscape.com.

Coronavirus infections are expected to continue to climb in the upper Midwest and intermountain West of the United States, which will strain an already-maxed-out system as increased hospitalizations and deaths follow, say infectious diseases specialists.

“I think the situation in 2 to 4 weeks is going to be grim,” said Andrew Pavia, MD, chief of the division of pediatric infectious diseases at the University of Utah School of Medicine in Salt Lake City, on a call yesterday with reporters, sponsored by the Infectious Diseases Society of America (IDSA).

Cases began rising in Utah in mid-September and have gone up steeply since, increasing from 450 cases per day to 2,650 reported on Nov. 8, according to the Johns Hopkins Coronavirus Resource Center. The New York Times reports that the 7-day rolling average for hospitalizations have gone up 34% and deaths have risen 93%, with 11 deaths this past Tuesday.

Other states in the west – Montana, Idaho, and Wyoming, which reported 1,232 cases on Tuesday and have been averaging 660 cases a day in the last week, according to the Times – are being equally hard hit. The same is true for states in the upper Midwest, including North Dakota, South Dakota, Minnesota, Wisconsin, and Iowa.

Most of the states being hit now have large swaths of rural countryside, which means health resources are limited and spread out, said Pavia.

“The situation really has to be described as dire,” said Pavia, noting that intensive care units in Utah are full, including contingency units that were purpose-built for the pandemic. Physicians and nurses are burned out and in short supply, he said. Instead of a 1:1 or 1:2 nurse-to-ICU patient ratio, the ratio is now 1:4, said Pavia. “Throughout the region, people are facing a crisis in staffing.”

The University of Utah hospital normally takes referrals from Idaho, Wyoming, and northern Arizona, but is prioritizing Utah residents for ICU admission, said Pavia.

Both Pavia and Daniel P. McQuillen, MD, president-elect of IDSA, also noted the shortage of infectious diseases specialists, which began at least a decade ago. McQuillen, senior infectious diseases physician at Beth Israel Lahey Health in Boston, said he and colleagues had done some research earlier this year anticipating the pandemic’s spread, and found that some 80% of counties – including the rural counties in the states now being hit – have one or zero infectious disease specialists.

Those specialists can help improve patient outcomes, explained McQuillen.
 

Colleges likely driving spike

Pavia said the reasons for sharp increases in the region vary, but there are several areas of commonality. Most of the states didn’t have many cases early in the pandemic, “so perhaps there was less fear of the virus.” There were fewer actions by government officials, driven perhaps by the reluctance to take on individuals who are distrustful of government, he said.

Cases started going up after some events – such as the August motorcycle rally in Sturgis, South Dakota – but the acceleration in September was likely driven by the reopening of colleges across the region, said Pavia.

“Most of the states have kept in-person schooling, and probably more importantly, they’ve kept extracurricular activities in sports,” he said, adding that in many of the areas the weather has turned cooler, driving people indoors.

McQuillen said it has been shown that a significant amount of transmission occurs within homes – and college students may be bringing the virus home and fueling spread, in addition to people not wearing masks while at small family gatherings.

Both he and Pavia said more emphasis needs to be placed on mitigation measures such as mask-wearing as well as on testing. IDSA is starting #MaskUpAmerica, a public service campaign aimed at getting people to wear masks in all community settings, including at work, in churches, at social gatherings, in gyms, and on public transportation.

Pavia said in some places people are refusing to be tested because they don’t want to be quarantined.

Utah Gov. Gary Herbert (R) issued a statewide mask mandate this past weekend and announced some other restrictions, including a 2-week pause on most, but not all, athletic events, according to CBS News. But local pushback could weaken those measures, said Pavia.

Many people are looking to vaccines to usher in a return to normal. But, said Pavia, “vaccines aren’t going to help us out much this winter,” noting that initial doses will be given mostly to first responders and healthcare workers.

“The only way we’re going to get out of this this winter is by doing the things that we’ve been talking about for months – wearing a mask, watching your social distance, and avoiding large gatherings,” he said.

There is an end in sight, said Pavia, but it won’t be in early 2021. “That end is next summer or fall,” he said. “And that’s a hard message to give but it’s really critical.”

McQuillen agreed: “Wearing masks and distancing are exactly all we have probably until middle of next year.”
 

This article first appeared on Medscape.com.

Coronavirus infections are expected to continue to climb in the upper Midwest and intermountain West of the United States, which will strain an already-maxed-out system as increased hospitalizations and deaths follow, say infectious diseases specialists.

“I think the situation in 2 to 4 weeks is going to be grim,” said Andrew Pavia, MD, chief of the division of pediatric infectious diseases at the University of Utah School of Medicine in Salt Lake City, on a call yesterday with reporters, sponsored by the Infectious Diseases Society of America (IDSA).

Cases began rising in Utah in mid-September and have gone up steeply since, increasing from 450 cases per day to 2,650 reported on Nov. 8, according to the Johns Hopkins Coronavirus Resource Center. The New York Times reports that the 7-day rolling average for hospitalizations have gone up 34% and deaths have risen 93%, with 11 deaths this past Tuesday.

Other states in the west – Montana, Idaho, and Wyoming, which reported 1,232 cases on Tuesday and have been averaging 660 cases a day in the last week, according to the Times – are being equally hard hit. The same is true for states in the upper Midwest, including North Dakota, South Dakota, Minnesota, Wisconsin, and Iowa.

Most of the states being hit now have large swaths of rural countryside, which means health resources are limited and spread out, said Pavia.

“The situation really has to be described as dire,” said Pavia, noting that intensive care units in Utah are full, including contingency units that were purpose-built for the pandemic. Physicians and nurses are burned out and in short supply, he said. Instead of a 1:1 or 1:2 nurse-to-ICU patient ratio, the ratio is now 1:4, said Pavia. “Throughout the region, people are facing a crisis in staffing.”

The University of Utah hospital normally takes referrals from Idaho, Wyoming, and northern Arizona, but is prioritizing Utah residents for ICU admission, said Pavia.

Both Pavia and Daniel P. McQuillen, MD, president-elect of IDSA, also noted the shortage of infectious diseases specialists, which began at least a decade ago. McQuillen, senior infectious diseases physician at Beth Israel Lahey Health in Boston, said he and colleagues had done some research earlier this year anticipating the pandemic’s spread, and found that some 80% of counties – including the rural counties in the states now being hit – have one or zero infectious disease specialists.

Those specialists can help improve patient outcomes, explained McQuillen.
 

Colleges likely driving spike

Pavia said the reasons for sharp increases in the region vary, but there are several areas of commonality. Most of the states didn’t have many cases early in the pandemic, “so perhaps there was less fear of the virus.” There were fewer actions by government officials, driven perhaps by the reluctance to take on individuals who are distrustful of government, he said.

Cases started going up after some events – such as the August motorcycle rally in Sturgis, South Dakota – but the acceleration in September was likely driven by the reopening of colleges across the region, said Pavia.

“Most of the states have kept in-person schooling, and probably more importantly, they’ve kept extracurricular activities in sports,” he said, adding that in many of the areas the weather has turned cooler, driving people indoors.

McQuillen said it has been shown that a significant amount of transmission occurs within homes – and college students may be bringing the virus home and fueling spread, in addition to people not wearing masks while at small family gatherings.

Both he and Pavia said more emphasis needs to be placed on mitigation measures such as mask-wearing as well as on testing. IDSA is starting #MaskUpAmerica, a public service campaign aimed at getting people to wear masks in all community settings, including at work, in churches, at social gatherings, in gyms, and on public transportation.

Pavia said in some places people are refusing to be tested because they don’t want to be quarantined.

Utah Gov. Gary Herbert (R) issued a statewide mask mandate this past weekend and announced some other restrictions, including a 2-week pause on most, but not all, athletic events, according to CBS News. But local pushback could weaken those measures, said Pavia.

Many people are looking to vaccines to usher in a return to normal. But, said Pavia, “vaccines aren’t going to help us out much this winter,” noting that initial doses will be given mostly to first responders and healthcare workers.

“The only way we’re going to get out of this this winter is by doing the things that we’ve been talking about for months – wearing a mask, watching your social distance, and avoiding large gatherings,” he said.

There is an end in sight, said Pavia, but it won’t be in early 2021. “That end is next summer or fall,” he said. “And that’s a hard message to give but it’s really critical.”

McQuillen agreed: “Wearing masks and distancing are exactly all we have probably until middle of next year.”
 

This article first appeared on Medscape.com.

One in five COVID-19 patients are diagnosed with a psychiatric disorder such as anxiety or depression within 3 months of testing positive for the virus, new research suggests.

“People have been worried that COVID-19 survivors will be at greater risk of psychiatric disorders, and our findings in a large and detailed study show this to be true,” principal investigator Paul Harrison, BM, DM, professor of psychiatry, University of Oxford, Oxford, United Kingdom, said in a statement.

Health services “need to be ready to provide care, especially since our results are likely to be underestimates of the actual number of cases,” said Harrison.

The study also showed that having a psychiatric disorder independently increases the risk of getting COVID-19 – a finding that’s in line with research published earlier this month.

“Having a psychiatric illness should be added to the list of risk factors for COVID-19,” study coauthor Maxime Taquet, PhD, University of Oxford, said in the release.

The study was published online Nov. 9 in The Lancet Psychiatry.
 

Double the risk

The investigators took advantage of the TriNetX analytics network, which captured deidentified data from electronic health records of a total of 69.8 million patients from 54 healthcare organizations in the United States.

Of those patients, 62,354 adults were diagnosed with COVID-19 between Jan. 20 and Aug. 1, 2020.

To assess the psychiatric sequelae of COVID-19, the investigators created propensity score–matched cohorts of patients who had received a diagnosis of other conditions that represented a range of common acute presentations.

In 14 to 90 days after being diagnosed with COVID-19, 5.8% of patients received a first recorded diagnosis of psychiatric illness. Among patients with health problems other than COVID, 2.5% to 3.4% of patients received a psychiatric diagnosis, the authors report. The risk was greatest for anxiety disorders, depression, and insomnia.

Older COVID-19 patients had a two- to threefold increased risk for a first dementia diagnosis, a finding that supports an earlier UK study.

Some of this excess risk could reflect misdiagnosed cases of delirium or transient cognitive impairment due to reversible cerebral events, the authors noted.

The study also revealed a bidirectional relationship between mental illness and COVID-19. Individuals with a psychiatric diagnosis were about 65% more likely to be diagnosed with COVID-19 in comparison with their counterparts who did not have mental illness, independently of known physical health risk factors for COVID-19.

“We did not anticipate that psychiatric history would be an independent risk factor for COVID-19. This finding appears robust, being observed in all age strata and in both sexes, and was substantial,” the authors write.

At present, “we don’t understand what the explanation is for the associations between COVID and mental illness. We are looking into this in more detail to try and understand better what subgroups are particularly vulnerable in this regard,” Harrison told Medscape Medical News.
 

“Ambitious” research

Commenting on the findings for Medscape Medical News, Roy H. Perlis, MD, Department of Psychiatry, Massachusetts General Hospital and Harvard Medical School, Boston, said this is “an ambitious effort to understand the short-term consequences of COVID in terms of brain diseases.”

Perlis said he’s not particularly surprised by the increase in psychiatric diagnoses among COVID-19 patients.

“After COVID infection, people are more likely to get close medical follow-up than usual. They’re more likely to be accessing the healthcare system; after all, they’ve already had COVID, so they’re probably less fearful of seeing their doctor. But, that probably also means they’re more likely to get a new diagnosis of something like depression,” he said.

Dementia may be the clearest illustration of this, Perlis said. “It seems less likely that dementia develops a month after COVID; more likely, something that happens during the illness leads someone to be more likely to diagnose dementia later on,” he noted.

Perlis cautioned against being “unnecessarily alarmed” by the findings in this study.

“We know that rates of depression in the UK and the US, as in much of the world, are substantially elevated right now. Much of this is likely a consequence of the stress and disruption that accompanies the pandemic,” said Perlis.

The study was funded by the National Institute for Health Research. Harrison has disclosed no relevant financial relationships. One author is an employee of TriNetX. Perlis has received consulting fees for service on scientific advisory boards of Belle Artificial Intelligence, Burrage Capital, Genomind, Psy Therapeutics, Outermost Therapeutics, RID Ventures, and Takeda. He holds equity in Psy Therapeutics and Outermost Therapeutics.
 

This article first appeared on Medscape.com.

One in five COVID-19 patients are diagnosed with a psychiatric disorder such as anxiety or depression within 3 months of testing positive for the virus, new research suggests.

“People have been worried that COVID-19 survivors will be at greater risk of psychiatric disorders, and our findings in a large and detailed study show this to be true,” principal investigator Paul Harrison, BM, DM, professor of psychiatry, University of Oxford, Oxford, United Kingdom, said in a statement.

Health services “need to be ready to provide care, especially since our results are likely to be underestimates of the actual number of cases,” said Harrison.

The study also showed that having a psychiatric disorder independently increases the risk of getting COVID-19 – a finding that’s in line with research published earlier this month.

“Having a psychiatric illness should be added to the list of risk factors for COVID-19,” study coauthor Maxime Taquet, PhD, University of Oxford, said in the release.

The study was published online Nov. 9 in The Lancet Psychiatry.
 

Double the risk

The investigators took advantage of the TriNetX analytics network, which captured deidentified data from electronic health records of a total of 69.8 million patients from 54 healthcare organizations in the United States.

Of those patients, 62,354 adults were diagnosed with COVID-19 between Jan. 20 and Aug. 1, 2020.

To assess the psychiatric sequelae of COVID-19, the investigators created propensity score–matched cohorts of patients who had received a diagnosis of other conditions that represented a range of common acute presentations.

In 14 to 90 days after being diagnosed with COVID-19, 5.8% of patients received a first recorded diagnosis of psychiatric illness. Among patients with health problems other than COVID, 2.5% to 3.4% of patients received a psychiatric diagnosis, the authors report. The risk was greatest for anxiety disorders, depression, and insomnia.

Older COVID-19 patients had a two- to threefold increased risk for a first dementia diagnosis, a finding that supports an earlier UK study.

Some of this excess risk could reflect misdiagnosed cases of delirium or transient cognitive impairment due to reversible cerebral events, the authors noted.

The study also revealed a bidirectional relationship between mental illness and COVID-19. Individuals with a psychiatric diagnosis were about 65% more likely to be diagnosed with COVID-19 in comparison with their counterparts who did not have mental illness, independently of known physical health risk factors for COVID-19.

“We did not anticipate that psychiatric history would be an independent risk factor for COVID-19. This finding appears robust, being observed in all age strata and in both sexes, and was substantial,” the authors write.

At present, “we don’t understand what the explanation is for the associations between COVID and mental illness. We are looking into this in more detail to try and understand better what subgroups are particularly vulnerable in this regard,” Harrison told Medscape Medical News.
 

“Ambitious” research

Commenting on the findings for Medscape Medical News, Roy H. Perlis, MD, Department of Psychiatry, Massachusetts General Hospital and Harvard Medical School, Boston, said this is “an ambitious effort to understand the short-term consequences of COVID in terms of brain diseases.”

Perlis said he’s not particularly surprised by the increase in psychiatric diagnoses among COVID-19 patients.

“After COVID infection, people are more likely to get close medical follow-up than usual. They’re more likely to be accessing the healthcare system; after all, they’ve already had COVID, so they’re probably less fearful of seeing their doctor. But, that probably also means they’re more likely to get a new diagnosis of something like depression,” he said.

Dementia may be the clearest illustration of this, Perlis said. “It seems less likely that dementia develops a month after COVID; more likely, something that happens during the illness leads someone to be more likely to diagnose dementia later on,” he noted.

Perlis cautioned against being “unnecessarily alarmed” by the findings in this study.

“We know that rates of depression in the UK and the US, as in much of the world, are substantially elevated right now. Much of this is likely a consequence of the stress and disruption that accompanies the pandemic,” said Perlis.

The study was funded by the National Institute for Health Research. Harrison has disclosed no relevant financial relationships. One author is an employee of TriNetX. Perlis has received consulting fees for service on scientific advisory boards of Belle Artificial Intelligence, Burrage Capital, Genomind, Psy Therapeutics, Outermost Therapeutics, RID Ventures, and Takeda. He holds equity in Psy Therapeutics and Outermost Therapeutics.
 

This article first appeared on Medscape.com.

One in five COVID-19 patients are diagnosed with a psychiatric disorder such as anxiety or depression within 3 months of testing positive for the virus, new research suggests.

“People have been worried that COVID-19 survivors will be at greater risk of psychiatric disorders, and our findings in a large and detailed study show this to be true,” principal investigator Paul Harrison, BM, DM, professor of psychiatry, University of Oxford, Oxford, United Kingdom, said in a statement.

Health services “need to be ready to provide care, especially since our results are likely to be underestimates of the actual number of cases,” said Harrison.

The study also showed that having a psychiatric disorder independently increases the risk of getting COVID-19 – a finding that’s in line with research published earlier this month.

“Having a psychiatric illness should be added to the list of risk factors for COVID-19,” study coauthor Maxime Taquet, PhD, University of Oxford, said in the release.

The study was published online Nov. 9 in The Lancet Psychiatry.
 

Double the risk

The investigators took advantage of the TriNetX analytics network, which captured deidentified data from electronic health records of a total of 69.8 million patients from 54 healthcare organizations in the United States.

Of those patients, 62,354 adults were diagnosed with COVID-19 between Jan. 20 and Aug. 1, 2020.

To assess the psychiatric sequelae of COVID-19, the investigators created propensity score–matched cohorts of patients who had received a diagnosis of other conditions that represented a range of common acute presentations.

In 14 to 90 days after being diagnosed with COVID-19, 5.8% of patients received a first recorded diagnosis of psychiatric illness. Among patients with health problems other than COVID, 2.5% to 3.4% of patients received a psychiatric diagnosis, the authors report. The risk was greatest for anxiety disorders, depression, and insomnia.

Older COVID-19 patients had a two- to threefold increased risk for a first dementia diagnosis, a finding that supports an earlier UK study.

Some of this excess risk could reflect misdiagnosed cases of delirium or transient cognitive impairment due to reversible cerebral events, the authors noted.

The study also revealed a bidirectional relationship between mental illness and COVID-19. Individuals with a psychiatric diagnosis were about 65% more likely to be diagnosed with COVID-19 in comparison with their counterparts who did not have mental illness, independently of known physical health risk factors for COVID-19.

“We did not anticipate that psychiatric history would be an independent risk factor for COVID-19. This finding appears robust, being observed in all age strata and in both sexes, and was substantial,” the authors write.

At present, “we don’t understand what the explanation is for the associations between COVID and mental illness. We are looking into this in more detail to try and understand better what subgroups are particularly vulnerable in this regard,” Harrison told Medscape Medical News.
 

“Ambitious” research

Commenting on the findings for Medscape Medical News, Roy H. Perlis, MD, Department of Psychiatry, Massachusetts General Hospital and Harvard Medical School, Boston, said this is “an ambitious effort to understand the short-term consequences of COVID in terms of brain diseases.”

Perlis said he’s not particularly surprised by the increase in psychiatric diagnoses among COVID-19 patients.

“After COVID infection, people are more likely to get close medical follow-up than usual. They’re more likely to be accessing the healthcare system; after all, they’ve already had COVID, so they’re probably less fearful of seeing their doctor. But, that probably also means they’re more likely to get a new diagnosis of something like depression,” he said.

Dementia may be the clearest illustration of this, Perlis said. “It seems less likely that dementia develops a month after COVID; more likely, something that happens during the illness leads someone to be more likely to diagnose dementia later on,” he noted.

Perlis cautioned against being “unnecessarily alarmed” by the findings in this study.

“We know that rates of depression in the UK and the US, as in much of the world, are substantially elevated right now. Much of this is likely a consequence of the stress and disruption that accompanies the pandemic,” said Perlis.

The study was funded by the National Institute for Health Research. Harrison has disclosed no relevant financial relationships. One author is an employee of TriNetX. Perlis has received consulting fees for service on scientific advisory boards of Belle Artificial Intelligence, Burrage Capital, Genomind, Psy Therapeutics, Outermost Therapeutics, RID Ventures, and Takeda. He holds equity in Psy Therapeutics and Outermost Therapeutics.
 

This article first appeared on Medscape.com.

Increasingly, clinicians are being called upon to advise athletes who have recovered from COVID-19 on when it is safe for them to return to play.

Now, they have two reports that offer more insights into the cardiotoxic effects of COVID-19 on the athletic heart.

In the first report, researchers report a high prevalence of pericardial involvement in college-student athletes who have recovered from COVID-19 and give their practical advice on how to let these athletes return to play safely.

In the second report, an expert panel of sports cardiologists provides a comprehensive guide to the appropriate imaging of athletes who may have cardiovascular complications from COVID-19.

Both are published in JACC: Cardiovascular Imaging.

“We were asked by the editors of JACC to submit this paper, and the impetus for it was the fact that there are so many athletes returning after being infected with COVID-19, we need to try and give guidance to cardiologists as to how best to evaluate these athletes,” Dermot Phelan, MD, PhD, Sanger Heart and Vascular Institute, Atrium Health, Charlotte, N.C., and lead author of the consensus statement, said in an interview.

The consensus statement acknowledges that information about the cardiovascular complications of COVID-19 continues to evolve. Meanwhile, pathologies such as myocarditis, pericarditis, and right ventricular dysfunction, in the absence of significant clinical symptoms, in athletes who have been affected by COVID-19 remain of considerable concern.

It also emphasizes the unique challenges the average cardiologist faces in distinguishing between what is normal for an athlete’s heart and what is true pathology after COVID-19 infection; details how different imaging modalities can help in screening, evaluating, and monitoring athletes with suspected cardiovascular complications of COVID-19 infection; and discusses the strengths and limitations of these modalities.

Finally, the consensus statement provides some well-needed guidance on return-to-play decision-making, for both the athlete and the clinician.
 

Athletic remodeling or covid-19 damage?

Athletes can develop certain cardiovascular characteristics because of their athletic activity, and sometimes, this can cloud the diagnostic picture.

“Is this change due to the effects of COVID-19, or is it just because this is an athlete’s heart? This was an international expert consensus, made up of sports cardiologists from all over the world who have a lot of experience in dealing with athletes,” Dr. Phelan said. “We were trying to relay the important information to the cardiologist who is not used to dealing with athletes on a day-to-day basis, as to what they might expect to find in that athlete, and what is not an expected finding and should be tested further.”

Phelan, a sports cardiologist, is familiar with what is normal for an athlete’s heart and what is pathology.

“We know that athletes, particularly long-term endurance athletes, develop changes in the heart that can affect not only the electrics but the structure of the heart, and sometimes, that overlaps with abnormalities with pathology. This can be a challenge for the nonsports cardiologist to differentiate,” he said.

Phelan and his group have written two other consensus documents on the management of cardiovascular problems that develop in some athletes who have been infected with COVID-19.

The first was published in May in JAMA Cardiology, and the second, which revised some of the original recommendations made in the first document, was published online Oct. 26 in JAMA Cardiology.

The first set of recommendations called for imaging studies to be done in all athletes, but the second set states that athletes who recover and are asymptomatic do not need extensive (and expensive) imaging tests.

“These two papers work hand in hand,” Dr. Phelan said. “In May, we had very little experience with COVID, and there was a lot of concern about hospitalized patients having a very high incidence of heart disease. We published those recommendations, but we recognized at the time that we had very little data and that we would reconsider once we had more experience with data.

“This current set of recommendations that we have put forth here are for those athletes who do need to get further testing, so it’s a step beyond,” Dr. Phelan added. “So the second iteration states that young athletes who had mild or no symptoms didn’t need to go through all of that cardiac testing, but others do need it.”

To do widespread cardiovascular imaging for many individuals would be very costly. Realistically, there are not that many centers in the United States that have all the sophisticated equipment required to do such testing, Dr. Phelan noted.

“One of our major points is difficulty obtaining the test, but also the cost; these are very expensive tests. There are limitations. They are useful when used in the correct context,” he said.
 

To play or not to play, that is the question

Partho P. Sengupta, MD, DM, had to answer that question for more than 50 young athletes who were returning to college at West Virginia University, anxious to be back with their teams and on the playing field. They had been infected with COVID-19 and needed to know when they could return to play.

Dr. Sengupta, who is also an author for the Phelan et al consensus statement on imaging, said there was a lot of pressure – from all the various stakeholders, and from anxious parents, worried college athletes, their teammates, and the university – to determine if the youngsters could return to play.

The fear was that COVID-19 infection left the young athlete’s heart vulnerable to myocarditis and, thus, sudden death on the playing field after strenuous activity.

“At the time we were doing this imaging, there was a lot of concern in the media, and papers were coming out reporting a lot of cardiac involvement or myocarditis associated with COVID-19. Nobody really knew what to do,” he explained.

“There were all kinds of questions, concerns. The parents were putting pressure on us, the athletes wanted to know, the teams, the university. So we put together a team and completed all of the examinations, including testing of blood markers, within a 2-week period. These young athletes, they’re scared, they’re worried and anxious, they don’t know what’s going to happen with their scholarship, so there was some urgency to this work,” Dr. Sengupta said.

“We had to screen all comers within a very short period. We had 54 consecutive patients, gave them full screening, full battery of tests, blood tests, all in a 2-week period,” he said.

Speed was of the essence, and Dr. Sengupta and his team rolled up their sleeves and got to work “We had to know who was safe to clear to return to play and who might need extra follow-up.”
 

Screening echocardiograms

They performed screening echocardiograms on 54 consecutive college athletes who had tested positive for COVID-19 on reverse transcription polymerase chain reaction nasal swab testing or who showed that they had IgG antibodies against COVID-19. The screening echocardiograms were done after the athletes had quarantined for at least 14 days and were no longer infectious.

Most (85%) were male, and the mean age was 19 years. A total of 16 (30%) athletes were asymptomatic, 36 (66%) reported mild COVID-19 related symptoms, and two (4%) reported moderate symptoms.

Of the 54 athletes who were initially screened with echocardiography, 48 (11 asymptomatic, 37 symptomatic), went on to have cardiac magnetic resonance imaging.

Results showed that more than half the athletes (27; 56.3%), showed some cardiac abnormality. The most common was pericardial late enhancement with associated pericardial effusion, affecting 19 (39.5%) athletes.

Of these, six (12.5%) had reduced global longitudinal strain (GLS) or an increased native T1.

One patient showed myocardial enhancement.

Additionally, seven athletes (14.6%) had reduced left ventricular ejection fraction or reduced GLS with or without increased native T1. Native T2 levels were normal in all subjects and no specific imaging features of myocardial inflammation were identified.

Participants were brought back to receive the results of their tests and to get an individualized plan about their safe return to play 3 to 5 weeks after they had ceased to be infectious with COVID-19.

“We saw pericardial inflammation that was resolving. We did not see any blood biomarkers to suggest that there was active inflammation going on,” he said. “We also did not see any muscle inflammation, but we did see pockets of fluid in over a third of our athletes.”

Fortunately, most were deemed able to get back to playing safely, despite having evidence of pericardial inflammation.

This was on strict condition that they be monitored very closely for any adverse events that might occur as they began to exercise again.

“Once they go back to the field to start exercising and practicing, it is under great supervision. We instructed all of our sports physicians and other team managers that these people need to be observed very carefully. So as long as they were asymptomatic, even though the signs of pericardial inflammation were there, if there were no signs of inflammation in the blood, we let them go back to play, closely monitored,” Dr. Sengupta said.

A small number remained very symptomatic at the end of the 5 weeks and were referred to cardiac rehabilitation, Dr. Sengupta said. “They were tired, fatigued, short of breath, even 5 weeks after they got over COVID, so we sent them for cardiac rehab to help them get conditioned again.”

The researchers plan to reevaluate and reimage all of the athletes in another 3 months to monitor their cardiac health.

Dr. Sengupta acknowledged the limitations of this single-center, nonrandomized, controlled report, but insists reports such as this add a bit more to what we are learning about COVID-19 every day.

“These kids were coming to us and asking questions. You have to use the best science you have available to you at that point in time. Some people ask why we did not have a control group, but how do you design a control population in the midst of a pandemic? The science may or may not be perfect, I agree, but the information we obtained is important,” he said.

“Right now, I don’t think we have enough science, and we are still learning. It is very difficult to predict who will develop the heart muscle disease or the pericardial disease,” Dr. Sengupta said. “We had to do our work quickly to give answers to the young athletes, their parents, their teammates, their university, as soon as possible, and we were doing this under pandemic conditions.”

The work was supported by the National Science Foundation National Institute of General Medical Sciences of the National Institutes of Health. Dr. Phelan reported no relevant financial relationships. Dr. Sengupta reported that he is a consultant for HeartSciences, Kencor Health, and Ultromics.

This article first appeared on Medscape.com.

Increasingly, clinicians are being called upon to advise athletes who have recovered from COVID-19 on when it is safe for them to return to play.

Now, they have two reports that offer more insights into the cardiotoxic effects of COVID-19 on the athletic heart.

In the first report, researchers report a high prevalence of pericardial involvement in college-student athletes who have recovered from COVID-19 and give their practical advice on how to let these athletes return to play safely.

In the second report, an expert panel of sports cardiologists provides a comprehensive guide to the appropriate imaging of athletes who may have cardiovascular complications from COVID-19.

Both are published in JACC: Cardiovascular Imaging.

“We were asked by the editors of JACC to submit this paper, and the impetus for it was the fact that there are so many athletes returning after being infected with COVID-19, we need to try and give guidance to cardiologists as to how best to evaluate these athletes,” Dermot Phelan, MD, PhD, Sanger Heart and Vascular Institute, Atrium Health, Charlotte, N.C., and lead author of the consensus statement, said in an interview.

The consensus statement acknowledges that information about the cardiovascular complications of COVID-19 continues to evolve. Meanwhile, pathologies such as myocarditis, pericarditis, and right ventricular dysfunction, in the absence of significant clinical symptoms, in athletes who have been affected by COVID-19 remain of considerable concern.

It also emphasizes the unique challenges the average cardiologist faces in distinguishing between what is normal for an athlete’s heart and what is true pathology after COVID-19 infection; details how different imaging modalities can help in screening, evaluating, and monitoring athletes with suspected cardiovascular complications of COVID-19 infection; and discusses the strengths and limitations of these modalities.

Finally, the consensus statement provides some well-needed guidance on return-to-play decision-making, for both the athlete and the clinician.
 

Athletic remodeling or covid-19 damage?

Athletes can develop certain cardiovascular characteristics because of their athletic activity, and sometimes, this can cloud the diagnostic picture.

“Is this change due to the effects of COVID-19, or is it just because this is an athlete’s heart? This was an international expert consensus, made up of sports cardiologists from all over the world who have a lot of experience in dealing with athletes,” Dr. Phelan said. “We were trying to relay the important information to the cardiologist who is not used to dealing with athletes on a day-to-day basis, as to what they might expect to find in that athlete, and what is not an expected finding and should be tested further.”

Phelan, a sports cardiologist, is familiar with what is normal for an athlete’s heart and what is pathology.

“We know that athletes, particularly long-term endurance athletes, develop changes in the heart that can affect not only the electrics but the structure of the heart, and sometimes, that overlaps with abnormalities with pathology. This can be a challenge for the nonsports cardiologist to differentiate,” he said.

Phelan and his group have written two other consensus documents on the management of cardiovascular problems that develop in some athletes who have been infected with COVID-19.

The first was published in May in JAMA Cardiology, and the second, which revised some of the original recommendations made in the first document, was published online Oct. 26 in JAMA Cardiology.

The first set of recommendations called for imaging studies to be done in all athletes, but the second set states that athletes who recover and are asymptomatic do not need extensive (and expensive) imaging tests.

“These two papers work hand in hand,” Dr. Phelan said. “In May, we had very little experience with COVID, and there was a lot of concern about hospitalized patients having a very high incidence of heart disease. We published those recommendations, but we recognized at the time that we had very little data and that we would reconsider once we had more experience with data.

“This current set of recommendations that we have put forth here are for those athletes who do need to get further testing, so it’s a step beyond,” Dr. Phelan added. “So the second iteration states that young athletes who had mild or no symptoms didn’t need to go through all of that cardiac testing, but others do need it.”

To do widespread cardiovascular imaging for many individuals would be very costly. Realistically, there are not that many centers in the United States that have all the sophisticated equipment required to do such testing, Dr. Phelan noted.

“One of our major points is difficulty obtaining the test, but also the cost; these are very expensive tests. There are limitations. They are useful when used in the correct context,” he said.
 

To play or not to play, that is the question

Partho P. Sengupta, MD, DM, had to answer that question for more than 50 young athletes who were returning to college at West Virginia University, anxious to be back with their teams and on the playing field. They had been infected with COVID-19 and needed to know when they could return to play.

Dr. Sengupta, who is also an author for the Phelan et al consensus statement on imaging, said there was a lot of pressure – from all the various stakeholders, and from anxious parents, worried college athletes, their teammates, and the university – to determine if the youngsters could return to play.

The fear was that COVID-19 infection left the young athlete’s heart vulnerable to myocarditis and, thus, sudden death on the playing field after strenuous activity.

“At the time we were doing this imaging, there was a lot of concern in the media, and papers were coming out reporting a lot of cardiac involvement or myocarditis associated with COVID-19. Nobody really knew what to do,” he explained.

“There were all kinds of questions, concerns. The parents were putting pressure on us, the athletes wanted to know, the teams, the university. So we put together a team and completed all of the examinations, including testing of blood markers, within a 2-week period. These young athletes, they’re scared, they’re worried and anxious, they don’t know what’s going to happen with their scholarship, so there was some urgency to this work,” Dr. Sengupta said.

“We had to screen all comers within a very short period. We had 54 consecutive patients, gave them full screening, full battery of tests, blood tests, all in a 2-week period,” he said.

Speed was of the essence, and Dr. Sengupta and his team rolled up their sleeves and got to work “We had to know who was safe to clear to return to play and who might need extra follow-up.”
 

Screening echocardiograms

They performed screening echocardiograms on 54 consecutive college athletes who had tested positive for COVID-19 on reverse transcription polymerase chain reaction nasal swab testing or who showed that they had IgG antibodies against COVID-19. The screening echocardiograms were done after the athletes had quarantined for at least 14 days and were no longer infectious.

Most (85%) were male, and the mean age was 19 years. A total of 16 (30%) athletes were asymptomatic, 36 (66%) reported mild COVID-19 related symptoms, and two (4%) reported moderate symptoms.

Of the 54 athletes who were initially screened with echocardiography, 48 (11 asymptomatic, 37 symptomatic), went on to have cardiac magnetic resonance imaging.

Results showed that more than half the athletes (27; 56.3%), showed some cardiac abnormality. The most common was pericardial late enhancement with associated pericardial effusion, affecting 19 (39.5%) athletes.

Of these, six (12.5%) had reduced global longitudinal strain (GLS) or an increased native T1.

One patient showed myocardial enhancement.

Additionally, seven athletes (14.6%) had reduced left ventricular ejection fraction or reduced GLS with or without increased native T1. Native T2 levels were normal in all subjects and no specific imaging features of myocardial inflammation were identified.

Participants were brought back to receive the results of their tests and to get an individualized plan about their safe return to play 3 to 5 weeks after they had ceased to be infectious with COVID-19.

“We saw pericardial inflammation that was resolving. We did not see any blood biomarkers to suggest that there was active inflammation going on,” he said. “We also did not see any muscle inflammation, but we did see pockets of fluid in over a third of our athletes.”

Fortunately, most were deemed able to get back to playing safely, despite having evidence of pericardial inflammation.

This was on strict condition that they be monitored very closely for any adverse events that might occur as they began to exercise again.

“Once they go back to the field to start exercising and practicing, it is under great supervision. We instructed all of our sports physicians and other team managers that these people need to be observed very carefully. So as long as they were asymptomatic, even though the signs of pericardial inflammation were there, if there were no signs of inflammation in the blood, we let them go back to play, closely monitored,” Dr. Sengupta said.

A small number remained very symptomatic at the end of the 5 weeks and were referred to cardiac rehabilitation, Dr. Sengupta said. “They were tired, fatigued, short of breath, even 5 weeks after they got over COVID, so we sent them for cardiac rehab to help them get conditioned again.”

The researchers plan to reevaluate and reimage all of the athletes in another 3 months to monitor their cardiac health.

Dr. Sengupta acknowledged the limitations of this single-center, nonrandomized, controlled report, but insists reports such as this add a bit more to what we are learning about COVID-19 every day.

“These kids were coming to us and asking questions. You have to use the best science you have available to you at that point in time. Some people ask why we did not have a control group, but how do you design a control population in the midst of a pandemic? The science may or may not be perfect, I agree, but the information we obtained is important,” he said.

“Right now, I don’t think we have enough science, and we are still learning. It is very difficult to predict who will develop the heart muscle disease or the pericardial disease,” Dr. Sengupta said. “We had to do our work quickly to give answers to the young athletes, their parents, their teammates, their university, as soon as possible, and we were doing this under pandemic conditions.”

The work was supported by the National Science Foundation National Institute of General Medical Sciences of the National Institutes of Health. Dr. Phelan reported no relevant financial relationships. Dr. Sengupta reported that he is a consultant for HeartSciences, Kencor Health, and Ultromics.

This article first appeared on Medscape.com.

Increasingly, clinicians are being called upon to advise athletes who have recovered from COVID-19 on when it is safe for them to return to play.

Now, they have two reports that offer more insights into the cardiotoxic effects of COVID-19 on the athletic heart.

In the first report, researchers report a high prevalence of pericardial involvement in college-student athletes who have recovered from COVID-19 and give their practical advice on how to let these athletes return to play safely.

In the second report, an expert panel of sports cardiologists provides a comprehensive guide to the appropriate imaging of athletes who may have cardiovascular complications from COVID-19.

Both are published in JACC: Cardiovascular Imaging.

“We were asked by the editors of JACC to submit this paper, and the impetus for it was the fact that there are so many athletes returning after being infected with COVID-19, we need to try and give guidance to cardiologists as to how best to evaluate these athletes,” Dermot Phelan, MD, PhD, Sanger Heart and Vascular Institute, Atrium Health, Charlotte, N.C., and lead author of the consensus statement, said in an interview.

The consensus statement acknowledges that information about the cardiovascular complications of COVID-19 continues to evolve. Meanwhile, pathologies such as myocarditis, pericarditis, and right ventricular dysfunction, in the absence of significant clinical symptoms, in athletes who have been affected by COVID-19 remain of considerable concern.

It also emphasizes the unique challenges the average cardiologist faces in distinguishing between what is normal for an athlete’s heart and what is true pathology after COVID-19 infection; details how different imaging modalities can help in screening, evaluating, and monitoring athletes with suspected cardiovascular complications of COVID-19 infection; and discusses the strengths and limitations of these modalities.

Finally, the consensus statement provides some well-needed guidance on return-to-play decision-making, for both the athlete and the clinician.
 

Athletic remodeling or covid-19 damage?

Athletes can develop certain cardiovascular characteristics because of their athletic activity, and sometimes, this can cloud the diagnostic picture.

“Is this change due to the effects of COVID-19, or is it just because this is an athlete’s heart? This was an international expert consensus, made up of sports cardiologists from all over the world who have a lot of experience in dealing with athletes,” Dr. Phelan said. “We were trying to relay the important information to the cardiologist who is not used to dealing with athletes on a day-to-day basis, as to what they might expect to find in that athlete, and what is not an expected finding and should be tested further.”

Phelan, a sports cardiologist, is familiar with what is normal for an athlete’s heart and what is pathology.

“We know that athletes, particularly long-term endurance athletes, develop changes in the heart that can affect not only the electrics but the structure of the heart, and sometimes, that overlaps with abnormalities with pathology. This can be a challenge for the nonsports cardiologist to differentiate,” he said.

Phelan and his group have written two other consensus documents on the management of cardiovascular problems that develop in some athletes who have been infected with COVID-19.

The first was published in May in JAMA Cardiology, and the second, which revised some of the original recommendations made in the first document, was published online Oct. 26 in JAMA Cardiology.

The first set of recommendations called for imaging studies to be done in all athletes, but the second set states that athletes who recover and are asymptomatic do not need extensive (and expensive) imaging tests.

“These two papers work hand in hand,” Dr. Phelan said. “In May, we had very little experience with COVID, and there was a lot of concern about hospitalized patients having a very high incidence of heart disease. We published those recommendations, but we recognized at the time that we had very little data and that we would reconsider once we had more experience with data.

“This current set of recommendations that we have put forth here are for those athletes who do need to get further testing, so it’s a step beyond,” Dr. Phelan added. “So the second iteration states that young athletes who had mild or no symptoms didn’t need to go through all of that cardiac testing, but others do need it.”

To do widespread cardiovascular imaging for many individuals would be very costly. Realistically, there are not that many centers in the United States that have all the sophisticated equipment required to do such testing, Dr. Phelan noted.

“One of our major points is difficulty obtaining the test, but also the cost; these are very expensive tests. There are limitations. They are useful when used in the correct context,” he said.
 

To play or not to play, that is the question

Partho P. Sengupta, MD, DM, had to answer that question for more than 50 young athletes who were returning to college at West Virginia University, anxious to be back with their teams and on the playing field. They had been infected with COVID-19 and needed to know when they could return to play.

Dr. Sengupta, who is also an author for the Phelan et al consensus statement on imaging, said there was a lot of pressure – from all the various stakeholders, and from anxious parents, worried college athletes, their teammates, and the university – to determine if the youngsters could return to play.

The fear was that COVID-19 infection left the young athlete’s heart vulnerable to myocarditis and, thus, sudden death on the playing field after strenuous activity.

“At the time we were doing this imaging, there was a lot of concern in the media, and papers were coming out reporting a lot of cardiac involvement or myocarditis associated with COVID-19. Nobody really knew what to do,” he explained.

“There were all kinds of questions, concerns. The parents were putting pressure on us, the athletes wanted to know, the teams, the university. So we put together a team and completed all of the examinations, including testing of blood markers, within a 2-week period. These young athletes, they’re scared, they’re worried and anxious, they don’t know what’s going to happen with their scholarship, so there was some urgency to this work,” Dr. Sengupta said.

“We had to screen all comers within a very short period. We had 54 consecutive patients, gave them full screening, full battery of tests, blood tests, all in a 2-week period,” he said.

Speed was of the essence, and Dr. Sengupta and his team rolled up their sleeves and got to work “We had to know who was safe to clear to return to play and who might need extra follow-up.”
 

Screening echocardiograms

They performed screening echocardiograms on 54 consecutive college athletes who had tested positive for COVID-19 on reverse transcription polymerase chain reaction nasal swab testing or who showed that they had IgG antibodies against COVID-19. The screening echocardiograms were done after the athletes had quarantined for at least 14 days and were no longer infectious.

Most (85%) were male, and the mean age was 19 years. A total of 16 (30%) athletes were asymptomatic, 36 (66%) reported mild COVID-19 related symptoms, and two (4%) reported moderate symptoms.

Of the 54 athletes who were initially screened with echocardiography, 48 (11 asymptomatic, 37 symptomatic), went on to have cardiac magnetic resonance imaging.

Results showed that more than half the athletes (27; 56.3%), showed some cardiac abnormality. The most common was pericardial late enhancement with associated pericardial effusion, affecting 19 (39.5%) athletes.

Of these, six (12.5%) had reduced global longitudinal strain (GLS) or an increased native T1.

One patient showed myocardial enhancement.

Additionally, seven athletes (14.6%) had reduced left ventricular ejection fraction or reduced GLS with or without increased native T1. Native T2 levels were normal in all subjects and no specific imaging features of myocardial inflammation were identified.

Participants were brought back to receive the results of their tests and to get an individualized plan about their safe return to play 3 to 5 weeks after they had ceased to be infectious with COVID-19.

“We saw pericardial inflammation that was resolving. We did not see any blood biomarkers to suggest that there was active inflammation going on,” he said. “We also did not see any muscle inflammation, but we did see pockets of fluid in over a third of our athletes.”

Fortunately, most were deemed able to get back to playing safely, despite having evidence of pericardial inflammation.

This was on strict condition that they be monitored very closely for any adverse events that might occur as they began to exercise again.

“Once they go back to the field to start exercising and practicing, it is under great supervision. We instructed all of our sports physicians and other team managers that these people need to be observed very carefully. So as long as they were asymptomatic, even though the signs of pericardial inflammation were there, if there were no signs of inflammation in the blood, we let them go back to play, closely monitored,” Dr. Sengupta said.

A small number remained very symptomatic at the end of the 5 weeks and were referred to cardiac rehabilitation, Dr. Sengupta said. “They were tired, fatigued, short of breath, even 5 weeks after they got over COVID, so we sent them for cardiac rehab to help them get conditioned again.”

The researchers plan to reevaluate and reimage all of the athletes in another 3 months to monitor their cardiac health.

Dr. Sengupta acknowledged the limitations of this single-center, nonrandomized, controlled report, but insists reports such as this add a bit more to what we are learning about COVID-19 every day.

“These kids were coming to us and asking questions. You have to use the best science you have available to you at that point in time. Some people ask why we did not have a control group, but how do you design a control population in the midst of a pandemic? The science may or may not be perfect, I agree, but the information we obtained is important,” he said.

“Right now, I don’t think we have enough science, and we are still learning. It is very difficult to predict who will develop the heart muscle disease or the pericardial disease,” Dr. Sengupta said. “We had to do our work quickly to give answers to the young athletes, their parents, their teammates, their university, as soon as possible, and we were doing this under pandemic conditions.”

The work was supported by the National Science Foundation National Institute of General Medical Sciences of the National Institutes of Health. Dr. Phelan reported no relevant financial relationships. Dr. Sengupta reported that he is a consultant for HeartSciences, Kencor Health, and Ultromics.

This article first appeared on Medscape.com.

The largest U.S. physician organization on Tuesday took a step to prepare for future payments for administration of two leading COVID-19 vaccine candidates, publishing new billing codes tailored to track each use of these medications.

The American Medical Association updated its CPT code set to reflect the expected future availability of COVID-19 vaccines. The new codes apply to the experimental vaccine being developed by Pfizer, in collaboration with a smaller German firm BioNTech, and to the similar product expected from Moderna, according to an AMA press release.

Positive news has emerged this week about both of these vaccines, which were developed using a newer – and as yet unproven – approach. They seek to use messenger RNA to instruct cells to produce a target protein for SARS-CoV-2.

New York–based Pfizer on Monday announced interim phase 3 data that was widely viewed as promising. Pfizer said the vaccine appeared to be 90% effective in preventing COVID-19 in trial volunteers who were without evidence of prior infection of the virus.

In a press release, Pfizer said it plans to ask the Food and Drug Administration to consider a special clearance, known as an emergency-use authorization, “soon after” a safety milestone is achieved in its vaccine trial. That milestone could be reached this month.

Moderna said it was on track to report early data from a late-stage trial of its experimental coronavirus vaccine later this month, and could file with the FDA for an emergency-use authorization in early December, according to a Reuters report.

The severity of the global pandemic has put the FDA under pressure to move quickly on approval of COVID-19 vaccines, based on limited data, while also working to make sure these products are safe. The creation of CPT codes for each of two coronavirus vaccines, as well as accompanying administration codes, will set up a way to keep tabs on each dose of each of these shots, the AMA said.

American Medical Association

“Correlating each coronavirus vaccine with its own unique CPT code provides analytical advantages to help track, allocate and optimize resources as an immunization program ramps up in the United States,” AMA President Susan R. Bailey, MD, said in the release.

AMA plans to introduce more vaccine-specific CPT codes as more vaccine candidates approach FDA review. These vaccine-specific CPT codes can go into effect only after the FDA grants a clearance.

The newly created Category I CPT codes and long descriptors for the vaccine products are:
 

• 91300; severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3mL dosage, diluent reconstituted, for intramuscular use (Pfizer/BioNTech)
• 91301; severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5mL dosage, for intramuscular use (Moderna)

These two administrative codes would apply to the Pfizer-BioNTech shot:

• 0001A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3 mL dosage, diluent reconstituted; first dose.
• 0002A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3 mL dosage, diluent reconstituted; second dose.

And these two administrative codes would apply to the Moderna shot:

• 0011A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5 mL dosage; first dose.
• 0012A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5 mL dosage; second dose.

A version of this article originally appeared on Medscape.com.

The largest U.S. physician organization on Tuesday took a step to prepare for future payments for administration of two leading COVID-19 vaccine candidates, publishing new billing codes tailored to track each use of these medications.

The American Medical Association updated its CPT code set to reflect the expected future availability of COVID-19 vaccines. The new codes apply to the experimental vaccine being developed by Pfizer, in collaboration with a smaller German firm BioNTech, and to the similar product expected from Moderna, according to an AMA press release.

Positive news has emerged this week about both of these vaccines, which were developed using a newer – and as yet unproven – approach. They seek to use messenger RNA to instruct cells to produce a target protein for SARS-CoV-2.

New York–based Pfizer on Monday announced interim phase 3 data that was widely viewed as promising. Pfizer said the vaccine appeared to be 90% effective in preventing COVID-19 in trial volunteers who were without evidence of prior infection of the virus.

In a press release, Pfizer said it plans to ask the Food and Drug Administration to consider a special clearance, known as an emergency-use authorization, “soon after” a safety milestone is achieved in its vaccine trial. That milestone could be reached this month.

Moderna said it was on track to report early data from a late-stage trial of its experimental coronavirus vaccine later this month, and could file with the FDA for an emergency-use authorization in early December, according to a Reuters report.

The severity of the global pandemic has put the FDA under pressure to move quickly on approval of COVID-19 vaccines, based on limited data, while also working to make sure these products are safe. The creation of CPT codes for each of two coronavirus vaccines, as well as accompanying administration codes, will set up a way to keep tabs on each dose of each of these shots, the AMA said.

American Medical Association

“Correlating each coronavirus vaccine with its own unique CPT code provides analytical advantages to help track, allocate and optimize resources as an immunization program ramps up in the United States,” AMA President Susan R. Bailey, MD, said in the release.

AMA plans to introduce more vaccine-specific CPT codes as more vaccine candidates approach FDA review. These vaccine-specific CPT codes can go into effect only after the FDA grants a clearance.

The newly created Category I CPT codes and long descriptors for the vaccine products are:
 

• 91300; severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3mL dosage, diluent reconstituted, for intramuscular use (Pfizer/BioNTech)
• 91301; severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5mL dosage, for intramuscular use (Moderna)

These two administrative codes would apply to the Pfizer-BioNTech shot:

• 0001A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3 mL dosage, diluent reconstituted; first dose.
• 0002A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3 mL dosage, diluent reconstituted; second dose.

And these two administrative codes would apply to the Moderna shot:

• 0011A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5 mL dosage; first dose.
• 0012A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5 mL dosage; second dose.

A version of this article originally appeared on Medscape.com.

The largest U.S. physician organization on Tuesday took a step to prepare for future payments for administration of two leading COVID-19 vaccine candidates, publishing new billing codes tailored to track each use of these medications.

The American Medical Association updated its CPT code set to reflect the expected future availability of COVID-19 vaccines. The new codes apply to the experimental vaccine being developed by Pfizer, in collaboration with a smaller German firm BioNTech, and to the similar product expected from Moderna, according to an AMA press release.

Positive news has emerged this week about both of these vaccines, which were developed using a newer – and as yet unproven – approach. They seek to use messenger RNA to instruct cells to produce a target protein for SARS-CoV-2.

New York–based Pfizer on Monday announced interim phase 3 data that was widely viewed as promising. Pfizer said the vaccine appeared to be 90% effective in preventing COVID-19 in trial volunteers who were without evidence of prior infection of the virus.

In a press release, Pfizer said it plans to ask the Food and Drug Administration to consider a special clearance, known as an emergency-use authorization, “soon after” a safety milestone is achieved in its vaccine trial. That milestone could be reached this month.

Moderna said it was on track to report early data from a late-stage trial of its experimental coronavirus vaccine later this month, and could file with the FDA for an emergency-use authorization in early December, according to a Reuters report.

The severity of the global pandemic has put the FDA under pressure to move quickly on approval of COVID-19 vaccines, based on limited data, while also working to make sure these products are safe. The creation of CPT codes for each of two coronavirus vaccines, as well as accompanying administration codes, will set up a way to keep tabs on each dose of each of these shots, the AMA said.

American Medical Association

“Correlating each coronavirus vaccine with its own unique CPT code provides analytical advantages to help track, allocate and optimize resources as an immunization program ramps up in the United States,” AMA President Susan R. Bailey, MD, said in the release.

AMA plans to introduce more vaccine-specific CPT codes as more vaccine candidates approach FDA review. These vaccine-specific CPT codes can go into effect only after the FDA grants a clearance.

The newly created Category I CPT codes and long descriptors for the vaccine products are:
 

• 91300; severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3mL dosage, diluent reconstituted, for intramuscular use (Pfizer/BioNTech)
• 91301; severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5mL dosage, for intramuscular use (Moderna)

These two administrative codes would apply to the Pfizer-BioNTech shot:

• 0001A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3 mL dosage, diluent reconstituted; first dose.
• 0002A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 30 mcg/0.3 mL dosage, diluent reconstituted; second dose.

And these two administrative codes would apply to the Moderna shot:

• 0011A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5 mL dosage; first dose.
• 0012A; Immunization administration by intramuscular injection of severe acute respiratory syndrome coronavirus 2 (SARS-CoV-2) (coronavirus disease [COVID-19]) vaccine, mRNA-LNP, spike protein, preservative free, 100 mcg/0.5 mL dosage; second dose.

A version of this article originally appeared on Medscape.com.

After a 50-year hiatus, psychedelic drugs are undergoing a research renaissance. Roland R. Griffiths, PhD, professor in the Departments of Psychiatry and Neuroscience and the Oliver Lee McCabe III, Professor in the Neuropsychopharmacology of Consciousness, and director of the Center for Psychedelic and Consciousness Research at Johns Hopkins University, Baltimore, discusses the status of these drugs in the United States and their potential to treat psychiatric disorders.

Classic psychedelics are compounds that bind to the 5-hydroxytryptamine 2A (5-HT2A) receptor and include the naturally occurring compounds psilocybin, N,N-dimethyltryptamine (DMT, a component of ayahuasca) and mescaline (peyote cactus), as well as the synthesized compound lysergic acid diethylamide (LSD).

Other drugs, such as ketamine, are sometimes referred to as “psychedelics” because they can produce subjective experiences that are similar to those of people who receive classic psychedelics. However, unlike classic psychedelics, the effects of ketamine tend to be short lived. Ketamine also has addictive potential and can be lethal in high doses, which is not the case with psilocybin.

Another compound sometimes referred to as a “psychedelic” is 3,4-methylenedioxymethamphetamine (MDMA), also known as “ecstasy.” The Food and Drug Administration granted breakthrough approval for the study of MDMA for posttraumatic stress disorder (PTSD). FDA-approved registration trials are ongoing. MDMA differs from classic psychedelics in risk profile and pharmacology. In particular, MDMA was widely abused as part of the “rave culture,” while classic psychedelic agents do not lend themselves to that type of misuse.
 

What is the current legal status of psychedelic agents in the United States? Can clinicians prescribe them, or are they available only in a research setting?

All classic psychedelics are considered to be “Schedule 1” which means they are illegal to possess and use except for research and only if approved by the FDA and under licensure of the Drug Enforcement Administration (DEA), so they are not available for clinical use.

In anticipation of the possibility that phase 3 research may support the efficacy and safety of psilocybin for one or more medical or mental health disorders, our team has reviewed available evidence regarding its abuse liability and concluded that, if psilocybin were approved as medication, it could possibly be included in the Schedule IV category, with additional FDA-mandated risk management provisions. However, this is not yet the case.
 

Which psychedelic agents are under investigation in the United States, and for which indications?

Psilocybin is under investigation in our center, as well as elsewhere in the United States. We have previously found it to be effective for smoking cessation, and we are conducting another study that is currently recruiting volunteers for this indication. We are also recruiting volunteers for studies on the use of psilocybin for major depression, Alzheimer’s disease, and anorexia nervosa. Further information about our studies can be found on the Web site for our center, the Center for Psychedelic and Consciousness Research.

Two companies – the Usona Institute and COMPASS Pathways – have received FDA Breakthrough Therapy Designation for their programs seeking approval of psilocybin as a treatment major depressive disorder and treatment-resistant depression (TRD), respectively. In addition, an international multicenter study currently underway, which includes US centers in Houston, Baltimore, New York, San Diego, and Atlanta, is investigating psilocybin for TRD.

A number of studies, including one conducted at our center, have investigated psilocybin for depression and anxiety in patients with cancer and found it effective.

Additional research showed that psilocybin alleviated symptoms of cancer-related anxiety and depression, both in the short-term and 5 years later.

LSD has been studied and found promising in the treatment of alcohol use disorder. Additional studies of LSD that are being conducted in Basel Switzerland and at the University of Chicago are examining its impact on mood in healthy volunteers.

Ayahuasca has been studied extensively for depression and anxiety and is also currently under investigation for PTSD. We found that its use in a naturalistic group setting was associated with unintended improvements in depression and anxiety.

Lastly, a lesser-known psychedelic agent is Salvinorin A, which our center has been studying, is the psychoactive constituent of the Salvia divinorum plant. While this is not a “classic” psychedelic compound, it is nevertheless the focus of much scientific interest because its effects are mediated at opioid receptors, rather than 5-HT2A receptors, and may prove to be a novel nonaddictive opioid that may ultimately be a promising treatment for pain and addiction.
 

What is the typical treatment regimen for psychedelic agents?

It is hard to speak of a “treatment regimen” in agents that are not used in clinical practice. Ongoing clinical trials with psilocybin generally involve one or two 6- to 8-hour sessions involving the oral administration of a moderately high dose under psychologically supported conditions.

Based on the current evidence base, which agents show the most promise?

Psilocybin is currently the most promising classic psychedelic undergoing clinical trials.

Do psychedelics have to be administered in a controlled setting in order to be effective?

Although many people have had meaningful experiences whether inside or outside of a controlled setting, there are serious potential risks associated with use of psilocybin and other classic psychedelics. The safety of psilocybin has been established in clinical studies in which participants have been carefully screened physically and psychologically, are psychologically prepared before their first session, and are psychologically supported during and after sessions. In vulnerable individuals, psilocybin has been associated with enduring psychiatric problems and sometimes persisting visual perceptual conditions. When taken in uncontrolled conditions, classic psychedelics can produce confusion and disorientation resulting in behavior dangerous to the participant and others – including life-threatening risk. Thus, for safety reasons, the optimal environment for using these agents is in a controlled setting.

Do results differ between patients who have used psychedelic agents previously and those who have not?

We have not found any difference between psychedelic-naive volunteers and those who have used psychedelics in the past.

Do you provide patient education prior to treatment initiation?

All of our study participants are thoroughly screened for medical concerns or mental health history such as psychosis, which would preclude their participation. They are educated about the effects of these agents and what they might expect and typically receive several hours of psychological preparation before the first session. They are also provided with psychological support after sessions. Additionally, we spend time developing trust and rapport prior to the first session.

How durable are the effects of psychedelic treatment?

Studies in patients and healthy participants suggest that the positive effects of psilocybin are long lasting, with most individuals reporting positive changes in moods, attitudes, and behavior that they attribute to psilocybin and which endure months or years after the session. The qualities of the acute session experience can vary widely ranging from experiences of transcendence or psychological insight to experiences of intense anxiety or fear.

An enduring shift in worldview and sense of self, as well as psychological insight, may increase psychological flexibility, thereby allowing individuals to subsequently avoid maladaptive patterns of behavior or thought and to make more healthy choices.

Our research has shown that the benefits of these experiences can last as long as 14 months, often longer, and that many participants characterize their psilocybin experience as among the most profound and personally meaningful experience of their lives.
 

Do participants experience any adverse effects? If so, how are they managed?

Sometimes, despite all the preparation, screening, and support we provide, some participants can have frightening experiences, such as fear and anxiety during the session. When that occurs, it is often shorted lived. The psychological preparation we provide before the session and the psychological support we provide during the session are important for managing such effects.

We provide support and encourage participants to stay with that experience, which may open to experiences of deep meaning or insight. A number of people report that these psychologically challenging states are a valuable part of the overall experience.

We conducted a survey of roughly 2,000 people who took high doses of psilocybin mushrooms and then had a challenging experience. About 10% reported they put themselves or others at risk of physical harm. Of more concern, of those whose experience occurred more than 1 year before, 8% sought treatment for enduring psychological symptoms. These findings underscore potential risks of psilocybin use but do not provide an estimate of the actual incidence of such effects.

Importantly, in our research at Johns Hopkins, we have not observed such effects in over 700 sessions that we have conducted with almost 400 participants, likely because we thoroughly screen and prepare participants and support them after they have completed the study. The potential for serious lasting harm represents a concern and points to the importance of adequate screening and aftercare.
 

What are the implications for future therapeutics?

We are living in exciting times, in terms of psychedelic research. The potential for a single treatment with a classic psychedelic to produce rapid and sustained therapeutic effects, possibly across a range of psychiatric conditions, is unprecedented in psychiatry. The effect appears to be an “inverse PTSD effect.”

In PTSD, a single exposure to a traumatic event can rewire the nervous system to the point that it produces enduring harm and toxicity. In the case of psychedelics, a single exposure appears to have enduring positive effects in worldview, mood, attitude, behavior, and overall life satisfaction. We can look forward to continued growth and expansion of this research including the refinement of protocols for a variety of therapeutic indications and to the development of a variety of new classic psychedelic compounds.
 

A version of this article originally appeared on Medscape.com.

After a 50-year hiatus, psychedelic drugs are undergoing a research renaissance. Roland R. Griffiths, PhD, professor in the Departments of Psychiatry and Neuroscience and the Oliver Lee McCabe III, Professor in the Neuropsychopharmacology of Consciousness, and director of the Center for Psychedelic and Consciousness Research at Johns Hopkins University, Baltimore, discusses the status of these drugs in the United States and their potential to treat psychiatric disorders.

Classic psychedelics are compounds that bind to the 5-hydroxytryptamine 2A (5-HT2A) receptor and include the naturally occurring compounds psilocybin, N,N-dimethyltryptamine (DMT, a component of ayahuasca) and mescaline (peyote cactus), as well as the synthesized compound lysergic acid diethylamide (LSD).

Other drugs, such as ketamine, are sometimes referred to as “psychedelics” because they can produce subjective experiences that are similar to those of people who receive classic psychedelics. However, unlike classic psychedelics, the effects of ketamine tend to be short lived. Ketamine also has addictive potential and can be lethal in high doses, which is not the case with psilocybin.

Another compound sometimes referred to as a “psychedelic” is 3,4-methylenedioxymethamphetamine (MDMA), also known as “ecstasy.” The Food and Drug Administration granted breakthrough approval for the study of MDMA for posttraumatic stress disorder (PTSD). FDA-approved registration trials are ongoing. MDMA differs from classic psychedelics in risk profile and pharmacology. In particular, MDMA was widely abused as part of the “rave culture,” while classic psychedelic agents do not lend themselves to that type of misuse.
 

What is the current legal status of psychedelic agents in the United States? Can clinicians prescribe them, or are they available only in a research setting?

All classic psychedelics are considered to be “Schedule 1” which means they are illegal to possess and use except for research and only if approved by the FDA and under licensure of the Drug Enforcement Administration (DEA), so they are not available for clinical use.

In anticipation of the possibility that phase 3 research may support the efficacy and safety of psilocybin for one or more medical or mental health disorders, our team has reviewed available evidence regarding its abuse liability and concluded that, if psilocybin were approved as medication, it could possibly be included in the Schedule IV category, with additional FDA-mandated risk management provisions. However, this is not yet the case.
 

Which psychedelic agents are under investigation in the United States, and for which indications?

Psilocybin is under investigation in our center, as well as elsewhere in the United States. We have previously found it to be effective for smoking cessation, and we are conducting another study that is currently recruiting volunteers for this indication. We are also recruiting volunteers for studies on the use of psilocybin for major depression, Alzheimer’s disease, and anorexia nervosa. Further information about our studies can be found on the Web site for our center, the Center for Psychedelic and Consciousness Research.

Two companies – the Usona Institute and COMPASS Pathways – have received FDA Breakthrough Therapy Designation for their programs seeking approval of psilocybin as a treatment major depressive disorder and treatment-resistant depression (TRD), respectively. In addition, an international multicenter study currently underway, which includes US centers in Houston, Baltimore, New York, San Diego, and Atlanta, is investigating psilocybin for TRD.

A number of studies, including one conducted at our center, have investigated psilocybin for depression and anxiety in patients with cancer and found it effective.

Additional research showed that psilocybin alleviated symptoms of cancer-related anxiety and depression, both in the short-term and 5 years later.

LSD has been studied and found promising in the treatment of alcohol use disorder. Additional studies of LSD that are being conducted in Basel Switzerland and at the University of Chicago are examining its impact on mood in healthy volunteers.

Ayahuasca has been studied extensively for depression and anxiety and is also currently under investigation for PTSD. We found that its use in a naturalistic group setting was associated with unintended improvements in depression and anxiety.

Lastly, a lesser-known psychedelic agent is Salvinorin A, which our center has been studying, is the psychoactive constituent of the Salvia divinorum plant. While this is not a “classic” psychedelic compound, it is nevertheless the focus of much scientific interest because its effects are mediated at opioid receptors, rather than 5-HT2A receptors, and may prove to be a novel nonaddictive opioid that may ultimately be a promising treatment for pain and addiction.
 

What is the typical treatment regimen for psychedelic agents?

It is hard to speak of a “treatment regimen” in agents that are not used in clinical practice. Ongoing clinical trials with psilocybin generally involve one or two 6- to 8-hour sessions involving the oral administration of a moderately high dose under psychologically supported conditions.

Based on the current evidence base, which agents show the most promise?

Psilocybin is currently the most promising classic psychedelic undergoing clinical trials.

Do psychedelics have to be administered in a controlled setting in order to be effective?

Although many people have had meaningful experiences whether inside or outside of a controlled setting, there are serious potential risks associated with use of psilocybin and other classic psychedelics. The safety of psilocybin has been established in clinical studies in which participants have been carefully screened physically and psychologically, are psychologically prepared before their first session, and are psychologically supported during and after sessions. In vulnerable individuals, psilocybin has been associated with enduring psychiatric problems and sometimes persisting visual perceptual conditions. When taken in uncontrolled conditions, classic psychedelics can produce confusion and disorientation resulting in behavior dangerous to the participant and others – including life-threatening risk. Thus, for safety reasons, the optimal environment for using these agents is in a controlled setting.

Do results differ between patients who have used psychedelic agents previously and those who have not?

We have not found any difference between psychedelic-naive volunteers and those who have used psychedelics in the past.

Do you provide patient education prior to treatment initiation?

All of our study participants are thoroughly screened for medical concerns or mental health history such as psychosis, which would preclude their participation. They are educated about the effects of these agents and what they might expect and typically receive several hours of psychological preparation before the first session. They are also provided with psychological support after sessions. Additionally, we spend time developing trust and rapport prior to the first session.

How durable are the effects of psychedelic treatment?

Studies in patients and healthy participants suggest that the positive effects of psilocybin are long lasting, with most individuals reporting positive changes in moods, attitudes, and behavior that they attribute to psilocybin and which endure months or years after the session. The qualities of the acute session experience can vary widely ranging from experiences of transcendence or psychological insight to experiences of intense anxiety or fear.

An enduring shift in worldview and sense of self, as well as psychological insight, may increase psychological flexibility, thereby allowing individuals to subsequently avoid maladaptive patterns of behavior or thought and to make more healthy choices.

Our research has shown that the benefits of these experiences can last as long as 14 months, often longer, and that many participants characterize their psilocybin experience as among the most profound and personally meaningful experience of their lives.
 

Do participants experience any adverse effects? If so, how are they managed?

Sometimes, despite all the preparation, screening, and support we provide, some participants can have frightening experiences, such as fear and anxiety during the session. When that occurs, it is often shorted lived. The psychological preparation we provide before the session and the psychological support we provide during the session are important for managing such effects.

We provide support and encourage participants to stay with that experience, which may open to experiences of deep meaning or insight. A number of people report that these psychologically challenging states are a valuable part of the overall experience.

We conducted a survey of roughly 2,000 people who took high doses of psilocybin mushrooms and then had a challenging experience. About 10% reported they put themselves or others at risk of physical harm. Of more concern, of those whose experience occurred more than 1 year before, 8% sought treatment for enduring psychological symptoms. These findings underscore potential risks of psilocybin use but do not provide an estimate of the actual incidence of such effects.

Importantly, in our research at Johns Hopkins, we have not observed such effects in over 700 sessions that we have conducted with almost 400 participants, likely because we thoroughly screen and prepare participants and support them after they have completed the study. The potential for serious lasting harm represents a concern and points to the importance of adequate screening and aftercare.
 

What are the implications for future therapeutics?

We are living in exciting times, in terms of psychedelic research. The potential for a single treatment with a classic psychedelic to produce rapid and sustained therapeutic effects, possibly across a range of psychiatric conditions, is unprecedented in psychiatry. The effect appears to be an “inverse PTSD effect.”

In PTSD, a single exposure to a traumatic event can rewire the nervous system to the point that it produces enduring harm and toxicity. In the case of psychedelics, a single exposure appears to have enduring positive effects in worldview, mood, attitude, behavior, and overall life satisfaction. We can look forward to continued growth and expansion of this research including the refinement of protocols for a variety of therapeutic indications and to the development of a variety of new classic psychedelic compounds.
 

A version of this article originally appeared on Medscape.com.

After a 50-year hiatus, psychedelic drugs are undergoing a research renaissance. Roland R. Griffiths, PhD, professor in the Departments of Psychiatry and Neuroscience and the Oliver Lee McCabe III, Professor in the Neuropsychopharmacology of Consciousness, and director of the Center for Psychedelic and Consciousness Research at Johns Hopkins University, Baltimore, discusses the status of these drugs in the United States and their potential to treat psychiatric disorders.

Classic psychedelics are compounds that bind to the 5-hydroxytryptamine 2A (5-HT2A) receptor and include the naturally occurring compounds psilocybin, N,N-dimethyltryptamine (DMT, a component of ayahuasca) and mescaline (peyote cactus), as well as the synthesized compound lysergic acid diethylamide (LSD).

Other drugs, such as ketamine, are sometimes referred to as “psychedelics” because they can produce subjective experiences that are similar to those of people who receive classic psychedelics. However, unlike classic psychedelics, the effects of ketamine tend to be short lived. Ketamine also has addictive potential and can be lethal in high doses, which is not the case with psilocybin.

Another compound sometimes referred to as a “psychedelic” is 3,4-methylenedioxymethamphetamine (MDMA), also known as “ecstasy.” The Food and Drug Administration granted breakthrough approval for the study of MDMA for posttraumatic stress disorder (PTSD). FDA-approved registration trials are ongoing. MDMA differs from classic psychedelics in risk profile and pharmacology. In particular, MDMA was widely abused as part of the “rave culture,” while classic psychedelic agents do not lend themselves to that type of misuse.
 

What is the current legal status of psychedelic agents in the United States? Can clinicians prescribe them, or are they available only in a research setting?

All classic psychedelics are considered to be “Schedule 1” which means they are illegal to possess and use except for research and only if approved by the FDA and under licensure of the Drug Enforcement Administration (DEA), so they are not available for clinical use.

In anticipation of the possibility that phase 3 research may support the efficacy and safety of psilocybin for one or more medical or mental health disorders, our team has reviewed available evidence regarding its abuse liability and concluded that, if psilocybin were approved as medication, it could possibly be included in the Schedule IV category, with additional FDA-mandated risk management provisions. However, this is not yet the case.
 

Which psychedelic agents are under investigation in the United States, and for which indications?

Psilocybin is under investigation in our center, as well as elsewhere in the United States. We have previously found it to be effective for smoking cessation, and we are conducting another study that is currently recruiting volunteers for this indication. We are also recruiting volunteers for studies on the use of psilocybin for major depression, Alzheimer’s disease, and anorexia nervosa. Further information about our studies can be found on the Web site for our center, the Center for Psychedelic and Consciousness Research.

Two companies – the Usona Institute and COMPASS Pathways – have received FDA Breakthrough Therapy Designation for their programs seeking approval of psilocybin as a treatment major depressive disorder and treatment-resistant depression (TRD), respectively. In addition, an international multicenter study currently underway, which includes US centers in Houston, Baltimore, New York, San Diego, and Atlanta, is investigating psilocybin for TRD.

A number of studies, including one conducted at our center, have investigated psilocybin for depression and anxiety in patients with cancer and found it effective.

Additional research showed that psilocybin alleviated symptoms of cancer-related anxiety and depression, both in the short-term and 5 years later.

LSD has been studied and found promising in the treatment of alcohol use disorder. Additional studies of LSD that are being conducted in Basel Switzerland and at the University of Chicago are examining its impact on mood in healthy volunteers.

Ayahuasca has been studied extensively for depression and anxiety and is also currently under investigation for PTSD. We found that its use in a naturalistic group setting was associated with unintended improvements in depression and anxiety.

Lastly, a lesser-known psychedelic agent is Salvinorin A, which our center has been studying, is the psychoactive constituent of the Salvia divinorum plant. While this is not a “classic” psychedelic compound, it is nevertheless the focus of much scientific interest because its effects are mediated at opioid receptors, rather than 5-HT2A receptors, and may prove to be a novel nonaddictive opioid that may ultimately be a promising treatment for pain and addiction.
 

What is the typical treatment regimen for psychedelic agents?

It is hard to speak of a “treatment regimen” in agents that are not used in clinical practice. Ongoing clinical trials with psilocybin generally involve one or two 6- to 8-hour sessions involving the oral administration of a moderately high dose under psychologically supported conditions.

Based on the current evidence base, which agents show the most promise?

Psilocybin is currently the most promising classic psychedelic undergoing clinical trials.

Do psychedelics have to be administered in a controlled setting in order to be effective?

Although many people have had meaningful experiences whether inside or outside of a controlled setting, there are serious potential risks associated with use of psilocybin and other classic psychedelics. The safety of psilocybin has been established in clinical studies in which participants have been carefully screened physically and psychologically, are psychologically prepared before their first session, and are psychologically supported during and after sessions. In vulnerable individuals, psilocybin has been associated with enduring psychiatric problems and sometimes persisting visual perceptual conditions. When taken in uncontrolled conditions, classic psychedelics can produce confusion and disorientation resulting in behavior dangerous to the participant and others – including life-threatening risk. Thus, for safety reasons, the optimal environment for using these agents is in a controlled setting.

Do results differ between patients who have used psychedelic agents previously and those who have not?

We have not found any difference between psychedelic-naive volunteers and those who have used psychedelics in the past.

Do you provide patient education prior to treatment initiation?

All of our study participants are thoroughly screened for medical concerns or mental health history such as psychosis, which would preclude their participation. They are educated about the effects of these agents and what they might expect and typically receive several hours of psychological preparation before the first session. They are also provided with psychological support after sessions. Additionally, we spend time developing trust and rapport prior to the first session.

How durable are the effects of psychedelic treatment?

Studies in patients and healthy participants suggest that the positive effects of psilocybin are long lasting, with most individuals reporting positive changes in moods, attitudes, and behavior that they attribute to psilocybin and which endure months or years after the session. The qualities of the acute session experience can vary widely ranging from experiences of transcendence or psychological insight to experiences of intense anxiety or fear.

An enduring shift in worldview and sense of self, as well as psychological insight, may increase psychological flexibility, thereby allowing individuals to subsequently avoid maladaptive patterns of behavior or thought and to make more healthy choices.

Our research has shown that the benefits of these experiences can last as long as 14 months, often longer, and that many participants characterize their psilocybin experience as among the most profound and personally meaningful experience of their lives.
 

Do participants experience any adverse effects? If so, how are they managed?

Sometimes, despite all the preparation, screening, and support we provide, some participants can have frightening experiences, such as fear and anxiety during the session. When that occurs, it is often shorted lived. The psychological preparation we provide before the session and the psychological support we provide during the session are important for managing such effects.

We provide support and encourage participants to stay with that experience, which may open to experiences of deep meaning or insight. A number of people report that these psychologically challenging states are a valuable part of the overall experience.

We conducted a survey of roughly 2,000 people who took high doses of psilocybin mushrooms and then had a challenging experience. About 10% reported they put themselves or others at risk of physical harm. Of more concern, of those whose experience occurred more than 1 year before, 8% sought treatment for enduring psychological symptoms. These findings underscore potential risks of psilocybin use but do not provide an estimate of the actual incidence of such effects.

Importantly, in our research at Johns Hopkins, we have not observed such effects in over 700 sessions that we have conducted with almost 400 participants, likely because we thoroughly screen and prepare participants and support them after they have completed the study. The potential for serious lasting harm represents a concern and points to the importance of adequate screening and aftercare.
 

What are the implications for future therapeutics?

We are living in exciting times, in terms of psychedelic research. The potential for a single treatment with a classic psychedelic to produce rapid and sustained therapeutic effects, possibly across a range of psychiatric conditions, is unprecedented in psychiatry. The effect appears to be an “inverse PTSD effect.”

In PTSD, a single exposure to a traumatic event can rewire the nervous system to the point that it produces enduring harm and toxicity. In the case of psychedelics, a single exposure appears to have enduring positive effects in worldview, mood, attitude, behavior, and overall life satisfaction. We can look forward to continued growth and expansion of this research including the refinement of protocols for a variety of therapeutic indications and to the development of a variety of new classic psychedelic compounds.
 

A version of this article originally appeared on Medscape.com.

About 1 in 11 patients discharged after COVID-19 treatment is readmitted to the same hospital, according to researchers from the Centers for Disease Control and Prevention (CDC).

Older age and chronic diseases are associated with increased risk, said senior author Adi V. Gundlapalli, MD, PhD, chief public health informatics officer of the CDC’s Center for Surveillance, Epidemiology, and Laboratory Services.

Gundlapalli and colleagues published the finding November 9 in Morbidity and Mortality Weekly Report.

To get a picture of readmission after COVID-19 hospitalization, the researchers analyzed records of 126,137 patients hospitalized with COVID-19 between March and July and included in the Premier Healthcare Database, which covers discharge records from 865 nongovernmental, community, and teaching hospitals.

Overall, 15% of the patients died during hospitalization. Of those who survived to discharge, 9% were readmitted to the same hospital within 2 months of discharge; 1.6% of patients were readmitted more than once. The median interval from discharge to first readmission was 8 days (interquartile range, 3-20 days). This short interval suggests that patients are probably not suffering a relapse, Gundlapalli said in an interview. More likely they experienced some adverse event, such as difficulty breathing, that led their caretakers to send them back to the hospital.

Forty-five percent of the primary discharge diagnoses after readmission were infectious and parasitic diseases, primarily COVID-19. The next most common were circulatory system symptoms (11%) and digestive symptoms (7%).

After controlling for covariates, the researchers found that patients were more likely to be readmitted if they had chronic obstructive pulmonary disease (odds ratio [OR], 1.4), heart failure (OR, 1.6), diabetes (OR, 1.2), or chronic kidney disease (OR, 1.6).

They also found increased odds among patients discharged from the index hospitalization to a skilled nursing facility (OR, 1.4) or with home health organization support (OR, 1.3), compared with being discharged to home or self-care. Looked at another way, the rate of readmission was 15% among those discharged to a skilled nursing facility, 12% among those needing home health care and 7% of those discharged to home or self-care.

The researchers also found that people who had been hospitalized within 3 months prior to the index hospitalization were 2.6 times more likely to be readmitted than were those without prior inpatient care.

Further, the odds of readmission increased significantly among people over 65 years of age, compared with people aged 18 to 39 years.

“The results are not surprising,” Gundlapalli said. “We have known from before that elderly patients, especially with chronic conditions, certain clinical conditions, and those who have been hospitalized before, are at risk for readmission.”

But admitting COVID-19 patients requires special planning because they must be isolated and because more personal protective equipment (PPE) is required, he pointed out.

One unexpected finding from the report is that non-Hispanic White people were more likely to be readmitted than were people of other racial or ethnic groups. This contrasts with other research showing Hispanic and Black individuals are more severely affected by COVID-19 than White people. More research is needed to explain this result, Gundlapalli said.

The authors have disclosed no relevant financial relationships.
 

This article first appeared on Medscape.com.

About 1 in 11 patients discharged after COVID-19 treatment is readmitted to the same hospital, according to researchers from the Centers for Disease Control and Prevention (CDC).

Older age and chronic diseases are associated with increased risk, said senior author Adi V. Gundlapalli, MD, PhD, chief public health informatics officer of the CDC’s Center for Surveillance, Epidemiology, and Laboratory Services.

Gundlapalli and colleagues published the finding November 9 in Morbidity and Mortality Weekly Report.

To get a picture of readmission after COVID-19 hospitalization, the researchers analyzed records of 126,137 patients hospitalized with COVID-19 between March and July and included in the Premier Healthcare Database, which covers discharge records from 865 nongovernmental, community, and teaching hospitals.

Overall, 15% of the patients died during hospitalization. Of those who survived to discharge, 9% were readmitted to the same hospital within 2 months of discharge; 1.6% of patients were readmitted more than once. The median interval from discharge to first readmission was 8 days (interquartile range, 3-20 days). This short interval suggests that patients are probably not suffering a relapse, Gundlapalli said in an interview. More likely they experienced some adverse event, such as difficulty breathing, that led their caretakers to send them back to the hospital.

Forty-five percent of the primary discharge diagnoses after readmission were infectious and parasitic diseases, primarily COVID-19. The next most common were circulatory system symptoms (11%) and digestive symptoms (7%).

After controlling for covariates, the researchers found that patients were more likely to be readmitted if they had chronic obstructive pulmonary disease (odds ratio [OR], 1.4), heart failure (OR, 1.6), diabetes (OR, 1.2), or chronic kidney disease (OR, 1.6).

They also found increased odds among patients discharged from the index hospitalization to a skilled nursing facility (OR, 1.4) or with home health organization support (OR, 1.3), compared with being discharged to home or self-care. Looked at another way, the rate of readmission was 15% among those discharged to a skilled nursing facility, 12% among those needing home health care and 7% of those discharged to home or self-care.

The researchers also found that people who had been hospitalized within 3 months prior to the index hospitalization were 2.6 times more likely to be readmitted than were those without prior inpatient care.

Further, the odds of readmission increased significantly among people over 65 years of age, compared with people aged 18 to 39 years.

“The results are not surprising,” Gundlapalli said. “We have known from before that elderly patients, especially with chronic conditions, certain clinical conditions, and those who have been hospitalized before, are at risk for readmission.”

But admitting COVID-19 patients requires special planning because they must be isolated and because more personal protective equipment (PPE) is required, he pointed out.

One unexpected finding from the report is that non-Hispanic White people were more likely to be readmitted than were people of other racial or ethnic groups. This contrasts with other research showing Hispanic and Black individuals are more severely affected by COVID-19 than White people. More research is needed to explain this result, Gundlapalli said.

The authors have disclosed no relevant financial relationships.
 

This article first appeared on Medscape.com.

About 1 in 11 patients discharged after COVID-19 treatment is readmitted to the same hospital, according to researchers from the Centers for Disease Control and Prevention (CDC).

Older age and chronic diseases are associated with increased risk, said senior author Adi V. Gundlapalli, MD, PhD, chief public health informatics officer of the CDC’s Center for Surveillance, Epidemiology, and Laboratory Services.

Gundlapalli and colleagues published the finding November 9 in Morbidity and Mortality Weekly Report.

To get a picture of readmission after COVID-19 hospitalization, the researchers analyzed records of 126,137 patients hospitalized with COVID-19 between March and July and included in the Premier Healthcare Database, which covers discharge records from 865 nongovernmental, community, and teaching hospitals.

Overall, 15% of the patients died during hospitalization. Of those who survived to discharge, 9% were readmitted to the same hospital within 2 months of discharge; 1.6% of patients were readmitted more than once. The median interval from discharge to first readmission was 8 days (interquartile range, 3-20 days). This short interval suggests that patients are probably not suffering a relapse, Gundlapalli said in an interview. More likely they experienced some adverse event, such as difficulty breathing, that led their caretakers to send them back to the hospital.

Forty-five percent of the primary discharge diagnoses after readmission were infectious and parasitic diseases, primarily COVID-19. The next most common were circulatory system symptoms (11%) and digestive symptoms (7%).

After controlling for covariates, the researchers found that patients were more likely to be readmitted if they had chronic obstructive pulmonary disease (odds ratio [OR], 1.4), heart failure (OR, 1.6), diabetes (OR, 1.2), or chronic kidney disease (OR, 1.6).

They also found increased odds among patients discharged from the index hospitalization to a skilled nursing facility (OR, 1.4) or with home health organization support (OR, 1.3), compared with being discharged to home or self-care. Looked at another way, the rate of readmission was 15% among those discharged to a skilled nursing facility, 12% among those needing home health care and 7% of those discharged to home or self-care.

The researchers also found that people who had been hospitalized within 3 months prior to the index hospitalization were 2.6 times more likely to be readmitted than were those without prior inpatient care.

Further, the odds of readmission increased significantly among people over 65 years of age, compared with people aged 18 to 39 years.

“The results are not surprising,” Gundlapalli said. “We have known from before that elderly patients, especially with chronic conditions, certain clinical conditions, and those who have been hospitalized before, are at risk for readmission.”

But admitting COVID-19 patients requires special planning because they must be isolated and because more personal protective equipment (PPE) is required, he pointed out.

One unexpected finding from the report is that non-Hispanic White people were more likely to be readmitted than were people of other racial or ethnic groups. This contrasts with other research showing Hispanic and Black individuals are more severely affected by COVID-19 than White people. More research is needed to explain this result, Gundlapalli said.

The authors have disclosed no relevant financial relationships.
 

This article first appeared on Medscape.com.