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Obesity, hypoxia predict severity in children with COVID-19
based on data from 281 patients at 8 locations.
Manifestations of COVID-19 in children include respiratory disease similar to that seen in adults, but the full spectrum of disease in children has been studied mainly in single settings or with a focus on one clinical manifestation, wrote Danielle M. Fernandes, MD, of Albert Einstein College of Medicine, New York, and colleagues.
In a study published in the Journal of Pediatrics, the researchers identified 281 children hospitalized with COVID-19 and/or multisystem inflammatory syndrome in children (MIS-C) at 8 sites in Connecticut, New Jersey, and New York. A total of 143 (51%) had respiratory disease, 69 (25%) had MIS-C, and 69 (25%) had other manifestations of illness including 32 patients with gastrointestinal problems, 21 infants with fever, 6 cases of neurologic disease, 6 cases of diabetic ketoacidosis, and 4 patients with other indications. The median age of the patients was 10 years, 60% were male, 51% were Hispanic, and 23% were non-Hispanic Black. The most common comorbidities were obesity (34%) and asthma (14%).
Independent predictors of disease severity in children found
After controlling for multiple variables, obesity and hypoxia at hospital admission were significant independent predictors of severe respiratory disease, with odds ratios of 3.39 and 4.01, respectively. In addition, lower absolute lymphocyte count (OR, 8.33 per unit decrease in 109 cells/L) and higher C-reactive protein (OR, 1.06 per unit increase in mg/dL) were significantly predictive of severe MIS-C (P = .001 and P = .017, respectively).
“The association between weight and severe respiratory COVID-19 is consistent with the adult literature; however, the mechanisms of this association require further study,” Dr. Fernandes and associates noted.
Overall, children with MIS-C were significantly more likely to be non-Hispanic Black, compared with children with respiratory disease, an 18% difference. However, neither race/ethnicity nor socioeconomic status were significant predictors of disease severity, the researchers wrote.
During the study period, 7 patients (2%) died and 114 (41%) were admitted to the ICU.
“We found a wide array of clinical manifestations in children and youth hospitalized with SARS-CoV-2,” Dr. Fernandes and associates wrote. Notably, gastrointestinal symptoms, ocular symptoms, and dermatologic symptoms have rarely been noted in adults with COVID-19, but occurred in more than 30% of the pediatric patients.
“We also found that SARS-CoV-2 can be an incidental finding in a substantial number of hospitalized pediatric patients,” the researchers said.
The findings were limited by several factors including a population of patients only from Connecticut, New Jersey, and New York, and the possibility that decisions on hospital and ICU admission may have varied by location, the researchers said. In addition, approaches may have varied in the absence of data on the optimal treatment of MIS-C.
“This study builds on the growing body of evidence showing that mortality in hospitalized pediatric patients is low, compared with adults,” Dr. Fernandes and associates said. “However, it highlights that the young population is not universally spared from morbidity, and that even previously healthy children and youth can develop severe disease requiring supportive therapy.”
Findings confirm other clinical experience
The study was important to show that, “although most children are spared severe illness from COVID-19, some children are hospitalized both with acute COVID-19 respiratory disease, with MIS-C and with a range of other complications,” Adrienne Randolph, MD, of Boston Children’s Hospital and Harvard Medical School, Boston, said in an interview.
Dr. Randolph said she was not surprised by the study findings, “as we are also seeing these types of complications at Boston Children’s Hospital where I work.”
Additional research is needed on the outcomes of these patients, “especially the longer-term sequelae of having COVID-19 or MIS-C early in life,” she emphasized.
The take-home message to clinicians from the findings at this time is to be aware that children and adolescents can become severely ill from COVID-19–related complications, said Dr. Randolph. “Some of the laboratory values on presentation appear to be associated with disease severity.”
The study received no outside funding. The researchers had no financial conflicts to disclose. Dr. Randolph disclosed funding from the Centers for Disease Control and Prevention to lead the Overcoming COVID-19 Study in U.S. Children and Adults.
SOURCE: Fernandes DM et al. J Pediatr. 2020 Nov 13. doi: 10.1016/j.jpeds.2020.11.016.
based on data from 281 patients at 8 locations.
Manifestations of COVID-19 in children include respiratory disease similar to that seen in adults, but the full spectrum of disease in children has been studied mainly in single settings or with a focus on one clinical manifestation, wrote Danielle M. Fernandes, MD, of Albert Einstein College of Medicine, New York, and colleagues.
In a study published in the Journal of Pediatrics, the researchers identified 281 children hospitalized with COVID-19 and/or multisystem inflammatory syndrome in children (MIS-C) at 8 sites in Connecticut, New Jersey, and New York. A total of 143 (51%) had respiratory disease, 69 (25%) had MIS-C, and 69 (25%) had other manifestations of illness including 32 patients with gastrointestinal problems, 21 infants with fever, 6 cases of neurologic disease, 6 cases of diabetic ketoacidosis, and 4 patients with other indications. The median age of the patients was 10 years, 60% were male, 51% were Hispanic, and 23% were non-Hispanic Black. The most common comorbidities were obesity (34%) and asthma (14%).
Independent predictors of disease severity in children found
After controlling for multiple variables, obesity and hypoxia at hospital admission were significant independent predictors of severe respiratory disease, with odds ratios of 3.39 and 4.01, respectively. In addition, lower absolute lymphocyte count (OR, 8.33 per unit decrease in 109 cells/L) and higher C-reactive protein (OR, 1.06 per unit increase in mg/dL) were significantly predictive of severe MIS-C (P = .001 and P = .017, respectively).
“The association between weight and severe respiratory COVID-19 is consistent with the adult literature; however, the mechanisms of this association require further study,” Dr. Fernandes and associates noted.
Overall, children with MIS-C were significantly more likely to be non-Hispanic Black, compared with children with respiratory disease, an 18% difference. However, neither race/ethnicity nor socioeconomic status were significant predictors of disease severity, the researchers wrote.
During the study period, 7 patients (2%) died and 114 (41%) were admitted to the ICU.
“We found a wide array of clinical manifestations in children and youth hospitalized with SARS-CoV-2,” Dr. Fernandes and associates wrote. Notably, gastrointestinal symptoms, ocular symptoms, and dermatologic symptoms have rarely been noted in adults with COVID-19, but occurred in more than 30% of the pediatric patients.
“We also found that SARS-CoV-2 can be an incidental finding in a substantial number of hospitalized pediatric patients,” the researchers said.
The findings were limited by several factors including a population of patients only from Connecticut, New Jersey, and New York, and the possibility that decisions on hospital and ICU admission may have varied by location, the researchers said. In addition, approaches may have varied in the absence of data on the optimal treatment of MIS-C.
“This study builds on the growing body of evidence showing that mortality in hospitalized pediatric patients is low, compared with adults,” Dr. Fernandes and associates said. “However, it highlights that the young population is not universally spared from morbidity, and that even previously healthy children and youth can develop severe disease requiring supportive therapy.”
Findings confirm other clinical experience
The study was important to show that, “although most children are spared severe illness from COVID-19, some children are hospitalized both with acute COVID-19 respiratory disease, with MIS-C and with a range of other complications,” Adrienne Randolph, MD, of Boston Children’s Hospital and Harvard Medical School, Boston, said in an interview.
Dr. Randolph said she was not surprised by the study findings, “as we are also seeing these types of complications at Boston Children’s Hospital where I work.”
Additional research is needed on the outcomes of these patients, “especially the longer-term sequelae of having COVID-19 or MIS-C early in life,” she emphasized.
The take-home message to clinicians from the findings at this time is to be aware that children and adolescents can become severely ill from COVID-19–related complications, said Dr. Randolph. “Some of the laboratory values on presentation appear to be associated with disease severity.”
The study received no outside funding. The researchers had no financial conflicts to disclose. Dr. Randolph disclosed funding from the Centers for Disease Control and Prevention to lead the Overcoming COVID-19 Study in U.S. Children and Adults.
SOURCE: Fernandes DM et al. J Pediatr. 2020 Nov 13. doi: 10.1016/j.jpeds.2020.11.016.
based on data from 281 patients at 8 locations.
Manifestations of COVID-19 in children include respiratory disease similar to that seen in adults, but the full spectrum of disease in children has been studied mainly in single settings or with a focus on one clinical manifestation, wrote Danielle M. Fernandes, MD, of Albert Einstein College of Medicine, New York, and colleagues.
In a study published in the Journal of Pediatrics, the researchers identified 281 children hospitalized with COVID-19 and/or multisystem inflammatory syndrome in children (MIS-C) at 8 sites in Connecticut, New Jersey, and New York. A total of 143 (51%) had respiratory disease, 69 (25%) had MIS-C, and 69 (25%) had other manifestations of illness including 32 patients with gastrointestinal problems, 21 infants with fever, 6 cases of neurologic disease, 6 cases of diabetic ketoacidosis, and 4 patients with other indications. The median age of the patients was 10 years, 60% were male, 51% were Hispanic, and 23% were non-Hispanic Black. The most common comorbidities were obesity (34%) and asthma (14%).
Independent predictors of disease severity in children found
After controlling for multiple variables, obesity and hypoxia at hospital admission were significant independent predictors of severe respiratory disease, with odds ratios of 3.39 and 4.01, respectively. In addition, lower absolute lymphocyte count (OR, 8.33 per unit decrease in 109 cells/L) and higher C-reactive protein (OR, 1.06 per unit increase in mg/dL) were significantly predictive of severe MIS-C (P = .001 and P = .017, respectively).
“The association between weight and severe respiratory COVID-19 is consistent with the adult literature; however, the mechanisms of this association require further study,” Dr. Fernandes and associates noted.
Overall, children with MIS-C were significantly more likely to be non-Hispanic Black, compared with children with respiratory disease, an 18% difference. However, neither race/ethnicity nor socioeconomic status were significant predictors of disease severity, the researchers wrote.
During the study period, 7 patients (2%) died and 114 (41%) were admitted to the ICU.
“We found a wide array of clinical manifestations in children and youth hospitalized with SARS-CoV-2,” Dr. Fernandes and associates wrote. Notably, gastrointestinal symptoms, ocular symptoms, and dermatologic symptoms have rarely been noted in adults with COVID-19, but occurred in more than 30% of the pediatric patients.
“We also found that SARS-CoV-2 can be an incidental finding in a substantial number of hospitalized pediatric patients,” the researchers said.
The findings were limited by several factors including a population of patients only from Connecticut, New Jersey, and New York, and the possibility that decisions on hospital and ICU admission may have varied by location, the researchers said. In addition, approaches may have varied in the absence of data on the optimal treatment of MIS-C.
“This study builds on the growing body of evidence showing that mortality in hospitalized pediatric patients is low, compared with adults,” Dr. Fernandes and associates said. “However, it highlights that the young population is not universally spared from morbidity, and that even previously healthy children and youth can develop severe disease requiring supportive therapy.”
Findings confirm other clinical experience
The study was important to show that, “although most children are spared severe illness from COVID-19, some children are hospitalized both with acute COVID-19 respiratory disease, with MIS-C and with a range of other complications,” Adrienne Randolph, MD, of Boston Children’s Hospital and Harvard Medical School, Boston, said in an interview.
Dr. Randolph said she was not surprised by the study findings, “as we are also seeing these types of complications at Boston Children’s Hospital where I work.”
Additional research is needed on the outcomes of these patients, “especially the longer-term sequelae of having COVID-19 or MIS-C early in life,” she emphasized.
The take-home message to clinicians from the findings at this time is to be aware that children and adolescents can become severely ill from COVID-19–related complications, said Dr. Randolph. “Some of the laboratory values on presentation appear to be associated with disease severity.”
The study received no outside funding. The researchers had no financial conflicts to disclose. Dr. Randolph disclosed funding from the Centers for Disease Control and Prevention to lead the Overcoming COVID-19 Study in U.S. Children and Adults.
SOURCE: Fernandes DM et al. J Pediatr. 2020 Nov 13. doi: 10.1016/j.jpeds.2020.11.016.
FROM THE JOURNAL OF PEDIATRICS
Can a probiotic prevent COVID-19?
On the Nov. 12 episode of the Blood & Cancer podcast, Anthony D. Sung, MD, of Duke University, Durham, N.C., joined host David H. Henry, MD, of Penn Medicine in Philadelphia, to discuss the trial of LGG as well as other research. The following transcript of that discussion has been edited for length and clarity.
David Henry, MD: Here we are in COVID. We’re recording this the first week in November. Sadly, cases are spiking in the country. And I understand you’ve got some information that you might share about how manipulating ... the microbiome that we all exist with inside our gut might somehow play into doing better or worse with COVID.
Anthony Sung, MD: Absolutely. So, as associate director of the Duke Microbiome Center, I was approached by one of my colleagues, Paul Wischmeyer, who is a professor of anesthesiology and critical care medicine at Duke. Paul had previously done some very nice murine studies with the probiotic Lactobacillus rhamnosus GG, or LGG.
He showed, in a murine model of pseudomonas pneumonia, that giving LGG to mice would help modulate their microbiome and, in turn, their immune system, leading to decreased inflammation, decreased TNF-alpha, IL [interleukin]-2, and IL-6, [and] increased Treg cells [Clin Nutr. 2017;36[6]:1549-57]. This also helped prevent lung injury, and it actually significantly improved survival in mice receiving LGG [Shock. 2013;40[6]:496-503].
In addition, there has been a randomized clinical trial of LGG showing that its administration would help prevent ventilator-associated pneumonia, or VAP [Am J Respir Crit Care Med. 2010 Oct 15;182[8]:1058-64].
And a few years ago, there was another RCT [randomized, controlled trial], published in Nature, showing that another Lactobacillus product significantly decreased the combined endpoint of sepsis and mortality, primarily by reducing lower respiratory tract infection [Nature. 2017 Aug 24;548[7668]:407-12].
Dr. Henry: And how is that working? What is the bacillus doing to help us?
Dr. Sung: We think it’s through modulating the immune system. As mentioned in Paul’s studies, we saw significantly decreased amounts of TNF-alpha, IL-2, and IL-6, which are the same cytokines that have been implicated in COVID-19 and associated with increased lung injury in patients during this pandemic.
And we believe that by giving individuals this probiotic, LGG, we may help modulate the immune system, decrease lung injury and symptoms, and maybe even prevent COVID-19.
So with support from the Duke Microbiome Center, as well as private donations and philanthropy, we are conducting a randomized clinical trial of LGG to prevent COVID-19 in household contacts who’ve been exposed to the disease. In other words, if someone in the house gets COVID-19, we want to try to prophylax everybody else living in that house and prevent them from coming down with the same infection.
Dr. Henry: And this is an oral administration?
Dr. Sung: Correct. This is an oral pill, two pills once a day.
Dr. Henry: And it’s an ongoing study, of course, in COVID right now?
Dr. Sung: Correct. So we have an IND [investigational new drug application] from the FDA [Food and Drug Administration], and we are actively recruiting subjects both at Duke University, but also due to the unique study design, we can enroll patients anywhere across the country. Because of the importance of social distancing, everything is done remotely.
So a household contact can hear about us, either through your podcast or one of our Facebook ads or through other media. They can reach out to our study website, which is https://sites.duke.edu/protectehc, or reach out to us at our study email, [email protected].
And we can go ahead and screen them for eligibility in our trial. And if they are eligible and they consent to participate, we will mail them a package basically overnight, FedEx, containing either LGG or placebo, as well as kits so that they can self-collect their stool and nasal swabs so we can test it for SARS-CoV-2 by PCR [polymerase chain reaction] and look at the microbiome.
Dr. Sung and Dr. Henry have no relevant disclosures. Funding for the trial is provided by the Duke Microbiome Center and philanthropic giving. The LGG and placebo used in the trial are provided by DSM.
On the Nov. 12 episode of the Blood & Cancer podcast, Anthony D. Sung, MD, of Duke University, Durham, N.C., joined host David H. Henry, MD, of Penn Medicine in Philadelphia, to discuss the trial of LGG as well as other research. The following transcript of that discussion has been edited for length and clarity.
David Henry, MD: Here we are in COVID. We’re recording this the first week in November. Sadly, cases are spiking in the country. And I understand you’ve got some information that you might share about how manipulating ... the microbiome that we all exist with inside our gut might somehow play into doing better or worse with COVID.
Anthony Sung, MD: Absolutely. So, as associate director of the Duke Microbiome Center, I was approached by one of my colleagues, Paul Wischmeyer, who is a professor of anesthesiology and critical care medicine at Duke. Paul had previously done some very nice murine studies with the probiotic Lactobacillus rhamnosus GG, or LGG.
He showed, in a murine model of pseudomonas pneumonia, that giving LGG to mice would help modulate their microbiome and, in turn, their immune system, leading to decreased inflammation, decreased TNF-alpha, IL [interleukin]-2, and IL-6, [and] increased Treg cells [Clin Nutr. 2017;36[6]:1549-57]. This also helped prevent lung injury, and it actually significantly improved survival in mice receiving LGG [Shock. 2013;40[6]:496-503].
In addition, there has been a randomized clinical trial of LGG showing that its administration would help prevent ventilator-associated pneumonia, or VAP [Am J Respir Crit Care Med. 2010 Oct 15;182[8]:1058-64].
And a few years ago, there was another RCT [randomized, controlled trial], published in Nature, showing that another Lactobacillus product significantly decreased the combined endpoint of sepsis and mortality, primarily by reducing lower respiratory tract infection [Nature. 2017 Aug 24;548[7668]:407-12].
Dr. Henry: And how is that working? What is the bacillus doing to help us?
Dr. Sung: We think it’s through modulating the immune system. As mentioned in Paul’s studies, we saw significantly decreased amounts of TNF-alpha, IL-2, and IL-6, which are the same cytokines that have been implicated in COVID-19 and associated with increased lung injury in patients during this pandemic.
And we believe that by giving individuals this probiotic, LGG, we may help modulate the immune system, decrease lung injury and symptoms, and maybe even prevent COVID-19.
So with support from the Duke Microbiome Center, as well as private donations and philanthropy, we are conducting a randomized clinical trial of LGG to prevent COVID-19 in household contacts who’ve been exposed to the disease. In other words, if someone in the house gets COVID-19, we want to try to prophylax everybody else living in that house and prevent them from coming down with the same infection.
Dr. Henry: And this is an oral administration?
Dr. Sung: Correct. This is an oral pill, two pills once a day.
Dr. Henry: And it’s an ongoing study, of course, in COVID right now?
Dr. Sung: Correct. So we have an IND [investigational new drug application] from the FDA [Food and Drug Administration], and we are actively recruiting subjects both at Duke University, but also due to the unique study design, we can enroll patients anywhere across the country. Because of the importance of social distancing, everything is done remotely.
So a household contact can hear about us, either through your podcast or one of our Facebook ads or through other media. They can reach out to our study website, which is https://sites.duke.edu/protectehc, or reach out to us at our study email, [email protected].
And we can go ahead and screen them for eligibility in our trial. And if they are eligible and they consent to participate, we will mail them a package basically overnight, FedEx, containing either LGG or placebo, as well as kits so that they can self-collect their stool and nasal swabs so we can test it for SARS-CoV-2 by PCR [polymerase chain reaction] and look at the microbiome.
Dr. Sung and Dr. Henry have no relevant disclosures. Funding for the trial is provided by the Duke Microbiome Center and philanthropic giving. The LGG and placebo used in the trial are provided by DSM.
On the Nov. 12 episode of the Blood & Cancer podcast, Anthony D. Sung, MD, of Duke University, Durham, N.C., joined host David H. Henry, MD, of Penn Medicine in Philadelphia, to discuss the trial of LGG as well as other research. The following transcript of that discussion has been edited for length and clarity.
David Henry, MD: Here we are in COVID. We’re recording this the first week in November. Sadly, cases are spiking in the country. And I understand you’ve got some information that you might share about how manipulating ... the microbiome that we all exist with inside our gut might somehow play into doing better or worse with COVID.
Anthony Sung, MD: Absolutely. So, as associate director of the Duke Microbiome Center, I was approached by one of my colleagues, Paul Wischmeyer, who is a professor of anesthesiology and critical care medicine at Duke. Paul had previously done some very nice murine studies with the probiotic Lactobacillus rhamnosus GG, or LGG.
He showed, in a murine model of pseudomonas pneumonia, that giving LGG to mice would help modulate their microbiome and, in turn, their immune system, leading to decreased inflammation, decreased TNF-alpha, IL [interleukin]-2, and IL-6, [and] increased Treg cells [Clin Nutr. 2017;36[6]:1549-57]. This also helped prevent lung injury, and it actually significantly improved survival in mice receiving LGG [Shock. 2013;40[6]:496-503].
In addition, there has been a randomized clinical trial of LGG showing that its administration would help prevent ventilator-associated pneumonia, or VAP [Am J Respir Crit Care Med. 2010 Oct 15;182[8]:1058-64].
And a few years ago, there was another RCT [randomized, controlled trial], published in Nature, showing that another Lactobacillus product significantly decreased the combined endpoint of sepsis and mortality, primarily by reducing lower respiratory tract infection [Nature. 2017 Aug 24;548[7668]:407-12].
Dr. Henry: And how is that working? What is the bacillus doing to help us?
Dr. Sung: We think it’s through modulating the immune system. As mentioned in Paul’s studies, we saw significantly decreased amounts of TNF-alpha, IL-2, and IL-6, which are the same cytokines that have been implicated in COVID-19 and associated with increased lung injury in patients during this pandemic.
And we believe that by giving individuals this probiotic, LGG, we may help modulate the immune system, decrease lung injury and symptoms, and maybe even prevent COVID-19.
So with support from the Duke Microbiome Center, as well as private donations and philanthropy, we are conducting a randomized clinical trial of LGG to prevent COVID-19 in household contacts who’ve been exposed to the disease. In other words, if someone in the house gets COVID-19, we want to try to prophylax everybody else living in that house and prevent them from coming down with the same infection.
Dr. Henry: And this is an oral administration?
Dr. Sung: Correct. This is an oral pill, two pills once a day.
Dr. Henry: And it’s an ongoing study, of course, in COVID right now?
Dr. Sung: Correct. So we have an IND [investigational new drug application] from the FDA [Food and Drug Administration], and we are actively recruiting subjects both at Duke University, but also due to the unique study design, we can enroll patients anywhere across the country. Because of the importance of social distancing, everything is done remotely.
So a household contact can hear about us, either through your podcast or one of our Facebook ads or through other media. They can reach out to our study website, which is https://sites.duke.edu/protectehc, or reach out to us at our study email, [email protected].
And we can go ahead and screen them for eligibility in our trial. And if they are eligible and they consent to participate, we will mail them a package basically overnight, FedEx, containing either LGG or placebo, as well as kits so that they can self-collect their stool and nasal swabs so we can test it for SARS-CoV-2 by PCR [polymerase chain reaction] and look at the microbiome.
Dr. Sung and Dr. Henry have no relevant disclosures. Funding for the trial is provided by the Duke Microbiome Center and philanthropic giving. The LGG and placebo used in the trial are provided by DSM.
New reports guide return to play in athletes with COVID-19
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.
Great Barrington coauthor backs off strict reliance on herd immunity
A coauthor of the Great Barrington Declaration says that he and colleagues have never argued against using mitigation strategies to keep COVID-19 from spreading, and that critics have mischaracterized the document as a “let it rip” strategy.
Jay Bhattacharya, MD, PhD, a professor and public health policy expert in infectious diseases at Stanford University in California, spoke on a JAMA Livestream debate on November 6. Marc Lipsitch, MD, an epidemiology professor at the Harvard T.H. Chan School of Public Health in Boston, Massachusetts, represented the 6900 signatories of the John Snow Memorandum, a rebuttal to the Great Barrington document.
The Great Barrington approach of “Focused Protection” advocates isolation and protection of people who are most vulnerable to COVID-19 while avoiding what they characterize as lockdowns. “The most compassionate approach that balances the risks and benefits of reaching herd immunity, is to allow those who are at minimal risk of death to live their lives normally to build up immunity to the virus through natural infection, while better protecting those who are at highest risk,” the document reads.
The Infectious Diseases Society of America (IDSA) and its HIV Medicine Association denounced the declaration, as reported by Medscape Medical News, and the World Health Organization (WHO) Director General Tedros Adhanom Ghebreyesus called the proposal “unethical.” But the idea has gained some traction at the White House, where Coronavirus Task Force Member and Stanford professor Scott Atlas, MD, has been advising President Donald J. Trump.
On the JAMA debate, Bhattacharya said, “I think all of the mitigation measures are really important,” listing social distancing, hand washing, and masks when distancing is not possible as chief among those strategies for the less vulnerable. “I don’t want to create infections intentionally, but I want us to allow people to go back to their lives as best they can, understanding of the risks they are taking when they do it,” he said, claiming that 99.95% of the population will survive infection.
“The harmful lockdowns are worse for many, many people,” Bhattacharya said.
“I think Jay is moving towards a middle ground which is not really what the Great Barrington Declaration seems to promote,” countered Lipsitch. The declaration does not say use masks or social distance, he said. “It just says we need to go back to a normal life.”
Bhattacharya’s statements to JAMA mean that “maybe we are approaching some common ground,” Lipsitch said.
Definition of a lockdown
Both men were asked to give their definition of a “lockdown.” To Lipsitch, it means people are not allowed out except for essential services and that most businesses are closed, with exceptions for those deemed essential.
Bhattacharya, however, said he views that as a quarantine. Lockdowns “are what we’re currently doing,” he said. Schools, churches, businesses, and arts and culture organizations are shuttered, and “almost every aspect of society is restricted in some way,” Bhattacharya said.
He blamed these lockdowns for most of the excess deaths over and above the COVID-19 deaths and said they had failed to control the pandemic.
Lipsitch said that “it feels to me that Jay is describing as lockdown everything that causes harm, even when it’s not locked down.” He noted that the country was truly closed down for 2 months or so in the spring.
“All of these harms I agree are real,” said Lipsitch. “But they are because the normal life of our society is being interfered with by viral transmission and by people’s inability to live their normal lives.”
Closures and lockdowns are essential to delaying cases and deaths, said Lipsitch. “A case today is worse than a case tomorrow and a lot worse than a case 6 months from now,” he said, noting that a vaccine or improved therapeutics could evolve.
“Delay is not nothing,” Lipsitch added. “It’s actually the goal as I see it, and as the John Snow memo says, we want to keep the virus under control in such a way as that the vulnerable people are not at risk.”
He predicted that cases will continue to grow exponentially because the nation is “not even close to herd immunity.” And, if intensive care units fill up, “there will be a responsive lockdown,” he said, adding that he did not endorse that as a general matter or favor it as a default position.
Bhattacharya claimed that Sweden has tallied only 1800 excess deaths since the pandemic began. “That’s lockdown harm avoided,” he said, advocating a similar strategy for the United States. But, infections have been on the rise in Sweden, and the nation has a higher COVID-19 death rate — with 6000 deaths — than other Nordic countries.
“If we keep this policy of lockdown we will have the same kind of outcomes we’ve already had — high excess deaths and sort of indifferent control of COVID,” Bhattacharya said.
“We’re still going to have misery and death going forward until we reach a point where there’s sufficient immunity either though a vaccine or through natural infection,” he said.
This article first appeared on Medscape.com.
A coauthor of the Great Barrington Declaration says that he and colleagues have never argued against using mitigation strategies to keep COVID-19 from spreading, and that critics have mischaracterized the document as a “let it rip” strategy.
Jay Bhattacharya, MD, PhD, a professor and public health policy expert in infectious diseases at Stanford University in California, spoke on a JAMA Livestream debate on November 6. Marc Lipsitch, MD, an epidemiology professor at the Harvard T.H. Chan School of Public Health in Boston, Massachusetts, represented the 6900 signatories of the John Snow Memorandum, a rebuttal to the Great Barrington document.
The Great Barrington approach of “Focused Protection” advocates isolation and protection of people who are most vulnerable to COVID-19 while avoiding what they characterize as lockdowns. “The most compassionate approach that balances the risks and benefits of reaching herd immunity, is to allow those who are at minimal risk of death to live their lives normally to build up immunity to the virus through natural infection, while better protecting those who are at highest risk,” the document reads.
The Infectious Diseases Society of America (IDSA) and its HIV Medicine Association denounced the declaration, as reported by Medscape Medical News, and the World Health Organization (WHO) Director General Tedros Adhanom Ghebreyesus called the proposal “unethical.” But the idea has gained some traction at the White House, where Coronavirus Task Force Member and Stanford professor Scott Atlas, MD, has been advising President Donald J. Trump.
On the JAMA debate, Bhattacharya said, “I think all of the mitigation measures are really important,” listing social distancing, hand washing, and masks when distancing is not possible as chief among those strategies for the less vulnerable. “I don’t want to create infections intentionally, but I want us to allow people to go back to their lives as best they can, understanding of the risks they are taking when they do it,” he said, claiming that 99.95% of the population will survive infection.
“The harmful lockdowns are worse for many, many people,” Bhattacharya said.
“I think Jay is moving towards a middle ground which is not really what the Great Barrington Declaration seems to promote,” countered Lipsitch. The declaration does not say use masks or social distance, he said. “It just says we need to go back to a normal life.”
Bhattacharya’s statements to JAMA mean that “maybe we are approaching some common ground,” Lipsitch said.
Definition of a lockdown
Both men were asked to give their definition of a “lockdown.” To Lipsitch, it means people are not allowed out except for essential services and that most businesses are closed, with exceptions for those deemed essential.
Bhattacharya, however, said he views that as a quarantine. Lockdowns “are what we’re currently doing,” he said. Schools, churches, businesses, and arts and culture organizations are shuttered, and “almost every aspect of society is restricted in some way,” Bhattacharya said.
He blamed these lockdowns for most of the excess deaths over and above the COVID-19 deaths and said they had failed to control the pandemic.
Lipsitch said that “it feels to me that Jay is describing as lockdown everything that causes harm, even when it’s not locked down.” He noted that the country was truly closed down for 2 months or so in the spring.
“All of these harms I agree are real,” said Lipsitch. “But they are because the normal life of our society is being interfered with by viral transmission and by people’s inability to live their normal lives.”
Closures and lockdowns are essential to delaying cases and deaths, said Lipsitch. “A case today is worse than a case tomorrow and a lot worse than a case 6 months from now,” he said, noting that a vaccine or improved therapeutics could evolve.
“Delay is not nothing,” Lipsitch added. “It’s actually the goal as I see it, and as the John Snow memo says, we want to keep the virus under control in such a way as that the vulnerable people are not at risk.”
He predicted that cases will continue to grow exponentially because the nation is “not even close to herd immunity.” And, if intensive care units fill up, “there will be a responsive lockdown,” he said, adding that he did not endorse that as a general matter or favor it as a default position.
Bhattacharya claimed that Sweden has tallied only 1800 excess deaths since the pandemic began. “That’s lockdown harm avoided,” he said, advocating a similar strategy for the United States. But, infections have been on the rise in Sweden, and the nation has a higher COVID-19 death rate — with 6000 deaths — than other Nordic countries.
“If we keep this policy of lockdown we will have the same kind of outcomes we’ve already had — high excess deaths and sort of indifferent control of COVID,” Bhattacharya said.
“We’re still going to have misery and death going forward until we reach a point where there’s sufficient immunity either though a vaccine or through natural infection,” he said.
This article first appeared on Medscape.com.
A coauthor of the Great Barrington Declaration says that he and colleagues have never argued against using mitigation strategies to keep COVID-19 from spreading, and that critics have mischaracterized the document as a “let it rip” strategy.
Jay Bhattacharya, MD, PhD, a professor and public health policy expert in infectious diseases at Stanford University in California, spoke on a JAMA Livestream debate on November 6. Marc Lipsitch, MD, an epidemiology professor at the Harvard T.H. Chan School of Public Health in Boston, Massachusetts, represented the 6900 signatories of the John Snow Memorandum, a rebuttal to the Great Barrington document.
The Great Barrington approach of “Focused Protection” advocates isolation and protection of people who are most vulnerable to COVID-19 while avoiding what they characterize as lockdowns. “The most compassionate approach that balances the risks and benefits of reaching herd immunity, is to allow those who are at minimal risk of death to live their lives normally to build up immunity to the virus through natural infection, while better protecting those who are at highest risk,” the document reads.
The Infectious Diseases Society of America (IDSA) and its HIV Medicine Association denounced the declaration, as reported by Medscape Medical News, and the World Health Organization (WHO) Director General Tedros Adhanom Ghebreyesus called the proposal “unethical.” But the idea has gained some traction at the White House, where Coronavirus Task Force Member and Stanford professor Scott Atlas, MD, has been advising President Donald J. Trump.
On the JAMA debate, Bhattacharya said, “I think all of the mitigation measures are really important,” listing social distancing, hand washing, and masks when distancing is not possible as chief among those strategies for the less vulnerable. “I don’t want to create infections intentionally, but I want us to allow people to go back to their lives as best they can, understanding of the risks they are taking when they do it,” he said, claiming that 99.95% of the population will survive infection.
“The harmful lockdowns are worse for many, many people,” Bhattacharya said.
“I think Jay is moving towards a middle ground which is not really what the Great Barrington Declaration seems to promote,” countered Lipsitch. The declaration does not say use masks or social distance, he said. “It just says we need to go back to a normal life.”
Bhattacharya’s statements to JAMA mean that “maybe we are approaching some common ground,” Lipsitch said.
Definition of a lockdown
Both men were asked to give their definition of a “lockdown.” To Lipsitch, it means people are not allowed out except for essential services and that most businesses are closed, with exceptions for those deemed essential.
Bhattacharya, however, said he views that as a quarantine. Lockdowns “are what we’re currently doing,” he said. Schools, churches, businesses, and arts and culture organizations are shuttered, and “almost every aspect of society is restricted in some way,” Bhattacharya said.
He blamed these lockdowns for most of the excess deaths over and above the COVID-19 deaths and said they had failed to control the pandemic.
Lipsitch said that “it feels to me that Jay is describing as lockdown everything that causes harm, even when it’s not locked down.” He noted that the country was truly closed down for 2 months or so in the spring.
“All of these harms I agree are real,” said Lipsitch. “But they are because the normal life of our society is being interfered with by viral transmission and by people’s inability to live their normal lives.”
Closures and lockdowns are essential to delaying cases and deaths, said Lipsitch. “A case today is worse than a case tomorrow and a lot worse than a case 6 months from now,” he said, noting that a vaccine or improved therapeutics could evolve.
“Delay is not nothing,” Lipsitch added. “It’s actually the goal as I see it, and as the John Snow memo says, we want to keep the virus under control in such a way as that the vulnerable people are not at risk.”
He predicted that cases will continue to grow exponentially because the nation is “not even close to herd immunity.” And, if intensive care units fill up, “there will be a responsive lockdown,” he said, adding that he did not endorse that as a general matter or favor it as a default position.
Bhattacharya claimed that Sweden has tallied only 1800 excess deaths since the pandemic began. “That’s lockdown harm avoided,” he said, advocating a similar strategy for the United States. But, infections have been on the rise in Sweden, and the nation has a higher COVID-19 death rate — with 6000 deaths — than other Nordic countries.
“If we keep this policy of lockdown we will have the same kind of outcomes we’ve already had — high excess deaths and sort of indifferent control of COVID,” Bhattacharya said.
“We’re still going to have misery and death going forward until we reach a point where there’s sufficient immunity either though a vaccine or through natural infection,” he said.
This article first appeared on Medscape.com.
Hospitals poised to launch first COVID-19 vaccines in clinicians
At first, when news spread of a 28-year-old doctor on the COVID-19 front lines in Brazil who died after receiving an experimental vaccine, doubts arose about the safety of one of the most promising coronavirus vaccine candidates. But then the story flipped. Although the vaccine maker wouldn’t confirm it, the doctor appeared to have been in the control group and had received a dose of an established meningitis vaccine. The danger came from exposure to the coronavirus itself.
That tragedy underscores the ongoing risk of COVID-19 to healthcare workers, who have been designated by US advisory panels as part of phase 1A – the first to receive doses of any approved vaccine. The Centers for Disease Control and Prevention (CDC) recently reported that 6% of adults hospitalized with COVID from March to May were healthcare workers. The report was based on surveillance data from 13 states. The average age of the patients was 49 years. The agency set a November 15 vaccination “readiness date” for jurisdictions, such as state health departments, even though a vaccine isn’t likely to be authorized by then.
As hospitals scramble to prepare, their watchword is flexibility. They don’t yet know how many initial doses they will get, of which vaccine, or in what time frame. They have a sophisticated infrastructure to deliver flu vaccines each fall, but that framework doesn’t align with the likely scenarios of limited supply, additional reporting requirements, two-dose regimens, and differing storage needs.
“Healthcare organizations have consistently risen to the challenge. I wholeheartedly believe in their potential to do this,” Anna Legreid Dopp, PharmD, senior director of quality improvement and guidelines for the American Society of Health-System Pharmacists, told Medscape Medical News.
Healthcare workers won’t face a vaccine mandate
Even after months of caring for COVID patients, most clinicians remain vulnerable to infection – at work and in their communities. That was what occupational medicine physician Kevin Smith, MD, realized when his health system, Toledo, Ohio–based ProMedica, offered antibody testing to all its 50,000 employees. About 2% of the 6933 tests given came back positive, he says.
Yet many physicians, nurses, and other healthcare workers share the public’s skepticism about the safety and effectiveness of a vaccine that receives swift US Food and Drug Administration (FDA) approval for emergency use. About half of nurses (47%) and almost 1 in 3 physicians (30%) say that they don’t want to get the vaccine when it first becomes available or that they’re unsure about vaccination, according to a Medscape survey.
Because vaccination of healthcare workers will set the stage for public acceptance of the vaccine, hospital epidemiologists are concerned. “We know that there will be some hesitancy in the healthcare workforce, just as there will be in the broader public,” said Marci Drees, MD, chief infection prevention officer and hospital epidemiologist for ChristianaCare in Newark, Delaware, and liaison from the Society for Healthcare Epidemiology of America to the CDC’s Advisory Committee on Immunization Practices.* “I do not think we can expect anyone to be vaccinated if we’re not willing to vaccinate ourselves.”
Healthcare workers are typically required to receive a range of vaccines, including measles, mumps, and rubella (MMR) and pertussis shots. Each year, close to half of US healthcare workers receive a flu vaccine under a workplace mandate. But COVID-19 will be different. The FDA requires anyone given products under an emergency use authorization (EUA) to receive information about risks and benefits and to have the option to decline. Hospitals instead will rely on education as they offer a novel vaccine (or more than one) that will have a minimum effectiveness of 50%.
ProMedica doesn’t require employees to be vaccinated against flu, but employees who decline must get a note from a doctor indicating that they have talked about the risks and benefits of the vaccine. A similar approach may be used with a COVID-19 vaccine, in which employees may be required to learn about the vaccine before they decline, Smith says. “I do believe some people will say they don’t want to get it,” he added.
Like colleagues across the country, Smith is identifying healthcare workers who are involved in direct care of COVID-19 patients and are at highest risk for exposure. Even within the top tier, those performing the riskiest tasks, such as respiratory therapists who provide breathing treatments that spread aerosols and droplets, will be tagged as a priority group, he says. Healthcare workers who spend the most time in proximity to COVID patients, such as nurses in a COVID unit, also are likely to get the first doses, he says.
Swirl, don’t shake, the vaccine
Hospitals are adept at ramping up vaccination campaigns. For example, last year, Vanderbilt University Medical Center, in Nashville, Tennessee, vaccinated nearly 16,000 employees against influenza in their 1-day “Flulapalooza” event. The medical center even earned a Guinness world record in 2011 at the first Flulapalooza for giving the most vaccinations ever within 8 hours.
The 10th anniversary of the event was canceled this year because of COVID restrictions. Instead, nurses, pharmacists, and other clinicians pitched in to vaccinate their coworkers against influenza. Now, plans for COVID-19 vaccination move forward amid uncertainty.
Instead of holding a mass event, “the delivery mechanisms will need to be more targeted and focused,” said Lori Rolando, MD, MPH, director of the Vanderbilt Occupational Health Clinic. In the CDC’s most recent version of its vaccination program “playbook,” the agency recommends giving the vaccines in an area that allows people to remain 6 feet apart and for them to wait for 15 minutes after receiving the shot to make sure they don’t faint, a potential risk common to almost all vaccines.
That’s the easy part. Planning becomes more complex, given the uncertainty as to which vaccines will receive approval and which one a hospital will receive.
If the Pfizer/BioNTech vaccine receives EUA in 2020, about 10 to 20 million doses could be available in November and 20 to 30 million doses in December. The ultracold containers used to ship the vaccines have to be replenished with dry ice within 24 hours of receipt and every 5 days thereafter. Hospitals will need temperature probes to monitor storage in the containers. The five-dose vials can be refrigerated before administering, but only for 5 days. The product must be diluted, and it then must be used within 6 hours.
The Moderna vaccine will be somewhat less plentiful at first. About 10 million doses are expected in November and 15 million doses by the end of December. The 10-dose vials are stored in a freezer. Once they are placed in a refrigerator to thaw, they have to be used within 7 days, and once they’re removed from the refrigerator, they have to be used within 12 hours. The pharmacist or other vaccinator must swirl – but not shake! – the vial before delivering a dose, according to the CDC playbook.
As more information emerges about the vaccines, instructions may change, and Smith is steeled for shifting scenarios. “These are all draft plans. We’re going to modify as we go along,” he says.
The Pfizer vaccine requires a second dose at 21 days, and the Moderna vaccine targets the second dose at 28 days. In addition to using information systems to track vaccinations and any adverse effects, hospitals will give employees a card indicating what vaccine they received, the date it was administered, and the date on which they need to return. (At this point, the time frame for the second dose doesn’t appear to be flexible.)
Regardless of the vaccine, one message stays the same: COVID precautions must continue. That means mask wearing, social distancing, and hand washing – practices that also must be followed by healthcare workers who test positive for naturally acquired antibodies.
“I don’t think anyone expects the COVID vaccine to be 100% effective at preventing COVID,” says Rolando. “So all of the other tools in our toolbox are going to need to be continued to be used as well.”
*Correction, 11/12/20: An earlier version of this article misstated the name of Dr. Drees' institution.
This article first appeared on Medscape.com.
At first, when news spread of a 28-year-old doctor on the COVID-19 front lines in Brazil who died after receiving an experimental vaccine, doubts arose about the safety of one of the most promising coronavirus vaccine candidates. But then the story flipped. Although the vaccine maker wouldn’t confirm it, the doctor appeared to have been in the control group and had received a dose of an established meningitis vaccine. The danger came from exposure to the coronavirus itself.
That tragedy underscores the ongoing risk of COVID-19 to healthcare workers, who have been designated by US advisory panels as part of phase 1A – the first to receive doses of any approved vaccine. The Centers for Disease Control and Prevention (CDC) recently reported that 6% of adults hospitalized with COVID from March to May were healthcare workers. The report was based on surveillance data from 13 states. The average age of the patients was 49 years. The agency set a November 15 vaccination “readiness date” for jurisdictions, such as state health departments, even though a vaccine isn’t likely to be authorized by then.
As hospitals scramble to prepare, their watchword is flexibility. They don’t yet know how many initial doses they will get, of which vaccine, or in what time frame. They have a sophisticated infrastructure to deliver flu vaccines each fall, but that framework doesn’t align with the likely scenarios of limited supply, additional reporting requirements, two-dose regimens, and differing storage needs.
“Healthcare organizations have consistently risen to the challenge. I wholeheartedly believe in their potential to do this,” Anna Legreid Dopp, PharmD, senior director of quality improvement and guidelines for the American Society of Health-System Pharmacists, told Medscape Medical News.
Healthcare workers won’t face a vaccine mandate
Even after months of caring for COVID patients, most clinicians remain vulnerable to infection – at work and in their communities. That was what occupational medicine physician Kevin Smith, MD, realized when his health system, Toledo, Ohio–based ProMedica, offered antibody testing to all its 50,000 employees. About 2% of the 6933 tests given came back positive, he says.
Yet many physicians, nurses, and other healthcare workers share the public’s skepticism about the safety and effectiveness of a vaccine that receives swift US Food and Drug Administration (FDA) approval for emergency use. About half of nurses (47%) and almost 1 in 3 physicians (30%) say that they don’t want to get the vaccine when it first becomes available or that they’re unsure about vaccination, according to a Medscape survey.
Because vaccination of healthcare workers will set the stage for public acceptance of the vaccine, hospital epidemiologists are concerned. “We know that there will be some hesitancy in the healthcare workforce, just as there will be in the broader public,” said Marci Drees, MD, chief infection prevention officer and hospital epidemiologist for ChristianaCare in Newark, Delaware, and liaison from the Society for Healthcare Epidemiology of America to the CDC’s Advisory Committee on Immunization Practices.* “I do not think we can expect anyone to be vaccinated if we’re not willing to vaccinate ourselves.”
Healthcare workers are typically required to receive a range of vaccines, including measles, mumps, and rubella (MMR) and pertussis shots. Each year, close to half of US healthcare workers receive a flu vaccine under a workplace mandate. But COVID-19 will be different. The FDA requires anyone given products under an emergency use authorization (EUA) to receive information about risks and benefits and to have the option to decline. Hospitals instead will rely on education as they offer a novel vaccine (or more than one) that will have a minimum effectiveness of 50%.
ProMedica doesn’t require employees to be vaccinated against flu, but employees who decline must get a note from a doctor indicating that they have talked about the risks and benefits of the vaccine. A similar approach may be used with a COVID-19 vaccine, in which employees may be required to learn about the vaccine before they decline, Smith says. “I do believe some people will say they don’t want to get it,” he added.
Like colleagues across the country, Smith is identifying healthcare workers who are involved in direct care of COVID-19 patients and are at highest risk for exposure. Even within the top tier, those performing the riskiest tasks, such as respiratory therapists who provide breathing treatments that spread aerosols and droplets, will be tagged as a priority group, he says. Healthcare workers who spend the most time in proximity to COVID patients, such as nurses in a COVID unit, also are likely to get the first doses, he says.
Swirl, don’t shake, the vaccine
Hospitals are adept at ramping up vaccination campaigns. For example, last year, Vanderbilt University Medical Center, in Nashville, Tennessee, vaccinated nearly 16,000 employees against influenza in their 1-day “Flulapalooza” event. The medical center even earned a Guinness world record in 2011 at the first Flulapalooza for giving the most vaccinations ever within 8 hours.
The 10th anniversary of the event was canceled this year because of COVID restrictions. Instead, nurses, pharmacists, and other clinicians pitched in to vaccinate their coworkers against influenza. Now, plans for COVID-19 vaccination move forward amid uncertainty.
Instead of holding a mass event, “the delivery mechanisms will need to be more targeted and focused,” said Lori Rolando, MD, MPH, director of the Vanderbilt Occupational Health Clinic. In the CDC’s most recent version of its vaccination program “playbook,” the agency recommends giving the vaccines in an area that allows people to remain 6 feet apart and for them to wait for 15 minutes after receiving the shot to make sure they don’t faint, a potential risk common to almost all vaccines.
That’s the easy part. Planning becomes more complex, given the uncertainty as to which vaccines will receive approval and which one a hospital will receive.
If the Pfizer/BioNTech vaccine receives EUA in 2020, about 10 to 20 million doses could be available in November and 20 to 30 million doses in December. The ultracold containers used to ship the vaccines have to be replenished with dry ice within 24 hours of receipt and every 5 days thereafter. Hospitals will need temperature probes to monitor storage in the containers. The five-dose vials can be refrigerated before administering, but only for 5 days. The product must be diluted, and it then must be used within 6 hours.
The Moderna vaccine will be somewhat less plentiful at first. About 10 million doses are expected in November and 15 million doses by the end of December. The 10-dose vials are stored in a freezer. Once they are placed in a refrigerator to thaw, they have to be used within 7 days, and once they’re removed from the refrigerator, they have to be used within 12 hours. The pharmacist or other vaccinator must swirl – but not shake! – the vial before delivering a dose, according to the CDC playbook.
As more information emerges about the vaccines, instructions may change, and Smith is steeled for shifting scenarios. “These are all draft plans. We’re going to modify as we go along,” he says.
The Pfizer vaccine requires a second dose at 21 days, and the Moderna vaccine targets the second dose at 28 days. In addition to using information systems to track vaccinations and any adverse effects, hospitals will give employees a card indicating what vaccine they received, the date it was administered, and the date on which they need to return. (At this point, the time frame for the second dose doesn’t appear to be flexible.)
Regardless of the vaccine, one message stays the same: COVID precautions must continue. That means mask wearing, social distancing, and hand washing – practices that also must be followed by healthcare workers who test positive for naturally acquired antibodies.
“I don’t think anyone expects the COVID vaccine to be 100% effective at preventing COVID,” says Rolando. “So all of the other tools in our toolbox are going to need to be continued to be used as well.”
*Correction, 11/12/20: An earlier version of this article misstated the name of Dr. Drees' institution.
This article first appeared on Medscape.com.
At first, when news spread of a 28-year-old doctor on the COVID-19 front lines in Brazil who died after receiving an experimental vaccine, doubts arose about the safety of one of the most promising coronavirus vaccine candidates. But then the story flipped. Although the vaccine maker wouldn’t confirm it, the doctor appeared to have been in the control group and had received a dose of an established meningitis vaccine. The danger came from exposure to the coronavirus itself.
That tragedy underscores the ongoing risk of COVID-19 to healthcare workers, who have been designated by US advisory panels as part of phase 1A – the first to receive doses of any approved vaccine. The Centers for Disease Control and Prevention (CDC) recently reported that 6% of adults hospitalized with COVID from March to May were healthcare workers. The report was based on surveillance data from 13 states. The average age of the patients was 49 years. The agency set a November 15 vaccination “readiness date” for jurisdictions, such as state health departments, even though a vaccine isn’t likely to be authorized by then.
As hospitals scramble to prepare, their watchword is flexibility. They don’t yet know how many initial doses they will get, of which vaccine, or in what time frame. They have a sophisticated infrastructure to deliver flu vaccines each fall, but that framework doesn’t align with the likely scenarios of limited supply, additional reporting requirements, two-dose regimens, and differing storage needs.
“Healthcare organizations have consistently risen to the challenge. I wholeheartedly believe in their potential to do this,” Anna Legreid Dopp, PharmD, senior director of quality improvement and guidelines for the American Society of Health-System Pharmacists, told Medscape Medical News.
Healthcare workers won’t face a vaccine mandate
Even after months of caring for COVID patients, most clinicians remain vulnerable to infection – at work and in their communities. That was what occupational medicine physician Kevin Smith, MD, realized when his health system, Toledo, Ohio–based ProMedica, offered antibody testing to all its 50,000 employees. About 2% of the 6933 tests given came back positive, he says.
Yet many physicians, nurses, and other healthcare workers share the public’s skepticism about the safety and effectiveness of a vaccine that receives swift US Food and Drug Administration (FDA) approval for emergency use. About half of nurses (47%) and almost 1 in 3 physicians (30%) say that they don’t want to get the vaccine when it first becomes available or that they’re unsure about vaccination, according to a Medscape survey.
Because vaccination of healthcare workers will set the stage for public acceptance of the vaccine, hospital epidemiologists are concerned. “We know that there will be some hesitancy in the healthcare workforce, just as there will be in the broader public,” said Marci Drees, MD, chief infection prevention officer and hospital epidemiologist for ChristianaCare in Newark, Delaware, and liaison from the Society for Healthcare Epidemiology of America to the CDC’s Advisory Committee on Immunization Practices.* “I do not think we can expect anyone to be vaccinated if we’re not willing to vaccinate ourselves.”
Healthcare workers are typically required to receive a range of vaccines, including measles, mumps, and rubella (MMR) and pertussis shots. Each year, close to half of US healthcare workers receive a flu vaccine under a workplace mandate. But COVID-19 will be different. The FDA requires anyone given products under an emergency use authorization (EUA) to receive information about risks and benefits and to have the option to decline. Hospitals instead will rely on education as they offer a novel vaccine (or more than one) that will have a minimum effectiveness of 50%.
ProMedica doesn’t require employees to be vaccinated against flu, but employees who decline must get a note from a doctor indicating that they have talked about the risks and benefits of the vaccine. A similar approach may be used with a COVID-19 vaccine, in which employees may be required to learn about the vaccine before they decline, Smith says. “I do believe some people will say they don’t want to get it,” he added.
Like colleagues across the country, Smith is identifying healthcare workers who are involved in direct care of COVID-19 patients and are at highest risk for exposure. Even within the top tier, those performing the riskiest tasks, such as respiratory therapists who provide breathing treatments that spread aerosols and droplets, will be tagged as a priority group, he says. Healthcare workers who spend the most time in proximity to COVID patients, such as nurses in a COVID unit, also are likely to get the first doses, he says.
Swirl, don’t shake, the vaccine
Hospitals are adept at ramping up vaccination campaigns. For example, last year, Vanderbilt University Medical Center, in Nashville, Tennessee, vaccinated nearly 16,000 employees against influenza in their 1-day “Flulapalooza” event. The medical center even earned a Guinness world record in 2011 at the first Flulapalooza for giving the most vaccinations ever within 8 hours.
The 10th anniversary of the event was canceled this year because of COVID restrictions. Instead, nurses, pharmacists, and other clinicians pitched in to vaccinate their coworkers against influenza. Now, plans for COVID-19 vaccination move forward amid uncertainty.
Instead of holding a mass event, “the delivery mechanisms will need to be more targeted and focused,” said Lori Rolando, MD, MPH, director of the Vanderbilt Occupational Health Clinic. In the CDC’s most recent version of its vaccination program “playbook,” the agency recommends giving the vaccines in an area that allows people to remain 6 feet apart and for them to wait for 15 minutes after receiving the shot to make sure they don’t faint, a potential risk common to almost all vaccines.
That’s the easy part. Planning becomes more complex, given the uncertainty as to which vaccines will receive approval and which one a hospital will receive.
If the Pfizer/BioNTech vaccine receives EUA in 2020, about 10 to 20 million doses could be available in November and 20 to 30 million doses in December. The ultracold containers used to ship the vaccines have to be replenished with dry ice within 24 hours of receipt and every 5 days thereafter. Hospitals will need temperature probes to monitor storage in the containers. The five-dose vials can be refrigerated before administering, but only for 5 days. The product must be diluted, and it then must be used within 6 hours.
The Moderna vaccine will be somewhat less plentiful at first. About 10 million doses are expected in November and 15 million doses by the end of December. The 10-dose vials are stored in a freezer. Once they are placed in a refrigerator to thaw, they have to be used within 7 days, and once they’re removed from the refrigerator, they have to be used within 12 hours. The pharmacist or other vaccinator must swirl – but not shake! – the vial before delivering a dose, according to the CDC playbook.
As more information emerges about the vaccines, instructions may change, and Smith is steeled for shifting scenarios. “These are all draft plans. We’re going to modify as we go along,” he says.
The Pfizer vaccine requires a second dose at 21 days, and the Moderna vaccine targets the second dose at 28 days. In addition to using information systems to track vaccinations and any adverse effects, hospitals will give employees a card indicating what vaccine they received, the date it was administered, and the date on which they need to return. (At this point, the time frame for the second dose doesn’t appear to be flexible.)
Regardless of the vaccine, one message stays the same: COVID precautions must continue. That means mask wearing, social distancing, and hand washing – practices that also must be followed by healthcare workers who test positive for naturally acquired antibodies.
“I don’t think anyone expects the COVID vaccine to be 100% effective at preventing COVID,” says Rolando. “So all of the other tools in our toolbox are going to need to be continued to be used as well.”
*Correction, 11/12/20: An earlier version of this article misstated the name of Dr. Drees' institution.
This article first appeared on Medscape.com.
Whales, seals, and dolphins: Will SARS-CoV-2–contaminated wastewater prove a killer?
Zoonoses are no respecter of biological boundaries and are notorious for crossing genus and even higher taxonomic boundaries. SARS-CoV-2 is no exception, the current outbreak most probably having originated in bats, a common source of human-affecting zoonoses throughout history. But it is not a one-way street, and the virus has been shown to spread from infected humans to a variety of other land mammals, including our domesticated animals and kept zoo species.
A recent troubling report, however, has indicated that sea mammals may be part of a next wave of likely candidates for infection, put at risk by the current human pandemic and environmental degradation on a global scale, according to a the results of a genomic analysis of four major groups of sea mammals.
Researchers Sabateeshan Mathavarajah and colleagues from Dalhousie University, Halifax, N.S., examined the sequences of the ACE2 receptors in the various marine mammal species. The ACE2 receptor has recently been identified as the SARS-CoV-2 receptor, which allows for infection.
The researchers examined genomic databases of the marine species to determine if their ACE2 receptor sequences indicated the potential for high, medium, or low susceptibility to infection, as reported in Science of the Total Environment. Database analysis was performed for four groups: Cetacea (whales and dolphins), Pinnepidia (seals), Sirenia (sea cows), and Fissipedia (sea otters and polar bears).
The researchers defined susceptibility values based on comparable binding with the receptor and came up with the following subgroups: higher than human, high (resembles human ACE2), medium (resembles cat ACE2), and low (resembles dog ACE2). It has yet to be established if these marine mammals actually are infected with SARS-CoV-2 and what the impact of such an infection might have on animal health or humans who come in contact with infected animals.
They also cross-referenced for the level of species endangerment and with maps of potential wastewater contamination for certain areas that species came in contact with, using Alaska as the model.
Populations in danger
The researchers found 15 species that are already at risk globally that fall under the categories of near threatened, vulnerable, endangered, and critically endangered that were predicted to be medium to higher susceptibility to the SARS-CoV-2 virus than humans. Cross infection is of particular concern because other coronaviruses have been shown to have severe and lethal effects among many of these species.
Among the potentially impacted species were the near threatened–status Antarctic Mink whale and the stellar sea lion; the vulnerable sperm whale, northern fur seal, and Atlantic walrus; the endangered northern and southern sea otters, the North Pacific right whale, and the Amazon River dolphin; and the critically threatened Baiji and Vaquita dolphin species.
Pollution risks
In Alaska, as of Aug. 7th, 2020, there were 4,221 confirmed cases of COVID-19 and this number continues to rise, according to the researchers. Since there is a diversity of marine mammals in Alaska and their populations are well documented, they compared this information with available data on the wastewater treatment plants in the state. They were thus able to determine the potential geographic locations and species at high risk for transmission of SARS-CoV-2 via wastewater effluent.
Among their findings, the city of Cold Bay discharges wastewater into Cold Bay, where there are Northern sea otter populations that are predicted to be highly susceptible to the virus. Beluga whales are also predicted to have high susceptibility and they can be found in Bristol Bay near Naknek, a city which relies only on lagoon treatment prior to the discharge of wastewater effluent; the city of Dillingham discharges wastewater into the Nushagak River where beluga whales are found. In Palmer, wastewater effluent flows into the Talkeetna River, which is a tributary to the Susitna River and home to two species predicted to have high susceptibility, beluga whales and harbor seals, the authors added.
Based on these results, the researchers predicted that there was likely a significant risk to sea mammals across the globe, especially where less-adequate treatment facilities and high population densities may lead to greater wastewater contamination.
“Given the proximity of marine animals to high-risk environments where viral spill over is likely, we must act with foresight to protect marine mammal species predicted to be at risk and mitigate the environmental impact of the COVID-19 pandemic,” the researchers concluded.
The authors reported that they had no disclosures.
SOURCE: Mathavarajah S et al. Sci Total Environ. 2020 Oct 29. doi: 10.1016/j.scitotenv.2020.143346.
Zoonoses are no respecter of biological boundaries and are notorious for crossing genus and even higher taxonomic boundaries. SARS-CoV-2 is no exception, the current outbreak most probably having originated in bats, a common source of human-affecting zoonoses throughout history. But it is not a one-way street, and the virus has been shown to spread from infected humans to a variety of other land mammals, including our domesticated animals and kept zoo species.
A recent troubling report, however, has indicated that sea mammals may be part of a next wave of likely candidates for infection, put at risk by the current human pandemic and environmental degradation on a global scale, according to a the results of a genomic analysis of four major groups of sea mammals.
Researchers Sabateeshan Mathavarajah and colleagues from Dalhousie University, Halifax, N.S., examined the sequences of the ACE2 receptors in the various marine mammal species. The ACE2 receptor has recently been identified as the SARS-CoV-2 receptor, which allows for infection.
The researchers examined genomic databases of the marine species to determine if their ACE2 receptor sequences indicated the potential for high, medium, or low susceptibility to infection, as reported in Science of the Total Environment. Database analysis was performed for four groups: Cetacea (whales and dolphins), Pinnepidia (seals), Sirenia (sea cows), and Fissipedia (sea otters and polar bears).
The researchers defined susceptibility values based on comparable binding with the receptor and came up with the following subgroups: higher than human, high (resembles human ACE2), medium (resembles cat ACE2), and low (resembles dog ACE2). It has yet to be established if these marine mammals actually are infected with SARS-CoV-2 and what the impact of such an infection might have on animal health or humans who come in contact with infected animals.
They also cross-referenced for the level of species endangerment and with maps of potential wastewater contamination for certain areas that species came in contact with, using Alaska as the model.
Populations in danger
The researchers found 15 species that are already at risk globally that fall under the categories of near threatened, vulnerable, endangered, and critically endangered that were predicted to be medium to higher susceptibility to the SARS-CoV-2 virus than humans. Cross infection is of particular concern because other coronaviruses have been shown to have severe and lethal effects among many of these species.
Among the potentially impacted species were the near threatened–status Antarctic Mink whale and the stellar sea lion; the vulnerable sperm whale, northern fur seal, and Atlantic walrus; the endangered northern and southern sea otters, the North Pacific right whale, and the Amazon River dolphin; and the critically threatened Baiji and Vaquita dolphin species.
Pollution risks
In Alaska, as of Aug. 7th, 2020, there were 4,221 confirmed cases of COVID-19 and this number continues to rise, according to the researchers. Since there is a diversity of marine mammals in Alaska and their populations are well documented, they compared this information with available data on the wastewater treatment plants in the state. They were thus able to determine the potential geographic locations and species at high risk for transmission of SARS-CoV-2 via wastewater effluent.
Among their findings, the city of Cold Bay discharges wastewater into Cold Bay, where there are Northern sea otter populations that are predicted to be highly susceptible to the virus. Beluga whales are also predicted to have high susceptibility and they can be found in Bristol Bay near Naknek, a city which relies only on lagoon treatment prior to the discharge of wastewater effluent; the city of Dillingham discharges wastewater into the Nushagak River where beluga whales are found. In Palmer, wastewater effluent flows into the Talkeetna River, which is a tributary to the Susitna River and home to two species predicted to have high susceptibility, beluga whales and harbor seals, the authors added.
Based on these results, the researchers predicted that there was likely a significant risk to sea mammals across the globe, especially where less-adequate treatment facilities and high population densities may lead to greater wastewater contamination.
“Given the proximity of marine animals to high-risk environments where viral spill over is likely, we must act with foresight to protect marine mammal species predicted to be at risk and mitigate the environmental impact of the COVID-19 pandemic,” the researchers concluded.
The authors reported that they had no disclosures.
SOURCE: Mathavarajah S et al. Sci Total Environ. 2020 Oct 29. doi: 10.1016/j.scitotenv.2020.143346.
Zoonoses are no respecter of biological boundaries and are notorious for crossing genus and even higher taxonomic boundaries. SARS-CoV-2 is no exception, the current outbreak most probably having originated in bats, a common source of human-affecting zoonoses throughout history. But it is not a one-way street, and the virus has been shown to spread from infected humans to a variety of other land mammals, including our domesticated animals and kept zoo species.
A recent troubling report, however, has indicated that sea mammals may be part of a next wave of likely candidates for infection, put at risk by the current human pandemic and environmental degradation on a global scale, according to a the results of a genomic analysis of four major groups of sea mammals.
Researchers Sabateeshan Mathavarajah and colleagues from Dalhousie University, Halifax, N.S., examined the sequences of the ACE2 receptors in the various marine mammal species. The ACE2 receptor has recently been identified as the SARS-CoV-2 receptor, which allows for infection.
The researchers examined genomic databases of the marine species to determine if their ACE2 receptor sequences indicated the potential for high, medium, or low susceptibility to infection, as reported in Science of the Total Environment. Database analysis was performed for four groups: Cetacea (whales and dolphins), Pinnepidia (seals), Sirenia (sea cows), and Fissipedia (sea otters and polar bears).
The researchers defined susceptibility values based on comparable binding with the receptor and came up with the following subgroups: higher than human, high (resembles human ACE2), medium (resembles cat ACE2), and low (resembles dog ACE2). It has yet to be established if these marine mammals actually are infected with SARS-CoV-2 and what the impact of such an infection might have on animal health or humans who come in contact with infected animals.
They also cross-referenced for the level of species endangerment and with maps of potential wastewater contamination for certain areas that species came in contact with, using Alaska as the model.
Populations in danger
The researchers found 15 species that are already at risk globally that fall under the categories of near threatened, vulnerable, endangered, and critically endangered that were predicted to be medium to higher susceptibility to the SARS-CoV-2 virus than humans. Cross infection is of particular concern because other coronaviruses have been shown to have severe and lethal effects among many of these species.
Among the potentially impacted species were the near threatened–status Antarctic Mink whale and the stellar sea lion; the vulnerable sperm whale, northern fur seal, and Atlantic walrus; the endangered northern and southern sea otters, the North Pacific right whale, and the Amazon River dolphin; and the critically threatened Baiji and Vaquita dolphin species.
Pollution risks
In Alaska, as of Aug. 7th, 2020, there were 4,221 confirmed cases of COVID-19 and this number continues to rise, according to the researchers. Since there is a diversity of marine mammals in Alaska and their populations are well documented, they compared this information with available data on the wastewater treatment plants in the state. They were thus able to determine the potential geographic locations and species at high risk for transmission of SARS-CoV-2 via wastewater effluent.
Among their findings, the city of Cold Bay discharges wastewater into Cold Bay, where there are Northern sea otter populations that are predicted to be highly susceptible to the virus. Beluga whales are also predicted to have high susceptibility and they can be found in Bristol Bay near Naknek, a city which relies only on lagoon treatment prior to the discharge of wastewater effluent; the city of Dillingham discharges wastewater into the Nushagak River where beluga whales are found. In Palmer, wastewater effluent flows into the Talkeetna River, which is a tributary to the Susitna River and home to two species predicted to have high susceptibility, beluga whales and harbor seals, the authors added.
Based on these results, the researchers predicted that there was likely a significant risk to sea mammals across the globe, especially where less-adequate treatment facilities and high population densities may lead to greater wastewater contamination.
“Given the proximity of marine animals to high-risk environments where viral spill over is likely, we must act with foresight to protect marine mammal species predicted to be at risk and mitigate the environmental impact of the COVID-19 pandemic,” the researchers concluded.
The authors reported that they had no disclosures.
SOURCE: Mathavarajah S et al. Sci Total Environ. 2020 Oct 29. doi: 10.1016/j.scitotenv.2020.143346.
FROM SCIENCE OF THE TOTAL ENVIRONMENT
VA joins Pentagon in recruiting volunteers for COVID vaccine trials
according to officials with the VA and Operation Warp Speed, the Trump administration’s initiative to fast-track a coronavirus vaccine.
The largely unpublicized effort follows a Department of Defense announcement in September that it has partnered with AstraZeneca to recruit volunteers at five of its medical facilities, which are separate from the VA system. DOD is also is in talks with developers of other vaccine candidates, although officials won’t say which ones.
Both federal departments have long experience in medical research and diverse populations – a crucial component of effective clinical trials, said J. Stephen Morrison, senior vice president and director of global health policy at the Center for Strategic and International Studies, a bipartisan think tank in Washington.
Since active troops are essential to national security, and veterans are extremely vulnerable to COVID-19, both departments have a vested interest in supporting the development of safe, effective vaccines, Mr. Morrison said.
“On the DOD active servicemen and -women side, it’s a question of making sure they’re ready, they are protected,” Mr. Morrison said. “With VA, their population, all elderly and infirm with underlying conditions, they could really be suffering if we don’t get a vaccine.”
According to a VA website, of its 20 medical centers involved, 17 would be part of the Johnson & Johnson vaccine trial, while the three others are recruiting – or have completed recruitment – for advanced-stage trials for Moderna, AstraZeneca, and Pfizer vaccines.
Matthew Hepburn, MD, head of vaccine development at Operation Warp Speed, said the VA effort lets veterans contribute to the overall well-being of the country.
“This is another way they can continue to serve in this way, fighting the pandemic as a volunteer,” Dr. Hepburn said during a discussion of vaccine and therapeutics development hosted by the Heritage Foundation on Oct. 27.
It’s not unusual for the military to participate in multicenter trials for treatments of ailments as diverse as cancer and trauma. Historically, many vaccines have been tested first by the military.
In the general population, clinicians often have difficulty recruiting African Americans and other minorities for medical research, and “the military provides a rich opportunity to find volunteers for those groups,” said retired Rear Adm. Thomas Cullison, MD, a doctor and former deputy surgeon general for the Navy.
Military health facilities are held to the same standards as private research facilities, he said.
No service members will be required to participate in the COVID vaccine trials. All volunteers will be paid by the developer.
Support for routine vaccinations runs high in the military, but some have expressed concerns about new vaccines and mandatory inoculations, especially for anthrax. In a 2002 federal study, 85% of those who received that vaccine reported an adverse reaction, with just under half noticing minor redness at the injection site. But nearly a quarter of the side effects reported were more systemic, including fevers, chills, fatigue and joint pain.
That survey of a small group of National Guard and Reserve members found that, while 73% said they believe immunizations are effective, two-thirds said they did not support the mandatory anthrax program, and 6 in 10 said they were not satisfied with the information they were given on the vaccines.
To quell concerns over the military’s role in supporting COVID vaccine development, the Pentagon has reiterated that troops or their dependents interested in participating in the research must provide voluntary written consent, and they will be allowed to take part only if they will be in the same location for the length of the research, expected to last at least 2 years.
In addition, active-duty members such as new recruits and boot camp participants will not be allowed to volunteer because they are “considered vulnerable from an ethical and regulatory standpoint,” an official said.
At the VA, officials are seeking to recruit healthy veterans aged 18-65 years old who are not pregnant and may be at risk for exposure. As with trials conducted in civilian facilities, participants will be paid by the developer, VA spokesperson Christina Noel said.
Also, VA nurses and caseworkers also are being asked to identify their sickest, highest-risk patients to determine who should be at the top of the list once a vaccine is approved, according to a VA nurse and other health officials who asked not to be identified because they were not authorized to speak with the press.
The U.S. military has a long history of contributing to research on vaccines, including a key role in developing inoculations against yellow fever and adenovirus, and the Walter Reed Army Institute of Research is developing its own vaccine against the coronavirus.
Some segments of the population remain skeptical of federal medical experiments. A survey by AP-NORC in May found that Black people are particularly reluctant to get the coronavirus vaccine. Many have concerns about federal research in part because of associations with the infamous Tuskegee Institute syphilis experiments, in which U.S. Public Health Service officials intentionally withheld a cure from Black men infected with the disease.
But Mr. Morrison, of the Center for Strategic and International Studies, said the Defense Department and VA are a “natural fit” for the COVID vaccine trials.
“DOD has lots of expertise. They know how to vaccinate; they know how to reach communities. They have a whole science infrastructure and research-and-development infrastructure. And when you are thinking what the mission of VA is, [VA] sees this is part of their mission,” Mr. Morrison said.
The Defense Department announced its agreement with AstraZeneca in September, shortly before the drugmaker’s vaccine trial was put on hold to study a serious medical condition that one participant reported. That research was approved by the Food and Drug Administration to begin again Oct. 23. The military plans to restart its efforts to recruit 3,000 volunteers.
The Pentagon has also signed an agreement with another vaccine developer, the head of the Defense Health Agency, Army Lt. Gen. Ronald Place, told reporters Oct. 8. He wouldn’t provide the company’s name.
Senator Elizabeth Warren (D-Mass.) and Senator Mazie Hirono (D-Hawaii) have called, unsuccessfully, for the Senate Armed Services Committee to investigate what they say is a lack of Pentagon transparency on its role in vaccine development and distribution. The Defense Department has awarded more than $6 billion in Operation Warp Speed contracts through an intermediary, Advanced Technology International, and the two senators want more information about those contracts.
“There may well be a valuable role for DoD officials in [Operation Warp Speed] – particularly given the department’s logistical capacity,” they wrote to the committee chair and ranking member. “But it is important that Congress conduct appropriate oversight of, and understand, DoD’s activities in this area.”
Neither department has disclosed the financial arrangements they have made with developers to support the vaccine research.
Kaiser Health News is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.
according to officials with the VA and Operation Warp Speed, the Trump administration’s initiative to fast-track a coronavirus vaccine.
The largely unpublicized effort follows a Department of Defense announcement in September that it has partnered with AstraZeneca to recruit volunteers at five of its medical facilities, which are separate from the VA system. DOD is also is in talks with developers of other vaccine candidates, although officials won’t say which ones.
Both federal departments have long experience in medical research and diverse populations – a crucial component of effective clinical trials, said J. Stephen Morrison, senior vice president and director of global health policy at the Center for Strategic and International Studies, a bipartisan think tank in Washington.
Since active troops are essential to national security, and veterans are extremely vulnerable to COVID-19, both departments have a vested interest in supporting the development of safe, effective vaccines, Mr. Morrison said.
“On the DOD active servicemen and -women side, it’s a question of making sure they’re ready, they are protected,” Mr. Morrison said. “With VA, their population, all elderly and infirm with underlying conditions, they could really be suffering if we don’t get a vaccine.”
According to a VA website, of its 20 medical centers involved, 17 would be part of the Johnson & Johnson vaccine trial, while the three others are recruiting – or have completed recruitment – for advanced-stage trials for Moderna, AstraZeneca, and Pfizer vaccines.
Matthew Hepburn, MD, head of vaccine development at Operation Warp Speed, said the VA effort lets veterans contribute to the overall well-being of the country.
“This is another way they can continue to serve in this way, fighting the pandemic as a volunteer,” Dr. Hepburn said during a discussion of vaccine and therapeutics development hosted by the Heritage Foundation on Oct. 27.
It’s not unusual for the military to participate in multicenter trials for treatments of ailments as diverse as cancer and trauma. Historically, many vaccines have been tested first by the military.
In the general population, clinicians often have difficulty recruiting African Americans and other minorities for medical research, and “the military provides a rich opportunity to find volunteers for those groups,” said retired Rear Adm. Thomas Cullison, MD, a doctor and former deputy surgeon general for the Navy.
Military health facilities are held to the same standards as private research facilities, he said.
No service members will be required to participate in the COVID vaccine trials. All volunteers will be paid by the developer.
Support for routine vaccinations runs high in the military, but some have expressed concerns about new vaccines and mandatory inoculations, especially for anthrax. In a 2002 federal study, 85% of those who received that vaccine reported an adverse reaction, with just under half noticing minor redness at the injection site. But nearly a quarter of the side effects reported were more systemic, including fevers, chills, fatigue and joint pain.
That survey of a small group of National Guard and Reserve members found that, while 73% said they believe immunizations are effective, two-thirds said they did not support the mandatory anthrax program, and 6 in 10 said they were not satisfied with the information they were given on the vaccines.
To quell concerns over the military’s role in supporting COVID vaccine development, the Pentagon has reiterated that troops or their dependents interested in participating in the research must provide voluntary written consent, and they will be allowed to take part only if they will be in the same location for the length of the research, expected to last at least 2 years.
In addition, active-duty members such as new recruits and boot camp participants will not be allowed to volunteer because they are “considered vulnerable from an ethical and regulatory standpoint,” an official said.
At the VA, officials are seeking to recruit healthy veterans aged 18-65 years old who are not pregnant and may be at risk for exposure. As with trials conducted in civilian facilities, participants will be paid by the developer, VA spokesperson Christina Noel said.
Also, VA nurses and caseworkers also are being asked to identify their sickest, highest-risk patients to determine who should be at the top of the list once a vaccine is approved, according to a VA nurse and other health officials who asked not to be identified because they were not authorized to speak with the press.
The U.S. military has a long history of contributing to research on vaccines, including a key role in developing inoculations against yellow fever and adenovirus, and the Walter Reed Army Institute of Research is developing its own vaccine against the coronavirus.
Some segments of the population remain skeptical of federal medical experiments. A survey by AP-NORC in May found that Black people are particularly reluctant to get the coronavirus vaccine. Many have concerns about federal research in part because of associations with the infamous Tuskegee Institute syphilis experiments, in which U.S. Public Health Service officials intentionally withheld a cure from Black men infected with the disease.
But Mr. Morrison, of the Center for Strategic and International Studies, said the Defense Department and VA are a “natural fit” for the COVID vaccine trials.
“DOD has lots of expertise. They know how to vaccinate; they know how to reach communities. They have a whole science infrastructure and research-and-development infrastructure. And when you are thinking what the mission of VA is, [VA] sees this is part of their mission,” Mr. Morrison said.
The Defense Department announced its agreement with AstraZeneca in September, shortly before the drugmaker’s vaccine trial was put on hold to study a serious medical condition that one participant reported. That research was approved by the Food and Drug Administration to begin again Oct. 23. The military plans to restart its efforts to recruit 3,000 volunteers.
The Pentagon has also signed an agreement with another vaccine developer, the head of the Defense Health Agency, Army Lt. Gen. Ronald Place, told reporters Oct. 8. He wouldn’t provide the company’s name.
Senator Elizabeth Warren (D-Mass.) and Senator Mazie Hirono (D-Hawaii) have called, unsuccessfully, for the Senate Armed Services Committee to investigate what they say is a lack of Pentagon transparency on its role in vaccine development and distribution. The Defense Department has awarded more than $6 billion in Operation Warp Speed contracts through an intermediary, Advanced Technology International, and the two senators want more information about those contracts.
“There may well be a valuable role for DoD officials in [Operation Warp Speed] – particularly given the department’s logistical capacity,” they wrote to the committee chair and ranking member. “But it is important that Congress conduct appropriate oversight of, and understand, DoD’s activities in this area.”
Neither department has disclosed the financial arrangements they have made with developers to support the vaccine research.
Kaiser Health News is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.
according to officials with the VA and Operation Warp Speed, the Trump administration’s initiative to fast-track a coronavirus vaccine.
The largely unpublicized effort follows a Department of Defense announcement in September that it has partnered with AstraZeneca to recruit volunteers at five of its medical facilities, which are separate from the VA system. DOD is also is in talks with developers of other vaccine candidates, although officials won’t say which ones.
Both federal departments have long experience in medical research and diverse populations – a crucial component of effective clinical trials, said J. Stephen Morrison, senior vice president and director of global health policy at the Center for Strategic and International Studies, a bipartisan think tank in Washington.
Since active troops are essential to national security, and veterans are extremely vulnerable to COVID-19, both departments have a vested interest in supporting the development of safe, effective vaccines, Mr. Morrison said.
“On the DOD active servicemen and -women side, it’s a question of making sure they’re ready, they are protected,” Mr. Morrison said. “With VA, their population, all elderly and infirm with underlying conditions, they could really be suffering if we don’t get a vaccine.”
According to a VA website, of its 20 medical centers involved, 17 would be part of the Johnson & Johnson vaccine trial, while the three others are recruiting – or have completed recruitment – for advanced-stage trials for Moderna, AstraZeneca, and Pfizer vaccines.
Matthew Hepburn, MD, head of vaccine development at Operation Warp Speed, said the VA effort lets veterans contribute to the overall well-being of the country.
“This is another way they can continue to serve in this way, fighting the pandemic as a volunteer,” Dr. Hepburn said during a discussion of vaccine and therapeutics development hosted by the Heritage Foundation on Oct. 27.
It’s not unusual for the military to participate in multicenter trials for treatments of ailments as diverse as cancer and trauma. Historically, many vaccines have been tested first by the military.
In the general population, clinicians often have difficulty recruiting African Americans and other minorities for medical research, and “the military provides a rich opportunity to find volunteers for those groups,” said retired Rear Adm. Thomas Cullison, MD, a doctor and former deputy surgeon general for the Navy.
Military health facilities are held to the same standards as private research facilities, he said.
No service members will be required to participate in the COVID vaccine trials. All volunteers will be paid by the developer.
Support for routine vaccinations runs high in the military, but some have expressed concerns about new vaccines and mandatory inoculations, especially for anthrax. In a 2002 federal study, 85% of those who received that vaccine reported an adverse reaction, with just under half noticing minor redness at the injection site. But nearly a quarter of the side effects reported were more systemic, including fevers, chills, fatigue and joint pain.
That survey of a small group of National Guard and Reserve members found that, while 73% said they believe immunizations are effective, two-thirds said they did not support the mandatory anthrax program, and 6 in 10 said they were not satisfied with the information they were given on the vaccines.
To quell concerns over the military’s role in supporting COVID vaccine development, the Pentagon has reiterated that troops or their dependents interested in participating in the research must provide voluntary written consent, and they will be allowed to take part only if they will be in the same location for the length of the research, expected to last at least 2 years.
In addition, active-duty members such as new recruits and boot camp participants will not be allowed to volunteer because they are “considered vulnerable from an ethical and regulatory standpoint,” an official said.
At the VA, officials are seeking to recruit healthy veterans aged 18-65 years old who are not pregnant and may be at risk for exposure. As with trials conducted in civilian facilities, participants will be paid by the developer, VA spokesperson Christina Noel said.
Also, VA nurses and caseworkers also are being asked to identify their sickest, highest-risk patients to determine who should be at the top of the list once a vaccine is approved, according to a VA nurse and other health officials who asked not to be identified because they were not authorized to speak with the press.
The U.S. military has a long history of contributing to research on vaccines, including a key role in developing inoculations against yellow fever and adenovirus, and the Walter Reed Army Institute of Research is developing its own vaccine against the coronavirus.
Some segments of the population remain skeptical of federal medical experiments. A survey by AP-NORC in May found that Black people are particularly reluctant to get the coronavirus vaccine. Many have concerns about federal research in part because of associations with the infamous Tuskegee Institute syphilis experiments, in which U.S. Public Health Service officials intentionally withheld a cure from Black men infected with the disease.
But Mr. Morrison, of the Center for Strategic and International Studies, said the Defense Department and VA are a “natural fit” for the COVID vaccine trials.
“DOD has lots of expertise. They know how to vaccinate; they know how to reach communities. They have a whole science infrastructure and research-and-development infrastructure. And when you are thinking what the mission of VA is, [VA] sees this is part of their mission,” Mr. Morrison said.
The Defense Department announced its agreement with AstraZeneca in September, shortly before the drugmaker’s vaccine trial was put on hold to study a serious medical condition that one participant reported. That research was approved by the Food and Drug Administration to begin again Oct. 23. The military plans to restart its efforts to recruit 3,000 volunteers.
The Pentagon has also signed an agreement with another vaccine developer, the head of the Defense Health Agency, Army Lt. Gen. Ronald Place, told reporters Oct. 8. He wouldn’t provide the company’s name.
Senator Elizabeth Warren (D-Mass.) and Senator Mazie Hirono (D-Hawaii) have called, unsuccessfully, for the Senate Armed Services Committee to investigate what they say is a lack of Pentagon transparency on its role in vaccine development and distribution. The Defense Department has awarded more than $6 billion in Operation Warp Speed contracts through an intermediary, Advanced Technology International, and the two senators want more information about those contracts.
“There may well be a valuable role for DoD officials in [Operation Warp Speed] – particularly given the department’s logistical capacity,” they wrote to the committee chair and ranking member. “But it is important that Congress conduct appropriate oversight of, and understand, DoD’s activities in this area.”
Neither department has disclosed the financial arrangements they have made with developers to support the vaccine research.
Kaiser Health News is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.
Lions and tigers and anteaters? U.S. scientists scan the menagerie for COVID
As COVID-19 cases surge in the United States, one Texas veterinarian has been quietly tracking the spread of the disease – not in people, but in their pets.
Since June, Dr. Sarah Hamer and her team at Texas A&M University have tested hundreds of animals from area households where humans contracted COVID-19. They’ve swabbed dogs and cats, sure, but also pet hamsters and guinea pigs, looking for signs of infection. “We’re open to all of it,” said Dr. Hamer, a professor of epidemiology, who has found at least 19 cases of infection.
One pet that tested positive was Phoenix, a 7-year-old part Siamese cat owned by Kaitlyn Romoser, who works in a university lab. Ms. Romoser, 23, was confirmed to have COVID-19 twice, once in March and again in September. The second time she was much sicker, she said, and Phoenix was her constant companion.
“If I would have known animals were just getting it everywhere, I would have tried to distance myself, but he will not distance himself from me,” Ms. Romoser said. “He sleeps in my bed with me. There was absolutely no social distancing.”
Across the country, veterinarians and other researchers are scouring the animal kingdom for signs of the virus that causes COVID-19. At least 2,000 animals in the U.S. have been tested for the coronavirus since the pandemic began, according to federal records. Cats and dogs that were exposed to sick owners represent most of the animals tested and 80% of the positive cases found.
But scientists have cast a wide net investigating other animals that could be at risk. In states from California to Florida, researchers have tested species ranging from farmed minks and zoo cats to unexpected critters like dolphins, armadillos, and anteaters.
The U.S. Department of Agriculture keeps an official tally of confirmed animal COVID cases that stands at several dozen. But that list is a vast undercount of actual infections. In Utah and Wisconsin, for instance, more than 14,000 minks died in recent weeks after contracting COVID infections initially spread by humans.
So far, there’s limited evidence that animals are transmitting the virus to people. Veterinarians emphasize that pet owners appear to be in no danger from their animal companions and should continue to love and care for them. But scientists say continued testing is one way to remain vigilant in the face of a previously unknown pathogen.
“We just know that coronaviruses, as a family, infect a lot of species, mostly mammals,” said Dr. Peter Rabinowitz, a professor of environmental and occupational health sciences and the director of the University of Washington Center for One Health Research in Seattle. “It makes sense to take a species-spanning approach and look at a wide spectrum.”
Much of the testing has been rooted in scientific curiosity. Since the pandemic began, a major puzzle has been how the virus, which likely originated in bats, spread to humans. A leading theory is that it jumped to an intermediate species, still unknown, and then to people.
In April, a 4-year-old Malayan tiger at the Bronx Zoo tested positive for COVID-19 in a first-of-its-kind case after seven big cats showed signs of respiratory illness. The tiger, Nadia, contracted the virus from a caretaker, federal health officials said. Four other tigers and three African lions were also confirmed to be infected.
In Washington state, the site of the first U.S. outbreak in humans, scientists rushed to design a COVID test for animals in March, said Charlie Powell, a spokesperson for the Washington State University College of Veterinary Medicine, Pullman. “We knew with warm-blooded animals, housed together, there’s going to be some cross-infection,” he said. Tests for animals use different reagent compounds than those used for tests in people, so they don’t deplete the human supply, Mr. Powell added.
Since spring, the Washington Animal Disease Diagnostic Laboratory has tested nearly 80 animals, including 38 dogs, 29 cats, 2 ferrets, a camel, and 2 tamanduas, a type of anteater. The lab also tested six minks from the outbreak in Utah, five of which accounted for the lab’s only positive tests.
All told, nearly 1,400 animals have been tested for COVID-19 through the National Animal Health Laboratory Network or private labs, said Lyndsay Cole, a spokesperson for the USDA’s Animal and Plant Health Inspection Service. More than 400 animals have been tested through the National Veterinary Services Laboratories. At least 250 more have been tested through academic research projects.
Most of the tests have been in household cats and dogs with suspicious respiratory symptoms. In June, the USDA reported that a dog in New York was the first pet dog to test positive for the coronavirus after falling ill and struggling to breathe. The dog, a 7-year-old German shepherd named Buddy, later died. Officials determined he’d contracted the virus from his owner.
Neither the Centers for Disease Control and Prevention nor the USDA recommends routine testing for house pets or other animals – but that hasn’t stopped owners from asking, said Dr. Douglas Kratt, president of the American Veterinary Medical Association.
“The questions have become a little more consistent at my practice,” he said. “People do want to know about COVID-19 and their pets. Can their pet pick it up at a clinic or boarding or in doggie day care?”
The answer, so far, is that humans are the primary source of infection in pets. In September, a small, unpublished study from the University of Guelph in Canada found that companion cats and dogs appeared to be infected by their sick owners, judging by antibodies to the coronavirus detected in their blood.
In Texas, Dr. Hamer started testing animals from households where someone had contracted COVID-19 to learn more about transmission pathways. “Right now, we’re very much trying to describe what’s happening in nature,” she said.
So far, most of the animals – including Phoenix, Ms. Romoser’s cat – have shown no signs of illness or disease. That’s true so far for many species of animals tested for COVID-19, veterinarians said. Most nonhuman creatures appear to weather COVID infection with mild symptoms like sniffles and lethargy, if any.
Still, owners should apply best practices for avoiding COVID infection to pets, too, Dr. Kratt said. Don’t let pets come into contact with unfamiliar animals, he suggested. Owners should wash their hands frequently and avoid nuzzling and other very close contact, if possible.
Cats appear to be more susceptible to COVID-19 than dogs, researchers said. And minks, which are farmed in the U.S. and elsewhere for their fur, appear quite vulnerable.
In the meantime, the list of creatures tested for COVID-19 – whether for illness or science – is growing. In Florida, 22 animals had been tested as of early October, including 3 wild dolphins, 2 civets, 2 clouded leopards, a gorilla, an orangutan, an alpaca, and a bush baby, state officials said.
In California, 29 animals had been tested by the end of September, including a meerkat, a monkey, and a coatimundi, a member of the raccoon family.
In Seattle, a plan to test orcas, or killer whales, in Puget Sound was called off at the last minute after a member of the scientific team was exposed to COVID-19 and had to quarantine, said Dr. Joe Gaydos, a senior wildlife veterinarian and science director for the SeaDoc Society, a conservation program at the University of California-Davis. The group missed its September window to locate the animals and obtain breath and fecal samples for analysis.
No one thinks marine animals will play a big role in the pandemic decimating the human population, Dr. Gaydos said. But testing many creatures on both land and sea is vital.
“We don’t know what this virus is going to do or can do,” Dr. Gaydos said.
Kaiser Health News is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.
As COVID-19 cases surge in the United States, one Texas veterinarian has been quietly tracking the spread of the disease – not in people, but in their pets.
Since June, Dr. Sarah Hamer and her team at Texas A&M University have tested hundreds of animals from area households where humans contracted COVID-19. They’ve swabbed dogs and cats, sure, but also pet hamsters and guinea pigs, looking for signs of infection. “We’re open to all of it,” said Dr. Hamer, a professor of epidemiology, who has found at least 19 cases of infection.
One pet that tested positive was Phoenix, a 7-year-old part Siamese cat owned by Kaitlyn Romoser, who works in a university lab. Ms. Romoser, 23, was confirmed to have COVID-19 twice, once in March and again in September. The second time she was much sicker, she said, and Phoenix was her constant companion.
“If I would have known animals were just getting it everywhere, I would have tried to distance myself, but he will not distance himself from me,” Ms. Romoser said. “He sleeps in my bed with me. There was absolutely no social distancing.”
Across the country, veterinarians and other researchers are scouring the animal kingdom for signs of the virus that causes COVID-19. At least 2,000 animals in the U.S. have been tested for the coronavirus since the pandemic began, according to federal records. Cats and dogs that were exposed to sick owners represent most of the animals tested and 80% of the positive cases found.
But scientists have cast a wide net investigating other animals that could be at risk. In states from California to Florida, researchers have tested species ranging from farmed minks and zoo cats to unexpected critters like dolphins, armadillos, and anteaters.
The U.S. Department of Agriculture keeps an official tally of confirmed animal COVID cases that stands at several dozen. But that list is a vast undercount of actual infections. In Utah and Wisconsin, for instance, more than 14,000 minks died in recent weeks after contracting COVID infections initially spread by humans.
So far, there’s limited evidence that animals are transmitting the virus to people. Veterinarians emphasize that pet owners appear to be in no danger from their animal companions and should continue to love and care for them. But scientists say continued testing is one way to remain vigilant in the face of a previously unknown pathogen.
“We just know that coronaviruses, as a family, infect a lot of species, mostly mammals,” said Dr. Peter Rabinowitz, a professor of environmental and occupational health sciences and the director of the University of Washington Center for One Health Research in Seattle. “It makes sense to take a species-spanning approach and look at a wide spectrum.”
Much of the testing has been rooted in scientific curiosity. Since the pandemic began, a major puzzle has been how the virus, which likely originated in bats, spread to humans. A leading theory is that it jumped to an intermediate species, still unknown, and then to people.
In April, a 4-year-old Malayan tiger at the Bronx Zoo tested positive for COVID-19 in a first-of-its-kind case after seven big cats showed signs of respiratory illness. The tiger, Nadia, contracted the virus from a caretaker, federal health officials said. Four other tigers and three African lions were also confirmed to be infected.
In Washington state, the site of the first U.S. outbreak in humans, scientists rushed to design a COVID test for animals in March, said Charlie Powell, a spokesperson for the Washington State University College of Veterinary Medicine, Pullman. “We knew with warm-blooded animals, housed together, there’s going to be some cross-infection,” he said. Tests for animals use different reagent compounds than those used for tests in people, so they don’t deplete the human supply, Mr. Powell added.
Since spring, the Washington Animal Disease Diagnostic Laboratory has tested nearly 80 animals, including 38 dogs, 29 cats, 2 ferrets, a camel, and 2 tamanduas, a type of anteater. The lab also tested six minks from the outbreak in Utah, five of which accounted for the lab’s only positive tests.
All told, nearly 1,400 animals have been tested for COVID-19 through the National Animal Health Laboratory Network or private labs, said Lyndsay Cole, a spokesperson for the USDA’s Animal and Plant Health Inspection Service. More than 400 animals have been tested through the National Veterinary Services Laboratories. At least 250 more have been tested through academic research projects.
Most of the tests have been in household cats and dogs with suspicious respiratory symptoms. In June, the USDA reported that a dog in New York was the first pet dog to test positive for the coronavirus after falling ill and struggling to breathe. The dog, a 7-year-old German shepherd named Buddy, later died. Officials determined he’d contracted the virus from his owner.
Neither the Centers for Disease Control and Prevention nor the USDA recommends routine testing for house pets or other animals – but that hasn’t stopped owners from asking, said Dr. Douglas Kratt, president of the American Veterinary Medical Association.
“The questions have become a little more consistent at my practice,” he said. “People do want to know about COVID-19 and their pets. Can their pet pick it up at a clinic or boarding or in doggie day care?”
The answer, so far, is that humans are the primary source of infection in pets. In September, a small, unpublished study from the University of Guelph in Canada found that companion cats and dogs appeared to be infected by their sick owners, judging by antibodies to the coronavirus detected in their blood.
In Texas, Dr. Hamer started testing animals from households where someone had contracted COVID-19 to learn more about transmission pathways. “Right now, we’re very much trying to describe what’s happening in nature,” she said.
So far, most of the animals – including Phoenix, Ms. Romoser’s cat – have shown no signs of illness or disease. That’s true so far for many species of animals tested for COVID-19, veterinarians said. Most nonhuman creatures appear to weather COVID infection with mild symptoms like sniffles and lethargy, if any.
Still, owners should apply best practices for avoiding COVID infection to pets, too, Dr. Kratt said. Don’t let pets come into contact with unfamiliar animals, he suggested. Owners should wash their hands frequently and avoid nuzzling and other very close contact, if possible.
Cats appear to be more susceptible to COVID-19 than dogs, researchers said. And minks, which are farmed in the U.S. and elsewhere for their fur, appear quite vulnerable.
In the meantime, the list of creatures tested for COVID-19 – whether for illness or science – is growing. In Florida, 22 animals had been tested as of early October, including 3 wild dolphins, 2 civets, 2 clouded leopards, a gorilla, an orangutan, an alpaca, and a bush baby, state officials said.
In California, 29 animals had been tested by the end of September, including a meerkat, a monkey, and a coatimundi, a member of the raccoon family.
In Seattle, a plan to test orcas, or killer whales, in Puget Sound was called off at the last minute after a member of the scientific team was exposed to COVID-19 and had to quarantine, said Dr. Joe Gaydos, a senior wildlife veterinarian and science director for the SeaDoc Society, a conservation program at the University of California-Davis. The group missed its September window to locate the animals and obtain breath and fecal samples for analysis.
No one thinks marine animals will play a big role in the pandemic decimating the human population, Dr. Gaydos said. But testing many creatures on both land and sea is vital.
“We don’t know what this virus is going to do or can do,” Dr. Gaydos said.
Kaiser Health News is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.
As COVID-19 cases surge in the United States, one Texas veterinarian has been quietly tracking the spread of the disease – not in people, but in their pets.
Since June, Dr. Sarah Hamer and her team at Texas A&M University have tested hundreds of animals from area households where humans contracted COVID-19. They’ve swabbed dogs and cats, sure, but also pet hamsters and guinea pigs, looking for signs of infection. “We’re open to all of it,” said Dr. Hamer, a professor of epidemiology, who has found at least 19 cases of infection.
One pet that tested positive was Phoenix, a 7-year-old part Siamese cat owned by Kaitlyn Romoser, who works in a university lab. Ms. Romoser, 23, was confirmed to have COVID-19 twice, once in March and again in September. The second time she was much sicker, she said, and Phoenix was her constant companion.
“If I would have known animals were just getting it everywhere, I would have tried to distance myself, but he will not distance himself from me,” Ms. Romoser said. “He sleeps in my bed with me. There was absolutely no social distancing.”
Across the country, veterinarians and other researchers are scouring the animal kingdom for signs of the virus that causes COVID-19. At least 2,000 animals in the U.S. have been tested for the coronavirus since the pandemic began, according to federal records. Cats and dogs that were exposed to sick owners represent most of the animals tested and 80% of the positive cases found.
But scientists have cast a wide net investigating other animals that could be at risk. In states from California to Florida, researchers have tested species ranging from farmed minks and zoo cats to unexpected critters like dolphins, armadillos, and anteaters.
The U.S. Department of Agriculture keeps an official tally of confirmed animal COVID cases that stands at several dozen. But that list is a vast undercount of actual infections. In Utah and Wisconsin, for instance, more than 14,000 minks died in recent weeks after contracting COVID infections initially spread by humans.
So far, there’s limited evidence that animals are transmitting the virus to people. Veterinarians emphasize that pet owners appear to be in no danger from their animal companions and should continue to love and care for them. But scientists say continued testing is one way to remain vigilant in the face of a previously unknown pathogen.
“We just know that coronaviruses, as a family, infect a lot of species, mostly mammals,” said Dr. Peter Rabinowitz, a professor of environmental and occupational health sciences and the director of the University of Washington Center for One Health Research in Seattle. “It makes sense to take a species-spanning approach and look at a wide spectrum.”
Much of the testing has been rooted in scientific curiosity. Since the pandemic began, a major puzzle has been how the virus, which likely originated in bats, spread to humans. A leading theory is that it jumped to an intermediate species, still unknown, and then to people.
In April, a 4-year-old Malayan tiger at the Bronx Zoo tested positive for COVID-19 in a first-of-its-kind case after seven big cats showed signs of respiratory illness. The tiger, Nadia, contracted the virus from a caretaker, federal health officials said. Four other tigers and three African lions were also confirmed to be infected.
In Washington state, the site of the first U.S. outbreak in humans, scientists rushed to design a COVID test for animals in March, said Charlie Powell, a spokesperson for the Washington State University College of Veterinary Medicine, Pullman. “We knew with warm-blooded animals, housed together, there’s going to be some cross-infection,” he said. Tests for animals use different reagent compounds than those used for tests in people, so they don’t deplete the human supply, Mr. Powell added.
Since spring, the Washington Animal Disease Diagnostic Laboratory has tested nearly 80 animals, including 38 dogs, 29 cats, 2 ferrets, a camel, and 2 tamanduas, a type of anteater. The lab also tested six minks from the outbreak in Utah, five of which accounted for the lab’s only positive tests.
All told, nearly 1,400 animals have been tested for COVID-19 through the National Animal Health Laboratory Network or private labs, said Lyndsay Cole, a spokesperson for the USDA’s Animal and Plant Health Inspection Service. More than 400 animals have been tested through the National Veterinary Services Laboratories. At least 250 more have been tested through academic research projects.
Most of the tests have been in household cats and dogs with suspicious respiratory symptoms. In June, the USDA reported that a dog in New York was the first pet dog to test positive for the coronavirus after falling ill and struggling to breathe. The dog, a 7-year-old German shepherd named Buddy, later died. Officials determined he’d contracted the virus from his owner.
Neither the Centers for Disease Control and Prevention nor the USDA recommends routine testing for house pets or other animals – but that hasn’t stopped owners from asking, said Dr. Douglas Kratt, president of the American Veterinary Medical Association.
“The questions have become a little more consistent at my practice,” he said. “People do want to know about COVID-19 and their pets. Can their pet pick it up at a clinic or boarding or in doggie day care?”
The answer, so far, is that humans are the primary source of infection in pets. In September, a small, unpublished study from the University of Guelph in Canada found that companion cats and dogs appeared to be infected by their sick owners, judging by antibodies to the coronavirus detected in their blood.
In Texas, Dr. Hamer started testing animals from households where someone had contracted COVID-19 to learn more about transmission pathways. “Right now, we’re very much trying to describe what’s happening in nature,” she said.
So far, most of the animals – including Phoenix, Ms. Romoser’s cat – have shown no signs of illness or disease. That’s true so far for many species of animals tested for COVID-19, veterinarians said. Most nonhuman creatures appear to weather COVID infection with mild symptoms like sniffles and lethargy, if any.
Still, owners should apply best practices for avoiding COVID infection to pets, too, Dr. Kratt said. Don’t let pets come into contact with unfamiliar animals, he suggested. Owners should wash their hands frequently and avoid nuzzling and other very close contact, if possible.
Cats appear to be more susceptible to COVID-19 than dogs, researchers said. And minks, which are farmed in the U.S. and elsewhere for their fur, appear quite vulnerable.
In the meantime, the list of creatures tested for COVID-19 – whether for illness or science – is growing. In Florida, 22 animals had been tested as of early October, including 3 wild dolphins, 2 civets, 2 clouded leopards, a gorilla, an orangutan, an alpaca, and a bush baby, state officials said.
In California, 29 animals had been tested by the end of September, including a meerkat, a monkey, and a coatimundi, a member of the raccoon family.
In Seattle, a plan to test orcas, or killer whales, in Puget Sound was called off at the last minute after a member of the scientific team was exposed to COVID-19 and had to quarantine, said Dr. Joe Gaydos, a senior wildlife veterinarian and science director for the SeaDoc Society, a conservation program at the University of California-Davis. The group missed its September window to locate the animals and obtain breath and fecal samples for analysis.
No one thinks marine animals will play a big role in the pandemic decimating the human population, Dr. Gaydos said. But testing many creatures on both land and sea is vital.
“We don’t know what this virus is going to do or can do,” Dr. Gaydos said.
Kaiser Health News is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.
Low-dose radiotherapy for lung inflammation in severe COVID-19
The first study to suggest benefit from low-dose radiotherapy for severe COVID-19–induced pneumonia involved only 20 patients, but the results were so promising that two larger randomized trials are now underway.
“RESCUE-119 was a trial based on the hypothesis that low-dose radiation therapy may help eliminate the stormy cytokine release and unchecked edema in hospitalized COVID-19 patients,” said Mohammed Khan, MD, PhD, Winship Cancer Institute of Emory University, Atlanta.
“We found patients had a quicker improvement in their time to clinical recovery with low-dose radiation therapy, compared to controls, and this was significant even in this small cohort of patients,” he said.
Dr. Khan was speaking at a special press briefing held during the virtual American Society for Radiation Oncology Annual Meeting 2020.
A total of 20 patients were involved in the trial. Ten patients were treated with low-dose radiotherapy; 10 others, who served as control patients, were treated with the best supportive care and COVID-directed therapies. The control patients were matched for age and comorbidities. All these patients were hospitalized and were oxygen dependent, Dr. Khan noted. In addition, for all patients, serial x-rays demonstrated consolidation and damage in the lung.
The intervention consisted of whole-lung low-dose radiotherapy delivered at a dose of 1.5 Gy.
The first five patients were assessed at an interim endpoint of 7 days to confirm the safety of the procedure. Subsequently, a total of 10 patients were treated with radiotherapy and were followed to day 28.
The main study endpoints were time to clinical recovery, determined on the basis of the patient’s being taken off oxygen, and improvement, evidenced on either serial x-rays or by inflammatory biomarkers.
The median time to clinical recovery was almost three times faster for the patients who received low-dose radiotherapy, at a median of 3 days; for control patients, the median was 12 days (P = .048).
“We also saw a trend toward getting patients out of hospital sooner,” Dr. Khan added. The mean time to hospital discharge was 12 days for the patients who received low-dose radiotherapy, compared with 20 days for control patients (P = .19).
Only one patient required intubation after receiving low-dose radiotherapy, whereas 4 of 10 control patients required some sort of intubation (P = .12), he noted.
Investigators also saw improvements on serial x-rays in 9 of 10 patients treated with low-dose radiotherapy, compared with only 4 patients in the control group. There was also a significant improvement in delirium among the low-dose radiotherapy group compared with control patients (P < .01). Before receiving low-dose radiotherapy, C-reactive protein levels increased by 22% per day. After receiving the 1.5-Gy radiation treatment, there was a sharp reduction in C-reactive protein levels (P < .01) as well as in lactate dehydrogenase levels (P = .03).
Overall survival, however, did not differ between the two treatment groups; 90% of both groups were alive at day 28.
“By focally dampening cytokine hyperactivation, [low-dose radiotherapy] may improve COVID-19 outcomes through immunomodulation,” Dr. Khan explained.
VENTED and PRE-VENT trials
These results from the small RESCUE-119 trial led to the launch of two larger phase 2 trials, the VENTED and the PRE-VENT trials, noted Arnab Chakravarti, MD, professor and chair of radiation oncology, the Ohio State University Comprehensive Cancer Center, Columbus.
To be enrolled in the VENTED trial, patients must have received mechanical ventilation. They will receive at least one dose of ultra-low-dose bilateral whole-lung radiotherapy, with the option of receiving a second dose. The primary objective is 30-day mortality rate.
“The hypothesis is that low-dose thoracic radiation will decrease inflammation and improve outcomes for these intubated COVID-19 patients,” Dr. Chakravarti explained.
The PRE-VENT trial will explore low-dose thoracic radiotherapy for hospitalized patients with severe respiratory compromise who have not yet been intubated. Two doses of low-dose radiotherapy will be tested and compared. The primary study objective is to determine which of the two doses appears to be the most efficacious, Dr. Chakravarti noted.
“The ultimate question to which we remain agnostic is whether the potential benefits of low-dose radiation therapy outweigh the risks,” he said.
Low-dose radiotherapy is readily available in most countries, unlike the newly developed COVID-19 drugs, which are only available in the developed world, he noted. “This creates a bit more economic equity in terms of COVID-19 treatment.”
In addition, it may offer a therapeutic option that could be useful in the future, “as low-dose radiation therapy does not discriminate against various viruses that may cause another pandemic,” he commented. It could offer “a stopgap measure where we don’t have to shut down society completely, which, as we have all witnessed, can cause tremendous financial and social unrest.”
Reasonable question
Whether or not radiotherapy has value for the short-term management of severe pulmonary inflammation caused by COVID-19 is a reasonable question to evaluate in clinical trials, commented discussant Ramesh Rengan, MD, PhD, professor and chair, department of radiation oncology, University of Washington, Seattle.
He noted that inflammatory cells are highly sensitive to radiation, and low-dose radiotherapy has been used effectively in other inflammatory conditions, such as arthritis. Indeed, before the discovery of antibiotics, low-dose radiation was used with reasonable efficacy to treat pneumonia.
“The pneumonia associated with this viral infection is a bit unique in that what happens is the infection triggers an inflammatory cascade – the so-called cytokine storm – that essentially overwhelms the lungs, thereby leading, unfortunately, to mortality,” Dr. Rengan noted. “So a big focus of our energy is how to stop this inflammatory cascade from occurring.”
Corticosteroids are currently the only therapeutic intervention that has shown any mortality benefit in COVID-19, he pointed out.
The question now being asked is: “Can we suppress inflammation specifically within the lung?” Dr. Rengan continued. The main problem with radiotherapy is that it has different effects on various tissues, both immediately and over the long term.
“The immediate benefit that we will likely see from these studies is the immediate sterilization of inflammatory cells,” he said. However, injury to normal lung tissue from low-dose radiotherapy could lead to inflammation weeks or months later, and this could contribute to the disease burden and increase the risk of dying.
Dr. Rengan also noted that there are some very real practical concerns about offering radiotherapy to COVID-19 patients, including potential COVID-19 transmission to vulnerable cancer patients.
Nevertheless, Dr. Rengan said the results to date are very important and that ongoing trials will provide important new information about the long-term impact of this particular treatment in high-risk patients.
“This is a race to the bottom – we are trying to find the lowest possible dose of radiation therapy that we can deliver to sterilize these inflammatory cells without creating any harm to the surrounding tissue,” he said.
“It also brings radiation oncologists into the fight against this deadly disease,” he added.
Dr. Rengan has received honoraria from Novocur and has served as a consultant to AstraZeneca.
A version of this article originally appeared on Medscape.com.
The first study to suggest benefit from low-dose radiotherapy for severe COVID-19–induced pneumonia involved only 20 patients, but the results were so promising that two larger randomized trials are now underway.
“RESCUE-119 was a trial based on the hypothesis that low-dose radiation therapy may help eliminate the stormy cytokine release and unchecked edema in hospitalized COVID-19 patients,” said Mohammed Khan, MD, PhD, Winship Cancer Institute of Emory University, Atlanta.
“We found patients had a quicker improvement in their time to clinical recovery with low-dose radiation therapy, compared to controls, and this was significant even in this small cohort of patients,” he said.
Dr. Khan was speaking at a special press briefing held during the virtual American Society for Radiation Oncology Annual Meeting 2020.
A total of 20 patients were involved in the trial. Ten patients were treated with low-dose radiotherapy; 10 others, who served as control patients, were treated with the best supportive care and COVID-directed therapies. The control patients were matched for age and comorbidities. All these patients were hospitalized and were oxygen dependent, Dr. Khan noted. In addition, for all patients, serial x-rays demonstrated consolidation and damage in the lung.
The intervention consisted of whole-lung low-dose radiotherapy delivered at a dose of 1.5 Gy.
The first five patients were assessed at an interim endpoint of 7 days to confirm the safety of the procedure. Subsequently, a total of 10 patients were treated with radiotherapy and were followed to day 28.
The main study endpoints were time to clinical recovery, determined on the basis of the patient’s being taken off oxygen, and improvement, evidenced on either serial x-rays or by inflammatory biomarkers.
The median time to clinical recovery was almost three times faster for the patients who received low-dose radiotherapy, at a median of 3 days; for control patients, the median was 12 days (P = .048).
“We also saw a trend toward getting patients out of hospital sooner,” Dr. Khan added. The mean time to hospital discharge was 12 days for the patients who received low-dose radiotherapy, compared with 20 days for control patients (P = .19).
Only one patient required intubation after receiving low-dose radiotherapy, whereas 4 of 10 control patients required some sort of intubation (P = .12), he noted.
Investigators also saw improvements on serial x-rays in 9 of 10 patients treated with low-dose radiotherapy, compared with only 4 patients in the control group. There was also a significant improvement in delirium among the low-dose radiotherapy group compared with control patients (P < .01). Before receiving low-dose radiotherapy, C-reactive protein levels increased by 22% per day. After receiving the 1.5-Gy radiation treatment, there was a sharp reduction in C-reactive protein levels (P < .01) as well as in lactate dehydrogenase levels (P = .03).
Overall survival, however, did not differ between the two treatment groups; 90% of both groups were alive at day 28.
“By focally dampening cytokine hyperactivation, [low-dose radiotherapy] may improve COVID-19 outcomes through immunomodulation,” Dr. Khan explained.
VENTED and PRE-VENT trials
These results from the small RESCUE-119 trial led to the launch of two larger phase 2 trials, the VENTED and the PRE-VENT trials, noted Arnab Chakravarti, MD, professor and chair of radiation oncology, the Ohio State University Comprehensive Cancer Center, Columbus.
To be enrolled in the VENTED trial, patients must have received mechanical ventilation. They will receive at least one dose of ultra-low-dose bilateral whole-lung radiotherapy, with the option of receiving a second dose. The primary objective is 30-day mortality rate.
“The hypothesis is that low-dose thoracic radiation will decrease inflammation and improve outcomes for these intubated COVID-19 patients,” Dr. Chakravarti explained.
The PRE-VENT trial will explore low-dose thoracic radiotherapy for hospitalized patients with severe respiratory compromise who have not yet been intubated. Two doses of low-dose radiotherapy will be tested and compared. The primary study objective is to determine which of the two doses appears to be the most efficacious, Dr. Chakravarti noted.
“The ultimate question to which we remain agnostic is whether the potential benefits of low-dose radiation therapy outweigh the risks,” he said.
Low-dose radiotherapy is readily available in most countries, unlike the newly developed COVID-19 drugs, which are only available in the developed world, he noted. “This creates a bit more economic equity in terms of COVID-19 treatment.”
In addition, it may offer a therapeutic option that could be useful in the future, “as low-dose radiation therapy does not discriminate against various viruses that may cause another pandemic,” he commented. It could offer “a stopgap measure where we don’t have to shut down society completely, which, as we have all witnessed, can cause tremendous financial and social unrest.”
Reasonable question
Whether or not radiotherapy has value for the short-term management of severe pulmonary inflammation caused by COVID-19 is a reasonable question to evaluate in clinical trials, commented discussant Ramesh Rengan, MD, PhD, professor and chair, department of radiation oncology, University of Washington, Seattle.
He noted that inflammatory cells are highly sensitive to radiation, and low-dose radiotherapy has been used effectively in other inflammatory conditions, such as arthritis. Indeed, before the discovery of antibiotics, low-dose radiation was used with reasonable efficacy to treat pneumonia.
“The pneumonia associated with this viral infection is a bit unique in that what happens is the infection triggers an inflammatory cascade – the so-called cytokine storm – that essentially overwhelms the lungs, thereby leading, unfortunately, to mortality,” Dr. Rengan noted. “So a big focus of our energy is how to stop this inflammatory cascade from occurring.”
Corticosteroids are currently the only therapeutic intervention that has shown any mortality benefit in COVID-19, he pointed out.
The question now being asked is: “Can we suppress inflammation specifically within the lung?” Dr. Rengan continued. The main problem with radiotherapy is that it has different effects on various tissues, both immediately and over the long term.
“The immediate benefit that we will likely see from these studies is the immediate sterilization of inflammatory cells,” he said. However, injury to normal lung tissue from low-dose radiotherapy could lead to inflammation weeks or months later, and this could contribute to the disease burden and increase the risk of dying.
Dr. Rengan also noted that there are some very real practical concerns about offering radiotherapy to COVID-19 patients, including potential COVID-19 transmission to vulnerable cancer patients.
Nevertheless, Dr. Rengan said the results to date are very important and that ongoing trials will provide important new information about the long-term impact of this particular treatment in high-risk patients.
“This is a race to the bottom – we are trying to find the lowest possible dose of radiation therapy that we can deliver to sterilize these inflammatory cells without creating any harm to the surrounding tissue,” he said.
“It also brings radiation oncologists into the fight against this deadly disease,” he added.
Dr. Rengan has received honoraria from Novocur and has served as a consultant to AstraZeneca.
A version of this article originally appeared on Medscape.com.
The first study to suggest benefit from low-dose radiotherapy for severe COVID-19–induced pneumonia involved only 20 patients, but the results were so promising that two larger randomized trials are now underway.
“RESCUE-119 was a trial based on the hypothesis that low-dose radiation therapy may help eliminate the stormy cytokine release and unchecked edema in hospitalized COVID-19 patients,” said Mohammed Khan, MD, PhD, Winship Cancer Institute of Emory University, Atlanta.
“We found patients had a quicker improvement in their time to clinical recovery with low-dose radiation therapy, compared to controls, and this was significant even in this small cohort of patients,” he said.
Dr. Khan was speaking at a special press briefing held during the virtual American Society for Radiation Oncology Annual Meeting 2020.
A total of 20 patients were involved in the trial. Ten patients were treated with low-dose radiotherapy; 10 others, who served as control patients, were treated with the best supportive care and COVID-directed therapies. The control patients were matched for age and comorbidities. All these patients were hospitalized and were oxygen dependent, Dr. Khan noted. In addition, for all patients, serial x-rays demonstrated consolidation and damage in the lung.
The intervention consisted of whole-lung low-dose radiotherapy delivered at a dose of 1.5 Gy.
The first five patients were assessed at an interim endpoint of 7 days to confirm the safety of the procedure. Subsequently, a total of 10 patients were treated with radiotherapy and were followed to day 28.
The main study endpoints were time to clinical recovery, determined on the basis of the patient’s being taken off oxygen, and improvement, evidenced on either serial x-rays or by inflammatory biomarkers.
The median time to clinical recovery was almost three times faster for the patients who received low-dose radiotherapy, at a median of 3 days; for control patients, the median was 12 days (P = .048).
“We also saw a trend toward getting patients out of hospital sooner,” Dr. Khan added. The mean time to hospital discharge was 12 days for the patients who received low-dose radiotherapy, compared with 20 days for control patients (P = .19).
Only one patient required intubation after receiving low-dose radiotherapy, whereas 4 of 10 control patients required some sort of intubation (P = .12), he noted.
Investigators also saw improvements on serial x-rays in 9 of 10 patients treated with low-dose radiotherapy, compared with only 4 patients in the control group. There was also a significant improvement in delirium among the low-dose radiotherapy group compared with control patients (P < .01). Before receiving low-dose radiotherapy, C-reactive protein levels increased by 22% per day. After receiving the 1.5-Gy radiation treatment, there was a sharp reduction in C-reactive protein levels (P < .01) as well as in lactate dehydrogenase levels (P = .03).
Overall survival, however, did not differ between the two treatment groups; 90% of both groups were alive at day 28.
“By focally dampening cytokine hyperactivation, [low-dose radiotherapy] may improve COVID-19 outcomes through immunomodulation,” Dr. Khan explained.
VENTED and PRE-VENT trials
These results from the small RESCUE-119 trial led to the launch of two larger phase 2 trials, the VENTED and the PRE-VENT trials, noted Arnab Chakravarti, MD, professor and chair of radiation oncology, the Ohio State University Comprehensive Cancer Center, Columbus.
To be enrolled in the VENTED trial, patients must have received mechanical ventilation. They will receive at least one dose of ultra-low-dose bilateral whole-lung radiotherapy, with the option of receiving a second dose. The primary objective is 30-day mortality rate.
“The hypothesis is that low-dose thoracic radiation will decrease inflammation and improve outcomes for these intubated COVID-19 patients,” Dr. Chakravarti explained.
The PRE-VENT trial will explore low-dose thoracic radiotherapy for hospitalized patients with severe respiratory compromise who have not yet been intubated. Two doses of low-dose radiotherapy will be tested and compared. The primary study objective is to determine which of the two doses appears to be the most efficacious, Dr. Chakravarti noted.
“The ultimate question to which we remain agnostic is whether the potential benefits of low-dose radiation therapy outweigh the risks,” he said.
Low-dose radiotherapy is readily available in most countries, unlike the newly developed COVID-19 drugs, which are only available in the developed world, he noted. “This creates a bit more economic equity in terms of COVID-19 treatment.”
In addition, it may offer a therapeutic option that could be useful in the future, “as low-dose radiation therapy does not discriminate against various viruses that may cause another pandemic,” he commented. It could offer “a stopgap measure where we don’t have to shut down society completely, which, as we have all witnessed, can cause tremendous financial and social unrest.”
Reasonable question
Whether or not radiotherapy has value for the short-term management of severe pulmonary inflammation caused by COVID-19 is a reasonable question to evaluate in clinical trials, commented discussant Ramesh Rengan, MD, PhD, professor and chair, department of radiation oncology, University of Washington, Seattle.
He noted that inflammatory cells are highly sensitive to radiation, and low-dose radiotherapy has been used effectively in other inflammatory conditions, such as arthritis. Indeed, before the discovery of antibiotics, low-dose radiation was used with reasonable efficacy to treat pneumonia.
“The pneumonia associated with this viral infection is a bit unique in that what happens is the infection triggers an inflammatory cascade – the so-called cytokine storm – that essentially overwhelms the lungs, thereby leading, unfortunately, to mortality,” Dr. Rengan noted. “So a big focus of our energy is how to stop this inflammatory cascade from occurring.”
Corticosteroids are currently the only therapeutic intervention that has shown any mortality benefit in COVID-19, he pointed out.
The question now being asked is: “Can we suppress inflammation specifically within the lung?” Dr. Rengan continued. The main problem with radiotherapy is that it has different effects on various tissues, both immediately and over the long term.
“The immediate benefit that we will likely see from these studies is the immediate sterilization of inflammatory cells,” he said. However, injury to normal lung tissue from low-dose radiotherapy could lead to inflammation weeks or months later, and this could contribute to the disease burden and increase the risk of dying.
Dr. Rengan also noted that there are some very real practical concerns about offering radiotherapy to COVID-19 patients, including potential COVID-19 transmission to vulnerable cancer patients.
Nevertheless, Dr. Rengan said the results to date are very important and that ongoing trials will provide important new information about the long-term impact of this particular treatment in high-risk patients.
“This is a race to the bottom – we are trying to find the lowest possible dose of radiation therapy that we can deliver to sterilize these inflammatory cells without creating any harm to the surrounding tissue,” he said.
“It also brings radiation oncologists into the fight against this deadly disease,” he added.
Dr. Rengan has received honoraria from Novocur and has served as a consultant to AstraZeneca.
A version of this article originally appeared on Medscape.com.
Primary care journals address systemic racism in medicine
Sumi Sexton, MD, editor in chief of American Family Physician (AFP), said in an interview she had been working on changes at her journal that would answer the need for action that was made clear by this summer’s Black Lives Matter protests and realized the issue was much bigger than one journal. She proposed the collaboration with the other editors.
The editors wrote a joint statement explaining what they plan to do collectively. It was published online Oct. 15 ahead of print and will be published in all 10 journals at the beginning of the year.
Following the action by family medicine editors, the American College of Physicians issued a statement expressing commitment to being an antiracist organization. It calls on all doctors to speak out against hate and discrimination and to act against institutional and systemic racism. The statement also apologizes for the organization’s own past actions: “ACP acknowledges and regrets its own historical organizational injustices and inequities, and past racism, discrimination and exclusionary practices throughout its history, whether intentional or unintentional, by act or omission.”
Family medicine journals plan changes
Changes will differ at each family medicine publication, according to Sexton and other interviewees. Some specific changes at AFP, for example, include creating a medical editor role dedicated to diversity, equity, and inclusion to ensure that content is not only accurate but also that more content addresses racism, Dr. Sexton said.
AFP is creating a Web page dedicated to diversity and will now capitalize the word “Black” in racial and cultural references. Recent calls for papers have included emphasis on finding authors from underrepresented groups and on mentoring new authors.
“We really need to enable our colleagues,” Dr. Sexton said.
The journals are also pooling their published research on topics of racism and inclusion and have established a joint bibliography.
The steps are important, Dr. Sexton said, because reform in research will start a “cascade of action” that will result in better patient care.
“Our mission is to care for the individual as a whole person,” Dr. Sexton said. “This is part of that mission.”
Increasing diversity on editorial boards
Family physician Kameron Leigh Matthews, MD, chief medical officer for the Veterans Health Administration, praised the journals’ plan.
She noted that the groups are addressing diversity on their editorial boards, as well as evaluating content. Effective change must also happen regarding the people reviewing the content, she said in an interview. “It has to be both.
“I’m very proud as a family physician that our editors came together and are giving the right response. It’s not enough to say we stand against racism. They’re actually offering concrete actions that they will take as editors, and that will influence health care,” she said.
Dr. Matthews pointed to an example of what can happen when the editorial process fails and racism is introduced in research.
She cited the retraction of an article in the Journal of the American Heart Association entitled, “Evolution of Race and Ethnicity Considerations for the Cardiology Workforce.” The article advocated for ending racial and ethnic preferences in undergraduate and medical school admissions.
The American Heart Association said the article concluded “incorrectly that Black and Hispanic trainees in medicine are less qualified than White and Asian trainees.” The article had “rightfully drawn criticism for its misrepresentations and conclusions,” the AHA said, adding that it would launch an investigation into how the article came to be published.
Dr. Matthews says that’s why it’s so important that, in their statement, the family medicine editors vow to address not only the content but also the editing process to avoid similar systemic lapses.
Dr. Matthews added that, because the proportion of physicians from underrepresented groups is small – only 5% of physicians are Black and 6% are Hispanic – it is vital, as recommended in the editors’ statement, to mentor researchers from underrepresented groups and to reach out to students and residents to be coauthors.
“To sit back and say there’s not enough to recruit from is not sufficient,” Dr. Matthews said. “You need to recognize that you need to assist with expanding the pool.”
She also said she would like to see the journals focus more heavily on solutions to racial disparities in health care rather than on pointing them out.
At the Journal of Family Practice (JFP), Editor in Chief John Hickner, MD, said adding diversity to the editorial board is a top priority. He also reiterated that diversity in top leadership is a concern across all the journals, inasmuch as only 1 of the 10 editors in chief is a person of color.
As an editor, he said, he will personally, as well as through family medicine department chairs, be seeking authors who are members of underrepresented groups and that he will be assisting those who need help.
“I’m committed to giving them special attention in the editorial process,” he said.
Dr. Hickner said the 10 journals have also committed to periodically evaluate whether their approaches are making substantial changes. He said the editors have vowed to meet at least once a year to review progress “and hold each other accountable.”
Statement authors, in addition to Dr. Sexton and Dr. Hickner, include these editors in chief: Caroline R. Richardson, MD, Annals of Family Medicine; Sarina B. Schrager, MD, FPM; Marjorie A. Bowman, MD, The Journal of the American Board of Family Medicine; Christopher P. Morley, PhD, PRiMER; Nicholas Pimlott, MD, PhD, Canadian Family Physician; John W. Saultz, MD, Family Medicine; and Barry D. Weiss, MD, FP Essentials.
The authors have disclosed no relevant financial relationships. The Journal of Family Practice is owned by the same news organization as this publication.
A version of this article originally appeared on Medscape.com.
Sumi Sexton, MD, editor in chief of American Family Physician (AFP), said in an interview she had been working on changes at her journal that would answer the need for action that was made clear by this summer’s Black Lives Matter protests and realized the issue was much bigger than one journal. She proposed the collaboration with the other editors.
The editors wrote a joint statement explaining what they plan to do collectively. It was published online Oct. 15 ahead of print and will be published in all 10 journals at the beginning of the year.
Following the action by family medicine editors, the American College of Physicians issued a statement expressing commitment to being an antiracist organization. It calls on all doctors to speak out against hate and discrimination and to act against institutional and systemic racism. The statement also apologizes for the organization’s own past actions: “ACP acknowledges and regrets its own historical organizational injustices and inequities, and past racism, discrimination and exclusionary practices throughout its history, whether intentional or unintentional, by act or omission.”
Family medicine journals plan changes
Changes will differ at each family medicine publication, according to Sexton and other interviewees. Some specific changes at AFP, for example, include creating a medical editor role dedicated to diversity, equity, and inclusion to ensure that content is not only accurate but also that more content addresses racism, Dr. Sexton said.
AFP is creating a Web page dedicated to diversity and will now capitalize the word “Black” in racial and cultural references. Recent calls for papers have included emphasis on finding authors from underrepresented groups and on mentoring new authors.
“We really need to enable our colleagues,” Dr. Sexton said.
The journals are also pooling their published research on topics of racism and inclusion and have established a joint bibliography.
The steps are important, Dr. Sexton said, because reform in research will start a “cascade of action” that will result in better patient care.
“Our mission is to care for the individual as a whole person,” Dr. Sexton said. “This is part of that mission.”
Increasing diversity on editorial boards
Family physician Kameron Leigh Matthews, MD, chief medical officer for the Veterans Health Administration, praised the journals’ plan.
She noted that the groups are addressing diversity on their editorial boards, as well as evaluating content. Effective change must also happen regarding the people reviewing the content, she said in an interview. “It has to be both.
“I’m very proud as a family physician that our editors came together and are giving the right response. It’s not enough to say we stand against racism. They’re actually offering concrete actions that they will take as editors, and that will influence health care,” she said.
Dr. Matthews pointed to an example of what can happen when the editorial process fails and racism is introduced in research.
She cited the retraction of an article in the Journal of the American Heart Association entitled, “Evolution of Race and Ethnicity Considerations for the Cardiology Workforce.” The article advocated for ending racial and ethnic preferences in undergraduate and medical school admissions.
The American Heart Association said the article concluded “incorrectly that Black and Hispanic trainees in medicine are less qualified than White and Asian trainees.” The article had “rightfully drawn criticism for its misrepresentations and conclusions,” the AHA said, adding that it would launch an investigation into how the article came to be published.
Dr. Matthews says that’s why it’s so important that, in their statement, the family medicine editors vow to address not only the content but also the editing process to avoid similar systemic lapses.
Dr. Matthews added that, because the proportion of physicians from underrepresented groups is small – only 5% of physicians are Black and 6% are Hispanic – it is vital, as recommended in the editors’ statement, to mentor researchers from underrepresented groups and to reach out to students and residents to be coauthors.
“To sit back and say there’s not enough to recruit from is not sufficient,” Dr. Matthews said. “You need to recognize that you need to assist with expanding the pool.”
She also said she would like to see the journals focus more heavily on solutions to racial disparities in health care rather than on pointing them out.
At the Journal of Family Practice (JFP), Editor in Chief John Hickner, MD, said adding diversity to the editorial board is a top priority. He also reiterated that diversity in top leadership is a concern across all the journals, inasmuch as only 1 of the 10 editors in chief is a person of color.
As an editor, he said, he will personally, as well as through family medicine department chairs, be seeking authors who are members of underrepresented groups and that he will be assisting those who need help.
“I’m committed to giving them special attention in the editorial process,” he said.
Dr. Hickner said the 10 journals have also committed to periodically evaluate whether their approaches are making substantial changes. He said the editors have vowed to meet at least once a year to review progress “and hold each other accountable.”
Statement authors, in addition to Dr. Sexton and Dr. Hickner, include these editors in chief: Caroline R. Richardson, MD, Annals of Family Medicine; Sarina B. Schrager, MD, FPM; Marjorie A. Bowman, MD, The Journal of the American Board of Family Medicine; Christopher P. Morley, PhD, PRiMER; Nicholas Pimlott, MD, PhD, Canadian Family Physician; John W. Saultz, MD, Family Medicine; and Barry D. Weiss, MD, FP Essentials.
The authors have disclosed no relevant financial relationships. The Journal of Family Practice is owned by the same news organization as this publication.
A version of this article originally appeared on Medscape.com.
Sumi Sexton, MD, editor in chief of American Family Physician (AFP), said in an interview she had been working on changes at her journal that would answer the need for action that was made clear by this summer’s Black Lives Matter protests and realized the issue was much bigger than one journal. She proposed the collaboration with the other editors.
The editors wrote a joint statement explaining what they plan to do collectively. It was published online Oct. 15 ahead of print and will be published in all 10 journals at the beginning of the year.
Following the action by family medicine editors, the American College of Physicians issued a statement expressing commitment to being an antiracist organization. It calls on all doctors to speak out against hate and discrimination and to act against institutional and systemic racism. The statement also apologizes for the organization’s own past actions: “ACP acknowledges and regrets its own historical organizational injustices and inequities, and past racism, discrimination and exclusionary practices throughout its history, whether intentional or unintentional, by act or omission.”
Family medicine journals plan changes
Changes will differ at each family medicine publication, according to Sexton and other interviewees. Some specific changes at AFP, for example, include creating a medical editor role dedicated to diversity, equity, and inclusion to ensure that content is not only accurate but also that more content addresses racism, Dr. Sexton said.
AFP is creating a Web page dedicated to diversity and will now capitalize the word “Black” in racial and cultural references. Recent calls for papers have included emphasis on finding authors from underrepresented groups and on mentoring new authors.
“We really need to enable our colleagues,” Dr. Sexton said.
The journals are also pooling their published research on topics of racism and inclusion and have established a joint bibliography.
The steps are important, Dr. Sexton said, because reform in research will start a “cascade of action” that will result in better patient care.
“Our mission is to care for the individual as a whole person,” Dr. Sexton said. “This is part of that mission.”
Increasing diversity on editorial boards
Family physician Kameron Leigh Matthews, MD, chief medical officer for the Veterans Health Administration, praised the journals’ plan.
She noted that the groups are addressing diversity on their editorial boards, as well as evaluating content. Effective change must also happen regarding the people reviewing the content, she said in an interview. “It has to be both.
“I’m very proud as a family physician that our editors came together and are giving the right response. It’s not enough to say we stand against racism. They’re actually offering concrete actions that they will take as editors, and that will influence health care,” she said.
Dr. Matthews pointed to an example of what can happen when the editorial process fails and racism is introduced in research.
She cited the retraction of an article in the Journal of the American Heart Association entitled, “Evolution of Race and Ethnicity Considerations for the Cardiology Workforce.” The article advocated for ending racial and ethnic preferences in undergraduate and medical school admissions.
The American Heart Association said the article concluded “incorrectly that Black and Hispanic trainees in medicine are less qualified than White and Asian trainees.” The article had “rightfully drawn criticism for its misrepresentations and conclusions,” the AHA said, adding that it would launch an investigation into how the article came to be published.
Dr. Matthews says that’s why it’s so important that, in their statement, the family medicine editors vow to address not only the content but also the editing process to avoid similar systemic lapses.
Dr. Matthews added that, because the proportion of physicians from underrepresented groups is small – only 5% of physicians are Black and 6% are Hispanic – it is vital, as recommended in the editors’ statement, to mentor researchers from underrepresented groups and to reach out to students and residents to be coauthors.
“To sit back and say there’s not enough to recruit from is not sufficient,” Dr. Matthews said. “You need to recognize that you need to assist with expanding the pool.”
She also said she would like to see the journals focus more heavily on solutions to racial disparities in health care rather than on pointing them out.
At the Journal of Family Practice (JFP), Editor in Chief John Hickner, MD, said adding diversity to the editorial board is a top priority. He also reiterated that diversity in top leadership is a concern across all the journals, inasmuch as only 1 of the 10 editors in chief is a person of color.
As an editor, he said, he will personally, as well as through family medicine department chairs, be seeking authors who are members of underrepresented groups and that he will be assisting those who need help.
“I’m committed to giving them special attention in the editorial process,” he said.
Dr. Hickner said the 10 journals have also committed to periodically evaluate whether their approaches are making substantial changes. He said the editors have vowed to meet at least once a year to review progress “and hold each other accountable.”
Statement authors, in addition to Dr. Sexton and Dr. Hickner, include these editors in chief: Caroline R. Richardson, MD, Annals of Family Medicine; Sarina B. Schrager, MD, FPM; Marjorie A. Bowman, MD, The Journal of the American Board of Family Medicine; Christopher P. Morley, PhD, PRiMER; Nicholas Pimlott, MD, PhD, Canadian Family Physician; John W. Saultz, MD, Family Medicine; and Barry D. Weiss, MD, FP Essentials.
The authors have disclosed no relevant financial relationships. The Journal of Family Practice is owned by the same news organization as this publication.
A version of this article originally appeared on Medscape.com.