MDedge Infectious Disease

The National Institutes of Health has launched a database to track COVID-19–related neurologic symptoms, complications, and outcomes as well as the effects of the virus on preexisting neurologic conditions.

“We know COVID-19 can disrupt multiple body systems, but the effects of the virus and the body’s response to COVID-19 infection on the brain, spinal cord, nerves, and muscle can be particularly devastating and contribute to persistence of disability even after the virus is cleared,” said Barbara Karp, MD, program director at the National Institute of Neurological Disorders and Stroke.

“There is an urgent need to understand COVID-19–related neurological problems, which not uncommonly include headaches, fatigue, cognitive difficulties, stroke, pain, and sleep disorders as well as some very rare complications of serious infections,” said Dr. Karp.

The COVID-19 NeuroDatabank/BioBank (NeuroCOVID) is funded by the NINDS. It was created and will be maintained by researchers at NYU Langone Health in New York.

The project is led by Andrea Troxel, ScD, professor of population health, and Eva Petkova, PhD, professor of population health and child and adolescent psychiatry, both at New York University.

“We’ve built a pretty comprehensive database that will accept deidentified patient information about new neurological issues that coincide with their COVID disease or worsening of preexisting neurological problems,” said Dr. Troxel. “In addition, we have a bio repository that will accept almost any kind of biological sample, such as blood, plasma, cerebrospinal fluid, and tissue,” she said.

“Neuroimages are very difficult to store because the files are so enormous, but we’ve had some questions about that, and we’re looking into whether we can accommodate neuroimages,” Dr. Troxel noted.

Dr. Troxel said a “blast of information and invitations” has gone out in an effort to acquire data and biospecimens. “We’ve been really pleased with the amount of interest already, interest not only from large academic medical centers, as you might expect, but also from some smaller stand-alone clinics and even some individuals who have either experienced some of these neurological problems of COVID or know those who have and are really eager to try to provide information,” she added.

Researchers interested in using data and biosamples from the database may submit requests to the NeuroCOVID Steering Committee. More information is available online on the NeuroCOVID website.

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

The National Institutes of Health has launched a database to track COVID-19–related neurologic symptoms, complications, and outcomes as well as the effects of the virus on preexisting neurologic conditions.

“We know COVID-19 can disrupt multiple body systems, but the effects of the virus and the body’s response to COVID-19 infection on the brain, spinal cord, nerves, and muscle can be particularly devastating and contribute to persistence of disability even after the virus is cleared,” said Barbara Karp, MD, program director at the National Institute of Neurological Disorders and Stroke.

“There is an urgent need to understand COVID-19–related neurological problems, which not uncommonly include headaches, fatigue, cognitive difficulties, stroke, pain, and sleep disorders as well as some very rare complications of serious infections,” said Dr. Karp.

The COVID-19 NeuroDatabank/BioBank (NeuroCOVID) is funded by the NINDS. It was created and will be maintained by researchers at NYU Langone Health in New York.

The project is led by Andrea Troxel, ScD, professor of population health, and Eva Petkova, PhD, professor of population health and child and adolescent psychiatry, both at New York University.

“We’ve built a pretty comprehensive database that will accept deidentified patient information about new neurological issues that coincide with their COVID disease or worsening of preexisting neurological problems,” said Dr. Troxel. “In addition, we have a bio repository that will accept almost any kind of biological sample, such as blood, plasma, cerebrospinal fluid, and tissue,” she said.

“Neuroimages are very difficult to store because the files are so enormous, but we’ve had some questions about that, and we’re looking into whether we can accommodate neuroimages,” Dr. Troxel noted.

Dr. Troxel said a “blast of information and invitations” has gone out in an effort to acquire data and biospecimens. “We’ve been really pleased with the amount of interest already, interest not only from large academic medical centers, as you might expect, but also from some smaller stand-alone clinics and even some individuals who have either experienced some of these neurological problems of COVID or know those who have and are really eager to try to provide information,” she added.

Researchers interested in using data and biosamples from the database may submit requests to the NeuroCOVID Steering Committee. More information is available online on the NeuroCOVID website.

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

The National Institutes of Health has launched a database to track COVID-19–related neurologic symptoms, complications, and outcomes as well as the effects of the virus on preexisting neurologic conditions.

“We know COVID-19 can disrupt multiple body systems, but the effects of the virus and the body’s response to COVID-19 infection on the brain, spinal cord, nerves, and muscle can be particularly devastating and contribute to persistence of disability even after the virus is cleared,” said Barbara Karp, MD, program director at the National Institute of Neurological Disorders and Stroke.

“There is an urgent need to understand COVID-19–related neurological problems, which not uncommonly include headaches, fatigue, cognitive difficulties, stroke, pain, and sleep disorders as well as some very rare complications of serious infections,” said Dr. Karp.

The COVID-19 NeuroDatabank/BioBank (NeuroCOVID) is funded by the NINDS. It was created and will be maintained by researchers at NYU Langone Health in New York.

The project is led by Andrea Troxel, ScD, professor of population health, and Eva Petkova, PhD, professor of population health and child and adolescent psychiatry, both at New York University.

“We’ve built a pretty comprehensive database that will accept deidentified patient information about new neurological issues that coincide with their COVID disease or worsening of preexisting neurological problems,” said Dr. Troxel. “In addition, we have a bio repository that will accept almost any kind of biological sample, such as blood, plasma, cerebrospinal fluid, and tissue,” she said.

“Neuroimages are very difficult to store because the files are so enormous, but we’ve had some questions about that, and we’re looking into whether we can accommodate neuroimages,” Dr. Troxel noted.

Dr. Troxel said a “blast of information and invitations” has gone out in an effort to acquire data and biospecimens. “We’ve been really pleased with the amount of interest already, interest not only from large academic medical centers, as you might expect, but also from some smaller stand-alone clinics and even some individuals who have either experienced some of these neurological problems of COVID or know those who have and are really eager to try to provide information,” she added.

Researchers interested in using data and biosamples from the database may submit requests to the NeuroCOVID Steering Committee. More information is available online on the NeuroCOVID website.

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

The United States is facing a “Category 5” storm as coronavirus variants begin to spread across the country, one of the nation’s top infectious disease experts said Sunday.

“We are going to see something like we have not seen yet in this country,” Michael Osterholm, PhD, MPH, director of the Center for Infectious Disease Research and Policy at the University of Minnesota, Minneapolis, said on NBC’s Meet the Press.

The United States has reported 467 cases of the coronavirus variant first identified in the United Kingdom, across 32 states, according to the CDC variant tracker. The United States has also reported three cases of the variant first identified in South Africa in South Carolina and Maryland. One case of the variant first identified in Brazil has been found in Minnesota.

Although overall COVID-19 cases and hospitalizations have declined during the past few weeks, another storm is brewing on the horizon with the variants, Dr. Osterholm told host Chuck Todd. The U.K. variant will likely cause a surge in COVID-19 cases during the next 6-14 weeks, he said. “You and I are sitting on this beach where it’s 70 degrees, perfectly blue skies, gentle breeze. But I see that hurricane 5, Category 5 or higher, 450 miles offshore. And telling people to evacuate on that nice blue sky day is going to be hard. But I can also tell you that hurricane is coming.”

Dr. Osterholm urged federal and state officials to vaccinate as many people as possible to reduce the oncoming storm. The United States has distributed 49.9 million doses and administered 31.1 million doses, according to the latest CDC data updated Sunday, including 25.2 million first doses and 5.6 million second doses.

Doling out more doses to older Americans, rather than holding onto the second dose of the two-shot regimen, is an urgent decision, Dr. Osterholm said.

“I think right now, in advance of this surge, we need to get as many one doses in as many people over 65 as we possibly can to reduce serious illnesses and deaths that are going to occur over the weeks ahead,” he said.

The U.K. variant will likely become the dominant coronavirus strain in the United States in coming weeks, Dr. Osterholm said, adding that COVID-19 vaccines should be able to protect against it. In the meantime, however, he’s worried that the variant will cause more infections and deaths until more people get vaccinated.

“What we have to do now is also anticipate this and understand that we’re going to have change quickly,” he said. “As fast as we’re opening restaurants, we’re likely going to be closing them in the near term.”

A version of this article first appeared on WebMD.com.

The United States is facing a “Category 5” storm as coronavirus variants begin to spread across the country, one of the nation’s top infectious disease experts said Sunday.

“We are going to see something like we have not seen yet in this country,” Michael Osterholm, PhD, MPH, director of the Center for Infectious Disease Research and Policy at the University of Minnesota, Minneapolis, said on NBC’s Meet the Press.

The United States has reported 467 cases of the coronavirus variant first identified in the United Kingdom, across 32 states, according to the CDC variant tracker. The United States has also reported three cases of the variant first identified in South Africa in South Carolina and Maryland. One case of the variant first identified in Brazil has been found in Minnesota.

Although overall COVID-19 cases and hospitalizations have declined during the past few weeks, another storm is brewing on the horizon with the variants, Dr. Osterholm told host Chuck Todd. The U.K. variant will likely cause a surge in COVID-19 cases during the next 6-14 weeks, he said. “You and I are sitting on this beach where it’s 70 degrees, perfectly blue skies, gentle breeze. But I see that hurricane 5, Category 5 or higher, 450 miles offshore. And telling people to evacuate on that nice blue sky day is going to be hard. But I can also tell you that hurricane is coming.”

Dr. Osterholm urged federal and state officials to vaccinate as many people as possible to reduce the oncoming storm. The United States has distributed 49.9 million doses and administered 31.1 million doses, according to the latest CDC data updated Sunday, including 25.2 million first doses and 5.6 million second doses.

Doling out more doses to older Americans, rather than holding onto the second dose of the two-shot regimen, is an urgent decision, Dr. Osterholm said.

“I think right now, in advance of this surge, we need to get as many one doses in as many people over 65 as we possibly can to reduce serious illnesses and deaths that are going to occur over the weeks ahead,” he said.

The U.K. variant will likely become the dominant coronavirus strain in the United States in coming weeks, Dr. Osterholm said, adding that COVID-19 vaccines should be able to protect against it. In the meantime, however, he’s worried that the variant will cause more infections and deaths until more people get vaccinated.

“What we have to do now is also anticipate this and understand that we’re going to have change quickly,” he said. “As fast as we’re opening restaurants, we’re likely going to be closing them in the near term.”

A version of this article first appeared on WebMD.com.

The United States is facing a “Category 5” storm as coronavirus variants begin to spread across the country, one of the nation’s top infectious disease experts said Sunday.

“We are going to see something like we have not seen yet in this country,” Michael Osterholm, PhD, MPH, director of the Center for Infectious Disease Research and Policy at the University of Minnesota, Minneapolis, said on NBC’s Meet the Press.

The United States has reported 467 cases of the coronavirus variant first identified in the United Kingdom, across 32 states, according to the CDC variant tracker. The United States has also reported three cases of the variant first identified in South Africa in South Carolina and Maryland. One case of the variant first identified in Brazil has been found in Minnesota.

Although overall COVID-19 cases and hospitalizations have declined during the past few weeks, another storm is brewing on the horizon with the variants, Dr. Osterholm told host Chuck Todd. The U.K. variant will likely cause a surge in COVID-19 cases during the next 6-14 weeks, he said. “You and I are sitting on this beach where it’s 70 degrees, perfectly blue skies, gentle breeze. But I see that hurricane 5, Category 5 or higher, 450 miles offshore. And telling people to evacuate on that nice blue sky day is going to be hard. But I can also tell you that hurricane is coming.”

Dr. Osterholm urged federal and state officials to vaccinate as many people as possible to reduce the oncoming storm. The United States has distributed 49.9 million doses and administered 31.1 million doses, according to the latest CDC data updated Sunday, including 25.2 million first doses and 5.6 million second doses.

Doling out more doses to older Americans, rather than holding onto the second dose of the two-shot regimen, is an urgent decision, Dr. Osterholm said.

“I think right now, in advance of this surge, we need to get as many one doses in as many people over 65 as we possibly can to reduce serious illnesses and deaths that are going to occur over the weeks ahead,” he said.

The U.K. variant will likely become the dominant coronavirus strain in the United States in coming weeks, Dr. Osterholm said, adding that COVID-19 vaccines should be able to protect against it. In the meantime, however, he’s worried that the variant will cause more infections and deaths until more people get vaccinated.

“What we have to do now is also anticipate this and understand that we’re going to have change quickly,” he said. “As fast as we’re opening restaurants, we’re likely going to be closing them in the near term.”

A version of this article first appeared on WebMD.com.

More people with fever and body aches are turning to NSAIDs to ease symptoms, but the drugs have come under new scrutiny as investigators work to determine whether they are a safe way to relieve the pain of COVID-19 vaccination or symptoms of the disease.

Early on in the pandemic, French health officials warned that NSAIDs, such as ibuprofen, could worsen coronavirus disease, and they recommended switching to acetaminophen instead.

The National Health Service in the United Kingdom followed with a similar recommendation for acetaminophen.

But the European Medicines Agency took a different approach, reporting “no scientific evidence” that NSAIDs could worsen COVID-19. The U.S. Food and Drug Administration also opted not to take a stance.

The debate prompted discussion on social media, with various reactions from around the world. It also inspired Craig Wilen, MD, PhD, from Yale University, New Haven, Conn., and associates to examine the effect of NSAIDs on COVID-19 infection and immune response. Their findings were published online Jan.20 in the Journal of Virology.

“It really bothered me that non–evidence-based decisions were driving the conversation,” Dr. Wilen said. “Millions of people are taking NSAIDs every day and clinical decisions about their care shouldn’t be made on a hypothesis.”

One theory is that NSAIDs alter susceptibility to infection by modifying ACE2. The drugs might also change the cell entry receptor for SARS-CoV-2, alter virus replication, or even modify the immune response.

British researchers, also questioning the safety of NSAIDs in patients with COVID-19, delved into National Health Service records to study two large groups of patients, some of whom were taking the pain relievers.

“We were watching the controversy and the lack of evidence and wanted to contribute,” lead investigator Angel Wong, PhD, from the London School of Hygiene and Tropical Medicine, said in an interview.

And with nearly 11 million NSAID prescriptions dispensed in primary care in England alone in the past 12 months, the inconsistency was concerning.

The team compared COVID-19–related deaths in two groups: one group of more than 700,000 people taking NSAIDs, including patients with rheumatoid arthritis and osteoarthritis; and another of almost 3.5 million people not on the medication.

NSAIDs work by inhibiting cyclooxygenase-1 and COX-2 enzymes in the body, which are crucial for the generation of prostaglandins. These lipid molecules play a role in inflammation and are blocked by NSAIDs.

The investigators found no evidence of a harmful effect of NSAIDs on COVID-19-related deaths; their results were published online Jan. 21 in the Annals of the Rheumatic Diseases.

The results, they pointed out, are in line with a Danish study that also showed no evidence of a higher risk for severe COVID-19 outcomes with NSAID use.

“It’s reassuring,” Dr. Wong said, “that patients can safely continue treatment.”
 

More new evidence

Dr. Wilen’s team found that SARS-CoV-2 infection stimulated COX-2 expression in human and mice cells. However, suppression of COX-2 by two commonly used NSAIDs, ibuprofen and meloxicam, had no effect on ACE2 expression, viral entry, or viral replication.

In their mouse model of SARS-CoV-2 infection, the investigators saw that NSAIDs impaired the production of proinflammatory cytokines and neutralizing antibodies. The findings suggest that NSAIDs influence COVID-19 outcomes by dampening the inflammatory response and production of protective antibodies, rather than modifying susceptibility to infection or viral replication.

Understanding the effect of NSAIDs on cytokine production is critical, Dr. Wilen pointed out, because they might be protective early in COVID-19 but pathologic at later stages.

Timing is crucial in the case of other immunomodulatory drugs. For example, dexamethasone lowers mortality in COVID-19 patients on respiratory support but is potentially harmful for those with milder disease.

There still is a lot to learn, Dr. Wilen acknowledged. “We may be seeing something similar going on with NSAIDs, where the timing of treatment is important.”

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

More people with fever and body aches are turning to NSAIDs to ease symptoms, but the drugs have come under new scrutiny as investigators work to determine whether they are a safe way to relieve the pain of COVID-19 vaccination or symptoms of the disease.

Early on in the pandemic, French health officials warned that NSAIDs, such as ibuprofen, could worsen coronavirus disease, and they recommended switching to acetaminophen instead.

The National Health Service in the United Kingdom followed with a similar recommendation for acetaminophen.

But the European Medicines Agency took a different approach, reporting “no scientific evidence” that NSAIDs could worsen COVID-19. The U.S. Food and Drug Administration also opted not to take a stance.

The debate prompted discussion on social media, with various reactions from around the world. It also inspired Craig Wilen, MD, PhD, from Yale University, New Haven, Conn., and associates to examine the effect of NSAIDs on COVID-19 infection and immune response. Their findings were published online Jan.20 in the Journal of Virology.

“It really bothered me that non–evidence-based decisions were driving the conversation,” Dr. Wilen said. “Millions of people are taking NSAIDs every day and clinical decisions about their care shouldn’t be made on a hypothesis.”

One theory is that NSAIDs alter susceptibility to infection by modifying ACE2. The drugs might also change the cell entry receptor for SARS-CoV-2, alter virus replication, or even modify the immune response.

British researchers, also questioning the safety of NSAIDs in patients with COVID-19, delved into National Health Service records to study two large groups of patients, some of whom were taking the pain relievers.

“We were watching the controversy and the lack of evidence and wanted to contribute,” lead investigator Angel Wong, PhD, from the London School of Hygiene and Tropical Medicine, said in an interview.

And with nearly 11 million NSAID prescriptions dispensed in primary care in England alone in the past 12 months, the inconsistency was concerning.

The team compared COVID-19–related deaths in two groups: one group of more than 700,000 people taking NSAIDs, including patients with rheumatoid arthritis and osteoarthritis; and another of almost 3.5 million people not on the medication.

NSAIDs work by inhibiting cyclooxygenase-1 and COX-2 enzymes in the body, which are crucial for the generation of prostaglandins. These lipid molecules play a role in inflammation and are blocked by NSAIDs.

The investigators found no evidence of a harmful effect of NSAIDs on COVID-19-related deaths; their results were published online Jan. 21 in the Annals of the Rheumatic Diseases.

The results, they pointed out, are in line with a Danish study that also showed no evidence of a higher risk for severe COVID-19 outcomes with NSAID use.

“It’s reassuring,” Dr. Wong said, “that patients can safely continue treatment.”
 

More new evidence

Dr. Wilen’s team found that SARS-CoV-2 infection stimulated COX-2 expression in human and mice cells. However, suppression of COX-2 by two commonly used NSAIDs, ibuprofen and meloxicam, had no effect on ACE2 expression, viral entry, or viral replication.

In their mouse model of SARS-CoV-2 infection, the investigators saw that NSAIDs impaired the production of proinflammatory cytokines and neutralizing antibodies. The findings suggest that NSAIDs influence COVID-19 outcomes by dampening the inflammatory response and production of protective antibodies, rather than modifying susceptibility to infection or viral replication.

Understanding the effect of NSAIDs on cytokine production is critical, Dr. Wilen pointed out, because they might be protective early in COVID-19 but pathologic at later stages.

Timing is crucial in the case of other immunomodulatory drugs. For example, dexamethasone lowers mortality in COVID-19 patients on respiratory support but is potentially harmful for those with milder disease.

There still is a lot to learn, Dr. Wilen acknowledged. “We may be seeing something similar going on with NSAIDs, where the timing of treatment is important.”

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

More people with fever and body aches are turning to NSAIDs to ease symptoms, but the drugs have come under new scrutiny as investigators work to determine whether they are a safe way to relieve the pain of COVID-19 vaccination or symptoms of the disease.

Early on in the pandemic, French health officials warned that NSAIDs, such as ibuprofen, could worsen coronavirus disease, and they recommended switching to acetaminophen instead.

The National Health Service in the United Kingdom followed with a similar recommendation for acetaminophen.

But the European Medicines Agency took a different approach, reporting “no scientific evidence” that NSAIDs could worsen COVID-19. The U.S. Food and Drug Administration also opted not to take a stance.

The debate prompted discussion on social media, with various reactions from around the world. It also inspired Craig Wilen, MD, PhD, from Yale University, New Haven, Conn., and associates to examine the effect of NSAIDs on COVID-19 infection and immune response. Their findings were published online Jan.20 in the Journal of Virology.

“It really bothered me that non–evidence-based decisions were driving the conversation,” Dr. Wilen said. “Millions of people are taking NSAIDs every day and clinical decisions about their care shouldn’t be made on a hypothesis.”

One theory is that NSAIDs alter susceptibility to infection by modifying ACE2. The drugs might also change the cell entry receptor for SARS-CoV-2, alter virus replication, or even modify the immune response.

British researchers, also questioning the safety of NSAIDs in patients with COVID-19, delved into National Health Service records to study two large groups of patients, some of whom were taking the pain relievers.

“We were watching the controversy and the lack of evidence and wanted to contribute,” lead investigator Angel Wong, PhD, from the London School of Hygiene and Tropical Medicine, said in an interview.

And with nearly 11 million NSAID prescriptions dispensed in primary care in England alone in the past 12 months, the inconsistency was concerning.

The team compared COVID-19–related deaths in two groups: one group of more than 700,000 people taking NSAIDs, including patients with rheumatoid arthritis and osteoarthritis; and another of almost 3.5 million people not on the medication.

NSAIDs work by inhibiting cyclooxygenase-1 and COX-2 enzymes in the body, which are crucial for the generation of prostaglandins. These lipid molecules play a role in inflammation and are blocked by NSAIDs.

The investigators found no evidence of a harmful effect of NSAIDs on COVID-19-related deaths; their results were published online Jan. 21 in the Annals of the Rheumatic Diseases.

The results, they pointed out, are in line with a Danish study that also showed no evidence of a higher risk for severe COVID-19 outcomes with NSAID use.

“It’s reassuring,” Dr. Wong said, “that patients can safely continue treatment.”
 

More new evidence

Dr. Wilen’s team found that SARS-CoV-2 infection stimulated COX-2 expression in human and mice cells. However, suppression of COX-2 by two commonly used NSAIDs, ibuprofen and meloxicam, had no effect on ACE2 expression, viral entry, or viral replication.

In their mouse model of SARS-CoV-2 infection, the investigators saw that NSAIDs impaired the production of proinflammatory cytokines and neutralizing antibodies. The findings suggest that NSAIDs influence COVID-19 outcomes by dampening the inflammatory response and production of protective antibodies, rather than modifying susceptibility to infection or viral replication.

Understanding the effect of NSAIDs on cytokine production is critical, Dr. Wilen pointed out, because they might be protective early in COVID-19 but pathologic at later stages.

Timing is crucial in the case of other immunomodulatory drugs. For example, dexamethasone lowers mortality in COVID-19 patients on respiratory support but is potentially harmful for those with milder disease.

There still is a lot to learn, Dr. Wilen acknowledged. “We may be seeing something similar going on with NSAIDs, where the timing of treatment is important.”

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

Antibodies against SARS-CoV-2 cross the placenta during pregnancy and are detectable in most newborns born to mothers who had COVID-19 during pregnancy, according to findings from a study presented Jan. 28 at the meeting sponsored by the Society for Maternal-Fetal Medicine.

“I think the most striking finding is that we noticed a high degree of neutralizing response to natural infection even among asymptomatic infection, but of course a higher degree was seen in those with symptomatic infection,” Naima Joseph, MD, MPH, of Emory University, Atlanta, said in an interview.

“Our data demonstrate maternal capacity to mount an appropriate and robust immune response,” and maternal protective immunity lasted at least 28 days after infection, Dr. Joseph said. “Also, we noted higher neonatal cord blood titers in moms with higher titers, which suggests a relationship, but we need to better understand how transplacental transfer occurs as well as establish neonatal correlates of protection in order to see if and how maternal immunity may also benefit neonates.”

The researchers analyzed the amount of IgG and IgM antibodies in maternal and cord blood samples prospectively collected at delivery from women who tested positive for COVID-19 at any time while pregnant. They used enzyme-linked immunosorbent assay to assess for antibodies for the receptor binding domain of the SARS-CoV-2 spike protein.

The 32 pairs of mothers and infants in the study were predominantly non-Hispanic Black (72%) and Hispanic (25%), and 84% used Medicaid as their payer. Most of the mothers (72%) had at least one comorbidity, most commonly obesity, hypertension, and asthma or pulmonary disease. Just over half the women (53%) were symptomatic while they were infected, and 88% were ill with COVID-19 during the third trimester. The average time from infection to delivery was 28 days.

All the mothers had IgG antibodies, 94% had IgM antibodies, and 94% had neutralizing antibodies against SARS-CoV-2. Among the cord blood samples, 91% had IgG antibodies, 9% had IgM antibodies, and 25% had neutralizing antibodies.

“It’s reassuring that, so far, the physiological response is exactly what we expected it to be,” Judette Louis, MD, MPH, an associate professor of ob.gyn. and the ob.gyn. department chair at the University of South Florida, Tampa, said in an interview. “It’s what we would expect, but it’s always helpful to have more data to support that. Otherwise, you’re extrapolating from what you know from other conditions,” said Dr. Louis, who moderated the oral abstracts session.

Symptomatic infection was associated with significantly higher IgG titers than asymptomatic infection (P = .03), but no correlation was seen for IgM or neutralizing antibodies. In addition, although mothers who delivered more than 28 days after their infection had higher IgG titers (P = .05), no differences existed in IgM or neutralizing response.

Infants’ cord blood titers were significantly lower than their corresponding maternal samples, independently of symptoms or latency from infection to delivery (P < .001), Dr. Joseph reported.

“Transplacental efficiency in other pathogens has been shown to be correlated with neonatal immunity when the ratio of cord to maternal blood is greater than 1,” Dr. Joseph said in her presentation. Their data showed “suboptimal efficiency” at a ratio of 0.81.

The study’s small sample size and lack of a control group were weaknesses, but a major strength was having a population at disproportionately higher risk for infection and severe morbidity than the general population.
 

Implications for maternal COVID-19 vaccination

Although the data are not yet available, Dr. Joseph said they have expanded their protocol to include vaccinated pregnant women.

“The key to developing an effective vaccine [for pregnant people] is in really characterizing adaptive immunity in pregnancy,” Dr. Joseph told SMFM attendees. “I think that these findings inform further vaccine development in demonstrating that maternal immunity is robust.”

The World Health Organization recently recommended withholding COVID-19 vaccines from pregnant people, but the SMFM and American College of Obstetricians and Gynecologists subsequently issued a joint statement reaffirming that the COVID-19 vaccines authorized by the FDA “should not be withheld from pregnant individuals who choose to receive the vaccine.”

“One of the questions people ask is whether in pregnancy you’re going to mount a good response to the vaccine the way you would outside of pregnancy,” Dr. Louis said. “If we can demonstrate that you do, that may provide the information that some mothers need to make their decisions.” Data such as those from Dr. Joseph’s study can also inform recommendations on timing of maternal vaccination.

“For instance, Dr. Joseph demonstrated that, 28 days out from the infection, you had more antibodies, so there may be a scenario where we say this vaccine may be more beneficial in the middle of the pregnancy for the purpose of forming those antibodies,” Dr. Louis said.
 

Consensus emerging from maternal antibodies data

The findings from Dr. Joseph’s study mirror those reported in a study published online Jan. 29 in JAMA Pediatrics. That study, led by Dustin D. Flannery, DO, MSCE, of Children’s Hospital of Philadelphia, also examined maternal and neonatal levels of IgG and IgM antibodies against the receptor binding domain of the SARS-CoV-2 spike protein. They also found a positive correlation between cord blood and maternal IgG concentrations (P < .001), but notably, the ratio of cord to maternal blood titers was greater than 1, unlike in Dr. Joseph’s study.

For their study, Dr. Flannery and colleagues obtained maternal and cord blood sera at the time of delivery from 1471 pairs of mothers and infants, independently of COVID status during pregnancy. The average maternal age was 32 years, and just over a quarter of the population (26%) were Black, non-Hispanic women. About half (51%) were White, 12% were Hispanic, and 7% were Asian.

About 6% of the women had either IgG or IgM antibodies at delivery, and 87% of infants born to those mothers had measurable IgG in their cord blood. No infants had IgM antibodies. As with the study presented at SMFM, the mothers’ infections included asymptomatic, mild, moderate, and severe cases, and the degree of severity of cases had no apparent effect on infant antibody concentrations. Most of the women who tested positive for COVID-19 (60%) were asymptomatic.

Among the 11 mothers who had antibodies but whose infants’ cord blood did not, 5 had only IgM antibodies, and 6 had significantly lower IgG concentrations than those seen in the other mothers.

In a commentary about the JAMA Pediatrics study, Flor Munoz, MD, of the Baylor College of Medicine, Houston, suggested that the findings are grounds for optimism about a maternal vaccination strategy to protect infants from COVID-19.

“However, the timing of maternal vaccination to protect the infant, as opposed to the mother alone, would necessitate an adequate interval from vaccination to delivery (of at least 4 weeks), while vaccination early in gestation and even late in the third trimester could still be protective for the mother,” Dr. Munoz wrote.

Given the interval between two-dose vaccination regimens and the fact that transplacental transfer begins at about the 17th week of gestation, “maternal vaccination starting in the early second trimester of gestation might be optimal to achieve the highest levels of antibodies in the newborn,” Dr. Munoz wrote. But questions remain, such as how effective the neonatal antibodies would be in protecting against COVID-19 and how long they last after birth.

No external funding was used in Dr. Joseph’s study. Dr. Joseph and Dr. Louis have disclosed no relevant financial relationships. The JAMA Pediatrics study was funded by the Children’s Hospital of Philadelphia. One coauthor received consultancy fees from Sanofi Pasteur, Lumen, Novavax, and Merck unrelated to the study. Dr. Munoz served on the data and safety monitoring boards of Moderna, Pfizer, Virometix, and Meissa Vaccines and has received grants from Novavax Research and Gilead Research.

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

Antibodies against SARS-CoV-2 cross the placenta during pregnancy and are detectable in most newborns born to mothers who had COVID-19 during pregnancy, according to findings from a study presented Jan. 28 at the meeting sponsored by the Society for Maternal-Fetal Medicine.

“I think the most striking finding is that we noticed a high degree of neutralizing response to natural infection even among asymptomatic infection, but of course a higher degree was seen in those with symptomatic infection,” Naima Joseph, MD, MPH, of Emory University, Atlanta, said in an interview.

“Our data demonstrate maternal capacity to mount an appropriate and robust immune response,” and maternal protective immunity lasted at least 28 days after infection, Dr. Joseph said. “Also, we noted higher neonatal cord blood titers in moms with higher titers, which suggests a relationship, but we need to better understand how transplacental transfer occurs as well as establish neonatal correlates of protection in order to see if and how maternal immunity may also benefit neonates.”

The researchers analyzed the amount of IgG and IgM antibodies in maternal and cord blood samples prospectively collected at delivery from women who tested positive for COVID-19 at any time while pregnant. They used enzyme-linked immunosorbent assay to assess for antibodies for the receptor binding domain of the SARS-CoV-2 spike protein.

The 32 pairs of mothers and infants in the study were predominantly non-Hispanic Black (72%) and Hispanic (25%), and 84% used Medicaid as their payer. Most of the mothers (72%) had at least one comorbidity, most commonly obesity, hypertension, and asthma or pulmonary disease. Just over half the women (53%) were symptomatic while they were infected, and 88% were ill with COVID-19 during the third trimester. The average time from infection to delivery was 28 days.

All the mothers had IgG antibodies, 94% had IgM antibodies, and 94% had neutralizing antibodies against SARS-CoV-2. Among the cord blood samples, 91% had IgG antibodies, 9% had IgM antibodies, and 25% had neutralizing antibodies.

“It’s reassuring that, so far, the physiological response is exactly what we expected it to be,” Judette Louis, MD, MPH, an associate professor of ob.gyn. and the ob.gyn. department chair at the University of South Florida, Tampa, said in an interview. “It’s what we would expect, but it’s always helpful to have more data to support that. Otherwise, you’re extrapolating from what you know from other conditions,” said Dr. Louis, who moderated the oral abstracts session.

Symptomatic infection was associated with significantly higher IgG titers than asymptomatic infection (P = .03), but no correlation was seen for IgM or neutralizing antibodies. In addition, although mothers who delivered more than 28 days after their infection had higher IgG titers (P = .05), no differences existed in IgM or neutralizing response.

Infants’ cord blood titers were significantly lower than their corresponding maternal samples, independently of symptoms or latency from infection to delivery (P < .001), Dr. Joseph reported.

“Transplacental efficiency in other pathogens has been shown to be correlated with neonatal immunity when the ratio of cord to maternal blood is greater than 1,” Dr. Joseph said in her presentation. Their data showed “suboptimal efficiency” at a ratio of 0.81.

The study’s small sample size and lack of a control group were weaknesses, but a major strength was having a population at disproportionately higher risk for infection and severe morbidity than the general population.
 

Implications for maternal COVID-19 vaccination

Although the data are not yet available, Dr. Joseph said they have expanded their protocol to include vaccinated pregnant women.

“The key to developing an effective vaccine [for pregnant people] is in really characterizing adaptive immunity in pregnancy,” Dr. Joseph told SMFM attendees. “I think that these findings inform further vaccine development in demonstrating that maternal immunity is robust.”

The World Health Organization recently recommended withholding COVID-19 vaccines from pregnant people, but the SMFM and American College of Obstetricians and Gynecologists subsequently issued a joint statement reaffirming that the COVID-19 vaccines authorized by the FDA “should not be withheld from pregnant individuals who choose to receive the vaccine.”

“One of the questions people ask is whether in pregnancy you’re going to mount a good response to the vaccine the way you would outside of pregnancy,” Dr. Louis said. “If we can demonstrate that you do, that may provide the information that some mothers need to make their decisions.” Data such as those from Dr. Joseph’s study can also inform recommendations on timing of maternal vaccination.

“For instance, Dr. Joseph demonstrated that, 28 days out from the infection, you had more antibodies, so there may be a scenario where we say this vaccine may be more beneficial in the middle of the pregnancy for the purpose of forming those antibodies,” Dr. Louis said.
 

Consensus emerging from maternal antibodies data

The findings from Dr. Joseph’s study mirror those reported in a study published online Jan. 29 in JAMA Pediatrics. That study, led by Dustin D. Flannery, DO, MSCE, of Children’s Hospital of Philadelphia, also examined maternal and neonatal levels of IgG and IgM antibodies against the receptor binding domain of the SARS-CoV-2 spike protein. They also found a positive correlation between cord blood and maternal IgG concentrations (P < .001), but notably, the ratio of cord to maternal blood titers was greater than 1, unlike in Dr. Joseph’s study.

For their study, Dr. Flannery and colleagues obtained maternal and cord blood sera at the time of delivery from 1471 pairs of mothers and infants, independently of COVID status during pregnancy. The average maternal age was 32 years, and just over a quarter of the population (26%) were Black, non-Hispanic women. About half (51%) were White, 12% were Hispanic, and 7% were Asian.

About 6% of the women had either IgG or IgM antibodies at delivery, and 87% of infants born to those mothers had measurable IgG in their cord blood. No infants had IgM antibodies. As with the study presented at SMFM, the mothers’ infections included asymptomatic, mild, moderate, and severe cases, and the degree of severity of cases had no apparent effect on infant antibody concentrations. Most of the women who tested positive for COVID-19 (60%) were asymptomatic.

Among the 11 mothers who had antibodies but whose infants’ cord blood did not, 5 had only IgM antibodies, and 6 had significantly lower IgG concentrations than those seen in the other mothers.

In a commentary about the JAMA Pediatrics study, Flor Munoz, MD, of the Baylor College of Medicine, Houston, suggested that the findings are grounds for optimism about a maternal vaccination strategy to protect infants from COVID-19.

“However, the timing of maternal vaccination to protect the infant, as opposed to the mother alone, would necessitate an adequate interval from vaccination to delivery (of at least 4 weeks), while vaccination early in gestation and even late in the third trimester could still be protective for the mother,” Dr. Munoz wrote.

Given the interval between two-dose vaccination regimens and the fact that transplacental transfer begins at about the 17th week of gestation, “maternal vaccination starting in the early second trimester of gestation might be optimal to achieve the highest levels of antibodies in the newborn,” Dr. Munoz wrote. But questions remain, such as how effective the neonatal antibodies would be in protecting against COVID-19 and how long they last after birth.

No external funding was used in Dr. Joseph’s study. Dr. Joseph and Dr. Louis have disclosed no relevant financial relationships. The JAMA Pediatrics study was funded by the Children’s Hospital of Philadelphia. One coauthor received consultancy fees from Sanofi Pasteur, Lumen, Novavax, and Merck unrelated to the study. Dr. Munoz served on the data and safety monitoring boards of Moderna, Pfizer, Virometix, and Meissa Vaccines and has received grants from Novavax Research and Gilead Research.

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

Antibodies against SARS-CoV-2 cross the placenta during pregnancy and are detectable in most newborns born to mothers who had COVID-19 during pregnancy, according to findings from a study presented Jan. 28 at the meeting sponsored by the Society for Maternal-Fetal Medicine.

“I think the most striking finding is that we noticed a high degree of neutralizing response to natural infection even among asymptomatic infection, but of course a higher degree was seen in those with symptomatic infection,” Naima Joseph, MD, MPH, of Emory University, Atlanta, said in an interview.

“Our data demonstrate maternal capacity to mount an appropriate and robust immune response,” and maternal protective immunity lasted at least 28 days after infection, Dr. Joseph said. “Also, we noted higher neonatal cord blood titers in moms with higher titers, which suggests a relationship, but we need to better understand how transplacental transfer occurs as well as establish neonatal correlates of protection in order to see if and how maternal immunity may also benefit neonates.”

The researchers analyzed the amount of IgG and IgM antibodies in maternal and cord blood samples prospectively collected at delivery from women who tested positive for COVID-19 at any time while pregnant. They used enzyme-linked immunosorbent assay to assess for antibodies for the receptor binding domain of the SARS-CoV-2 spike protein.

The 32 pairs of mothers and infants in the study were predominantly non-Hispanic Black (72%) and Hispanic (25%), and 84% used Medicaid as their payer. Most of the mothers (72%) had at least one comorbidity, most commonly obesity, hypertension, and asthma or pulmonary disease. Just over half the women (53%) were symptomatic while they were infected, and 88% were ill with COVID-19 during the third trimester. The average time from infection to delivery was 28 days.

All the mothers had IgG antibodies, 94% had IgM antibodies, and 94% had neutralizing antibodies against SARS-CoV-2. Among the cord blood samples, 91% had IgG antibodies, 9% had IgM antibodies, and 25% had neutralizing antibodies.

“It’s reassuring that, so far, the physiological response is exactly what we expected it to be,” Judette Louis, MD, MPH, an associate professor of ob.gyn. and the ob.gyn. department chair at the University of South Florida, Tampa, said in an interview. “It’s what we would expect, but it’s always helpful to have more data to support that. Otherwise, you’re extrapolating from what you know from other conditions,” said Dr. Louis, who moderated the oral abstracts session.

Symptomatic infection was associated with significantly higher IgG titers than asymptomatic infection (P = .03), but no correlation was seen for IgM or neutralizing antibodies. In addition, although mothers who delivered more than 28 days after their infection had higher IgG titers (P = .05), no differences existed in IgM or neutralizing response.

Infants’ cord blood titers were significantly lower than their corresponding maternal samples, independently of symptoms or latency from infection to delivery (P < .001), Dr. Joseph reported.

“Transplacental efficiency in other pathogens has been shown to be correlated with neonatal immunity when the ratio of cord to maternal blood is greater than 1,” Dr. Joseph said in her presentation. Their data showed “suboptimal efficiency” at a ratio of 0.81.

The study’s small sample size and lack of a control group were weaknesses, but a major strength was having a population at disproportionately higher risk for infection and severe morbidity than the general population.
 

Implications for maternal COVID-19 vaccination

Although the data are not yet available, Dr. Joseph said they have expanded their protocol to include vaccinated pregnant women.

“The key to developing an effective vaccine [for pregnant people] is in really characterizing adaptive immunity in pregnancy,” Dr. Joseph told SMFM attendees. “I think that these findings inform further vaccine development in demonstrating that maternal immunity is robust.”

The World Health Organization recently recommended withholding COVID-19 vaccines from pregnant people, but the SMFM and American College of Obstetricians and Gynecologists subsequently issued a joint statement reaffirming that the COVID-19 vaccines authorized by the FDA “should not be withheld from pregnant individuals who choose to receive the vaccine.”

“One of the questions people ask is whether in pregnancy you’re going to mount a good response to the vaccine the way you would outside of pregnancy,” Dr. Louis said. “If we can demonstrate that you do, that may provide the information that some mothers need to make their decisions.” Data such as those from Dr. Joseph’s study can also inform recommendations on timing of maternal vaccination.

“For instance, Dr. Joseph demonstrated that, 28 days out from the infection, you had more antibodies, so there may be a scenario where we say this vaccine may be more beneficial in the middle of the pregnancy for the purpose of forming those antibodies,” Dr. Louis said.
 

Consensus emerging from maternal antibodies data

The findings from Dr. Joseph’s study mirror those reported in a study published online Jan. 29 in JAMA Pediatrics. That study, led by Dustin D. Flannery, DO, MSCE, of Children’s Hospital of Philadelphia, also examined maternal and neonatal levels of IgG and IgM antibodies against the receptor binding domain of the SARS-CoV-2 spike protein. They also found a positive correlation between cord blood and maternal IgG concentrations (P < .001), but notably, the ratio of cord to maternal blood titers was greater than 1, unlike in Dr. Joseph’s study.

For their study, Dr. Flannery and colleagues obtained maternal and cord blood sera at the time of delivery from 1471 pairs of mothers and infants, independently of COVID status during pregnancy. The average maternal age was 32 years, and just over a quarter of the population (26%) were Black, non-Hispanic women. About half (51%) were White, 12% were Hispanic, and 7% were Asian.

About 6% of the women had either IgG or IgM antibodies at delivery, and 87% of infants born to those mothers had measurable IgG in their cord blood. No infants had IgM antibodies. As with the study presented at SMFM, the mothers’ infections included asymptomatic, mild, moderate, and severe cases, and the degree of severity of cases had no apparent effect on infant antibody concentrations. Most of the women who tested positive for COVID-19 (60%) were asymptomatic.

Among the 11 mothers who had antibodies but whose infants’ cord blood did not, 5 had only IgM antibodies, and 6 had significantly lower IgG concentrations than those seen in the other mothers.

In a commentary about the JAMA Pediatrics study, Flor Munoz, MD, of the Baylor College of Medicine, Houston, suggested that the findings are grounds for optimism about a maternal vaccination strategy to protect infants from COVID-19.

“However, the timing of maternal vaccination to protect the infant, as opposed to the mother alone, would necessitate an adequate interval from vaccination to delivery (of at least 4 weeks), while vaccination early in gestation and even late in the third trimester could still be protective for the mother,” Dr. Munoz wrote.

Given the interval between two-dose vaccination regimens and the fact that transplacental transfer begins at about the 17th week of gestation, “maternal vaccination starting in the early second trimester of gestation might be optimal to achieve the highest levels of antibodies in the newborn,” Dr. Munoz wrote. But questions remain, such as how effective the neonatal antibodies would be in protecting against COVID-19 and how long they last after birth.

No external funding was used in Dr. Joseph’s study. Dr. Joseph and Dr. Louis have disclosed no relevant financial relationships. The JAMA Pediatrics study was funded by the Children’s Hospital of Philadelphia. One coauthor received consultancy fees from Sanofi Pasteur, Lumen, Novavax, and Merck unrelated to the study. Dr. Munoz served on the data and safety monitoring boards of Moderna, Pfizer, Virometix, and Meissa Vaccines and has received grants from Novavax Research and Gilead Research.

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

New data on COVID-19 vaccines should serve as a “wake-up call” about the need to stop the spread of the SARS-CoV-2 virus among people and thus deprive it of opportunities to evolve its defenses, the top federal expert on infectious diseases said.

“The virus will continue to mutate and will mutate for its own selective advantage,” said Anthony S. Fauci, MD, director of the National Institute of Allergy and Infectious Diseases, at a Friday news conference organized by the White House.

The continued transmission of SARS-CoV-2 “gives the virus the chance to adapt to the forces, in this case the immune response, that’s trying to get rid of it,” Dr. Fauci said. “That’s where you get mutations.”

Federal health officials are working to boost the U.S. supply of COVID-19 vaccines, even as signals emerge about the extent that the virus is already evolving.

Data released this week about the Janssen/Johnson & Johnson (J&J) and Novavax COVID-19 vaccines in late-stage development provides further evidence that they may not protect as well against emerging variants, Dr. Fauci said.

“Mutations that lead to different lineage do have clinical consequences,” he said, while also emphasizing that the emerging vaccines appear to confer broad protection. Dr. Fauci earlier in the day addressed the “messaging challenge” for clinicians and researchers in discussing the results of the J&J vaccine trial, which appear to fall short of those reported for the two vaccines already approved and in use in the United States. He noted the benefits of possibly soon having more authorized vaccines to combat COVID-19. But continued community spread of the infection will foster conditions that can undermine the vaccines’ effectiveness.

“Even though the long-range effect in the sense of severe disease is still handled reasonably well by the vaccines, this is a wake-up call to all of us,” Dr. Fauci said.

Pharmaceutical scientists and executives and government health officials will need to work together to continue to develop vaccines that can outwit the emerging variants, he said.

On Jan. 29, J&J reported that its highly anticipated single-dose vaccine had shown its worst results in South Africa where many cases of COVID-19 were caused by infection with a SARS-CoV-2 variant from the B.1.351 lineage. The overall efficacy was 66% globally, 72% in the United States, and 57% in South Africa against moderate to severe SARS-CoV-2, J&J said.

Novavax on Jan. 28 reported an efficacy rate for its COVID-19 vaccine of 49.4% from a clinical trial conducted in South Africa, compared with an 89.3% rate from a U.K. study. There already have been attempts to estimate how well the Pfizer/BioNTech and Moderna vaccines can handle new variants of the virus. They both have been granted emergency-use authorization by the U.S. Food and Drug Administration.
 

‘Genomic surveillance’

The Centers for Disease Control and Prevention on Thursday reported the first U.S.-documented cases of the B.1.351 variant of SARS-CoV-2 in South Carolina. On Jan. 26, the first confirmed U.S. case of a highly transmissible Brazilian coronavirus variant was detected in Minnesota, state health officials said.

The CDC’s stepped-up “genomic surveillance” will help keep clinicians and researchers aware of how SARS-CoV-2 is changing, Dr. Fauci said.

Speaking at the same White House news conference, CDC director Rochelle Walensky, MD, MPH, said the two South Carolina cases of the B.1.351 variant were reported in different parts of the state and not believed to be epidemiologically linked. The people involved “did not have any travel history,” she added.

The SARS-CoV-2 mutations were expected to emerge at some point, as with any virus, but their appearance underscores the need for people to remain vigilant about precautions that can stop its spread, Dr. Walensky said.

She and Dr. Fauci both stressed the need for continued use of masks and social distancing and urged people to get COVID-19 vaccines as they become available. Continued community spread of the virus allows this global health threat to keep replicating, and thus increases its chances to thwart medical interventions, Dr. Fauci said.

“The virus has a playing field, as it were, to mutate,” Dr. Fauci said. “If you stop that and stop the replication, the viruses cannot mutate if they don’t replicate.”

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

New data on COVID-19 vaccines should serve as a “wake-up call” about the need to stop the spread of the SARS-CoV-2 virus among people and thus deprive it of opportunities to evolve its defenses, the top federal expert on infectious diseases said.

“The virus will continue to mutate and will mutate for its own selective advantage,” said Anthony S. Fauci, MD, director of the National Institute of Allergy and Infectious Diseases, at a Friday news conference organized by the White House.

The continued transmission of SARS-CoV-2 “gives the virus the chance to adapt to the forces, in this case the immune response, that’s trying to get rid of it,” Dr. Fauci said. “That’s where you get mutations.”

Federal health officials are working to boost the U.S. supply of COVID-19 vaccines, even as signals emerge about the extent that the virus is already evolving.

Data released this week about the Janssen/Johnson & Johnson (J&J) and Novavax COVID-19 vaccines in late-stage development provides further evidence that they may not protect as well against emerging variants, Dr. Fauci said.

“Mutations that lead to different lineage do have clinical consequences,” he said, while also emphasizing that the emerging vaccines appear to confer broad protection. Dr. Fauci earlier in the day addressed the “messaging challenge” for clinicians and researchers in discussing the results of the J&J vaccine trial, which appear to fall short of those reported for the two vaccines already approved and in use in the United States. He noted the benefits of possibly soon having more authorized vaccines to combat COVID-19. But continued community spread of the infection will foster conditions that can undermine the vaccines’ effectiveness.

“Even though the long-range effect in the sense of severe disease is still handled reasonably well by the vaccines, this is a wake-up call to all of us,” Dr. Fauci said.

Pharmaceutical scientists and executives and government health officials will need to work together to continue to develop vaccines that can outwit the emerging variants, he said.

On Jan. 29, J&J reported that its highly anticipated single-dose vaccine had shown its worst results in South Africa where many cases of COVID-19 were caused by infection with a SARS-CoV-2 variant from the B.1.351 lineage. The overall efficacy was 66% globally, 72% in the United States, and 57% in South Africa against moderate to severe SARS-CoV-2, J&J said.

Novavax on Jan. 28 reported an efficacy rate for its COVID-19 vaccine of 49.4% from a clinical trial conducted in South Africa, compared with an 89.3% rate from a U.K. study. There already have been attempts to estimate how well the Pfizer/BioNTech and Moderna vaccines can handle new variants of the virus. They both have been granted emergency-use authorization by the U.S. Food and Drug Administration.
 

‘Genomic surveillance’

The Centers for Disease Control and Prevention on Thursday reported the first U.S.-documented cases of the B.1.351 variant of SARS-CoV-2 in South Carolina. On Jan. 26, the first confirmed U.S. case of a highly transmissible Brazilian coronavirus variant was detected in Minnesota, state health officials said.

The CDC’s stepped-up “genomic surveillance” will help keep clinicians and researchers aware of how SARS-CoV-2 is changing, Dr. Fauci said.

Speaking at the same White House news conference, CDC director Rochelle Walensky, MD, MPH, said the two South Carolina cases of the B.1.351 variant were reported in different parts of the state and not believed to be epidemiologically linked. The people involved “did not have any travel history,” she added.

The SARS-CoV-2 mutations were expected to emerge at some point, as with any virus, but their appearance underscores the need for people to remain vigilant about precautions that can stop its spread, Dr. Walensky said.

She and Dr. Fauci both stressed the need for continued use of masks and social distancing and urged people to get COVID-19 vaccines as they become available. Continued community spread of the virus allows this global health threat to keep replicating, and thus increases its chances to thwart medical interventions, Dr. Fauci said.

“The virus has a playing field, as it were, to mutate,” Dr. Fauci said. “If you stop that and stop the replication, the viruses cannot mutate if they don’t replicate.”

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

New data on COVID-19 vaccines should serve as a “wake-up call” about the need to stop the spread of the SARS-CoV-2 virus among people and thus deprive it of opportunities to evolve its defenses, the top federal expert on infectious diseases said.

“The virus will continue to mutate and will mutate for its own selective advantage,” said Anthony S. Fauci, MD, director of the National Institute of Allergy and Infectious Diseases, at a Friday news conference organized by the White House.

The continued transmission of SARS-CoV-2 “gives the virus the chance to adapt to the forces, in this case the immune response, that’s trying to get rid of it,” Dr. Fauci said. “That’s where you get mutations.”

Federal health officials are working to boost the U.S. supply of COVID-19 vaccines, even as signals emerge about the extent that the virus is already evolving.

Data released this week about the Janssen/Johnson & Johnson (J&J) and Novavax COVID-19 vaccines in late-stage development provides further evidence that they may not protect as well against emerging variants, Dr. Fauci said.

“Mutations that lead to different lineage do have clinical consequences,” he said, while also emphasizing that the emerging vaccines appear to confer broad protection. Dr. Fauci earlier in the day addressed the “messaging challenge” for clinicians and researchers in discussing the results of the J&J vaccine trial, which appear to fall short of those reported for the two vaccines already approved and in use in the United States. He noted the benefits of possibly soon having more authorized vaccines to combat COVID-19. But continued community spread of the infection will foster conditions that can undermine the vaccines’ effectiveness.

“Even though the long-range effect in the sense of severe disease is still handled reasonably well by the vaccines, this is a wake-up call to all of us,” Dr. Fauci said.

Pharmaceutical scientists and executives and government health officials will need to work together to continue to develop vaccines that can outwit the emerging variants, he said.

On Jan. 29, J&J reported that its highly anticipated single-dose vaccine had shown its worst results in South Africa where many cases of COVID-19 were caused by infection with a SARS-CoV-2 variant from the B.1.351 lineage. The overall efficacy was 66% globally, 72% in the United States, and 57% in South Africa against moderate to severe SARS-CoV-2, J&J said.

Novavax on Jan. 28 reported an efficacy rate for its COVID-19 vaccine of 49.4% from a clinical trial conducted in South Africa, compared with an 89.3% rate from a U.K. study. There already have been attempts to estimate how well the Pfizer/BioNTech and Moderna vaccines can handle new variants of the virus. They both have been granted emergency-use authorization by the U.S. Food and Drug Administration.
 

‘Genomic surveillance’

The Centers for Disease Control and Prevention on Thursday reported the first U.S.-documented cases of the B.1.351 variant of SARS-CoV-2 in South Carolina. On Jan. 26, the first confirmed U.S. case of a highly transmissible Brazilian coronavirus variant was detected in Minnesota, state health officials said.

The CDC’s stepped-up “genomic surveillance” will help keep clinicians and researchers aware of how SARS-CoV-2 is changing, Dr. Fauci said.

Speaking at the same White House news conference, CDC director Rochelle Walensky, MD, MPH, said the two South Carolina cases of the B.1.351 variant were reported in different parts of the state and not believed to be epidemiologically linked. The people involved “did not have any travel history,” she added.

The SARS-CoV-2 mutations were expected to emerge at some point, as with any virus, but their appearance underscores the need for people to remain vigilant about precautions that can stop its spread, Dr. Walensky said.

She and Dr. Fauci both stressed the need for continued use of masks and social distancing and urged people to get COVID-19 vaccines as they become available. Continued community spread of the virus allows this global health threat to keep replicating, and thus increases its chances to thwart medical interventions, Dr. Fauci said.

“The virus has a playing field, as it were, to mutate,” Dr. Fauci said. “If you stop that and stop the replication, the viruses cannot mutate if they don’t replicate.”

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

An international team of researchers studying COVID-19 has made a startling and pivotal discovery: The virus appears to cause the body to make weapons to attack its own tissues.

The finding could unlock a number of COVID-19’s clinical mysteries. They include the puzzling collection of symptoms that can come with the infection; the persistence of symptoms in some people for months after they clear the virus, a phenomenon dubbed long COVID-19; and why some children and adults have a serious inflammatory syndrome, called multisystem inflammatory syndrome in children (MIS-C) or MIS in adults (MIS-A), after their infections.

“It suggests that the virus might be directly causing autoimmunity, which would be fascinating,” says lead study author Paul Utz, MD, who studies immunology and autoimmunity at Stanford (Calif.) University.

The study also deepens the question of whether other respiratory viruses might also break the body’s tolerance to itself, setting people up for autoimmune diseases like multiple sclerosis, rheumatoid arthritis, and lupus later in life.

Dr. Utz said he and his team are next going to study flu patients to see if that virus might also cause this phenomenon.

“My prediction is that it isn’t going to be specific just to SARS-CoV-2. I’m willing to bet that we will find this with other respiratory viruses,” he said.

The study comes on the heels of a handful of smaller, detailed investigations that have come to similar conclusions.

The study included data from more than 300 patients from four hospitals: two in California, one in Pennsylvania, and another in Germany.

Researchers used blood tests to study their immune responses as their infections progressed. Researchers looked for autoantibodies – weapons of the immune system that go rogue and launch an attack against the body’s own tissues. They compared these autoantibodies with those found in people who were not infected with the virus that causes COVID.

As previous studies have found, autoantibodies were more common after COVID – 50% of people hospitalized for their infections had autoantibodies, compared with less than 15% of those who were healthy and uninfected.

Some people with autoantibodies had little change in them as their infections progressed. That suggests the autoantibodies were there to begin with, possibly allowing the infection to burn out of control in the body.

“Their body is set up to get bad COVID, and it’s probably caused by the autoantibodies,” Dr. Utz said.

But in others, about 20% of people who had them, the autoantibodies became more common as the infection progressed, suggesting they were directly related to the viral infection, instead of being a preexisting condition.

Some of these were antibodies that attack key components of the immune system’s weapons against the virus, like interferon. Interferons are proteins that help infected cells call for reinforcements and can also interfere with a virus’s ability to copy itself. Taking them out is a powerful evasive tactic, and previous studies have shown that people who are born with genes that cause them to have lower interferon function, or who make autoantibodies against these proteins, appear to be at higher risk for life-threatening COVID infections.

“It seems to give the virus a powerful advantage,” said study author, John Wherry, PhD, who directs the Institute for Immunology at the University of Pennsylvania, Philadelphia. “Now your immune system, instead of having a tiny little hill to climb, is staring at Mount Everest. That really is devious.”

In addition to those that sabotage the immune system, some people in the study had autoantibodies against muscles and connective tissues that are seen in some rare disorders.

Dr. Utz said they started the study after seeing COVID patients with strange collections of symptoms that looked more like autoimmune diseases than viral infections – skin rashes, joint pain, fatigue, aching muscles, brain swelling, dry eyes, blood that clots easily, and inflamed blood vessels.

“One thing that’s very important to note is that we don’t know if these patients are going to go on to develop autoimmune disease,” Dr. Utz said. “I think we’ll be able to answer that question in the next 6-12 months as we follow the long haulers and study their samples.”

Dr. Utz said it will be important to study autoantibodies in long haulers to see if they can identify exactly which ones seem to be at work in the condition. If you can catch them early, it might be possible to treat those at risk for enduring symptoms with drugs that suppress the immune system.

What this means, he said, is that COVID will be with us for a long, long time.

“We have to realize that there’s going to be long-term damage from this virus for the survivors. Not just the long haulers, but all the people who have lung damage and heart damage and everything else. We’re going to be studying this virus and it’s badness for decades,” Dr. Utz said.

A version of this article first appeared on WebMD.com.

An international team of researchers studying COVID-19 has made a startling and pivotal discovery: The virus appears to cause the body to make weapons to attack its own tissues.

The finding could unlock a number of COVID-19’s clinical mysteries. They include the puzzling collection of symptoms that can come with the infection; the persistence of symptoms in some people for months after they clear the virus, a phenomenon dubbed long COVID-19; and why some children and adults have a serious inflammatory syndrome, called multisystem inflammatory syndrome in children (MIS-C) or MIS in adults (MIS-A), after their infections.

“It suggests that the virus might be directly causing autoimmunity, which would be fascinating,” says lead study author Paul Utz, MD, who studies immunology and autoimmunity at Stanford (Calif.) University.

The study also deepens the question of whether other respiratory viruses might also break the body’s tolerance to itself, setting people up for autoimmune diseases like multiple sclerosis, rheumatoid arthritis, and lupus later in life.

Dr. Utz said he and his team are next going to study flu patients to see if that virus might also cause this phenomenon.

“My prediction is that it isn’t going to be specific just to SARS-CoV-2. I’m willing to bet that we will find this with other respiratory viruses,” he said.

The study comes on the heels of a handful of smaller, detailed investigations that have come to similar conclusions.

The study included data from more than 300 patients from four hospitals: two in California, one in Pennsylvania, and another in Germany.

Researchers used blood tests to study their immune responses as their infections progressed. Researchers looked for autoantibodies – weapons of the immune system that go rogue and launch an attack against the body’s own tissues. They compared these autoantibodies with those found in people who were not infected with the virus that causes COVID.

As previous studies have found, autoantibodies were more common after COVID – 50% of people hospitalized for their infections had autoantibodies, compared with less than 15% of those who were healthy and uninfected.

Some people with autoantibodies had little change in them as their infections progressed. That suggests the autoantibodies were there to begin with, possibly allowing the infection to burn out of control in the body.

“Their body is set up to get bad COVID, and it’s probably caused by the autoantibodies,” Dr. Utz said.

But in others, about 20% of people who had them, the autoantibodies became more common as the infection progressed, suggesting they were directly related to the viral infection, instead of being a preexisting condition.

Some of these were antibodies that attack key components of the immune system’s weapons against the virus, like interferon. Interferons are proteins that help infected cells call for reinforcements and can also interfere with a virus’s ability to copy itself. Taking them out is a powerful evasive tactic, and previous studies have shown that people who are born with genes that cause them to have lower interferon function, or who make autoantibodies against these proteins, appear to be at higher risk for life-threatening COVID infections.

“It seems to give the virus a powerful advantage,” said study author, John Wherry, PhD, who directs the Institute for Immunology at the University of Pennsylvania, Philadelphia. “Now your immune system, instead of having a tiny little hill to climb, is staring at Mount Everest. That really is devious.”

In addition to those that sabotage the immune system, some people in the study had autoantibodies against muscles and connective tissues that are seen in some rare disorders.

Dr. Utz said they started the study after seeing COVID patients with strange collections of symptoms that looked more like autoimmune diseases than viral infections – skin rashes, joint pain, fatigue, aching muscles, brain swelling, dry eyes, blood that clots easily, and inflamed blood vessels.

“One thing that’s very important to note is that we don’t know if these patients are going to go on to develop autoimmune disease,” Dr. Utz said. “I think we’ll be able to answer that question in the next 6-12 months as we follow the long haulers and study their samples.”

Dr. Utz said it will be important to study autoantibodies in long haulers to see if they can identify exactly which ones seem to be at work in the condition. If you can catch them early, it might be possible to treat those at risk for enduring symptoms with drugs that suppress the immune system.

What this means, he said, is that COVID will be with us for a long, long time.

“We have to realize that there’s going to be long-term damage from this virus for the survivors. Not just the long haulers, but all the people who have lung damage and heart damage and everything else. We’re going to be studying this virus and it’s badness for decades,” Dr. Utz said.

A version of this article first appeared on WebMD.com.

An international team of researchers studying COVID-19 has made a startling and pivotal discovery: The virus appears to cause the body to make weapons to attack its own tissues.

The finding could unlock a number of COVID-19’s clinical mysteries. They include the puzzling collection of symptoms that can come with the infection; the persistence of symptoms in some people for months after they clear the virus, a phenomenon dubbed long COVID-19; and why some children and adults have a serious inflammatory syndrome, called multisystem inflammatory syndrome in children (MIS-C) or MIS in adults (MIS-A), after their infections.

“It suggests that the virus might be directly causing autoimmunity, which would be fascinating,” says lead study author Paul Utz, MD, who studies immunology and autoimmunity at Stanford (Calif.) University.

The study also deepens the question of whether other respiratory viruses might also break the body’s tolerance to itself, setting people up for autoimmune diseases like multiple sclerosis, rheumatoid arthritis, and lupus later in life.

Dr. Utz said he and his team are next going to study flu patients to see if that virus might also cause this phenomenon.

“My prediction is that it isn’t going to be specific just to SARS-CoV-2. I’m willing to bet that we will find this with other respiratory viruses,” he said.

The study comes on the heels of a handful of smaller, detailed investigations that have come to similar conclusions.

The study included data from more than 300 patients from four hospitals: two in California, one in Pennsylvania, and another in Germany.

Researchers used blood tests to study their immune responses as their infections progressed. Researchers looked for autoantibodies – weapons of the immune system that go rogue and launch an attack against the body’s own tissues. They compared these autoantibodies with those found in people who were not infected with the virus that causes COVID.

As previous studies have found, autoantibodies were more common after COVID – 50% of people hospitalized for their infections had autoantibodies, compared with less than 15% of those who were healthy and uninfected.

Some people with autoantibodies had little change in them as their infections progressed. That suggests the autoantibodies were there to begin with, possibly allowing the infection to burn out of control in the body.

“Their body is set up to get bad COVID, and it’s probably caused by the autoantibodies,” Dr. Utz said.

But in others, about 20% of people who had them, the autoantibodies became more common as the infection progressed, suggesting they were directly related to the viral infection, instead of being a preexisting condition.

Some of these were antibodies that attack key components of the immune system’s weapons against the virus, like interferon. Interferons are proteins that help infected cells call for reinforcements and can also interfere with a virus’s ability to copy itself. Taking them out is a powerful evasive tactic, and previous studies have shown that people who are born with genes that cause them to have lower interferon function, or who make autoantibodies against these proteins, appear to be at higher risk for life-threatening COVID infections.

“It seems to give the virus a powerful advantage,” said study author, John Wherry, PhD, who directs the Institute for Immunology at the University of Pennsylvania, Philadelphia. “Now your immune system, instead of having a tiny little hill to climb, is staring at Mount Everest. That really is devious.”

In addition to those that sabotage the immune system, some people in the study had autoantibodies against muscles and connective tissues that are seen in some rare disorders.

Dr. Utz said they started the study after seeing COVID patients with strange collections of symptoms that looked more like autoimmune diseases than viral infections – skin rashes, joint pain, fatigue, aching muscles, brain swelling, dry eyes, blood that clots easily, and inflamed blood vessels.

“One thing that’s very important to note is that we don’t know if these patients are going to go on to develop autoimmune disease,” Dr. Utz said. “I think we’ll be able to answer that question in the next 6-12 months as we follow the long haulers and study their samples.”

Dr. Utz said it will be important to study autoantibodies in long haulers to see if they can identify exactly which ones seem to be at work in the condition. If you can catch them early, it might be possible to treat those at risk for enduring symptoms with drugs that suppress the immune system.

What this means, he said, is that COVID will be with us for a long, long time.

“We have to realize that there’s going to be long-term damage from this virus for the survivors. Not just the long haulers, but all the people who have lung damage and heart damage and everything else. We’re going to be studying this virus and it’s badness for decades,” Dr. Utz said.

A version of this article first appeared on WebMD.com.

Ceftolozane-tazobactam (C/T) was found effective for treating pneumonia, intra-abdominal, and urinary tract infections caused by Pseudomonas aeruginosa, according to the results of a retrospective, observational study conducted in critically ill patients.

The multicenter, observational study assessed 95 patients who received C/T for P. aeruginosa serious infections, according to a report published online in the International Journal of Antimicrobial Agents.

C/T is a novel beta-lactam/ beta-lactamase inhibitor combination active against gram-negative bacteria including P. aeruginosa, “This paper presents the largest real-life experience published on C/T therapy for treating serious P. aeruginosa infections according to researchers Barbara Balandin, MD, of the Hospital Universitario Puerta de Hierro, Majadahonda, Spain, and colleagues.

The main infections treated were nosocomial pneumonia (56.2%), intra-abdominal infection (10.5%), tracheobronchitis (8.4%), and urinary tract infection (6.3%). Most infections were complicated with sepsis (49.5%) or septic shock (45.3%), and bacteremia (10.5%).

A total of 46 episodes were treated with high-dose C/T (3 g every 8 hours), and 38 episodes were treated with standard dosage (1.5 g every 8 hours). Almost half (44.2%) of the patients were treated with C/T monotherapy, and the remaining group received combination therapy with other antibiotics, according to the researchers.

The primary outcome of the study was to assess the efficacy and toxicity of C/T therapy. The secondary outcome was to evaluate the risk factors for all-cause 30-day mortality from the first day of therapy.

Favorable results

Most of the infections (93.7%) were severe and included the presence of sepsis (49.5%) or septic shock (45.3%). Bacteremia was observed in 15 (15.7%) patients. Bacteremia was secondary to nosocomial pneumonia in eight cases, catheter infection in five, urinary tract infection in one, and soft tissue infection in one. According to their susceptibility profiles, 46 (48.4%) of the strains were classified as extensively drug-resistant (XDR) P. aeruginosa and 35 (36.5%) were multidrug-resistant (MDR) P. aeruginosa.

Sixty-eight (71.6%) patients presented a favorable clinical response, which was defined as a resolution of presenting symptoms and signs of the infection by the end of therapy. An unfavorable clinical response was considered as persistence or worsening of the presenting symptoms and signs or death occurring during treatment with no other cause identified. Death associated with infection was defined as persistence of signs and symptoms of P. aeruginosa infection during C/T therapy with no other cause identified.

Microbiological eradication was documented in 42.1% (40/95) of the episodes. However, the global ICU mortality was still high, at 36.5%, with mortality mainly related to the severity of the infection.

Mortality was found to be significantly correlated with the Charlson Comorbidity Index (5.7 vs. 4.3; P = .04) and the need for life-supporting therapies such as vasopressors (66.6% vs. 46.9%; P = .03) and renal replacement therapy (46.6% vs. 18.1%; P = .002). In addition, mortality was significantly associated with a higher sequential organ failure assessment (SOFA) score during C/T therapy (SOFA1, SOFA 3, and SOFA 7; P < .001).

No significant differences in outcomes were correlated with demographic features, type and severity of infection, and dose of C/T. Also, there were no differences seen in outcomes between patients treated with C/T monotherapy and combined therapy (30.9% vs. 30.1%; P = .55).

“The lack of a positive effect from combined therapy suggests that C/T monotherapy may be sufficient for treating P. aeruginosa isolates that are susceptible to that agent,” the researchers suggested. “This study shows that C/T appears to be a suitable, effective, and safe drug for treating severe infections due to P. aeruginosa, highlighting nosocomial pneumonia caused by MDR/XDR P. aeruginosa in ICU patients with multiple comorbidities, such as immunosuppression, and needing life-sustaining therapies,” they concluded.

The authors reported that they had no outside funding source and had no conflicts of interest.

mlesney@mdedge.com

Ceftolozane-tazobactam (C/T) was found effective for treating pneumonia, intra-abdominal, and urinary tract infections caused by Pseudomonas aeruginosa, according to the results of a retrospective, observational study conducted in critically ill patients.

The multicenter, observational study assessed 95 patients who received C/T for P. aeruginosa serious infections, according to a report published online in the International Journal of Antimicrobial Agents.

C/T is a novel beta-lactam/ beta-lactamase inhibitor combination active against gram-negative bacteria including P. aeruginosa, “This paper presents the largest real-life experience published on C/T therapy for treating serious P. aeruginosa infections according to researchers Barbara Balandin, MD, of the Hospital Universitario Puerta de Hierro, Majadahonda, Spain, and colleagues.

The main infections treated were nosocomial pneumonia (56.2%), intra-abdominal infection (10.5%), tracheobronchitis (8.4%), and urinary tract infection (6.3%). Most infections were complicated with sepsis (49.5%) or septic shock (45.3%), and bacteremia (10.5%).

A total of 46 episodes were treated with high-dose C/T (3 g every 8 hours), and 38 episodes were treated with standard dosage (1.5 g every 8 hours). Almost half (44.2%) of the patients were treated with C/T monotherapy, and the remaining group received combination therapy with other antibiotics, according to the researchers.

The primary outcome of the study was to assess the efficacy and toxicity of C/T therapy. The secondary outcome was to evaluate the risk factors for all-cause 30-day mortality from the first day of therapy.

Favorable results

Most of the infections (93.7%) were severe and included the presence of sepsis (49.5%) or septic shock (45.3%). Bacteremia was observed in 15 (15.7%) patients. Bacteremia was secondary to nosocomial pneumonia in eight cases, catheter infection in five, urinary tract infection in one, and soft tissue infection in one. According to their susceptibility profiles, 46 (48.4%) of the strains were classified as extensively drug-resistant (XDR) P. aeruginosa and 35 (36.5%) were multidrug-resistant (MDR) P. aeruginosa.

Sixty-eight (71.6%) patients presented a favorable clinical response, which was defined as a resolution of presenting symptoms and signs of the infection by the end of therapy. An unfavorable clinical response was considered as persistence or worsening of the presenting symptoms and signs or death occurring during treatment with no other cause identified. Death associated with infection was defined as persistence of signs and symptoms of P. aeruginosa infection during C/T therapy with no other cause identified.

Microbiological eradication was documented in 42.1% (40/95) of the episodes. However, the global ICU mortality was still high, at 36.5%, with mortality mainly related to the severity of the infection.

Mortality was found to be significantly correlated with the Charlson Comorbidity Index (5.7 vs. 4.3; P = .04) and the need for life-supporting therapies such as vasopressors (66.6% vs. 46.9%; P = .03) and renal replacement therapy (46.6% vs. 18.1%; P = .002). In addition, mortality was significantly associated with a higher sequential organ failure assessment (SOFA) score during C/T therapy (SOFA1, SOFA 3, and SOFA 7; P < .001).

No significant differences in outcomes were correlated with demographic features, type and severity of infection, and dose of C/T. Also, there were no differences seen in outcomes between patients treated with C/T monotherapy and combined therapy (30.9% vs. 30.1%; P = .55).

“The lack of a positive effect from combined therapy suggests that C/T monotherapy may be sufficient for treating P. aeruginosa isolates that are susceptible to that agent,” the researchers suggested. “This study shows that C/T appears to be a suitable, effective, and safe drug for treating severe infections due to P. aeruginosa, highlighting nosocomial pneumonia caused by MDR/XDR P. aeruginosa in ICU patients with multiple comorbidities, such as immunosuppression, and needing life-sustaining therapies,” they concluded.

The authors reported that they had no outside funding source and had no conflicts of interest.

mlesney@mdedge.com

Ceftolozane-tazobactam (C/T) was found effective for treating pneumonia, intra-abdominal, and urinary tract infections caused by Pseudomonas aeruginosa, according to the results of a retrospective, observational study conducted in critically ill patients.

The multicenter, observational study assessed 95 patients who received C/T for P. aeruginosa serious infections, according to a report published online in the International Journal of Antimicrobial Agents.

C/T is a novel beta-lactam/ beta-lactamase inhibitor combination active against gram-negative bacteria including P. aeruginosa, “This paper presents the largest real-life experience published on C/T therapy for treating serious P. aeruginosa infections according to researchers Barbara Balandin, MD, of the Hospital Universitario Puerta de Hierro, Majadahonda, Spain, and colleagues.

The main infections treated were nosocomial pneumonia (56.2%), intra-abdominal infection (10.5%), tracheobronchitis (8.4%), and urinary tract infection (6.3%). Most infections were complicated with sepsis (49.5%) or septic shock (45.3%), and bacteremia (10.5%).

A total of 46 episodes were treated with high-dose C/T (3 g every 8 hours), and 38 episodes were treated with standard dosage (1.5 g every 8 hours). Almost half (44.2%) of the patients were treated with C/T monotherapy, and the remaining group received combination therapy with other antibiotics, according to the researchers.

The primary outcome of the study was to assess the efficacy and toxicity of C/T therapy. The secondary outcome was to evaluate the risk factors for all-cause 30-day mortality from the first day of therapy.

Favorable results

Most of the infections (93.7%) were severe and included the presence of sepsis (49.5%) or septic shock (45.3%). Bacteremia was observed in 15 (15.7%) patients. Bacteremia was secondary to nosocomial pneumonia in eight cases, catheter infection in five, urinary tract infection in one, and soft tissue infection in one. According to their susceptibility profiles, 46 (48.4%) of the strains were classified as extensively drug-resistant (XDR) P. aeruginosa and 35 (36.5%) were multidrug-resistant (MDR) P. aeruginosa.

Sixty-eight (71.6%) patients presented a favorable clinical response, which was defined as a resolution of presenting symptoms and signs of the infection by the end of therapy. An unfavorable clinical response was considered as persistence or worsening of the presenting symptoms and signs or death occurring during treatment with no other cause identified. Death associated with infection was defined as persistence of signs and symptoms of P. aeruginosa infection during C/T therapy with no other cause identified.

Microbiological eradication was documented in 42.1% (40/95) of the episodes. However, the global ICU mortality was still high, at 36.5%, with mortality mainly related to the severity of the infection.

Mortality was found to be significantly correlated with the Charlson Comorbidity Index (5.7 vs. 4.3; P = .04) and the need for life-supporting therapies such as vasopressors (66.6% vs. 46.9%; P = .03) and renal replacement therapy (46.6% vs. 18.1%; P = .002). In addition, mortality was significantly associated with a higher sequential organ failure assessment (SOFA) score during C/T therapy (SOFA1, SOFA 3, and SOFA 7; P < .001).

No significant differences in outcomes were correlated with demographic features, type and severity of infection, and dose of C/T. Also, there were no differences seen in outcomes between patients treated with C/T monotherapy and combined therapy (30.9% vs. 30.1%; P = .55).

“The lack of a positive effect from combined therapy suggests that C/T monotherapy may be sufficient for treating P. aeruginosa isolates that are susceptible to that agent,” the researchers suggested. “This study shows that C/T appears to be a suitable, effective, and safe drug for treating severe infections due to P. aeruginosa, highlighting nosocomial pneumonia caused by MDR/XDR P. aeruginosa in ICU patients with multiple comorbidities, such as immunosuppression, and needing life-sustaining therapies,” they concluded.

The authors reported that they had no outside funding source and had no conflicts of interest.

mlesney@mdedge.com

COVID-19 infection altered the gut microbiota of adult patients and caused depletion of several types of bacteria with known immunomodulatory properties, based on data from a cohort study of 100 patients with confirmed COVID-19 infections from two hospitals.

“As the GI tract is the largest immunological organ in the body and its resident microbiota are known to modulate host immune responses, we hypothesized that the gut microbiota is associated with host inflammatory immune responses in COVID19,” wrote Yun Kit Yeoh, PhD, of the Chinese University of Hong Kong, and colleagues.

In a study published in Gut, the researchers investigated patient microbiota by collecting blood, stool, and patient records between February and May 2020 from 100 confirmed SARS-CoV-2–infected patients in Hong Kong during hospitalization, as well as follow-up stool samples from 27 patients up to 30 days after they cleared the COVID-19 virus; these observations were compared with 78 non–COVID-19 controls.

Overall, 274 stool samples were sequenced. Samples collected from patients during hospitalization for COVID-19 were compared with non–COVID-19 controls. The presence of phylum Bacteroidetes was significantly higher in COVID-19 patients compared with controls (23.9% vs. 12.8%; P < .001), as were Actinobacteria (26.1% vs. 19.0%; P < .001).

After controlling for antibiotics, the investigators found that “differences between cohorts were primarily linked to enrichment of taxa such as Parabacteroides, Sutterella wadsworthensis, and Bacteroides caccae and depletion of Adlercreutzia equolifaciens, Dorea formicigenerans, and Clostridium leptum in COVID-19 relative to non-COVID-19” (P < .05). In addition, Faecalibacterium prausnitzii and Bifidobacterium bifidum were negatively correlated with COVID-19 severity after investigators controlled for patient age and antibiotic use (P < .05).

The researchers also examined bacteria in COVID-19 patients and controls in the context of cytokines and other inflammatory markers. “We hypothesized that these compositional changes play a role in exacerbating disease by contributing to dysregulation of the immune response,” they said.

In fact, species depleted in COVID-19 patients including included B. adolescentis, E. rectale, and F. prausnitzii were negatively correlated with inflammatory markers including CXCL10, IL-10, TNF-alpha, and CCL2.

In addition, 42 stool samples from 27 patients showed significantly distinct gut microbiota from controls up to 30 days (median, 6 days) after virus clearance, regardless of antibiotics use (P < .05), the researchers said.
 

Long-term data needed

The study findings were limited by several factors, including the potential confounding of microbial signatures associated with COVID-19 because of heterogeneous patient management in the clinical setting and the potential that gut microbiota reflects a patient’s health with no impact on disease severity, as well as lack of data on the role of antibiotics for severe and critical patients, the researchers noted. In addition, “gut microbiota composition is highly heterogeneous across human populations and changes in compositions reported here may not necessarily be reflected in patients with COVID-19 from other biogeographies,” they wrote.

The “longer follow-up of patients with COVID-19 (e.g., 3 months to 1 year after clearing the virus) is needed to address questions related to the duration of gut microbiota dysbiosis post recovery, link between microbiota dysbiosis and long-term persistent symptoms, and whether the dysbiosis or enrichment/depletion of specific gut microorganisms predisposes recovered individuals to future health problems,” they wrote.

However, the results suggest a likely role for gut microorganisms in host inflammatory responses to COVID-19 infection, and “underscore an urgent need to understand the specific roles of gut microorganisms in human immune function and systemic inflammation,” they concluded.
 

More than infectious

“A growing body of evidence suggests that severity of illness from COVID-19 is largely determined by the patient’s aberrant immune response to the virus,” Jatin Roper, MD, of Duke University, Durham, N.C., said in an interview. “Therefore, a critical question is: What patient factors determine this immune response? The gut microbiota closely interact with the host immune system and are altered in many immunological diseases,” he said. “Furthermore, the SARS-CoV-2 virus infects enterocytes in the intestine and causes symptomatic gastrointestinal disease in a subset of patients. Therefore, understanding a possible association between gut microbiota and COVID-19 may reveal microbial species involved in disease pathogenesis,” he emphasized.   

In the current study, “I was surprised to find that COVID-19 infection is associated with depletion of immunomodulatory gut bacteria,” said Dr. Roper. “An open question is whether these changes are caused by the SARS-CoV-2 virus and then result in altered immune response. Alternatively, the changes in gut microbiota may be a result of the immune response or other changes associated with the disease,” he said.

“COVID-19 is an immunological disease, not just an infectious disease,” explained Dr. Roper. “The gut microbiota may play an important role in the pathogenesis of the disease. Thus, specific gut microbes could one day be analyzed to risk stratify patients, or even modified to treat the disease,” he noted.
 

Beyond COVID-19

“Given the impact of the gut microbiota on health and disease, as well as the impact of diseases on the microbiota, I am not at all surprised to find that there were significant changes in the microbiota of COVID-19 patients and that these changes are associated with inflammatory cytokines, chemokines, and blood markers of tissue damage,” said Anthony Sung, MD, also of Duke University.

According to Dr. Sung, researchers have already been investigating possible connections between gut microbiota and other conditions such as Alzheimer’s disease, and it’s been hypothesized that these connections are mediated by interactions between the gut microbiota and the immune system.

“While this is an important paper in our understanding of COVID-19, and highlights the microbiome as a potential therapeutic target, we need to conduct clinical trials of microbiota-based interventions before we can fully realize the clinical implications of these findings,” he said.

The study was supported by the Health and Medical Research Fund, the Food and Health Bureau, The Government of the Hong Kong Special Administrative Region, and donations from Hui Hoy & Chow Sin Lan Charity Fund Limited, Pine and Crane Company Limited, Mr. Hui Ming, and The D.H. Chen Foundation. The researchers had no financial conflicts to disclose. Dr. Roper and Dr. Sung had no financial conflicts to disclose.

COVID-19 infection altered the gut microbiota of adult patients and caused depletion of several types of bacteria with known immunomodulatory properties, based on data from a cohort study of 100 patients with confirmed COVID-19 infections from two hospitals.

“As the GI tract is the largest immunological organ in the body and its resident microbiota are known to modulate host immune responses, we hypothesized that the gut microbiota is associated with host inflammatory immune responses in COVID19,” wrote Yun Kit Yeoh, PhD, of the Chinese University of Hong Kong, and colleagues.

In a study published in Gut, the researchers investigated patient microbiota by collecting blood, stool, and patient records between February and May 2020 from 100 confirmed SARS-CoV-2–infected patients in Hong Kong during hospitalization, as well as follow-up stool samples from 27 patients up to 30 days after they cleared the COVID-19 virus; these observations were compared with 78 non–COVID-19 controls.

Overall, 274 stool samples were sequenced. Samples collected from patients during hospitalization for COVID-19 were compared with non–COVID-19 controls. The presence of phylum Bacteroidetes was significantly higher in COVID-19 patients compared with controls (23.9% vs. 12.8%; P < .001), as were Actinobacteria (26.1% vs. 19.0%; P < .001).

After controlling for antibiotics, the investigators found that “differences between cohorts were primarily linked to enrichment of taxa such as Parabacteroides, Sutterella wadsworthensis, and Bacteroides caccae and depletion of Adlercreutzia equolifaciens, Dorea formicigenerans, and Clostridium leptum in COVID-19 relative to non-COVID-19” (P < .05). In addition, Faecalibacterium prausnitzii and Bifidobacterium bifidum were negatively correlated with COVID-19 severity after investigators controlled for patient age and antibiotic use (P < .05).

The researchers also examined bacteria in COVID-19 patients and controls in the context of cytokines and other inflammatory markers. “We hypothesized that these compositional changes play a role in exacerbating disease by contributing to dysregulation of the immune response,” they said.

In fact, species depleted in COVID-19 patients including included B. adolescentis, E. rectale, and F. prausnitzii were negatively correlated with inflammatory markers including CXCL10, IL-10, TNF-alpha, and CCL2.

In addition, 42 stool samples from 27 patients showed significantly distinct gut microbiota from controls up to 30 days (median, 6 days) after virus clearance, regardless of antibiotics use (P < .05), the researchers said.
 

Long-term data needed

The study findings were limited by several factors, including the potential confounding of microbial signatures associated with COVID-19 because of heterogeneous patient management in the clinical setting and the potential that gut microbiota reflects a patient’s health with no impact on disease severity, as well as lack of data on the role of antibiotics for severe and critical patients, the researchers noted. In addition, “gut microbiota composition is highly heterogeneous across human populations and changes in compositions reported here may not necessarily be reflected in patients with COVID-19 from other biogeographies,” they wrote.

The “longer follow-up of patients with COVID-19 (e.g., 3 months to 1 year after clearing the virus) is needed to address questions related to the duration of gut microbiota dysbiosis post recovery, link between microbiota dysbiosis and long-term persistent symptoms, and whether the dysbiosis or enrichment/depletion of specific gut microorganisms predisposes recovered individuals to future health problems,” they wrote.

However, the results suggest a likely role for gut microorganisms in host inflammatory responses to COVID-19 infection, and “underscore an urgent need to understand the specific roles of gut microorganisms in human immune function and systemic inflammation,” they concluded.
 

More than infectious

“A growing body of evidence suggests that severity of illness from COVID-19 is largely determined by the patient’s aberrant immune response to the virus,” Jatin Roper, MD, of Duke University, Durham, N.C., said in an interview. “Therefore, a critical question is: What patient factors determine this immune response? The gut microbiota closely interact with the host immune system and are altered in many immunological diseases,” he said. “Furthermore, the SARS-CoV-2 virus infects enterocytes in the intestine and causes symptomatic gastrointestinal disease in a subset of patients. Therefore, understanding a possible association between gut microbiota and COVID-19 may reveal microbial species involved in disease pathogenesis,” he emphasized.   

In the current study, “I was surprised to find that COVID-19 infection is associated with depletion of immunomodulatory gut bacteria,” said Dr. Roper. “An open question is whether these changes are caused by the SARS-CoV-2 virus and then result in altered immune response. Alternatively, the changes in gut microbiota may be a result of the immune response or other changes associated with the disease,” he said.

“COVID-19 is an immunological disease, not just an infectious disease,” explained Dr. Roper. “The gut microbiota may play an important role in the pathogenesis of the disease. Thus, specific gut microbes could one day be analyzed to risk stratify patients, or even modified to treat the disease,” he noted.
 

Beyond COVID-19

“Given the impact of the gut microbiota on health and disease, as well as the impact of diseases on the microbiota, I am not at all surprised to find that there were significant changes in the microbiota of COVID-19 patients and that these changes are associated with inflammatory cytokines, chemokines, and blood markers of tissue damage,” said Anthony Sung, MD, also of Duke University.

According to Dr. Sung, researchers have already been investigating possible connections between gut microbiota and other conditions such as Alzheimer’s disease, and it’s been hypothesized that these connections are mediated by interactions between the gut microbiota and the immune system.

“While this is an important paper in our understanding of COVID-19, and highlights the microbiome as a potential therapeutic target, we need to conduct clinical trials of microbiota-based interventions before we can fully realize the clinical implications of these findings,” he said.

The study was supported by the Health and Medical Research Fund, the Food and Health Bureau, The Government of the Hong Kong Special Administrative Region, and donations from Hui Hoy & Chow Sin Lan Charity Fund Limited, Pine and Crane Company Limited, Mr. Hui Ming, and The D.H. Chen Foundation. The researchers had no financial conflicts to disclose. Dr. Roper and Dr. Sung had no financial conflicts to disclose.

COVID-19 infection altered the gut microbiota of adult patients and caused depletion of several types of bacteria with known immunomodulatory properties, based on data from a cohort study of 100 patients with confirmed COVID-19 infections from two hospitals.

“As the GI tract is the largest immunological organ in the body and its resident microbiota are known to modulate host immune responses, we hypothesized that the gut microbiota is associated with host inflammatory immune responses in COVID19,” wrote Yun Kit Yeoh, PhD, of the Chinese University of Hong Kong, and colleagues.

In a study published in Gut, the researchers investigated patient microbiota by collecting blood, stool, and patient records between February and May 2020 from 100 confirmed SARS-CoV-2–infected patients in Hong Kong during hospitalization, as well as follow-up stool samples from 27 patients up to 30 days after they cleared the COVID-19 virus; these observations were compared with 78 non–COVID-19 controls.

Overall, 274 stool samples were sequenced. Samples collected from patients during hospitalization for COVID-19 were compared with non–COVID-19 controls. The presence of phylum Bacteroidetes was significantly higher in COVID-19 patients compared with controls (23.9% vs. 12.8%; P < .001), as were Actinobacteria (26.1% vs. 19.0%; P < .001).

After controlling for antibiotics, the investigators found that “differences between cohorts were primarily linked to enrichment of taxa such as Parabacteroides, Sutterella wadsworthensis, and Bacteroides caccae and depletion of Adlercreutzia equolifaciens, Dorea formicigenerans, and Clostridium leptum in COVID-19 relative to non-COVID-19” (P < .05). In addition, Faecalibacterium prausnitzii and Bifidobacterium bifidum were negatively correlated with COVID-19 severity after investigators controlled for patient age and antibiotic use (P < .05).

The researchers also examined bacteria in COVID-19 patients and controls in the context of cytokines and other inflammatory markers. “We hypothesized that these compositional changes play a role in exacerbating disease by contributing to dysregulation of the immune response,” they said.

In fact, species depleted in COVID-19 patients including included B. adolescentis, E. rectale, and F. prausnitzii were negatively correlated with inflammatory markers including CXCL10, IL-10, TNF-alpha, and CCL2.

In addition, 42 stool samples from 27 patients showed significantly distinct gut microbiota from controls up to 30 days (median, 6 days) after virus clearance, regardless of antibiotics use (P < .05), the researchers said.
 

Long-term data needed

The study findings were limited by several factors, including the potential confounding of microbial signatures associated with COVID-19 because of heterogeneous patient management in the clinical setting and the potential that gut microbiota reflects a patient’s health with no impact on disease severity, as well as lack of data on the role of antibiotics for severe and critical patients, the researchers noted. In addition, “gut microbiota composition is highly heterogeneous across human populations and changes in compositions reported here may not necessarily be reflected in patients with COVID-19 from other biogeographies,” they wrote.

The “longer follow-up of patients with COVID-19 (e.g., 3 months to 1 year after clearing the virus) is needed to address questions related to the duration of gut microbiota dysbiosis post recovery, link between microbiota dysbiosis and long-term persistent symptoms, and whether the dysbiosis or enrichment/depletion of specific gut microorganisms predisposes recovered individuals to future health problems,” they wrote.

However, the results suggest a likely role for gut microorganisms in host inflammatory responses to COVID-19 infection, and “underscore an urgent need to understand the specific roles of gut microorganisms in human immune function and systemic inflammation,” they concluded.
 

More than infectious

“A growing body of evidence suggests that severity of illness from COVID-19 is largely determined by the patient’s aberrant immune response to the virus,” Jatin Roper, MD, of Duke University, Durham, N.C., said in an interview. “Therefore, a critical question is: What patient factors determine this immune response? The gut microbiota closely interact with the host immune system and are altered in many immunological diseases,” he said. “Furthermore, the SARS-CoV-2 virus infects enterocytes in the intestine and causes symptomatic gastrointestinal disease in a subset of patients. Therefore, understanding a possible association between gut microbiota and COVID-19 may reveal microbial species involved in disease pathogenesis,” he emphasized.   

In the current study, “I was surprised to find that COVID-19 infection is associated with depletion of immunomodulatory gut bacteria,” said Dr. Roper. “An open question is whether these changes are caused by the SARS-CoV-2 virus and then result in altered immune response. Alternatively, the changes in gut microbiota may be a result of the immune response or other changes associated with the disease,” he said.

“COVID-19 is an immunological disease, not just an infectious disease,” explained Dr. Roper. “The gut microbiota may play an important role in the pathogenesis of the disease. Thus, specific gut microbes could one day be analyzed to risk stratify patients, or even modified to treat the disease,” he noted.
 

Beyond COVID-19

“Given the impact of the gut microbiota on health and disease, as well as the impact of diseases on the microbiota, I am not at all surprised to find that there were significant changes in the microbiota of COVID-19 patients and that these changes are associated with inflammatory cytokines, chemokines, and blood markers of tissue damage,” said Anthony Sung, MD, also of Duke University.

According to Dr. Sung, researchers have already been investigating possible connections between gut microbiota and other conditions such as Alzheimer’s disease, and it’s been hypothesized that these connections are mediated by interactions between the gut microbiota and the immune system.

“While this is an important paper in our understanding of COVID-19, and highlights the microbiome as a potential therapeutic target, we need to conduct clinical trials of microbiota-based interventions before we can fully realize the clinical implications of these findings,” he said.

The study was supported by the Health and Medical Research Fund, the Food and Health Bureau, The Government of the Hong Kong Special Administrative Region, and donations from Hui Hoy & Chow Sin Lan Charity Fund Limited, Pine and Crane Company Limited, Mr. Hui Ming, and The D.H. Chen Foundation. The researchers had no financial conflicts to disclose. Dr. Roper and Dr. Sung had no financial conflicts to disclose.

The COVID-19 variants that have emerged in the United Kingdom, Brazil, South Africa and now Southern California are eliciting two notably distinct responses from U.S. public health officials.

janiecbros/iStock/Getty Images Plus

First, broad concern. A variant that wreaked havoc in the United Kingdom, leading to a spike in cases and hospitalizations, is surfacing in a growing number of places in the United States. During the week of Jan. 24, another worrisome variant seen in Brazil surfaced in Minnesota. If these or other strains significantly change the way the virus transmits and attacks the body, as scientists fear they might, they could cause yet another prolonged surge in illness and death in the U.S., even as cases have begun to plateau and vaccines are rolling out.

On the other hand, variants aren’t novel or even uncommon in viral illnesses. The viruses that trigger common colds and flus regularly evolve. Even if a mutated strain of SARS-CoV-2, the virus that causes COVID-19, makes it more contagious or makes people sicker, the basic public health response stays the same: Monitor the virus, and any mutations, as it moves across communities. Use masking, testing, physical distancing, and quarantine to contain the spread.

The problem is that the U.S. has struggled with every step of its public health response in its first year of battle against COVID-19. And that raises the question of whether the nation will devote the attention and resources needed to outflank the virus as it evolves.

Researchers are quick to stress that a coronavirus mutation in itself is no cause for alarm. In the course of making millions and billions of copies as part of the infection process, small changes to a virus’s genome happen all the time as a function of evolutionary biology.

“The word ‘variant’ and the word ‘mutation’ have these scary connotations, and they aren’t necessarily scary,” said Kelly Wroblewski, director of infectious disease programs for the Association of Public Health Laboratories.

When a mutation rings public health alarms, it’s typically because it has combined with other mutations and, collectively, changed how the virus behaves. At that point, it may be named a variant. A variant can make a virus spread faster, or more easily jump between species. It can make a virus more successful at making people sicker, or change how our immune systems respond.

SARS-CoV-2 has been mutating for as long as we’ve known about it; mutations were identified by scientists throughout 2020. Though relevant scientifically – mutations can actually be helpful, acting like a fingerprint that allows scientists to track a virus’s spread – the identified strains mostly carried little concern for public health.

Then came the end of the year, when several variants began drawing scrutiny. One of the most concerning, first detected in the United Kingdom, appears to make the virus more transmissible. Emerging evidence suggests it also could be deadlier, though scientists are still debating that.

We know more about the U.K. variant than others not because it’s necessarily worse, but because the British have one of the best virus surveillance programs in the world, said William Hanage, PhD, an epidemiologist and a professor at Harvard University.

By contrast, the U.S. has one of the weakest genomic surveillance programs of any rich country, Dr. Hanage said. “As it is, people like me cobble together partnerships with places and try and beg them” for samples, he said on a recent call with reporters.

Other variant strains were identified in South Africa and Brazil, and they share some mutations with the U.K. variant. That those changes evolved independently in several parts of the world suggests they might present an evolutionary advantage for the virus. Yet another strain was recently identified in Southern California and flagged due to its increasing presence in hard-hit cities like Los Angeles.

The Southern California strain was detected because a team of researchers at Cedars-Sinai, a hospital and research center in Los Angeles, has unfettered access to patient samples. They were able to see that the strain made up a growing share of cases at the hospital in recent weeks, as well as among the limited number of other samples haphazardly collected at a network of labs in the region.

Not only does the U.S. do less genomic sequencing than most wealthy countries, but it also does its surveillance by happenstance. That means it takes longer to detect new strains and draw conclusions about them. It’s not yet clear, for example, whether that Southern California strain was truly worthy of a press release.

Vast swaths of America’s privatized and decentralized system of health care aren’t set up to send samples to public health or academic labs. “I’m more concerned about the systems to detect variants than I am these particular variants,” said Mark Pandori, PhD, director of Nevada’s public health laboratory and associate professor at the University of Nevada-Reno School of Medicine.

Limited genomic surveillance of viruses is yet another side effect of a fragmented and underfunded public health system that’s struggled to test, track contacts and get COVID-19 under control throughout the pandemic, Ms. Wroblewski said.

The nation’s public health infrastructure, generally funded on a disease-by-disease basis, has decent systems set up to sequence flu, foodborne illnesses and tuberculosis, but there has been no national strategy on COVID-19. “To look for variants, it needs to be a national picture if it’s going to be done well,” Ms. Wroblewski said.

The Biden administration has outlined a strategy for a national response to COVID-19, which includes expanded surveillance for variants.

So far, vaccines for COVID-19 appear to protect against the known variants. Moderna has said its vaccine is effective against the U.K. and South African strains, though it yields fewer antibodies in the face of the latter. The company is working to develop a revised dose of the vaccine that could be added to the current two-shot regimen as a precaution.

But a lot of damage can be done in the time it will take to roll out the current vaccine, let alone an update.

Even with limited sampling, the U.K. variant has been detected in more than two dozen U.S. states, and the Centers for Disease Control and Prevention has warned it could be the predominant strain in the U.S. by March. When it took off in the United Kingdom at the end of last year, it caused a swell in cases, overwhelmed hospitals, and led to a holiday lockdown. Whether the U.S. faces the same fate could depend on which strains it is competing against, and how the public behaves in the weeks ahead.

Already risky interactions among people could, on average, get a little riskier. Many researchers are calling for better masks and better indoor ventilation. But any updates on recommendations likely would play at the margins. Even if variants spread more easily, the same recommendations public health experts have been espousing for months – masking, physical distancing, and limiting time indoors with others – will be the best way to ward them off, said Kirsten Bibbins-Domingo, MD, a physician and professor at the University of California, San Francisco.

“It’s very unsexy what the solutions are,” Dr. Bibbins-Domingo said. “But we need everyone to do them.”

That doesn’t make the task simple. Masking remains controversial in many states, and the public’s patience for maintaining physical distance has worn thin.

Adding to the concerns: Though case numbers stabilized in many parts of the U.S. in January, they have stabilized at rates many times what they were during previous periods in the pandemic or in other parts of the world. Having all that virus in so many bodies creates more opportunities for new mutations and new variants to emerge.

“If we keep letting this thing sneak around, it’s going to get around all the measures we take against it, and that’s the worst possible thing,” said Nevada’s Dr. Pandori.

Compared with less virulent strains, a more contagious variant likely will require that more people be vaccinated before a community can see the benefits of widespread immunity. It’s a bleak outlook for a nation already falling behind in the race to vaccinate enough people to bring the pandemic under control.

“When your best solution is to ask people to do the things that they don’t like to do anyway, that’s very scary,” said Dr. Bibbins-Domingo.
 

This story was produced by KHN, which publishes California Healthline, an editorially independent service of the California Health Care Foundation.

The COVID-19 variants that have emerged in the United Kingdom, Brazil, South Africa and now Southern California are eliciting two notably distinct responses from U.S. public health officials.

janiecbros/iStock/Getty Images Plus

First, broad concern. A variant that wreaked havoc in the United Kingdom, leading to a spike in cases and hospitalizations, is surfacing in a growing number of places in the United States. During the week of Jan. 24, another worrisome variant seen in Brazil surfaced in Minnesota. If these or other strains significantly change the way the virus transmits and attacks the body, as scientists fear they might, they could cause yet another prolonged surge in illness and death in the U.S., even as cases have begun to plateau and vaccines are rolling out.

On the other hand, variants aren’t novel or even uncommon in viral illnesses. The viruses that trigger common colds and flus regularly evolve. Even if a mutated strain of SARS-CoV-2, the virus that causes COVID-19, makes it more contagious or makes people sicker, the basic public health response stays the same: Monitor the virus, and any mutations, as it moves across communities. Use masking, testing, physical distancing, and quarantine to contain the spread.

The problem is that the U.S. has struggled with every step of its public health response in its first year of battle against COVID-19. And that raises the question of whether the nation will devote the attention and resources needed to outflank the virus as it evolves.

Researchers are quick to stress that a coronavirus mutation in itself is no cause for alarm. In the course of making millions and billions of copies as part of the infection process, small changes to a virus’s genome happen all the time as a function of evolutionary biology.

“The word ‘variant’ and the word ‘mutation’ have these scary connotations, and they aren’t necessarily scary,” said Kelly Wroblewski, director of infectious disease programs for the Association of Public Health Laboratories.

When a mutation rings public health alarms, it’s typically because it has combined with other mutations and, collectively, changed how the virus behaves. At that point, it may be named a variant. A variant can make a virus spread faster, or more easily jump between species. It can make a virus more successful at making people sicker, or change how our immune systems respond.

SARS-CoV-2 has been mutating for as long as we’ve known about it; mutations were identified by scientists throughout 2020. Though relevant scientifically – mutations can actually be helpful, acting like a fingerprint that allows scientists to track a virus’s spread – the identified strains mostly carried little concern for public health.

Then came the end of the year, when several variants began drawing scrutiny. One of the most concerning, first detected in the United Kingdom, appears to make the virus more transmissible. Emerging evidence suggests it also could be deadlier, though scientists are still debating that.

We know more about the U.K. variant than others not because it’s necessarily worse, but because the British have one of the best virus surveillance programs in the world, said William Hanage, PhD, an epidemiologist and a professor at Harvard University.

By contrast, the U.S. has one of the weakest genomic surveillance programs of any rich country, Dr. Hanage said. “As it is, people like me cobble together partnerships with places and try and beg them” for samples, he said on a recent call with reporters.

Other variant strains were identified in South Africa and Brazil, and they share some mutations with the U.K. variant. That those changes evolved independently in several parts of the world suggests they might present an evolutionary advantage for the virus. Yet another strain was recently identified in Southern California and flagged due to its increasing presence in hard-hit cities like Los Angeles.

The Southern California strain was detected because a team of researchers at Cedars-Sinai, a hospital and research center in Los Angeles, has unfettered access to patient samples. They were able to see that the strain made up a growing share of cases at the hospital in recent weeks, as well as among the limited number of other samples haphazardly collected at a network of labs in the region.

Not only does the U.S. do less genomic sequencing than most wealthy countries, but it also does its surveillance by happenstance. That means it takes longer to detect new strains and draw conclusions about them. It’s not yet clear, for example, whether that Southern California strain was truly worthy of a press release.

Vast swaths of America’s privatized and decentralized system of health care aren’t set up to send samples to public health or academic labs. “I’m more concerned about the systems to detect variants than I am these particular variants,” said Mark Pandori, PhD, director of Nevada’s public health laboratory and associate professor at the University of Nevada-Reno School of Medicine.

Limited genomic surveillance of viruses is yet another side effect of a fragmented and underfunded public health system that’s struggled to test, track contacts and get COVID-19 under control throughout the pandemic, Ms. Wroblewski said.

The nation’s public health infrastructure, generally funded on a disease-by-disease basis, has decent systems set up to sequence flu, foodborne illnesses and tuberculosis, but there has been no national strategy on COVID-19. “To look for variants, it needs to be a national picture if it’s going to be done well,” Ms. Wroblewski said.

The Biden administration has outlined a strategy for a national response to COVID-19, which includes expanded surveillance for variants.

So far, vaccines for COVID-19 appear to protect against the known variants. Moderna has said its vaccine is effective against the U.K. and South African strains, though it yields fewer antibodies in the face of the latter. The company is working to develop a revised dose of the vaccine that could be added to the current two-shot regimen as a precaution.

But a lot of damage can be done in the time it will take to roll out the current vaccine, let alone an update.

Even with limited sampling, the U.K. variant has been detected in more than two dozen U.S. states, and the Centers for Disease Control and Prevention has warned it could be the predominant strain in the U.S. by March. When it took off in the United Kingdom at the end of last year, it caused a swell in cases, overwhelmed hospitals, and led to a holiday lockdown. Whether the U.S. faces the same fate could depend on which strains it is competing against, and how the public behaves in the weeks ahead.

Already risky interactions among people could, on average, get a little riskier. Many researchers are calling for better masks and better indoor ventilation. But any updates on recommendations likely would play at the margins. Even if variants spread more easily, the same recommendations public health experts have been espousing for months – masking, physical distancing, and limiting time indoors with others – will be the best way to ward them off, said Kirsten Bibbins-Domingo, MD, a physician and professor at the University of California, San Francisco.

“It’s very unsexy what the solutions are,” Dr. Bibbins-Domingo said. “But we need everyone to do them.”

That doesn’t make the task simple. Masking remains controversial in many states, and the public’s patience for maintaining physical distance has worn thin.

Adding to the concerns: Though case numbers stabilized in many parts of the U.S. in January, they have stabilized at rates many times what they were during previous periods in the pandemic or in other parts of the world. Having all that virus in so many bodies creates more opportunities for new mutations and new variants to emerge.

“If we keep letting this thing sneak around, it’s going to get around all the measures we take against it, and that’s the worst possible thing,” said Nevada’s Dr. Pandori.

Compared with less virulent strains, a more contagious variant likely will require that more people be vaccinated before a community can see the benefits of widespread immunity. It’s a bleak outlook for a nation already falling behind in the race to vaccinate enough people to bring the pandemic under control.

“When your best solution is to ask people to do the things that they don’t like to do anyway, that’s very scary,” said Dr. Bibbins-Domingo.
 

This story was produced by KHN, which publishes California Healthline, an editorially independent service of the California Health Care Foundation.

The COVID-19 variants that have emerged in the United Kingdom, Brazil, South Africa and now Southern California are eliciting two notably distinct responses from U.S. public health officials.

janiecbros/iStock/Getty Images Plus

First, broad concern. A variant that wreaked havoc in the United Kingdom, leading to a spike in cases and hospitalizations, is surfacing in a growing number of places in the United States. During the week of Jan. 24, another worrisome variant seen in Brazil surfaced in Minnesota. If these or other strains significantly change the way the virus transmits and attacks the body, as scientists fear they might, they could cause yet another prolonged surge in illness and death in the U.S., even as cases have begun to plateau and vaccines are rolling out.

On the other hand, variants aren’t novel or even uncommon in viral illnesses. The viruses that trigger common colds and flus regularly evolve. Even if a mutated strain of SARS-CoV-2, the virus that causes COVID-19, makes it more contagious or makes people sicker, the basic public health response stays the same: Monitor the virus, and any mutations, as it moves across communities. Use masking, testing, physical distancing, and quarantine to contain the spread.

The problem is that the U.S. has struggled with every step of its public health response in its first year of battle against COVID-19. And that raises the question of whether the nation will devote the attention and resources needed to outflank the virus as it evolves.

Researchers are quick to stress that a coronavirus mutation in itself is no cause for alarm. In the course of making millions and billions of copies as part of the infection process, small changes to a virus’s genome happen all the time as a function of evolutionary biology.

“The word ‘variant’ and the word ‘mutation’ have these scary connotations, and they aren’t necessarily scary,” said Kelly Wroblewski, director of infectious disease programs for the Association of Public Health Laboratories.

When a mutation rings public health alarms, it’s typically because it has combined with other mutations and, collectively, changed how the virus behaves. At that point, it may be named a variant. A variant can make a virus spread faster, or more easily jump between species. It can make a virus more successful at making people sicker, or change how our immune systems respond.

SARS-CoV-2 has been mutating for as long as we’ve known about it; mutations were identified by scientists throughout 2020. Though relevant scientifically – mutations can actually be helpful, acting like a fingerprint that allows scientists to track a virus’s spread – the identified strains mostly carried little concern for public health.

Then came the end of the year, when several variants began drawing scrutiny. One of the most concerning, first detected in the United Kingdom, appears to make the virus more transmissible. Emerging evidence suggests it also could be deadlier, though scientists are still debating that.

We know more about the U.K. variant than others not because it’s necessarily worse, but because the British have one of the best virus surveillance programs in the world, said William Hanage, PhD, an epidemiologist and a professor at Harvard University.

By contrast, the U.S. has one of the weakest genomic surveillance programs of any rich country, Dr. Hanage said. “As it is, people like me cobble together partnerships with places and try and beg them” for samples, he said on a recent call with reporters.

Other variant strains were identified in South Africa and Brazil, and they share some mutations with the U.K. variant. That those changes evolved independently in several parts of the world suggests they might present an evolutionary advantage for the virus. Yet another strain was recently identified in Southern California and flagged due to its increasing presence in hard-hit cities like Los Angeles.

The Southern California strain was detected because a team of researchers at Cedars-Sinai, a hospital and research center in Los Angeles, has unfettered access to patient samples. They were able to see that the strain made up a growing share of cases at the hospital in recent weeks, as well as among the limited number of other samples haphazardly collected at a network of labs in the region.

Not only does the U.S. do less genomic sequencing than most wealthy countries, but it also does its surveillance by happenstance. That means it takes longer to detect new strains and draw conclusions about them. It’s not yet clear, for example, whether that Southern California strain was truly worthy of a press release.

Vast swaths of America’s privatized and decentralized system of health care aren’t set up to send samples to public health or academic labs. “I’m more concerned about the systems to detect variants than I am these particular variants,” said Mark Pandori, PhD, director of Nevada’s public health laboratory and associate professor at the University of Nevada-Reno School of Medicine.

Limited genomic surveillance of viruses is yet another side effect of a fragmented and underfunded public health system that’s struggled to test, track contacts and get COVID-19 under control throughout the pandemic, Ms. Wroblewski said.

The nation’s public health infrastructure, generally funded on a disease-by-disease basis, has decent systems set up to sequence flu, foodborne illnesses and tuberculosis, but there has been no national strategy on COVID-19. “To look for variants, it needs to be a national picture if it’s going to be done well,” Ms. Wroblewski said.

The Biden administration has outlined a strategy for a national response to COVID-19, which includes expanded surveillance for variants.

So far, vaccines for COVID-19 appear to protect against the known variants. Moderna has said its vaccine is effective against the U.K. and South African strains, though it yields fewer antibodies in the face of the latter. The company is working to develop a revised dose of the vaccine that could be added to the current two-shot regimen as a precaution.

But a lot of damage can be done in the time it will take to roll out the current vaccine, let alone an update.

Even with limited sampling, the U.K. variant has been detected in more than two dozen U.S. states, and the Centers for Disease Control and Prevention has warned it could be the predominant strain in the U.S. by March. When it took off in the United Kingdom at the end of last year, it caused a swell in cases, overwhelmed hospitals, and led to a holiday lockdown. Whether the U.S. faces the same fate could depend on which strains it is competing against, and how the public behaves in the weeks ahead.

Already risky interactions among people could, on average, get a little riskier. Many researchers are calling for better masks and better indoor ventilation. But any updates on recommendations likely would play at the margins. Even if variants spread more easily, the same recommendations public health experts have been espousing for months – masking, physical distancing, and limiting time indoors with others – will be the best way to ward them off, said Kirsten Bibbins-Domingo, MD, a physician and professor at the University of California, San Francisco.

“It’s very unsexy what the solutions are,” Dr. Bibbins-Domingo said. “But we need everyone to do them.”

That doesn’t make the task simple. Masking remains controversial in many states, and the public’s patience for maintaining physical distance has worn thin.

Adding to the concerns: Though case numbers stabilized in many parts of the U.S. in January, they have stabilized at rates many times what they were during previous periods in the pandemic or in other parts of the world. Having all that virus in so many bodies creates more opportunities for new mutations and new variants to emerge.

“If we keep letting this thing sneak around, it’s going to get around all the measures we take against it, and that’s the worst possible thing,” said Nevada’s Dr. Pandori.

Compared with less virulent strains, a more contagious variant likely will require that more people be vaccinated before a community can see the benefits of widespread immunity. It’s a bleak outlook for a nation already falling behind in the race to vaccinate enough people to bring the pandemic under control.

“When your best solution is to ask people to do the things that they don’t like to do anyway, that’s very scary,” said Dr. Bibbins-Domingo.
 

This story was produced by KHN, which publishes California Healthline, an editorially independent service of the California Health Care Foundation.

Experts discuss how to best protect people with diabetes from serious COVID-19 outcomes in a newly published article that summarizes in-depth discussions on the topic from a conference held online last year.

Lead author and Diabetes Technology Society founder and director David C. Klonoff, MD, said in an interview: “To my knowledge this is the largest article or learning that has been written anywhere ever about the co-occurrence of COVID-19 and diabetes and how COVID-19 affects diabetes ... There are a lot of different dimensions.” 

The 37-page report covers all sessions from the Virtual International COVID-19 and Diabetes Summit, held Aug. 26-27, 2020, which had 800 attendees from six continents, on topics including pathophysiology and COVID-19 risk factors, the impact of social determinants of health on diabetes and COVID-19, and psychological aspects of the COVID-19 pandemic for people with diabetes.

The freely available report was published online Jan. 21 in the Journal of Diabetes Science and Technology by Jennifer Y. Zhang of the Diabetes Technology Society, Burlingame, Calif., and colleagues.

Other topics include medications and vaccines, outpatient diabetes management during the COVID-19 pandemic and the growth of telehealth, inpatient management of diabetes in patients with or without COVID-19, ethical considerations, children, pregnancy, economics of care for COVID-19, government policy, regulation of tests and treatments, patient surveillance/privacy, and research gaps and opportunities.

“A comprehensive report like this is so important because it covers such a wide range of topics that are all relevant when it comes to protecting patients with diabetes during a pandemic. Our report aims to bring together all these different aspects of policy during the pandemic, patient physiology, and patient psychology, so I hope it will be widely read and widely appreciated,” Ms. Zhang said in an interview.

Two important clinical trends arising as a result of the pandemic – the advent of telehealth in diabetes management and the use of continuous glucose monitoring (CGM) in hospital – are expected to continue even after COVID-19 abates, said Dr. Klonoff, medical director of the Diabetes Research Institute at Mills-Peninsula Medical Center, San Mateo, Calif.


 

Telehealth in diabetes here to stay, in U.S. at least  

Dr. Klonoff noted that with diabetes telehealth, or “telediabetes” as it’s been dubbed, by using downloaded device data patients don’t have to travel, pay for parking, or take as much time off work. “There are advantages ... patients really like it,” he said.

And for health care providers, an advantage of remote visits is that the clinician can look at the patient while reviewing the patient’s data. “With telehealth for diabetes, the patient’s face and the software data are right next to each other on the same screen. Even as I’m typing I’m looking at the patient ... I consider that a huge advantage,” Dr. Klonoff said.

Rule changes early in the pandemic made the shift to telehealth in the United States possible, he said.

“Fortunately, Medicare and other payers are covering telehealth. It used to be there was no coverage, so that was a damper. Now that it’s covered I don’t think that’s going to go back. Everybody likes it,” he said. 
 

CGM in hospitals helps detect hypoglycemia on wards

Regarding the increase of inpatient CGM (continuous glucose monitoring) prompted by the need to minimize patient exposure of nursing staff during the pandemic and the relaxing of Food and Drug Administration rules about its use, Dr. Klonoff said this phenomenon has led to two other positive developments.

“For FDA, it’s actually an opportunity to see some data collected. To do a clinical trial [prior to] March 2020 you had to go through a lot of processes to do a study. Once it becomes part of clinical care, then you can collect a lot of data,” he noted.   

Moreover, Dr. Klonoff said there’s an important new area where hospital use of CGM is emerging: detection of hypoglycemia on wards.

“When a patient is in the ICU, if they become hypoglycemic or hyperglycemic it will likely be detected. But on the wards, they simply don’t get the same attention. Just about every doctor has had a case where somebody drifted into hypoglycemia that wasn’t recognized and maybe even died,” he explained.

If, however, “patients treated with insulin could all have CGMs that would be so useful. It would send out an alarm. A lot of times people don’t eat when you think they will. Suddenly the insulin dose is inappropriate and the nurse didn’t realize. Or, if IV nutrition stops and the insulin is given [it can be harmful].”

Another example, he said, is a common scenario when insulin is used in patients who are treated with steroids. “They need insulin, but then the steroid is decreased and the insulin dose isn’t decreased fast enough. All those situations can be helped with CGM.”

Overall, he concluded, COVID-19 has provided many lessons, which are “expanding our horizons.”

Ms. Zhang has reported no relevant financial relationships. Dr. Klonoff has reported being a consultant for Dexcom, EOFlow, Fractyl, Lifecare, Novo Nordisk, Roche Diagnostics, Samsung, and Thirdwayv.

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

Experts discuss how to best protect people with diabetes from serious COVID-19 outcomes in a newly published article that summarizes in-depth discussions on the topic from a conference held online last year.

Lead author and Diabetes Technology Society founder and director David C. Klonoff, MD, said in an interview: “To my knowledge this is the largest article or learning that has been written anywhere ever about the co-occurrence of COVID-19 and diabetes and how COVID-19 affects diabetes ... There are a lot of different dimensions.” 

The 37-page report covers all sessions from the Virtual International COVID-19 and Diabetes Summit, held Aug. 26-27, 2020, which had 800 attendees from six continents, on topics including pathophysiology and COVID-19 risk factors, the impact of social determinants of health on diabetes and COVID-19, and psychological aspects of the COVID-19 pandemic for people with diabetes.

The freely available report was published online Jan. 21 in the Journal of Diabetes Science and Technology by Jennifer Y. Zhang of the Diabetes Technology Society, Burlingame, Calif., and colleagues.

Other topics include medications and vaccines, outpatient diabetes management during the COVID-19 pandemic and the growth of telehealth, inpatient management of diabetes in patients with or without COVID-19, ethical considerations, children, pregnancy, economics of care for COVID-19, government policy, regulation of tests and treatments, patient surveillance/privacy, and research gaps and opportunities.

“A comprehensive report like this is so important because it covers such a wide range of topics that are all relevant when it comes to protecting patients with diabetes during a pandemic. Our report aims to bring together all these different aspects of policy during the pandemic, patient physiology, and patient psychology, so I hope it will be widely read and widely appreciated,” Ms. Zhang said in an interview.

Two important clinical trends arising as a result of the pandemic – the advent of telehealth in diabetes management and the use of continuous glucose monitoring (CGM) in hospital – are expected to continue even after COVID-19 abates, said Dr. Klonoff, medical director of the Diabetes Research Institute at Mills-Peninsula Medical Center, San Mateo, Calif.


 

Telehealth in diabetes here to stay, in U.S. at least  

Dr. Klonoff noted that with diabetes telehealth, or “telediabetes” as it’s been dubbed, by using downloaded device data patients don’t have to travel, pay for parking, or take as much time off work. “There are advantages ... patients really like it,” he said.

And for health care providers, an advantage of remote visits is that the clinician can look at the patient while reviewing the patient’s data. “With telehealth for diabetes, the patient’s face and the software data are right next to each other on the same screen. Even as I’m typing I’m looking at the patient ... I consider that a huge advantage,” Dr. Klonoff said.

Rule changes early in the pandemic made the shift to telehealth in the United States possible, he said.

“Fortunately, Medicare and other payers are covering telehealth. It used to be there was no coverage, so that was a damper. Now that it’s covered I don’t think that’s going to go back. Everybody likes it,” he said. 
 

CGM in hospitals helps detect hypoglycemia on wards

Regarding the increase of inpatient CGM (continuous glucose monitoring) prompted by the need to minimize patient exposure of nursing staff during the pandemic and the relaxing of Food and Drug Administration rules about its use, Dr. Klonoff said this phenomenon has led to two other positive developments.

“For FDA, it’s actually an opportunity to see some data collected. To do a clinical trial [prior to] March 2020 you had to go through a lot of processes to do a study. Once it becomes part of clinical care, then you can collect a lot of data,” he noted.   

Moreover, Dr. Klonoff said there’s an important new area where hospital use of CGM is emerging: detection of hypoglycemia on wards.

“When a patient is in the ICU, if they become hypoglycemic or hyperglycemic it will likely be detected. But on the wards, they simply don’t get the same attention. Just about every doctor has had a case where somebody drifted into hypoglycemia that wasn’t recognized and maybe even died,” he explained.

If, however, “patients treated with insulin could all have CGMs that would be so useful. It would send out an alarm. A lot of times people don’t eat when you think they will. Suddenly the insulin dose is inappropriate and the nurse didn’t realize. Or, if IV nutrition stops and the insulin is given [it can be harmful].”

Another example, he said, is a common scenario when insulin is used in patients who are treated with steroids. “They need insulin, but then the steroid is decreased and the insulin dose isn’t decreased fast enough. All those situations can be helped with CGM.”

Overall, he concluded, COVID-19 has provided many lessons, which are “expanding our horizons.”

Ms. Zhang has reported no relevant financial relationships. Dr. Klonoff has reported being a consultant for Dexcom, EOFlow, Fractyl, Lifecare, Novo Nordisk, Roche Diagnostics, Samsung, and Thirdwayv.

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

Experts discuss how to best protect people with diabetes from serious COVID-19 outcomes in a newly published article that summarizes in-depth discussions on the topic from a conference held online last year.

Lead author and Diabetes Technology Society founder and director David C. Klonoff, MD, said in an interview: “To my knowledge this is the largest article or learning that has been written anywhere ever about the co-occurrence of COVID-19 and diabetes and how COVID-19 affects diabetes ... There are a lot of different dimensions.” 

The 37-page report covers all sessions from the Virtual International COVID-19 and Diabetes Summit, held Aug. 26-27, 2020, which had 800 attendees from six continents, on topics including pathophysiology and COVID-19 risk factors, the impact of social determinants of health on diabetes and COVID-19, and psychological aspects of the COVID-19 pandemic for people with diabetes.

The freely available report was published online Jan. 21 in the Journal of Diabetes Science and Technology by Jennifer Y. Zhang of the Diabetes Technology Society, Burlingame, Calif., and colleagues.

Other topics include medications and vaccines, outpatient diabetes management during the COVID-19 pandemic and the growth of telehealth, inpatient management of diabetes in patients with or without COVID-19, ethical considerations, children, pregnancy, economics of care for COVID-19, government policy, regulation of tests and treatments, patient surveillance/privacy, and research gaps and opportunities.

“A comprehensive report like this is so important because it covers such a wide range of topics that are all relevant when it comes to protecting patients with diabetes during a pandemic. Our report aims to bring together all these different aspects of policy during the pandemic, patient physiology, and patient psychology, so I hope it will be widely read and widely appreciated,” Ms. Zhang said in an interview.

Two important clinical trends arising as a result of the pandemic – the advent of telehealth in diabetes management and the use of continuous glucose monitoring (CGM) in hospital – are expected to continue even after COVID-19 abates, said Dr. Klonoff, medical director of the Diabetes Research Institute at Mills-Peninsula Medical Center, San Mateo, Calif.


 

Telehealth in diabetes here to stay, in U.S. at least  

Dr. Klonoff noted that with diabetes telehealth, or “telediabetes” as it’s been dubbed, by using downloaded device data patients don’t have to travel, pay for parking, or take as much time off work. “There are advantages ... patients really like it,” he said.

And for health care providers, an advantage of remote visits is that the clinician can look at the patient while reviewing the patient’s data. “With telehealth for diabetes, the patient’s face and the software data are right next to each other on the same screen. Even as I’m typing I’m looking at the patient ... I consider that a huge advantage,” Dr. Klonoff said.

Rule changes early in the pandemic made the shift to telehealth in the United States possible, he said.

“Fortunately, Medicare and other payers are covering telehealth. It used to be there was no coverage, so that was a damper. Now that it’s covered I don’t think that’s going to go back. Everybody likes it,” he said. 
 

CGM in hospitals helps detect hypoglycemia on wards

Regarding the increase of inpatient CGM (continuous glucose monitoring) prompted by the need to minimize patient exposure of nursing staff during the pandemic and the relaxing of Food and Drug Administration rules about its use, Dr. Klonoff said this phenomenon has led to two other positive developments.

“For FDA, it’s actually an opportunity to see some data collected. To do a clinical trial [prior to] March 2020 you had to go through a lot of processes to do a study. Once it becomes part of clinical care, then you can collect a lot of data,” he noted.   

Moreover, Dr. Klonoff said there’s an important new area where hospital use of CGM is emerging: detection of hypoglycemia on wards.

“When a patient is in the ICU, if they become hypoglycemic or hyperglycemic it will likely be detected. But on the wards, they simply don’t get the same attention. Just about every doctor has had a case where somebody drifted into hypoglycemia that wasn’t recognized and maybe even died,” he explained.

If, however, “patients treated with insulin could all have CGMs that would be so useful. It would send out an alarm. A lot of times people don’t eat when you think they will. Suddenly the insulin dose is inappropriate and the nurse didn’t realize. Or, if IV nutrition stops and the insulin is given [it can be harmful].”

Another example, he said, is a common scenario when insulin is used in patients who are treated with steroids. “They need insulin, but then the steroid is decreased and the insulin dose isn’t decreased fast enough. All those situations can be helped with CGM.”

Overall, he concluded, COVID-19 has provided many lessons, which are “expanding our horizons.”

Ms. Zhang has reported no relevant financial relationships. Dr. Klonoff has reported being a consultant for Dexcom, EOFlow, Fractyl, Lifecare, Novo Nordisk, Roche Diagnostics, Samsung, and Thirdwayv.

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