Pulmonology

The same devices used to take selfies and type out tweets are being repurposed and commercialized for quick access to information needed for monitoring a patient’s health. A fingertip pressed against a phone’s camera lens can measure a heart rate. The microphone, kept by the bedside, can screen for sleep apnea. Even the speaker is being tapped, to monitor breathing using sonar technology.

In the best of this new world, the data is conveyed remotely to a medical professional for the convenience and comfort of the patient or, in some cases, to support a clinician without the need for costly hardware.

But using smartphones as diagnostic tools is a work in progress, experts say. Although doctors and their patients have found some real-world success in deploying the phone as a medical device, the overall potential remains unfulfilled and uncertain.

Smartphones come packed with sensors capable of monitoring a patient’s vital signs. They can help assess people for concussions, watch for atrial fibrillation, and conduct mental health wellness checks, to name the uses of a few nascent applications.

Companies and researchers eager to find medical applications for smartphone technology are tapping into modern phones’ built-in cameras and light sensors; microphones; accelerometers, which detect body movements; gyroscopes; and even speakers. The apps then use artificial intelligence software to analyze the collected sights and sounds to create an easy connection between patients and physicians. Earning potential and marketability are evidenced by the more than 350,000 digital health products available in app stores, according to a Grand View Research report.

“It’s very hard to put devices into the patient home or in the hospital, but everybody is just walking around with a cellphone that has a network connection,” said Dr. Andrew Gostine, CEO of the sensor network company Artisight. Most Americans own a smartphone, including more than 60% of people 65 and over, an increase from just 13% a decade ago, according the Pew Research Center. The COVID-19 pandemic has also pushed people to become more comfortable with virtual care.

Some of these products have sought FDA clearance to be marketed as a medical device. That way, if patients must pay to use the software, health insurers are more likely to cover at least part of the cost. Other products are designated as exempt from this regulatory process, placed in the same clinical classification as a Band-Aid. But how the agency handles AI and machine learning–based medical devices is still being adjusted to reflect software’s adaptive nature.

Ensuring accuracy and clinical validation is crucial to securing buy-in from health care providers. And many tools still need fine-tuning, said Eugene Yang, MD, a professor of medicine at the University of Washington, Seattle. Currently, Dr. Yang is testing contactless measurement of blood pressure, heart rate, and oxygen saturation gleaned remotely via Zoom camera footage of a patient’s face.

Judging these new technologies is difficult because they rely on algorithms built by machine learning and artificial intelligence to collect data, rather than the physical tools typically used in hospitals. So researchers cannot “compare apples to apples” with medical industry standards, Dr. Yang said. Failure to build in such assurances undermines the technology’s ultimate goals of easing costs and access because a doctor still must verify results.

“False positives and false negatives lead to more testing and more cost to the health care system,” he said.

Big tech companies like Google have heavily invested in researching this kind of technology, catering to clinicians and in-home caregivers, as well as consumers. Currently, in the Google Fit app, users can check their heart rate by placing their finger on the rear-facing camera lens or track their breathing rate using the front-facing camera.

“If you took the sensor out of the phone and out of a clinical device, they are probably the same thing,” said Shwetak Patel, director of health technologies at Google and a professor of electrical and computer engineering at the University of Washington.

Google’s research uses machine learning and computer vision, a field within AI based on information from visual inputs like videos or images. So instead of using a blood pressure cuff, for example, the algorithm can interpret slight visual changes to the body that serve as proxies and biosignals for a patient’s blood pressure, Mr. Patel said.

Google is also investigating the effectiveness of the built-in microphone for detecting heartbeats and murmurs and using the camera to preserve eyesight by screening for diabetic eye disease, according to information the company published last year.

The tech giant recently purchased Sound Life Sciences, a Seattle startup with an FDA-cleared sonar technology app. It uses a smart device’s speaker to bounce inaudible pulses off a patient’s body to identify movement and monitor breathing.

Binah.ai, based in Israel, is another company using the smartphone camera to calculate vital signs. Its software looks at the region around the eyes, where the skin is a bit thinner, and analyzes the light reflecting off blood vessels back to the lens. The company is wrapping up a U.S. clinical trial and marketing its wellness app directly to insurers and other health companies, said company spokesperson Mona Popilian-Yona.

The applications even reach into disciplines such as optometry and mental health:

• With the microphone, Canary Speech uses the same underlying technology as Amazon’s Alexa to analyze patients’ voices for mental health conditions. The software can integrate with telemedicine appointments and allow clinicians to screen for anxiety and depression using a library of vocal biomarkers and predictive analytics, said Henry O’Connell, the company’s CEO.
• Australia-based ResApp Health last year for its iPhone app that screens for moderate to severe obstructive sleep apnea by listening to breathing and snoring. SleepCheckRx, which will require a prescription, is minimally invasive compared with sleep studies currently used to diagnose sleep apnea. Those can cost thousands of dollars and require an array of tests.
• Brightlamp’s Reflex app is a clinical decision support tool for helping manage concussions and vision rehabilitation, among other things. Using an iPad’s or iPhone’s camera, the mobile app measures how a person’s pupils react to changes in light. Through machine learning analysis, the imagery gives practitioners data points for evaluating patients. Brightlamp sells directly to health care providers and is being used in more than 230 clinics. Clinicians pay a $400 standard annual fee per account, which is currently not covered by insurance. The Department of Defense has an ongoing clinical trial using Reflex.

In some cases, such as with the Reflex app, the data is processed directly on the phone – rather than in the cloud, Brightlamp CEO Kurtis Sluss said. By processing everything on the device, the app avoids running into privacy issues, as streaming data elsewhere requires patient consent.

But algorithms need to be trained and tested by collecting reams of data, and that is an ongoing process.

Researchers, for example, have found that some computer vision applications, like heart rate or blood pressure monitoring, can be less accurate for darker skin. Studies are underway to find better solutions.

Small algorithm glitches can also produce false alarms and frighten patients enough to keep widespread adoption out of reach. For example, Apple’s new car-crash detection feature, available on both the latest iPhone and Apple Watch, was set off when people were riding roller coasters and automatically dialed 911.

“We’re not there yet,” Dr. Yang said. “That’s the bottom line.”
 

KHN (Kaiser Health News) is a national newsroom that produces in-depth journalism about health issues. Together with Policy Analysis and Polling, KHN is one of the three major operating programs at KFF (Kaiser Family Foundation). KFF is an endowed nonprofit organization providing information on health issues to the nation.

The same devices used to take selfies and type out tweets are being repurposed and commercialized for quick access to information needed for monitoring a patient’s health. A fingertip pressed against a phone’s camera lens can measure a heart rate. The microphone, kept by the bedside, can screen for sleep apnea. Even the speaker is being tapped, to monitor breathing using sonar technology.

In the best of this new world, the data is conveyed remotely to a medical professional for the convenience and comfort of the patient or, in some cases, to support a clinician without the need for costly hardware.

But using smartphones as diagnostic tools is a work in progress, experts say. Although doctors and their patients have found some real-world success in deploying the phone as a medical device, the overall potential remains unfulfilled and uncertain.

Smartphones come packed with sensors capable of monitoring a patient’s vital signs. They can help assess people for concussions, watch for atrial fibrillation, and conduct mental health wellness checks, to name the uses of a few nascent applications.

Companies and researchers eager to find medical applications for smartphone technology are tapping into modern phones’ built-in cameras and light sensors; microphones; accelerometers, which detect body movements; gyroscopes; and even speakers. The apps then use artificial intelligence software to analyze the collected sights and sounds to create an easy connection between patients and physicians. Earning potential and marketability are evidenced by the more than 350,000 digital health products available in app stores, according to a Grand View Research report.

“It’s very hard to put devices into the patient home or in the hospital, but everybody is just walking around with a cellphone that has a network connection,” said Dr. Andrew Gostine, CEO of the sensor network company Artisight. Most Americans own a smartphone, including more than 60% of people 65 and over, an increase from just 13% a decade ago, according the Pew Research Center. The COVID-19 pandemic has also pushed people to become more comfortable with virtual care.

Some of these products have sought FDA clearance to be marketed as a medical device. That way, if patients must pay to use the software, health insurers are more likely to cover at least part of the cost. Other products are designated as exempt from this regulatory process, placed in the same clinical classification as a Band-Aid. But how the agency handles AI and machine learning–based medical devices is still being adjusted to reflect software’s adaptive nature.

Ensuring accuracy and clinical validation is crucial to securing buy-in from health care providers. And many tools still need fine-tuning, said Eugene Yang, MD, a professor of medicine at the University of Washington, Seattle. Currently, Dr. Yang is testing contactless measurement of blood pressure, heart rate, and oxygen saturation gleaned remotely via Zoom camera footage of a patient’s face.

Judging these new technologies is difficult because they rely on algorithms built by machine learning and artificial intelligence to collect data, rather than the physical tools typically used in hospitals. So researchers cannot “compare apples to apples” with medical industry standards, Dr. Yang said. Failure to build in such assurances undermines the technology’s ultimate goals of easing costs and access because a doctor still must verify results.

“False positives and false negatives lead to more testing and more cost to the health care system,” he said.

Big tech companies like Google have heavily invested in researching this kind of technology, catering to clinicians and in-home caregivers, as well as consumers. Currently, in the Google Fit app, users can check their heart rate by placing their finger on the rear-facing camera lens or track their breathing rate using the front-facing camera.

“If you took the sensor out of the phone and out of a clinical device, they are probably the same thing,” said Shwetak Patel, director of health technologies at Google and a professor of electrical and computer engineering at the University of Washington.

Google’s research uses machine learning and computer vision, a field within AI based on information from visual inputs like videos or images. So instead of using a blood pressure cuff, for example, the algorithm can interpret slight visual changes to the body that serve as proxies and biosignals for a patient’s blood pressure, Mr. Patel said.

Google is also investigating the effectiveness of the built-in microphone for detecting heartbeats and murmurs and using the camera to preserve eyesight by screening for diabetic eye disease, according to information the company published last year.

The tech giant recently purchased Sound Life Sciences, a Seattle startup with an FDA-cleared sonar technology app. It uses a smart device’s speaker to bounce inaudible pulses off a patient’s body to identify movement and monitor breathing.

Binah.ai, based in Israel, is another company using the smartphone camera to calculate vital signs. Its software looks at the region around the eyes, where the skin is a bit thinner, and analyzes the light reflecting off blood vessels back to the lens. The company is wrapping up a U.S. clinical trial and marketing its wellness app directly to insurers and other health companies, said company spokesperson Mona Popilian-Yona.

The applications even reach into disciplines such as optometry and mental health:

• With the microphone, Canary Speech uses the same underlying technology as Amazon’s Alexa to analyze patients’ voices for mental health conditions. The software can integrate with telemedicine appointments and allow clinicians to screen for anxiety and depression using a library of vocal biomarkers and predictive analytics, said Henry O’Connell, the company’s CEO.
• Australia-based ResApp Health last year for its iPhone app that screens for moderate to severe obstructive sleep apnea by listening to breathing and snoring. SleepCheckRx, which will require a prescription, is minimally invasive compared with sleep studies currently used to diagnose sleep apnea. Those can cost thousands of dollars and require an array of tests.
• Brightlamp’s Reflex app is a clinical decision support tool for helping manage concussions and vision rehabilitation, among other things. Using an iPad’s or iPhone’s camera, the mobile app measures how a person’s pupils react to changes in light. Through machine learning analysis, the imagery gives practitioners data points for evaluating patients. Brightlamp sells directly to health care providers and is being used in more than 230 clinics. Clinicians pay a $400 standard annual fee per account, which is currently not covered by insurance. The Department of Defense has an ongoing clinical trial using Reflex.

In some cases, such as with the Reflex app, the data is processed directly on the phone – rather than in the cloud, Brightlamp CEO Kurtis Sluss said. By processing everything on the device, the app avoids running into privacy issues, as streaming data elsewhere requires patient consent.

But algorithms need to be trained and tested by collecting reams of data, and that is an ongoing process.

Researchers, for example, have found that some computer vision applications, like heart rate or blood pressure monitoring, can be less accurate for darker skin. Studies are underway to find better solutions.

Small algorithm glitches can also produce false alarms and frighten patients enough to keep widespread adoption out of reach. For example, Apple’s new car-crash detection feature, available on both the latest iPhone and Apple Watch, was set off when people were riding roller coasters and automatically dialed 911.

“We’re not there yet,” Dr. Yang said. “That’s the bottom line.”
 

KHN (Kaiser Health News) is a national newsroom that produces in-depth journalism about health issues. Together with Policy Analysis and Polling, KHN is one of the three major operating programs at KFF (Kaiser Family Foundation). KFF is an endowed nonprofit organization providing information on health issues to the nation.

The same devices used to take selfies and type out tweets are being repurposed and commercialized for quick access to information needed for monitoring a patient’s health. A fingertip pressed against a phone’s camera lens can measure a heart rate. The microphone, kept by the bedside, can screen for sleep apnea. Even the speaker is being tapped, to monitor breathing using sonar technology.

In the best of this new world, the data is conveyed remotely to a medical professional for the convenience and comfort of the patient or, in some cases, to support a clinician without the need for costly hardware.

But using smartphones as diagnostic tools is a work in progress, experts say. Although doctors and their patients have found some real-world success in deploying the phone as a medical device, the overall potential remains unfulfilled and uncertain.

Smartphones come packed with sensors capable of monitoring a patient’s vital signs. They can help assess people for concussions, watch for atrial fibrillation, and conduct mental health wellness checks, to name the uses of a few nascent applications.

Companies and researchers eager to find medical applications for smartphone technology are tapping into modern phones’ built-in cameras and light sensors; microphones; accelerometers, which detect body movements; gyroscopes; and even speakers. The apps then use artificial intelligence software to analyze the collected sights and sounds to create an easy connection between patients and physicians. Earning potential and marketability are evidenced by the more than 350,000 digital health products available in app stores, according to a Grand View Research report.

“It’s very hard to put devices into the patient home or in the hospital, but everybody is just walking around with a cellphone that has a network connection,” said Dr. Andrew Gostine, CEO of the sensor network company Artisight. Most Americans own a smartphone, including more than 60% of people 65 and over, an increase from just 13% a decade ago, according the Pew Research Center. The COVID-19 pandemic has also pushed people to become more comfortable with virtual care.

Some of these products have sought FDA clearance to be marketed as a medical device. That way, if patients must pay to use the software, health insurers are more likely to cover at least part of the cost. Other products are designated as exempt from this regulatory process, placed in the same clinical classification as a Band-Aid. But how the agency handles AI and machine learning–based medical devices is still being adjusted to reflect software’s adaptive nature.

Ensuring accuracy and clinical validation is crucial to securing buy-in from health care providers. And many tools still need fine-tuning, said Eugene Yang, MD, a professor of medicine at the University of Washington, Seattle. Currently, Dr. Yang is testing contactless measurement of blood pressure, heart rate, and oxygen saturation gleaned remotely via Zoom camera footage of a patient’s face.

Judging these new technologies is difficult because they rely on algorithms built by machine learning and artificial intelligence to collect data, rather than the physical tools typically used in hospitals. So researchers cannot “compare apples to apples” with medical industry standards, Dr. Yang said. Failure to build in such assurances undermines the technology’s ultimate goals of easing costs and access because a doctor still must verify results.

“False positives and false negatives lead to more testing and more cost to the health care system,” he said.

Big tech companies like Google have heavily invested in researching this kind of technology, catering to clinicians and in-home caregivers, as well as consumers. Currently, in the Google Fit app, users can check their heart rate by placing their finger on the rear-facing camera lens or track their breathing rate using the front-facing camera.

“If you took the sensor out of the phone and out of a clinical device, they are probably the same thing,” said Shwetak Patel, director of health technologies at Google and a professor of electrical and computer engineering at the University of Washington.

Google’s research uses machine learning and computer vision, a field within AI based on information from visual inputs like videos or images. So instead of using a blood pressure cuff, for example, the algorithm can interpret slight visual changes to the body that serve as proxies and biosignals for a patient’s blood pressure, Mr. Patel said.

Google is also investigating the effectiveness of the built-in microphone for detecting heartbeats and murmurs and using the camera to preserve eyesight by screening for diabetic eye disease, according to information the company published last year.

The tech giant recently purchased Sound Life Sciences, a Seattle startup with an FDA-cleared sonar technology app. It uses a smart device’s speaker to bounce inaudible pulses off a patient’s body to identify movement and monitor breathing.

Binah.ai, based in Israel, is another company using the smartphone camera to calculate vital signs. Its software looks at the region around the eyes, where the skin is a bit thinner, and analyzes the light reflecting off blood vessels back to the lens. The company is wrapping up a U.S. clinical trial and marketing its wellness app directly to insurers and other health companies, said company spokesperson Mona Popilian-Yona.

The applications even reach into disciplines such as optometry and mental health:

• With the microphone, Canary Speech uses the same underlying technology as Amazon’s Alexa to analyze patients’ voices for mental health conditions. The software can integrate with telemedicine appointments and allow clinicians to screen for anxiety and depression using a library of vocal biomarkers and predictive analytics, said Henry O’Connell, the company’s CEO.
• Australia-based ResApp Health last year for its iPhone app that screens for moderate to severe obstructive sleep apnea by listening to breathing and snoring. SleepCheckRx, which will require a prescription, is minimally invasive compared with sleep studies currently used to diagnose sleep apnea. Those can cost thousands of dollars and require an array of tests.
• Brightlamp’s Reflex app is a clinical decision support tool for helping manage concussions and vision rehabilitation, among other things. Using an iPad’s or iPhone’s camera, the mobile app measures how a person’s pupils react to changes in light. Through machine learning analysis, the imagery gives practitioners data points for evaluating patients. Brightlamp sells directly to health care providers and is being used in more than 230 clinics. Clinicians pay a $400 standard annual fee per account, which is currently not covered by insurance. The Department of Defense has an ongoing clinical trial using Reflex.

In some cases, such as with the Reflex app, the data is processed directly on the phone – rather than in the cloud, Brightlamp CEO Kurtis Sluss said. By processing everything on the device, the app avoids running into privacy issues, as streaming data elsewhere requires patient consent.

But algorithms need to be trained and tested by collecting reams of data, and that is an ongoing process.

Researchers, for example, have found that some computer vision applications, like heart rate or blood pressure monitoring, can be less accurate for darker skin. Studies are underway to find better solutions.

Small algorithm glitches can also produce false alarms and frighten patients enough to keep widespread adoption out of reach. For example, Apple’s new car-crash detection feature, available on both the latest iPhone and Apple Watch, was set off when people were riding roller coasters and automatically dialed 911.

“We’re not there yet,” Dr. Yang said. “That’s the bottom line.”
 

KHN (Kaiser Health News) is a national newsroom that produces in-depth journalism about health issues. Together with Policy Analysis and Polling, KHN is one of the three major operating programs at KFF (Kaiser Family Foundation). KFF is an endowed nonprofit organization providing information on health issues to the nation.

A vaccine database found a possible link between the Pfizer/BioNTech bivalent COVID-19 vaccine and ischemic strokes in people over 65 who got the shot, the Centers for Disease Control and Prevention and the Food and Drug Administration said in a joint news release.

The release did not recommend people change their vaccine practices, saying the database finding probably did not represent a “true clinical risk.” The CDC said everybody, including people over 65, should stay up to date on their COVID vaccines, including the bivalent booster.

The news release said the Vaccine Safety Datalink (VSD), “a near real-time surveillance system,” raised a safety concern about the Pfizer/BioNTech booster.

“Rapid-response investigation of the signal in the VSD raised a question of whether people 65 and older who have received the Pfizer-BioNTech COVID-19 Vaccine, Bivalent were more likely to have an ischemic stroke in the 21 days following vaccination compared with days 22-44 following vaccination,” the news release said.

Ischemic strokes are blockages of blood to the brain, often caused by blood clots.

“Although the totality of the data currently suggests that it is very unlikely that the signal in VSD (Vaccine Safety Datalink) represents a true clinical risk, we believe it is important to share this information with the public, as we have in the past, when one of our safety monitoring systems detects a signal,” the release said.

No higher likelihood of strokes linked to the Pfizer bivalent vaccine had been found by Pfizer/BioNTech, the Department of Veterans Affairs, the Vaccine Adverse Event Reporting System maintained by the CDC and the FDA, or other agencies that monitor reactions of vaccines, the news release said. No safety issues about strokes have been identified with the Moderna bivalent vaccine. 

CNN, citing a CDC official, reported that about 550,000 seniors who got Pfizer bivalent boosters were tracked by the VSD, and 130 of them had strokes within 3 weeks of getting the shot. None of those 130 people died, CNN said. The official spoke on the condition of anonymity because they weren’t authorized to share the data. 

The issue will be discussed at the January meeting of the FDA’s Vaccines and Related Biological Products Advisory Committee.

In a joint statement, Pfizer and BioNTech said: “Neither Pfizer and BioNTech nor the CDC or FDA have observed similar findings across numerous other monitoring systems in the U.S. and globally and there is no evidence to conclude that ischemic stroke is associated with the use of the companies’ COVID-19 vaccines.”

Bivalent boosters contain two strains of vaccine – one to protect against the original COVID-19 virus and another targeting Omicron subvariants.

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

A vaccine database found a possible link between the Pfizer/BioNTech bivalent COVID-19 vaccine and ischemic strokes in people over 65 who got the shot, the Centers for Disease Control and Prevention and the Food and Drug Administration said in a joint news release.

The release did not recommend people change their vaccine practices, saying the database finding probably did not represent a “true clinical risk.” The CDC said everybody, including people over 65, should stay up to date on their COVID vaccines, including the bivalent booster.

The news release said the Vaccine Safety Datalink (VSD), “a near real-time surveillance system,” raised a safety concern about the Pfizer/BioNTech booster.

“Rapid-response investigation of the signal in the VSD raised a question of whether people 65 and older who have received the Pfizer-BioNTech COVID-19 Vaccine, Bivalent were more likely to have an ischemic stroke in the 21 days following vaccination compared with days 22-44 following vaccination,” the news release said.

Ischemic strokes are blockages of blood to the brain, often caused by blood clots.

“Although the totality of the data currently suggests that it is very unlikely that the signal in VSD (Vaccine Safety Datalink) represents a true clinical risk, we believe it is important to share this information with the public, as we have in the past, when one of our safety monitoring systems detects a signal,” the release said.

No higher likelihood of strokes linked to the Pfizer bivalent vaccine had been found by Pfizer/BioNTech, the Department of Veterans Affairs, the Vaccine Adverse Event Reporting System maintained by the CDC and the FDA, or other agencies that monitor reactions of vaccines, the news release said. No safety issues about strokes have been identified with the Moderna bivalent vaccine. 

CNN, citing a CDC official, reported that about 550,000 seniors who got Pfizer bivalent boosters were tracked by the VSD, and 130 of them had strokes within 3 weeks of getting the shot. None of those 130 people died, CNN said. The official spoke on the condition of anonymity because they weren’t authorized to share the data. 

The issue will be discussed at the January meeting of the FDA’s Vaccines and Related Biological Products Advisory Committee.

In a joint statement, Pfizer and BioNTech said: “Neither Pfizer and BioNTech nor the CDC or FDA have observed similar findings across numerous other monitoring systems in the U.S. and globally and there is no evidence to conclude that ischemic stroke is associated with the use of the companies’ COVID-19 vaccines.”

Bivalent boosters contain two strains of vaccine – one to protect against the original COVID-19 virus and another targeting Omicron subvariants.

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

A vaccine database found a possible link between the Pfizer/BioNTech bivalent COVID-19 vaccine and ischemic strokes in people over 65 who got the shot, the Centers for Disease Control and Prevention and the Food and Drug Administration said in a joint news release.

The release did not recommend people change their vaccine practices, saying the database finding probably did not represent a “true clinical risk.” The CDC said everybody, including people over 65, should stay up to date on their COVID vaccines, including the bivalent booster.

The news release said the Vaccine Safety Datalink (VSD), “a near real-time surveillance system,” raised a safety concern about the Pfizer/BioNTech booster.

“Rapid-response investigation of the signal in the VSD raised a question of whether people 65 and older who have received the Pfizer-BioNTech COVID-19 Vaccine, Bivalent were more likely to have an ischemic stroke in the 21 days following vaccination compared with days 22-44 following vaccination,” the news release said.

Ischemic strokes are blockages of blood to the brain, often caused by blood clots.

“Although the totality of the data currently suggests that it is very unlikely that the signal in VSD (Vaccine Safety Datalink) represents a true clinical risk, we believe it is important to share this information with the public, as we have in the past, when one of our safety monitoring systems detects a signal,” the release said.

No higher likelihood of strokes linked to the Pfizer bivalent vaccine had been found by Pfizer/BioNTech, the Department of Veterans Affairs, the Vaccine Adverse Event Reporting System maintained by the CDC and the FDA, or other agencies that monitor reactions of vaccines, the news release said. No safety issues about strokes have been identified with the Moderna bivalent vaccine. 

CNN, citing a CDC official, reported that about 550,000 seniors who got Pfizer bivalent boosters were tracked by the VSD, and 130 of them had strokes within 3 weeks of getting the shot. None of those 130 people died, CNN said. The official spoke on the condition of anonymity because they weren’t authorized to share the data. 

The issue will be discussed at the January meeting of the FDA’s Vaccines and Related Biological Products Advisory Committee.

In a joint statement, Pfizer and BioNTech said: “Neither Pfizer and BioNTech nor the CDC or FDA have observed similar findings across numerous other monitoring systems in the U.S. and globally and there is no evidence to conclude that ischemic stroke is associated with the use of the companies’ COVID-19 vaccines.”

Bivalent boosters contain two strains of vaccine – one to protect against the original COVID-19 virus and another targeting Omicron subvariants.

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

People with long COVID may have dizziness, headaches, sleep problems, sluggish thinking, and many other problems. But they can also face another problem – stigma.

Most people with long COVID find they’re facing stigma due to their condition, according to a new report from researchers in the United Kingdom. In short: Relatives and friends may not believe they’re truly sick.

The U.K. team found that more than three-quarters of people studied had experienced stigma often or always. 

In fact, 95% of people with long COVID faced at least one type of stigma at least sometimes, according to the study, published in November in the journal PLOS One.

Those conclusions had surprised the study’s lead researcher, Marija Pantelic, PhD, a public health lecturer at Brighton and Sussex Medical School, England.

“After years of working on HIV-related stigma, I was shocked to see how many people were turning a blind eye to and dismissing the difficulties experienced by people with long COVID,” Dr. Pantelic says. “It has also been clear to me from the start that this stigma is detrimental not just for people’s dignity, but also public health.”

Even some doctors argue that the growing attention paid to long COVID is excessive.

“It’s often normal to experience mild fatigue or weaknesses for weeks after being sick and inactive and not eating well. Calling these cases long COVID is the medicalization of modern life,” Marty Makary, MD, a surgeon and public policy researcher at Johns Hopkins University, Baltimore, wrote in a commentary in the Wall Street Journal.

Other doctors strongly disagree, including Alba Azola, MD, codirector of the Johns Hopkins Post-Acute COVID-19 Team and an expert in the stigma surrounding long COVID.

“Putting that spin on things, it’s just hurting people,” she says.

One example is people who cannot return to work.

“A lot of their family members tell me that they’re being lazy,” Dr. Azola says. “That’s part of the public stigma, that these are people just trying to get out of work.”

Some experts say the U.K. study represents a landmark.

“When you have data like this on long COVID stigma, it becomes more difficult to deny its existence or address it,” says Naomi Torres-Mackie, PhD, a clinical psychologist at Lenox Hill Hospital in New York. She also is head of research at the New York–based Mental Health Coalition, a group of experts working to end the stigma surrounding mental health.

She recalls her first patient with long COVID.

“She experienced the discomfort and pain itself, and then she had this crushing feeling that it wasn’t valid, or real. She felt very alone in it,” Dr. Torres-Mackie says.

Another one of her patients is working at her job from home but facing doubt about her condition from her employers.

“Every month, her medical doctor has to produce a letter confirming her medical condition,” Dr. Torres-Mackie says.

Taking part in the British stigma survey were 1,166 people, including 966 residents of the United Kingdom, with the average age of 48. Nearly 85% were female, and more than three-quarters were educated at the university level or higher.

Half of them said they had a clinical diagnosis of long COVID.

More than 60% of them said that at least some of the time, they were cautious about who they talked to about their condition. And fully 34% of those who did disclose their diagnosis said that they regretted having done so.

That’s a difficult experience for those with long COVID, says Leonard Jason, PhD, a professor of psychology at DePaul University in Chicago.

“It’s like they’re traumatized by the initial experience of being sick, and retraumatized by the response of others to them,” he says.

Unexplained illnesses are not well-regarded by the general public, Dr. Jason says.

He gave the example of multiple sclerosis. Before the 1980s, those with MS were considered to have a psychological illness, he says. “Then, in the 1980s, there were biomarkers that said, ‘Here’s the evidence.’ ”

The British study described three types of stigma stemming from the long COVID diagnosis of those questioned:

• Enacted stigma: People were directly treated unfairly because of their condition.
• Internalized stigma: People felt embarrassed by that condition.
• Anticipated stigma: People expected they would be treated poorly because of their diagnosis.

Dr. Azola calls the medical community a major problem when it comes to dealing with long COVID.

“What I see with my patients is medical trauma,” she says. They may have symptoms that send them to the emergency room, and then the tests come back negative. “Instead of tracking the patients’ symptoms, patients get told, ‘Everything looks good, you can go home, this is a panic attack,’ ” she says.

Some people go online to search for treatments, sometimes launching GoFundMe campaigns to raise money for unreliable treatments.

Long COVID patients may have gone through 5 to 10 doctors before they arrive for treatment with the Johns Hopkins Post-Acute COVID-19 Team. The clinic began in April 2020 remotely and in August of that year in person.

Today, the clinic staff spends an hour with a first-time long COVID patient, hearing their stories and helping relieve anxiety, Dr. Azola says.

The phenomenon of long COVID is similar to what patients have had with chronic fatigue syndrome, lupus, or fibromyalgia, where people have symptoms that are hard to explain, says Jennifer Chevinsky, MD, deputy public health officer for Riverside County, Calif.

“Stigma within medicine or health care is nothing new,” she says.

In Chicago, Dr. Jason notes that the federal government’s decision to invest hundreds of millions of dollars in long COVID research “shows the government is helping destigmatize it.”

Dr. Pantelic says she and her colleagues are continuing their research.

“We are interested in understanding the impacts of this stigma, and how to mitigate any adverse outcomes for patients and services,” she says.

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

People with long COVID may have dizziness, headaches, sleep problems, sluggish thinking, and many other problems. But they can also face another problem – stigma.

Most people with long COVID find they’re facing stigma due to their condition, according to a new report from researchers in the United Kingdom. In short: Relatives and friends may not believe they’re truly sick.

The U.K. team found that more than three-quarters of people studied had experienced stigma often or always. 

In fact, 95% of people with long COVID faced at least one type of stigma at least sometimes, according to the study, published in November in the journal PLOS One.

Those conclusions had surprised the study’s lead researcher, Marija Pantelic, PhD, a public health lecturer at Brighton and Sussex Medical School, England.

“After years of working on HIV-related stigma, I was shocked to see how many people were turning a blind eye to and dismissing the difficulties experienced by people with long COVID,” Dr. Pantelic says. “It has also been clear to me from the start that this stigma is detrimental not just for people’s dignity, but also public health.”

Even some doctors argue that the growing attention paid to long COVID is excessive.

“It’s often normal to experience mild fatigue or weaknesses for weeks after being sick and inactive and not eating well. Calling these cases long COVID is the medicalization of modern life,” Marty Makary, MD, a surgeon and public policy researcher at Johns Hopkins University, Baltimore, wrote in a commentary in the Wall Street Journal.

Other doctors strongly disagree, including Alba Azola, MD, codirector of the Johns Hopkins Post-Acute COVID-19 Team and an expert in the stigma surrounding long COVID.

“Putting that spin on things, it’s just hurting people,” she says.

One example is people who cannot return to work.

“A lot of their family members tell me that they’re being lazy,” Dr. Azola says. “That’s part of the public stigma, that these are people just trying to get out of work.”

Some experts say the U.K. study represents a landmark.

“When you have data like this on long COVID stigma, it becomes more difficult to deny its existence or address it,” says Naomi Torres-Mackie, PhD, a clinical psychologist at Lenox Hill Hospital in New York. She also is head of research at the New York–based Mental Health Coalition, a group of experts working to end the stigma surrounding mental health.

She recalls her first patient with long COVID.

“She experienced the discomfort and pain itself, and then she had this crushing feeling that it wasn’t valid, or real. She felt very alone in it,” Dr. Torres-Mackie says.

Another one of her patients is working at her job from home but facing doubt about her condition from her employers.

“Every month, her medical doctor has to produce a letter confirming her medical condition,” Dr. Torres-Mackie says.

Taking part in the British stigma survey were 1,166 people, including 966 residents of the United Kingdom, with the average age of 48. Nearly 85% were female, and more than three-quarters were educated at the university level or higher.

Half of them said they had a clinical diagnosis of long COVID.

More than 60% of them said that at least some of the time, they were cautious about who they talked to about their condition. And fully 34% of those who did disclose their diagnosis said that they regretted having done so.

That’s a difficult experience for those with long COVID, says Leonard Jason, PhD, a professor of psychology at DePaul University in Chicago.

“It’s like they’re traumatized by the initial experience of being sick, and retraumatized by the response of others to them,” he says.

Unexplained illnesses are not well-regarded by the general public, Dr. Jason says.

He gave the example of multiple sclerosis. Before the 1980s, those with MS were considered to have a psychological illness, he says. “Then, in the 1980s, there were biomarkers that said, ‘Here’s the evidence.’ ”

The British study described three types of stigma stemming from the long COVID diagnosis of those questioned:

• Enacted stigma: People were directly treated unfairly because of their condition.
• Internalized stigma: People felt embarrassed by that condition.
• Anticipated stigma: People expected they would be treated poorly because of their diagnosis.

Dr. Azola calls the medical community a major problem when it comes to dealing with long COVID.

“What I see with my patients is medical trauma,” she says. They may have symptoms that send them to the emergency room, and then the tests come back negative. “Instead of tracking the patients’ symptoms, patients get told, ‘Everything looks good, you can go home, this is a panic attack,’ ” she says.

Some people go online to search for treatments, sometimes launching GoFundMe campaigns to raise money for unreliable treatments.

Long COVID patients may have gone through 5 to 10 doctors before they arrive for treatment with the Johns Hopkins Post-Acute COVID-19 Team. The clinic began in April 2020 remotely and in August of that year in person.

Today, the clinic staff spends an hour with a first-time long COVID patient, hearing their stories and helping relieve anxiety, Dr. Azola says.

The phenomenon of long COVID is similar to what patients have had with chronic fatigue syndrome, lupus, or fibromyalgia, where people have symptoms that are hard to explain, says Jennifer Chevinsky, MD, deputy public health officer for Riverside County, Calif.

“Stigma within medicine or health care is nothing new,” she says.

In Chicago, Dr. Jason notes that the federal government’s decision to invest hundreds of millions of dollars in long COVID research “shows the government is helping destigmatize it.”

Dr. Pantelic says she and her colleagues are continuing their research.

“We are interested in understanding the impacts of this stigma, and how to mitigate any adverse outcomes for patients and services,” she says.

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

People with long COVID may have dizziness, headaches, sleep problems, sluggish thinking, and many other problems. But they can also face another problem – stigma.

Most people with long COVID find they’re facing stigma due to their condition, according to a new report from researchers in the United Kingdom. In short: Relatives and friends may not believe they’re truly sick.

The U.K. team found that more than three-quarters of people studied had experienced stigma often or always. 

In fact, 95% of people with long COVID faced at least one type of stigma at least sometimes, according to the study, published in November in the journal PLOS One.

Those conclusions had surprised the study’s lead researcher, Marija Pantelic, PhD, a public health lecturer at Brighton and Sussex Medical School, England.

“After years of working on HIV-related stigma, I was shocked to see how many people were turning a blind eye to and dismissing the difficulties experienced by people with long COVID,” Dr. Pantelic says. “It has also been clear to me from the start that this stigma is detrimental not just for people’s dignity, but also public health.”

Even some doctors argue that the growing attention paid to long COVID is excessive.

“It’s often normal to experience mild fatigue or weaknesses for weeks after being sick and inactive and not eating well. Calling these cases long COVID is the medicalization of modern life,” Marty Makary, MD, a surgeon and public policy researcher at Johns Hopkins University, Baltimore, wrote in a commentary in the Wall Street Journal.

Other doctors strongly disagree, including Alba Azola, MD, codirector of the Johns Hopkins Post-Acute COVID-19 Team and an expert in the stigma surrounding long COVID.

“Putting that spin on things, it’s just hurting people,” she says.

One example is people who cannot return to work.

“A lot of their family members tell me that they’re being lazy,” Dr. Azola says. “That’s part of the public stigma, that these are people just trying to get out of work.”

Some experts say the U.K. study represents a landmark.

“When you have data like this on long COVID stigma, it becomes more difficult to deny its existence or address it,” says Naomi Torres-Mackie, PhD, a clinical psychologist at Lenox Hill Hospital in New York. She also is head of research at the New York–based Mental Health Coalition, a group of experts working to end the stigma surrounding mental health.

She recalls her first patient with long COVID.

“She experienced the discomfort and pain itself, and then she had this crushing feeling that it wasn’t valid, or real. She felt very alone in it,” Dr. Torres-Mackie says.

Another one of her patients is working at her job from home but facing doubt about her condition from her employers.

“Every month, her medical doctor has to produce a letter confirming her medical condition,” Dr. Torres-Mackie says.

Taking part in the British stigma survey were 1,166 people, including 966 residents of the United Kingdom, with the average age of 48. Nearly 85% were female, and more than three-quarters were educated at the university level or higher.

Half of them said they had a clinical diagnosis of long COVID.

More than 60% of them said that at least some of the time, they were cautious about who they talked to about their condition. And fully 34% of those who did disclose their diagnosis said that they regretted having done so.

That’s a difficult experience for those with long COVID, says Leonard Jason, PhD, a professor of psychology at DePaul University in Chicago.

“It’s like they’re traumatized by the initial experience of being sick, and retraumatized by the response of others to them,” he says.

Unexplained illnesses are not well-regarded by the general public, Dr. Jason says.

He gave the example of multiple sclerosis. Before the 1980s, those with MS were considered to have a psychological illness, he says. “Then, in the 1980s, there were biomarkers that said, ‘Here’s the evidence.’ ”

The British study described three types of stigma stemming from the long COVID diagnosis of those questioned:

• Enacted stigma: People were directly treated unfairly because of their condition.
• Internalized stigma: People felt embarrassed by that condition.
• Anticipated stigma: People expected they would be treated poorly because of their diagnosis.

Dr. Azola calls the medical community a major problem when it comes to dealing with long COVID.

“What I see with my patients is medical trauma,” she says. They may have symptoms that send them to the emergency room, and then the tests come back negative. “Instead of tracking the patients’ symptoms, patients get told, ‘Everything looks good, you can go home, this is a panic attack,’ ” she says.

Some people go online to search for treatments, sometimes launching GoFundMe campaigns to raise money for unreliable treatments.

Long COVID patients may have gone through 5 to 10 doctors before they arrive for treatment with the Johns Hopkins Post-Acute COVID-19 Team. The clinic began in April 2020 remotely and in August of that year in person.

Today, the clinic staff spends an hour with a first-time long COVID patient, hearing their stories and helping relieve anxiety, Dr. Azola says.

The phenomenon of long COVID is similar to what patients have had with chronic fatigue syndrome, lupus, or fibromyalgia, where people have symptoms that are hard to explain, says Jennifer Chevinsky, MD, deputy public health officer for Riverside County, Calif.

“Stigma within medicine or health care is nothing new,” she says.

In Chicago, Dr. Jason notes that the federal government’s decision to invest hundreds of millions of dollars in long COVID research “shows the government is helping destigmatize it.”

Dr. Pantelic says she and her colleagues are continuing their research.

“We are interested in understanding the impacts of this stigma, and how to mitigate any adverse outcomes for patients and services,” she says.

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

Asthma affects more than 300 million people worldwide.¹ While many of these cases can achieve control with standard therapy, 5% to 10% of these cases are classified as severe asthma, remaining poorly controlled despite treatment with inhaled corticosteroids (ICS) and long-acting β agonists (LABA).² These patients also account for the majority of morbidity and mortality associated with the disease, with increased hospitalizations, intensive care unit (ICU) stays, detrimental adverse effects of oral corticosteroids (OCS), and lower quality of life.^3-6 Additionally, the financial repercussions of severe asthma are notable; in the United States, the estimated cost of asthma management is $82 billion annually, with $3 billion accounting for asthma-related work/school absences.⁷

In the past several years, the use of anti-immunoglobulin E (IgE), anti-interleukin-4 (IL-4), and anti-IL-5 biologic agents for severe asthma has been shown to decrease asthma exacerbations, improve lung function, reduce corticosteroid use, and decrease hospitalizations, especially for type 2 helper T cell (TH2-high) asthma.^8-10 However, clinicians have observed significant barriers to the implementation and widespread use of biologics, including insurance coverage, long wait times, follow-up, and limited access for lower income groups.^11,12

This article describes a unique model for a severe asthma clinic located at the Washington DC Veterans Affairs Medical Center (WDCVAMC) that is dually staffed by an allergist and pulmonologist. This clinic uses biologic agents for patients with difficult-to-treat asthma, many of whom require repeated or prolonged steroid use, in addition to prolonged and recurrent hospitalizations for exacerbations. The objective of this clinic is to provide a standardized approach to the management of severe asthma with the perspective of both an allergist and pulmonologist, thereby reducing the need to schedule appointments with multiple specialties and reducing delays in initiating biologics. This article presents the preliminary findings of 30 months of severe asthma management with various biologic agents, examining the impact of these therapies on hospitalizations, asthma exacerbations, ICU stays, and OCS use. The findings of this study support the benefits of biologics and suggest that the use of these agents within a dually staffed clinic may be a particularly effective model through which to manage severe asthma.

Background

Asthma affects approximately 20 million adults in the United States.¹³ Veterans are a population particularly impacted by asthma. Between 2015 and 2018, 10.9% of all veterans reported being diagnosed with asthma and 5.1% stated that they currently have asthma, compared with 13.4% and 8.0% of nonveterans, respectively.¹⁴ Veterans are susceptible to many of the factors that can trigger exacerbations while engaging in military service, such as chemical and environmental exposures both abroad and domestically.^15,16 Additionally, medication adherence is often challenging among the veteran population, particularly with more involved therapy, such as inhaler use.¹⁷ Such factors contribute to asthma exacerbations, with 2.9% of veterans reporting at least 1 asthma exacerbation in the past 12 months.¹⁴

Over the past several years, the development and use of biologic agents have transformed the management of severe asthma.⁸ Before the development of biologic agents for severe asthma, treatment options for patients were limited. While OCS are frequently used for asthma exacerbations, they are associated with a multiplicity of undesirable adverse effects, including weight gain, mood lability, gastrointestinal upset, hyperglycemia, risk of bone fractures, and hypertension.^18-20 The regular use of OCS are particularly problematic among other medical comorbidities commonly affecting the veteran population, such as diabetes and hypertension.^21-22

The WDCVAMC severe allergy clinic used 3 biologic agents: omalizumab (anti-IgE), benralizumab (anti-IL-5), and agent dupilumab (anti-IL-4). These medications have shown significant improvements in quality of life, reduction in asthma exacerbations and hospitalizations, and decreased use of OCS.^8,9 While research has firmly established the medical benefits of the use of biologic agents in severe asthma, several barriers exist in implementing widespread use.^11,12

In Gelhorn and colleagues’ study examining both physician and patient challenges in the use of biologics for severe asthma, scheduling, administrative time, and insurance costs were found to be major barriers to the use of these medications.¹² Patients expressed a preference for the administration of these medications in a specialist’s office but cited long wait times and scheduling difficulties as barriers. One of the most notable challenges from the physician perspective was the difficulty in obtaining reimbursement from insurance companies, requiring them to devote significant portions of time to prior authorizations and documentation.¹²

This article examines a dual specialty clinic that focuses on the treatment of severe asthma with biologic agents. This model is unique for several reasons. First, given the US Department of Veterans Affairs (VA) health care model, the health care practitioners (HCPs) in this clinic can avoid much of the administrative burden of obtaining reimbursement or working with insurance companies. Additionally, by dedicating specific days to the severe asthma clinic, patients do not experience long wait times to see both an allergist and pulmonologist. By seeing both clinicians, concurrent allergic and pulmonary issues can be addressed in the same visit, rather than delaying treatment by waiting on 2 specialist appointments.

Severe Asthma Clinic

The severe asthma clinic was started in September 2017 by a pulmonologist and an allergist at WDCVAMC. After experiencing substantial delays with the initiation of biologics for their patients and multiple referrals between their clinics, these physicians wanted to start a dually staffed asthma clinic to specifically focus on evaluating and treating severe asthma. A dedicated severe asthma clinic allowed the allergist and pulmonologist to streamline resources and collaborate to advocate for patients with the pharmacy section. Additionally, patients can benefit from the perspective of both specialists, as both the pulmonologist and allergist evaluate each patient and discuss the next steps of management.

This clinic is composed of 4 registered nurses, an allergist, and a pulmonologist. Clinic is held twice monthly through both telemedicine and in-office visits. The VA has strict guidelines for the use of certain biologics, including blood eosinophil count > 150 cells/µL, failure of traditional therapy, and frequent use of OCS. Additionally, to ensure these biologic agents are prescribed to patients that will benefit from them, the patients enrolled in this clinic are already on maximum therapy for their asthma, meaning all other therapeutic options (inhalers and oral medications) are being used. The clinic services all patients with severe asthma, not just patients who are on biologic therapy. Often, patients are referred to the severe allergy clinic late in their disease course given a lack of familiarity with biologic agents from prescribers and both institutional and insurance barriers.

Before the COVID-19 pandemic, spirometry and fractional exhaled nitric oxide (FENO) tests were recorded at each visit. Initially during the pandemic, the clinic transitioned to primarily telemedicine visits due to patients’ hesitance to seek in-person care. More recently, the clinic has transitioned back to primarily office visits; patients are seen in clinic on average every 3 months. At each visit, the patient is seen by both the pulmonologist and allergist. Additionally, the nursing staff reviews inhaler adherence with patients, spacer use, documents, Asthma Control Test (ACT) scores, and schedules follow-up visits.

Every 4 to 8 weeks, patients receive biologics agent at the WDCVAMC infusion center depending on the agent. The infusion center also instructs patients how to handle self-administered medications, like benralizumab, if the patient expresses a preference for taking it at home. Omalizumab has a boxed warning for anaphylaxis, although the other biologics in this study have a low risk of anaphylaxis. All patients receiving omalizumab, benralizumab, and dupilumab were provided with epinephrine injection devices in case of an allergic reaction and were taught how to use them in the clinic.^23,24

If patients continued to experience asthma exacerbations after the initiation of a biologic, a change in agent was considered after 4 to 6 months. Additionally, a complete blood count, respiratory allergy panel, and pulmonary function tests (PFTs) were completed.

Clinic Patients

Preliminary data were obtained from a retrospective chart review of 15 patients enrolled in the severe asthma clinic over 30 months. The inclusion criteria for chart review consisted of patients aged > 18 years receiving a biologic agent for > 3 months for the treatment of severe asthma. The outcomes examined included steroid use, emergency department (ED) visits, hospitalizations, FEV₁, and ICU stays.

Seven patients used benralizumab, 6 used dupilumab, and 2 used omalizumab (Table).

There was a notable clinical improvement in these patients. Before starting a biologic agent, all the patients in this study were prescribed steroids at least once a year for an asthma exacerbation, with a mean of 4.2 steroid tapers per year.

Discussion

The 15 patients in this initial data were referred to the severe asthma clinic by pulmonology, ear, nose, and throat (ENT), primary care, and a hospitalist during an in-patient stay. As the enrollment in our clinic grows, an increasing number of patients are referred from the allergy clinic as well. Patients in the severe asthma clinic also are referred by regional centers as news of the clinic is spread by word of mouth to surrounding VA facilities. As our clinic gains the capacity to serve more patients, we hope to contact WDCVAMC primary care, pulmonology, allergy, and ENT departments to raise awareness of the clinic.

Benralizumab and dupilumab were the most used agents in this preliminary data. This finding was largely due to the ability of patients to self-administer benralizumab, which was particularly beneficial during the COVID-19 pandemic. Of note, 5 patients in this study switched from another biologic agent to benralizumab due to the ability to self-administer. Three of 5 patients that required steroids after initiating benralizumab used fewer steroids than they had previously. This finding suggests benralizumab may be the preferred agent when travel time to health care is a challenge, reducing the need for frequent clinic visits and transportation.

This preliminary data supports previous studies that have demonstrated that biologic agents improve clinical outcomes by reducing asthma exacerbations, OCS use, hospitalizations, and ICU stays for patients on all 4 biologic agents. In addition to improving patient health through avoiding complications of prolonged OCS use and hospital stays, the decrease in ED visits and hospitalizations provides a substantial cost reduction to the health care system.  

These findings highlight the strength of a unique model of a combined allergy/pulmonary clinic. Before this combined clinic model, both pulmonology and allergy clinics noted delays in the initiation of biologics for patients who were potential candidates. Impediments include referrals between each specialty for evaluation of concurrent pulmonary conditions or allergy testing, overlap in asthma management, and a delay in coordination with the pharmacy department to start biologic agents. A dedicated severe asthma clinic staffed by both an allergist and pulmonologist provides a convenient option for patients to be seen by both specialists, reducing the need for separate appointments with each specialty, transportation to those appointments, and clinical time. This is particularly beneficial in a clinic such as this model, as this clinic serves patients from 4 states and Washington, DC. An additional benefit of this model is trained staff who directly communicate with the pharmacy in the initiation of these agents, allocate time to educating patients in biologic use, and coordinate follow-up.

Limitations

There were several limitations to this report. First, the number of patients examined in this preliminary data set is small. Due to the COVID-19 pandemic, there was a limited ability to see patients in person, and patients were seen exclusively over telemedicine for several months. For this reason, collecting data such as patient surveys and laboratory work following the initiation of a biologic was a challenge. Additionally, during the height of COVID-19, WDCVAMC did not perform aerosolizing procedures, such as PFTs and FENOs; thus, peak flows were obtained instead. Examining metrics, such as FENOs and IgE levels, and expanding PFT data would provide additional insight into the impact of biologic agents on clinical outcomes. Patient survey data in the form of ACTs or satisfaction surveys would also yield important data examining the impact of this clinic design and biologic use on patient experience. As of December 2022, 114 patients are enrolled in the clinic. We are working to collect the above laboratory results and spirometry for these patients so that these results can be published with a more robust data set. Another limitation of the information presented is that it is a retrospective data analysis; the data collected was contingent upon documentation and the assumption that these patients were exclusively receiving care through the VA. For example, steroid use before and after initiation of biologic was taken from asthma clinic notes and the patient’s medication list. Therefore, there is a possibility that not all instances were accounted for if that patient sought care outside the VA or whether it was not documented in a follow-up note.

Conclusions

The model of a combined allergy/pulmonology clinic can be particularly efficacious in the treatment of severe asthma, as it reduces the need for multiple appointments with different specialties, reduces wait time before starting a biologic agent, and offers the perspective of 2 specialists. This kind of model could be an example to many clinics in the VA. With a rapid increase in telemedicine due to the COVID-19 pandemic, multiple physicians consulting simultaneously is becoming a more feasible possibility across multiple specialties. As the use of biologics becomes more widespread, a combined clinic design is an efficient and promising method to improve severe asthma management.

This preliminary data continue to support previous research that shows biologic agents have led to better clinical outcomes through the reduction of asthma exacerbations, hospitalizations, and improved PFTs. While this initial data set highlights the results for 15 patients, there are 86 patients currently enrolled in this clinic. We are collecting additional data to publish more comprehensive results.

Asthma affects more than 300 million people worldwide.¹ While many of these cases can achieve control with standard therapy, 5% to 10% of these cases are classified as severe asthma, remaining poorly controlled despite treatment with inhaled corticosteroids (ICS) and long-acting β agonists (LABA).² These patients also account for the majority of morbidity and mortality associated with the disease, with increased hospitalizations, intensive care unit (ICU) stays, detrimental adverse effects of oral corticosteroids (OCS), and lower quality of life.^3-6 Additionally, the financial repercussions of severe asthma are notable; in the United States, the estimated cost of asthma management is $82 billion annually, with $3 billion accounting for asthma-related work/school absences.⁷

In the past several years, the use of anti-immunoglobulin E (IgE), anti-interleukin-4 (IL-4), and anti-IL-5 biologic agents for severe asthma has been shown to decrease asthma exacerbations, improve lung function, reduce corticosteroid use, and decrease hospitalizations, especially for type 2 helper T cell (TH2-high) asthma.^8-10 However, clinicians have observed significant barriers to the implementation and widespread use of biologics, including insurance coverage, long wait times, follow-up, and limited access for lower income groups.^11,12

This article describes a unique model for a severe asthma clinic located at the Washington DC Veterans Affairs Medical Center (WDCVAMC) that is dually staffed by an allergist and pulmonologist. This clinic uses biologic agents for patients with difficult-to-treat asthma, many of whom require repeated or prolonged steroid use, in addition to prolonged and recurrent hospitalizations for exacerbations. The objective of this clinic is to provide a standardized approach to the management of severe asthma with the perspective of both an allergist and pulmonologist, thereby reducing the need to schedule appointments with multiple specialties and reducing delays in initiating biologics. This article presents the preliminary findings of 30 months of severe asthma management with various biologic agents, examining the impact of these therapies on hospitalizations, asthma exacerbations, ICU stays, and OCS use. The findings of this study support the benefits of biologics and suggest that the use of these agents within a dually staffed clinic may be a particularly effective model through which to manage severe asthma.

Background

Asthma affects approximately 20 million adults in the United States.¹³ Veterans are a population particularly impacted by asthma. Between 2015 and 2018, 10.9% of all veterans reported being diagnosed with asthma and 5.1% stated that they currently have asthma, compared with 13.4% and 8.0% of nonveterans, respectively.¹⁴ Veterans are susceptible to many of the factors that can trigger exacerbations while engaging in military service, such as chemical and environmental exposures both abroad and domestically.^15,16 Additionally, medication adherence is often challenging among the veteran population, particularly with more involved therapy, such as inhaler use.¹⁷ Such factors contribute to asthma exacerbations, with 2.9% of veterans reporting at least 1 asthma exacerbation in the past 12 months.¹⁴

Over the past several years, the development and use of biologic agents have transformed the management of severe asthma.⁸ Before the development of biologic agents for severe asthma, treatment options for patients were limited. While OCS are frequently used for asthma exacerbations, they are associated with a multiplicity of undesirable adverse effects, including weight gain, mood lability, gastrointestinal upset, hyperglycemia, risk of bone fractures, and hypertension.^18-20 The regular use of OCS are particularly problematic among other medical comorbidities commonly affecting the veteran population, such as diabetes and hypertension.^21-22

The WDCVAMC severe allergy clinic used 3 biologic agents: omalizumab (anti-IgE), benralizumab (anti-IL-5), and agent dupilumab (anti-IL-4). These medications have shown significant improvements in quality of life, reduction in asthma exacerbations and hospitalizations, and decreased use of OCS.^8,9 While research has firmly established the medical benefits of the use of biologic agents in severe asthma, several barriers exist in implementing widespread use.^11,12

In Gelhorn and colleagues’ study examining both physician and patient challenges in the use of biologics for severe asthma, scheduling, administrative time, and insurance costs were found to be major barriers to the use of these medications.¹² Patients expressed a preference for the administration of these medications in a specialist’s office but cited long wait times and scheduling difficulties as barriers. One of the most notable challenges from the physician perspective was the difficulty in obtaining reimbursement from insurance companies, requiring them to devote significant portions of time to prior authorizations and documentation.¹²

This article examines a dual specialty clinic that focuses on the treatment of severe asthma with biologic agents. This model is unique for several reasons. First, given the US Department of Veterans Affairs (VA) health care model, the health care practitioners (HCPs) in this clinic can avoid much of the administrative burden of obtaining reimbursement or working with insurance companies. Additionally, by dedicating specific days to the severe asthma clinic, patients do not experience long wait times to see both an allergist and pulmonologist. By seeing both clinicians, concurrent allergic and pulmonary issues can be addressed in the same visit, rather than delaying treatment by waiting on 2 specialist appointments.

Severe Asthma Clinic

The severe asthma clinic was started in September 2017 by a pulmonologist and an allergist at WDCVAMC. After experiencing substantial delays with the initiation of biologics for their patients and multiple referrals between their clinics, these physicians wanted to start a dually staffed asthma clinic to specifically focus on evaluating and treating severe asthma. A dedicated severe asthma clinic allowed the allergist and pulmonologist to streamline resources and collaborate to advocate for patients with the pharmacy section. Additionally, patients can benefit from the perspective of both specialists, as both the pulmonologist and allergist evaluate each patient and discuss the next steps of management.

This clinic is composed of 4 registered nurses, an allergist, and a pulmonologist. Clinic is held twice monthly through both telemedicine and in-office visits. The VA has strict guidelines for the use of certain biologics, including blood eosinophil count > 150 cells/µL, failure of traditional therapy, and frequent use of OCS. Additionally, to ensure these biologic agents are prescribed to patients that will benefit from them, the patients enrolled in this clinic are already on maximum therapy for their asthma, meaning all other therapeutic options (inhalers and oral medications) are being used. The clinic services all patients with severe asthma, not just patients who are on biologic therapy. Often, patients are referred to the severe allergy clinic late in their disease course given a lack of familiarity with biologic agents from prescribers and both institutional and insurance barriers.

Before the COVID-19 pandemic, spirometry and fractional exhaled nitric oxide (FENO) tests were recorded at each visit. Initially during the pandemic, the clinic transitioned to primarily telemedicine visits due to patients’ hesitance to seek in-person care. More recently, the clinic has transitioned back to primarily office visits; patients are seen in clinic on average every 3 months. At each visit, the patient is seen by both the pulmonologist and allergist. Additionally, the nursing staff reviews inhaler adherence with patients, spacer use, documents, Asthma Control Test (ACT) scores, and schedules follow-up visits.

Every 4 to 8 weeks, patients receive biologics agent at the WDCVAMC infusion center depending on the agent. The infusion center also instructs patients how to handle self-administered medications, like benralizumab, if the patient expresses a preference for taking it at home. Omalizumab has a boxed warning for anaphylaxis, although the other biologics in this study have a low risk of anaphylaxis. All patients receiving omalizumab, benralizumab, and dupilumab were provided with epinephrine injection devices in case of an allergic reaction and were taught how to use them in the clinic.^23,24

If patients continued to experience asthma exacerbations after the initiation of a biologic, a change in agent was considered after 4 to 6 months. Additionally, a complete blood count, respiratory allergy panel, and pulmonary function tests (PFTs) were completed.

Clinic Patients

Preliminary data were obtained from a retrospective chart review of 15 patients enrolled in the severe asthma clinic over 30 months. The inclusion criteria for chart review consisted of patients aged > 18 years receiving a biologic agent for > 3 months for the treatment of severe asthma. The outcomes examined included steroid use, emergency department (ED) visits, hospitalizations, FEV₁, and ICU stays.

Seven patients used benralizumab, 6 used dupilumab, and 2 used omalizumab (Table).

There was a notable clinical improvement in these patients. Before starting a biologic agent, all the patients in this study were prescribed steroids at least once a year for an asthma exacerbation, with a mean of 4.2 steroid tapers per year.

Discussion

The 15 patients in this initial data were referred to the severe asthma clinic by pulmonology, ear, nose, and throat (ENT), primary care, and a hospitalist during an in-patient stay. As the enrollment in our clinic grows, an increasing number of patients are referred from the allergy clinic as well. Patients in the severe asthma clinic also are referred by regional centers as news of the clinic is spread by word of mouth to surrounding VA facilities. As our clinic gains the capacity to serve more patients, we hope to contact WDCVAMC primary care, pulmonology, allergy, and ENT departments to raise awareness of the clinic.

Benralizumab and dupilumab were the most used agents in this preliminary data. This finding was largely due to the ability of patients to self-administer benralizumab, which was particularly beneficial during the COVID-19 pandemic. Of note, 5 patients in this study switched from another biologic agent to benralizumab due to the ability to self-administer. Three of 5 patients that required steroids after initiating benralizumab used fewer steroids than they had previously. This finding suggests benralizumab may be the preferred agent when travel time to health care is a challenge, reducing the need for frequent clinic visits and transportation.

This preliminary data supports previous studies that have demonstrated that biologic agents improve clinical outcomes by reducing asthma exacerbations, OCS use, hospitalizations, and ICU stays for patients on all 4 biologic agents. In addition to improving patient health through avoiding complications of prolonged OCS use and hospital stays, the decrease in ED visits and hospitalizations provides a substantial cost reduction to the health care system.  

These findings highlight the strength of a unique model of a combined allergy/pulmonary clinic. Before this combined clinic model, both pulmonology and allergy clinics noted delays in the initiation of biologics for patients who were potential candidates. Impediments include referrals between each specialty for evaluation of concurrent pulmonary conditions or allergy testing, overlap in asthma management, and a delay in coordination with the pharmacy department to start biologic agents. A dedicated severe asthma clinic staffed by both an allergist and pulmonologist provides a convenient option for patients to be seen by both specialists, reducing the need for separate appointments with each specialty, transportation to those appointments, and clinical time. This is particularly beneficial in a clinic such as this model, as this clinic serves patients from 4 states and Washington, DC. An additional benefit of this model is trained staff who directly communicate with the pharmacy in the initiation of these agents, allocate time to educating patients in biologic use, and coordinate follow-up.

Limitations

There were several limitations to this report. First, the number of patients examined in this preliminary data set is small. Due to the COVID-19 pandemic, there was a limited ability to see patients in person, and patients were seen exclusively over telemedicine for several months. For this reason, collecting data such as patient surveys and laboratory work following the initiation of a biologic was a challenge. Additionally, during the height of COVID-19, WDCVAMC did not perform aerosolizing procedures, such as PFTs and FENOs; thus, peak flows were obtained instead. Examining metrics, such as FENOs and IgE levels, and expanding PFT data would provide additional insight into the impact of biologic agents on clinical outcomes. Patient survey data in the form of ACTs or satisfaction surveys would also yield important data examining the impact of this clinic design and biologic use on patient experience. As of December 2022, 114 patients are enrolled in the clinic. We are working to collect the above laboratory results and spirometry for these patients so that these results can be published with a more robust data set. Another limitation of the information presented is that it is a retrospective data analysis; the data collected was contingent upon documentation and the assumption that these patients were exclusively receiving care through the VA. For example, steroid use before and after initiation of biologic was taken from asthma clinic notes and the patient’s medication list. Therefore, there is a possibility that not all instances were accounted for if that patient sought care outside the VA or whether it was not documented in a follow-up note.

Conclusions

The model of a combined allergy/pulmonology clinic can be particularly efficacious in the treatment of severe asthma, as it reduces the need for multiple appointments with different specialties, reduces wait time before starting a biologic agent, and offers the perspective of 2 specialists. This kind of model could be an example to many clinics in the VA. With a rapid increase in telemedicine due to the COVID-19 pandemic, multiple physicians consulting simultaneously is becoming a more feasible possibility across multiple specialties. As the use of biologics becomes more widespread, a combined clinic design is an efficient and promising method to improve severe asthma management.

This preliminary data continue to support previous research that shows biologic agents have led to better clinical outcomes through the reduction of asthma exacerbations, hospitalizations, and improved PFTs. While this initial data set highlights the results for 15 patients, there are 86 patients currently enrolled in this clinic. We are collecting additional data to publish more comprehensive results.

Asthma affects more than 300 million people worldwide.¹ While many of these cases can achieve control with standard therapy, 5% to 10% of these cases are classified as severe asthma, remaining poorly controlled despite treatment with inhaled corticosteroids (ICS) and long-acting β agonists (LABA).² These patients also account for the majority of morbidity and mortality associated with the disease, with increased hospitalizations, intensive care unit (ICU) stays, detrimental adverse effects of oral corticosteroids (OCS), and lower quality of life.^3-6 Additionally, the financial repercussions of severe asthma are notable; in the United States, the estimated cost of asthma management is $82 billion annually, with $3 billion accounting for asthma-related work/school absences.⁷

In the past several years, the use of anti-immunoglobulin E (IgE), anti-interleukin-4 (IL-4), and anti-IL-5 biologic agents for severe asthma has been shown to decrease asthma exacerbations, improve lung function, reduce corticosteroid use, and decrease hospitalizations, especially for type 2 helper T cell (TH2-high) asthma.^8-10 However, clinicians have observed significant barriers to the implementation and widespread use of biologics, including insurance coverage, long wait times, follow-up, and limited access for lower income groups.^11,12

This article describes a unique model for a severe asthma clinic located at the Washington DC Veterans Affairs Medical Center (WDCVAMC) that is dually staffed by an allergist and pulmonologist. This clinic uses biologic agents for patients with difficult-to-treat asthma, many of whom require repeated or prolonged steroid use, in addition to prolonged and recurrent hospitalizations for exacerbations. The objective of this clinic is to provide a standardized approach to the management of severe asthma with the perspective of both an allergist and pulmonologist, thereby reducing the need to schedule appointments with multiple specialties and reducing delays in initiating biologics. This article presents the preliminary findings of 30 months of severe asthma management with various biologic agents, examining the impact of these therapies on hospitalizations, asthma exacerbations, ICU stays, and OCS use. The findings of this study support the benefits of biologics and suggest that the use of these agents within a dually staffed clinic may be a particularly effective model through which to manage severe asthma.

Background

Asthma affects approximately 20 million adults in the United States.¹³ Veterans are a population particularly impacted by asthma. Between 2015 and 2018, 10.9% of all veterans reported being diagnosed with asthma and 5.1% stated that they currently have asthma, compared with 13.4% and 8.0% of nonveterans, respectively.¹⁴ Veterans are susceptible to many of the factors that can trigger exacerbations while engaging in military service, such as chemical and environmental exposures both abroad and domestically.^15,16 Additionally, medication adherence is often challenging among the veteran population, particularly with more involved therapy, such as inhaler use.¹⁷ Such factors contribute to asthma exacerbations, with 2.9% of veterans reporting at least 1 asthma exacerbation in the past 12 months.¹⁴

Over the past several years, the development and use of biologic agents have transformed the management of severe asthma.⁸ Before the development of biologic agents for severe asthma, treatment options for patients were limited. While OCS are frequently used for asthma exacerbations, they are associated with a multiplicity of undesirable adverse effects, including weight gain, mood lability, gastrointestinal upset, hyperglycemia, risk of bone fractures, and hypertension.^18-20 The regular use of OCS are particularly problematic among other medical comorbidities commonly affecting the veteran population, such as diabetes and hypertension.^21-22

The WDCVAMC severe allergy clinic used 3 biologic agents: omalizumab (anti-IgE), benralizumab (anti-IL-5), and agent dupilumab (anti-IL-4). These medications have shown significant improvements in quality of life, reduction in asthma exacerbations and hospitalizations, and decreased use of OCS.^8,9 While research has firmly established the medical benefits of the use of biologic agents in severe asthma, several barriers exist in implementing widespread use.^11,12

In Gelhorn and colleagues’ study examining both physician and patient challenges in the use of biologics for severe asthma, scheduling, administrative time, and insurance costs were found to be major barriers to the use of these medications.¹² Patients expressed a preference for the administration of these medications in a specialist’s office but cited long wait times and scheduling difficulties as barriers. One of the most notable challenges from the physician perspective was the difficulty in obtaining reimbursement from insurance companies, requiring them to devote significant portions of time to prior authorizations and documentation.¹²

This article examines a dual specialty clinic that focuses on the treatment of severe asthma with biologic agents. This model is unique for several reasons. First, given the US Department of Veterans Affairs (VA) health care model, the health care practitioners (HCPs) in this clinic can avoid much of the administrative burden of obtaining reimbursement or working with insurance companies. Additionally, by dedicating specific days to the severe asthma clinic, patients do not experience long wait times to see both an allergist and pulmonologist. By seeing both clinicians, concurrent allergic and pulmonary issues can be addressed in the same visit, rather than delaying treatment by waiting on 2 specialist appointments.

Severe Asthma Clinic

The severe asthma clinic was started in September 2017 by a pulmonologist and an allergist at WDCVAMC. After experiencing substantial delays with the initiation of biologics for their patients and multiple referrals between their clinics, these physicians wanted to start a dually staffed asthma clinic to specifically focus on evaluating and treating severe asthma. A dedicated severe asthma clinic allowed the allergist and pulmonologist to streamline resources and collaborate to advocate for patients with the pharmacy section. Additionally, patients can benefit from the perspective of both specialists, as both the pulmonologist and allergist evaluate each patient and discuss the next steps of management.

This clinic is composed of 4 registered nurses, an allergist, and a pulmonologist. Clinic is held twice monthly through both telemedicine and in-office visits. The VA has strict guidelines for the use of certain biologics, including blood eosinophil count > 150 cells/µL, failure of traditional therapy, and frequent use of OCS. Additionally, to ensure these biologic agents are prescribed to patients that will benefit from them, the patients enrolled in this clinic are already on maximum therapy for their asthma, meaning all other therapeutic options (inhalers and oral medications) are being used. The clinic services all patients with severe asthma, not just patients who are on biologic therapy. Often, patients are referred to the severe allergy clinic late in their disease course given a lack of familiarity with biologic agents from prescribers and both institutional and insurance barriers.

Before the COVID-19 pandemic, spirometry and fractional exhaled nitric oxide (FENO) tests were recorded at each visit. Initially during the pandemic, the clinic transitioned to primarily telemedicine visits due to patients’ hesitance to seek in-person care. More recently, the clinic has transitioned back to primarily office visits; patients are seen in clinic on average every 3 months. At each visit, the patient is seen by both the pulmonologist and allergist. Additionally, the nursing staff reviews inhaler adherence with patients, spacer use, documents, Asthma Control Test (ACT) scores, and schedules follow-up visits.

Every 4 to 8 weeks, patients receive biologics agent at the WDCVAMC infusion center depending on the agent. The infusion center also instructs patients how to handle self-administered medications, like benralizumab, if the patient expresses a preference for taking it at home. Omalizumab has a boxed warning for anaphylaxis, although the other biologics in this study have a low risk of anaphylaxis. All patients receiving omalizumab, benralizumab, and dupilumab were provided with epinephrine injection devices in case of an allergic reaction and were taught how to use them in the clinic.^23,24

If patients continued to experience asthma exacerbations after the initiation of a biologic, a change in agent was considered after 4 to 6 months. Additionally, a complete blood count, respiratory allergy panel, and pulmonary function tests (PFTs) were completed.

Clinic Patients

Preliminary data were obtained from a retrospective chart review of 15 patients enrolled in the severe asthma clinic over 30 months. The inclusion criteria for chart review consisted of patients aged > 18 years receiving a biologic agent for > 3 months for the treatment of severe asthma. The outcomes examined included steroid use, emergency department (ED) visits, hospitalizations, FEV₁, and ICU stays.

Seven patients used benralizumab, 6 used dupilumab, and 2 used omalizumab (Table).

There was a notable clinical improvement in these patients. Before starting a biologic agent, all the patients in this study were prescribed steroids at least once a year for an asthma exacerbation, with a mean of 4.2 steroid tapers per year.

Discussion

The 15 patients in this initial data were referred to the severe asthma clinic by pulmonology, ear, nose, and throat (ENT), primary care, and a hospitalist during an in-patient stay. As the enrollment in our clinic grows, an increasing number of patients are referred from the allergy clinic as well. Patients in the severe asthma clinic also are referred by regional centers as news of the clinic is spread by word of mouth to surrounding VA facilities. As our clinic gains the capacity to serve more patients, we hope to contact WDCVAMC primary care, pulmonology, allergy, and ENT departments to raise awareness of the clinic.

Benralizumab and dupilumab were the most used agents in this preliminary data. This finding was largely due to the ability of patients to self-administer benralizumab, which was particularly beneficial during the COVID-19 pandemic. Of note, 5 patients in this study switched from another biologic agent to benralizumab due to the ability to self-administer. Three of 5 patients that required steroids after initiating benralizumab used fewer steroids than they had previously. This finding suggests benralizumab may be the preferred agent when travel time to health care is a challenge, reducing the need for frequent clinic visits and transportation.

This preliminary data supports previous studies that have demonstrated that biologic agents improve clinical outcomes by reducing asthma exacerbations, OCS use, hospitalizations, and ICU stays for patients on all 4 biologic agents. In addition to improving patient health through avoiding complications of prolonged OCS use and hospital stays, the decrease in ED visits and hospitalizations provides a substantial cost reduction to the health care system.  

These findings highlight the strength of a unique model of a combined allergy/pulmonary clinic. Before this combined clinic model, both pulmonology and allergy clinics noted delays in the initiation of biologics for patients who were potential candidates. Impediments include referrals between each specialty for evaluation of concurrent pulmonary conditions or allergy testing, overlap in asthma management, and a delay in coordination with the pharmacy department to start biologic agents. A dedicated severe asthma clinic staffed by both an allergist and pulmonologist provides a convenient option for patients to be seen by both specialists, reducing the need for separate appointments with each specialty, transportation to those appointments, and clinical time. This is particularly beneficial in a clinic such as this model, as this clinic serves patients from 4 states and Washington, DC. An additional benefit of this model is trained staff who directly communicate with the pharmacy in the initiation of these agents, allocate time to educating patients in biologic use, and coordinate follow-up.

Limitations

There were several limitations to this report. First, the number of patients examined in this preliminary data set is small. Due to the COVID-19 pandemic, there was a limited ability to see patients in person, and patients were seen exclusively over telemedicine for several months. For this reason, collecting data such as patient surveys and laboratory work following the initiation of a biologic was a challenge. Additionally, during the height of COVID-19, WDCVAMC did not perform aerosolizing procedures, such as PFTs and FENOs; thus, peak flows were obtained instead. Examining metrics, such as FENOs and IgE levels, and expanding PFT data would provide additional insight into the impact of biologic agents on clinical outcomes. Patient survey data in the form of ACTs or satisfaction surveys would also yield important data examining the impact of this clinic design and biologic use on patient experience. As of December 2022, 114 patients are enrolled in the clinic. We are working to collect the above laboratory results and spirometry for these patients so that these results can be published with a more robust data set. Another limitation of the information presented is that it is a retrospective data analysis; the data collected was contingent upon documentation and the assumption that these patients were exclusively receiving care through the VA. For example, steroid use before and after initiation of biologic was taken from asthma clinic notes and the patient’s medication list. Therefore, there is a possibility that not all instances were accounted for if that patient sought care outside the VA or whether it was not documented in a follow-up note.

Conclusions

The model of a combined allergy/pulmonology clinic can be particularly efficacious in the treatment of severe asthma, as it reduces the need for multiple appointments with different specialties, reduces wait time before starting a biologic agent, and offers the perspective of 2 specialists. This kind of model could be an example to many clinics in the VA. With a rapid increase in telemedicine due to the COVID-19 pandemic, multiple physicians consulting simultaneously is becoming a more feasible possibility across multiple specialties. As the use of biologics becomes more widespread, a combined clinic design is an efficient and promising method to improve severe asthma management.

This preliminary data continue to support previous research that shows biologic agents have led to better clinical outcomes through the reduction of asthma exacerbations, hospitalizations, and improved PFTs. While this initial data set highlights the results for 15 patients, there are 86 patients currently enrolled in this clinic. We are collecting additional data to publish more comprehensive results.

COVID-19 remained the top-ranked cause of death among law enforcement officers last year. 

A new report says 70 officers died of COVID-related causes after getting the virus while on the job. The number is down dramatically from 2021, when 405 officer deaths were attributed to COVID.

The annual count was published Wednesday by the National Law Enforcement Officers Memorial Fund.

In total, 226 officers died in the line of duty in 2022, which is a decrease of 61% from 2021.

The decrease “is almost entirely related to the significant reduction in COVID-19 deaths,” the report stated. The authors said the decline was likely due to “reduced infection rates and the broad availability and use of vaccinations.”

Reported deaths included federal, state, tribal, and local law enforcement officers.

Firearms-related fatalities were the second-leading cause of death among officers, with 64 in 2022. That count sustains a 21% increase seen in 2021, up from the decade-long average of 53 firearms-related deaths annually from 2010 to 2020. 

Traffic-related causes ranked third for cause of death in 2022, accounting for 56 deaths. 

“While overall line-of-duty deaths are trending down, the continuing trend of greater-than-average firearms-related deaths continues to be a serious concern,” Marcia Ferranto, the organization’s chief executive officer, said in a news release. “Using and reporting on this data allows us to highlight the continuing cost of maintaining our democracy, regrettably measured in the lives of the many law enforcement professionals who sacrifice everything fulfilling their promise to serve and protect.”

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

COVID-19 remained the top-ranked cause of death among law enforcement officers last year. 

A new report says 70 officers died of COVID-related causes after getting the virus while on the job. The number is down dramatically from 2021, when 405 officer deaths were attributed to COVID.

The annual count was published Wednesday by the National Law Enforcement Officers Memorial Fund.

In total, 226 officers died in the line of duty in 2022, which is a decrease of 61% from 2021.

The decrease “is almost entirely related to the significant reduction in COVID-19 deaths,” the report stated. The authors said the decline was likely due to “reduced infection rates and the broad availability and use of vaccinations.”

Reported deaths included federal, state, tribal, and local law enforcement officers.

Firearms-related fatalities were the second-leading cause of death among officers, with 64 in 2022. That count sustains a 21% increase seen in 2021, up from the decade-long average of 53 firearms-related deaths annually from 2010 to 2020. 

Traffic-related causes ranked third for cause of death in 2022, accounting for 56 deaths. 

“While overall line-of-duty deaths are trending down, the continuing trend of greater-than-average firearms-related deaths continues to be a serious concern,” Marcia Ferranto, the organization’s chief executive officer, said in a news release. “Using and reporting on this data allows us to highlight the continuing cost of maintaining our democracy, regrettably measured in the lives of the many law enforcement professionals who sacrifice everything fulfilling their promise to serve and protect.”

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

COVID-19 remained the top-ranked cause of death among law enforcement officers last year. 

A new report says 70 officers died of COVID-related causes after getting the virus while on the job. The number is down dramatically from 2021, when 405 officer deaths were attributed to COVID.

The annual count was published Wednesday by the National Law Enforcement Officers Memorial Fund.

In total, 226 officers died in the line of duty in 2022, which is a decrease of 61% from 2021.

The decrease “is almost entirely related to the significant reduction in COVID-19 deaths,” the report stated. The authors said the decline was likely due to “reduced infection rates and the broad availability and use of vaccinations.”

Reported deaths included federal, state, tribal, and local law enforcement officers.

Firearms-related fatalities were the second-leading cause of death among officers, with 64 in 2022. That count sustains a 21% increase seen in 2021, up from the decade-long average of 53 firearms-related deaths annually from 2010 to 2020. 

Traffic-related causes ranked third for cause of death in 2022, accounting for 56 deaths. 

“While overall line-of-duty deaths are trending down, the continuing trend of greater-than-average firearms-related deaths continues to be a serious concern,” Marcia Ferranto, the organization’s chief executive officer, said in a news release. “Using and reporting on this data allows us to highlight the continuing cost of maintaining our democracy, regrettably measured in the lives of the many law enforcement professionals who sacrifice everything fulfilling their promise to serve and protect.”

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

It started as a mountain biking excursion with two friends. When we drove into the trailhead parking lot, we saw several emergency vehicles. Then a helicopter passed overhead. As we got on our bikes, a police officer told us there’d been an accident out on the trail and to be careful because emergency personnel were going to be bringing in the patient. So we started the ride cautiously, ready to yield to emergency medical services.

Half a mile down the trail, we encountered another police officer. He asked if we would be willing to go back to get an oxygen tank from the ambulance and carry it out to the scene. The three of us turned around, went back to the parking lot and were able to snag a tank of oxygen. We put it in a backpack and biked out again.

We found the scene about a mile down the trail. An adult male was lying on his back in the dirt after a crash. His eyes were closed and he wasn’t moving except for occasional breaths. Six emergency medical personnel huddled around him, one assisting breaths with a bag mask. I didn’t introduce myself initially. I just listened to hear what was happening.

They were debating the dose of medication to give him in order to intubate. I knew the answer to that question, so I introduced myself. They were happy to have somebody else to assist.

They already had an IV in place and quite a lot of supplies. They administered the meds and the paramedic attempted to intubate through the mouth. Within a few seconds, she pulled the intubating blade out and said, “I’m not going to be able to get this. His tongue is too big.”

I took the blade myself and kneeled at the head of the victim. I made three attempts at intubating, and each time couldn’t view the landmarks. I wasn’t sure if his tongue was too large or if there was some traumatic injury. To make it more difficult, a lot of secretions clogged the airway. The paramedics had a portable suction, which was somewhat functional, but I still couldn’t visualize the landmarks.

I started asking about alternative methods of establishing an airway. They had an i-gel, which is a supraglottic device that goes into the back of the mouth. So, we placed it. But when we attached the bag, air still wasn’t getting into the lungs.

We removed it and put the bag mask back on. Now I was worried. We were having difficulty keeping his oxygen above 90%. I examined the chest and abdomen again. I was wondering if perhaps he was having some gastric distention, which can result from prolonged bagging, but that didn’t seem to be the case.

Bagging became progressively more difficult, and the oxygen slowly trended down through the 80s. Then the 70s. Heart rate dropped below 60 beats per minute. The trajectory was obvious.

That’s when I asked if they had the tools for a surgical airway.

No one thought the question was crazy. In fact, they pulled out a scalpel from an equipment bag.

But now I had to actually do it. I knelt next to the patient, trying to palpate the front of the neck to identify the correct location to cut. I had difficulty finding the appropriate landmarks there as well. Frustrating.

I glanced at the monitor. O₂ was now in the 60s. Later the paramedic told me the heart rate was down to 30.

One of the medics looked me in the eye and said, “We’ve got to do something. The time is now.” That helped me snap out of it and act. I made my large vertical incision on the front of the victim’s neck, which of course resulted in quite a bit of bleeding.

My two friends, who were watching, later told me this was the moment the intensity of the scene really increased (it was already pretty intense for me, thanks).

Next, I made the horizontal stab incision. Then I probed with my finger, but it seems the incision hadn’t reached the trachea. I had to make the stab much deeper than I would’ve thought.

And then air bubbled out through the blood. A paramedic was ready with the ET tube in hand and she put it through the incision. We attached the bag. We had air movement into the lungs, and within minutes the oxygen came up.

Not long after, the flight paramedics from the helicopter showed up, having jogged a mile through the woods. They seemed rather surprised to find a patient with a cricothyrotomy. We filled them in on the situation. Now we had to get the patient out of the woods (literally and figuratively).

The emergency responders had a really great transport device: A litter with one big wheel underneath in the middle so we could roll the patient down the mountain bike trail over rocks relatively safely. One person’s job was to hold the tube as we went since we didn’t have suture to hold it in place.

We got back to the parking lot and loaded him into the ambulance, which drove another mile to the helicopter, which then had to take him a hundred miles to the hospital.

To be honest, I thought the prognosis was poor. I suspected he had an intercranial bleed slowly squeezing his brain (that later turned out to not be the case). Even though we had established an airway, it took us so long to get him to the ambulance.

The director of the local EMS called me that evening and said the patient had made it to the hospital. I had never been a part of anything with this intensity. I definitely lost sleep over it. Partly just from the uncertainty of not knowing what the outcome would be. But also second-guessing if I had done everything that I could have.

The story doesn’t quite end there, however.

A week later, a friend of the patient called me. He had recovered well and was going to be discharged from the hospital. He’d chosen to share the story with the media, and the local TV station was going to interview him. They had asked if I would agree to be interviewed.

After the local news story ran, it was kind of a media blitz. In came numerous media requests. But honestly, the portrayal of the story made me feel really weird. It was overly dramatized and not entirely accurate. It really didn’t sit well with me.

Friends all over the country saw the story, and here’s what they got from the coverage:

I was biking behind the patient when he crashed.

I had my own tools. Even the patient himself was told I used my own blade to make the incision.

The true story is what I just told you: A half-dozen emergency medical personnel were already there when I arrived. It was a combination of all of us – together – in the right place at the right time.

A month later, the patient and his family drove to the city where I live to take me out to lunch. It was emotional. There were plenty of tears. His wife and daughter were expressing a lot of gratitude and had some gifts for me. I was able to get his version of the story and learned some details. He had facial trauma in the past with some reconstruction. I realized that perhaps those anatomical changes affected my ability to do the intubation.

I hope to never again have to do this outside of the hospital. But I suppose I’m more prepared than ever now. I’ve reviewed my cricothyrotomy technique many times since then.

I was trained as a family doctor and did clinic and hospital medicine for several years. It was only in 2020 that I transitioned to doing emergency medicine work in a rural hospital. So, 2 years earlier, I’m not sure I would’ve been able to do what I did that day. To me, it was almost symbolic of the transition of my practice to emergency medicine.

I’m still in touch with the patient. We’ve talked about biking together. That hasn’t happened yet, but it may very well happen someday.

Jesse Coenen, MD, is an emergency medicine physician at Hayward Area Memorial Hospital in Hayward, Wisc.

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

It started as a mountain biking excursion with two friends. When we drove into the trailhead parking lot, we saw several emergency vehicles. Then a helicopter passed overhead. As we got on our bikes, a police officer told us there’d been an accident out on the trail and to be careful because emergency personnel were going to be bringing in the patient. So we started the ride cautiously, ready to yield to emergency medical services.

Half a mile down the trail, we encountered another police officer. He asked if we would be willing to go back to get an oxygen tank from the ambulance and carry it out to the scene. The three of us turned around, went back to the parking lot and were able to snag a tank of oxygen. We put it in a backpack and biked out again.

We found the scene about a mile down the trail. An adult male was lying on his back in the dirt after a crash. His eyes were closed and he wasn’t moving except for occasional breaths. Six emergency medical personnel huddled around him, one assisting breaths with a bag mask. I didn’t introduce myself initially. I just listened to hear what was happening.

They were debating the dose of medication to give him in order to intubate. I knew the answer to that question, so I introduced myself. They were happy to have somebody else to assist.

They already had an IV in place and quite a lot of supplies. They administered the meds and the paramedic attempted to intubate through the mouth. Within a few seconds, she pulled the intubating blade out and said, “I’m not going to be able to get this. His tongue is too big.”

I took the blade myself and kneeled at the head of the victim. I made three attempts at intubating, and each time couldn’t view the landmarks. I wasn’t sure if his tongue was too large or if there was some traumatic injury. To make it more difficult, a lot of secretions clogged the airway. The paramedics had a portable suction, which was somewhat functional, but I still couldn’t visualize the landmarks.

I started asking about alternative methods of establishing an airway. They had an i-gel, which is a supraglottic device that goes into the back of the mouth. So, we placed it. But when we attached the bag, air still wasn’t getting into the lungs.

We removed it and put the bag mask back on. Now I was worried. We were having difficulty keeping his oxygen above 90%. I examined the chest and abdomen again. I was wondering if perhaps he was having some gastric distention, which can result from prolonged bagging, but that didn’t seem to be the case.

Bagging became progressively more difficult, and the oxygen slowly trended down through the 80s. Then the 70s. Heart rate dropped below 60 beats per minute. The trajectory was obvious.

That’s when I asked if they had the tools for a surgical airway.

No one thought the question was crazy. In fact, they pulled out a scalpel from an equipment bag.

But now I had to actually do it. I knelt next to the patient, trying to palpate the front of the neck to identify the correct location to cut. I had difficulty finding the appropriate landmarks there as well. Frustrating.

I glanced at the monitor. O₂ was now in the 60s. Later the paramedic told me the heart rate was down to 30.

One of the medics looked me in the eye and said, “We’ve got to do something. The time is now.” That helped me snap out of it and act. I made my large vertical incision on the front of the victim’s neck, which of course resulted in quite a bit of bleeding.

My two friends, who were watching, later told me this was the moment the intensity of the scene really increased (it was already pretty intense for me, thanks).

Next, I made the horizontal stab incision. Then I probed with my finger, but it seems the incision hadn’t reached the trachea. I had to make the stab much deeper than I would’ve thought.

And then air bubbled out through the blood. A paramedic was ready with the ET tube in hand and she put it through the incision. We attached the bag. We had air movement into the lungs, and within minutes the oxygen came up.

Not long after, the flight paramedics from the helicopter showed up, having jogged a mile through the woods. They seemed rather surprised to find a patient with a cricothyrotomy. We filled them in on the situation. Now we had to get the patient out of the woods (literally and figuratively).

The emergency responders had a really great transport device: A litter with one big wheel underneath in the middle so we could roll the patient down the mountain bike trail over rocks relatively safely. One person’s job was to hold the tube as we went since we didn’t have suture to hold it in place.

We got back to the parking lot and loaded him into the ambulance, which drove another mile to the helicopter, which then had to take him a hundred miles to the hospital.

To be honest, I thought the prognosis was poor. I suspected he had an intercranial bleed slowly squeezing his brain (that later turned out to not be the case). Even though we had established an airway, it took us so long to get him to the ambulance.

The director of the local EMS called me that evening and said the patient had made it to the hospital. I had never been a part of anything with this intensity. I definitely lost sleep over it. Partly just from the uncertainty of not knowing what the outcome would be. But also second-guessing if I had done everything that I could have.

The story doesn’t quite end there, however.

A week later, a friend of the patient called me. He had recovered well and was going to be discharged from the hospital. He’d chosen to share the story with the media, and the local TV station was going to interview him. They had asked if I would agree to be interviewed.

After the local news story ran, it was kind of a media blitz. In came numerous media requests. But honestly, the portrayal of the story made me feel really weird. It was overly dramatized and not entirely accurate. It really didn’t sit well with me.

Friends all over the country saw the story, and here’s what they got from the coverage:

I was biking behind the patient when he crashed.

I had my own tools. Even the patient himself was told I used my own blade to make the incision.

The true story is what I just told you: A half-dozen emergency medical personnel were already there when I arrived. It was a combination of all of us – together – in the right place at the right time.

A month later, the patient and his family drove to the city where I live to take me out to lunch. It was emotional. There were plenty of tears. His wife and daughter were expressing a lot of gratitude and had some gifts for me. I was able to get his version of the story and learned some details. He had facial trauma in the past with some reconstruction. I realized that perhaps those anatomical changes affected my ability to do the intubation.

I hope to never again have to do this outside of the hospital. But I suppose I’m more prepared than ever now. I’ve reviewed my cricothyrotomy technique many times since then.

I was trained as a family doctor and did clinic and hospital medicine for several years. It was only in 2020 that I transitioned to doing emergency medicine work in a rural hospital. So, 2 years earlier, I’m not sure I would’ve been able to do what I did that day. To me, it was almost symbolic of the transition of my practice to emergency medicine.

I’m still in touch with the patient. We’ve talked about biking together. That hasn’t happened yet, but it may very well happen someday.

Jesse Coenen, MD, is an emergency medicine physician at Hayward Area Memorial Hospital in Hayward, Wisc.

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

It started as a mountain biking excursion with two friends. When we drove into the trailhead parking lot, we saw several emergency vehicles. Then a helicopter passed overhead. As we got on our bikes, a police officer told us there’d been an accident out on the trail and to be careful because emergency personnel were going to be bringing in the patient. So we started the ride cautiously, ready to yield to emergency medical services.

Half a mile down the trail, we encountered another police officer. He asked if we would be willing to go back to get an oxygen tank from the ambulance and carry it out to the scene. The three of us turned around, went back to the parking lot and were able to snag a tank of oxygen. We put it in a backpack and biked out again.

We found the scene about a mile down the trail. An adult male was lying on his back in the dirt after a crash. His eyes were closed and he wasn’t moving except for occasional breaths. Six emergency medical personnel huddled around him, one assisting breaths with a bag mask. I didn’t introduce myself initially. I just listened to hear what was happening.

They were debating the dose of medication to give him in order to intubate. I knew the answer to that question, so I introduced myself. They were happy to have somebody else to assist.

They already had an IV in place and quite a lot of supplies. They administered the meds and the paramedic attempted to intubate through the mouth. Within a few seconds, she pulled the intubating blade out and said, “I’m not going to be able to get this. His tongue is too big.”

I took the blade myself and kneeled at the head of the victim. I made three attempts at intubating, and each time couldn’t view the landmarks. I wasn’t sure if his tongue was too large or if there was some traumatic injury. To make it more difficult, a lot of secretions clogged the airway. The paramedics had a portable suction, which was somewhat functional, but I still couldn’t visualize the landmarks.

I started asking about alternative methods of establishing an airway. They had an i-gel, which is a supraglottic device that goes into the back of the mouth. So, we placed it. But when we attached the bag, air still wasn’t getting into the lungs.

We removed it and put the bag mask back on. Now I was worried. We were having difficulty keeping his oxygen above 90%. I examined the chest and abdomen again. I was wondering if perhaps he was having some gastric distention, which can result from prolonged bagging, but that didn’t seem to be the case.

Bagging became progressively more difficult, and the oxygen slowly trended down through the 80s. Then the 70s. Heart rate dropped below 60 beats per minute. The trajectory was obvious.

That’s when I asked if they had the tools for a surgical airway.

No one thought the question was crazy. In fact, they pulled out a scalpel from an equipment bag.

But now I had to actually do it. I knelt next to the patient, trying to palpate the front of the neck to identify the correct location to cut. I had difficulty finding the appropriate landmarks there as well. Frustrating.

I glanced at the monitor. O₂ was now in the 60s. Later the paramedic told me the heart rate was down to 30.

One of the medics looked me in the eye and said, “We’ve got to do something. The time is now.” That helped me snap out of it and act. I made my large vertical incision on the front of the victim’s neck, which of course resulted in quite a bit of bleeding.

My two friends, who were watching, later told me this was the moment the intensity of the scene really increased (it was already pretty intense for me, thanks).

Next, I made the horizontal stab incision. Then I probed with my finger, but it seems the incision hadn’t reached the trachea. I had to make the stab much deeper than I would’ve thought.

And then air bubbled out through the blood. A paramedic was ready with the ET tube in hand and she put it through the incision. We attached the bag. We had air movement into the lungs, and within minutes the oxygen came up.

Not long after, the flight paramedics from the helicopter showed up, having jogged a mile through the woods. They seemed rather surprised to find a patient with a cricothyrotomy. We filled them in on the situation. Now we had to get the patient out of the woods (literally and figuratively).

The emergency responders had a really great transport device: A litter with one big wheel underneath in the middle so we could roll the patient down the mountain bike trail over rocks relatively safely. One person’s job was to hold the tube as we went since we didn’t have suture to hold it in place.

We got back to the parking lot and loaded him into the ambulance, which drove another mile to the helicopter, which then had to take him a hundred miles to the hospital.

To be honest, I thought the prognosis was poor. I suspected he had an intercranial bleed slowly squeezing his brain (that later turned out to not be the case). Even though we had established an airway, it took us so long to get him to the ambulance.

The director of the local EMS called me that evening and said the patient had made it to the hospital. I had never been a part of anything with this intensity. I definitely lost sleep over it. Partly just from the uncertainty of not knowing what the outcome would be. But also second-guessing if I had done everything that I could have.

The story doesn’t quite end there, however.

A week later, a friend of the patient called me. He had recovered well and was going to be discharged from the hospital. He’d chosen to share the story with the media, and the local TV station was going to interview him. They had asked if I would agree to be interviewed.

After the local news story ran, it was kind of a media blitz. In came numerous media requests. But honestly, the portrayal of the story made me feel really weird. It was overly dramatized and not entirely accurate. It really didn’t sit well with me.

Friends all over the country saw the story, and here’s what they got from the coverage:

I was biking behind the patient when he crashed.

I had my own tools. Even the patient himself was told I used my own blade to make the incision.

The true story is what I just told you: A half-dozen emergency medical personnel were already there when I arrived. It was a combination of all of us – together – in the right place at the right time.

A month later, the patient and his family drove to the city where I live to take me out to lunch. It was emotional. There were plenty of tears. His wife and daughter were expressing a lot of gratitude and had some gifts for me. I was able to get his version of the story and learned some details. He had facial trauma in the past with some reconstruction. I realized that perhaps those anatomical changes affected my ability to do the intubation.

I hope to never again have to do this outside of the hospital. But I suppose I’m more prepared than ever now. I’ve reviewed my cricothyrotomy technique many times since then.

I was trained as a family doctor and did clinic and hospital medicine for several years. It was only in 2020 that I transitioned to doing emergency medicine work in a rural hospital. So, 2 years earlier, I’m not sure I would’ve been able to do what I did that day. To me, it was almost symbolic of the transition of my practice to emergency medicine.

I’m still in touch with the patient. We’ve talked about biking together. That hasn’t happened yet, but it may very well happen someday.

Jesse Coenen, MD, is an emergency medicine physician at Hayward Area Memorial Hospital in Hayward, Wisc.

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

Long COVID is typically characterized by anosmia and dysgeusia, cognitive impairment, dyspnea, weakness, and palpitations, with younger patients showing greatest improvements at 1 year, according to a nationwide cohort study conducted in Israel.

These findings help define long COVID, guiding providers and patients through the recovery process, Barak Mizrahi, MSc, of KI Research Institute, Kfar Malal, Israel, and colleagues reported.

“To provide efficient continuous treatment and prevent adverse events related to potential long term effects and delayed symptoms of COVID-19, determining the magnitude and severity of this phenomenon and distinguishing it from similar clinical manifestations that occur normally or following infections with other pathogens is essential,” the investigators wrote in The BMJ.

To this end, they conducted a retrospective, nationwide cohort study involving 1,913,234 people who took a polymerase chain reaction test for SARS-CoV-2 between March 1, 2020, and Oct. 1, 2021. They compared a range of long-term outcomes at different intervals post infection, and compared these trends across subgroups sorted by age, sex, and variant. Outcomes ranged broadly, including respiratory disorders, cough, arthralgia, weakness, hair loss, and others.

The investigators compared hazard ratios for each of these outcomes among patients who tested positive versus those who tested negative at three intervals after testing: 30-90 days, 30-180 days, and 180-360 days. Statistically significant differences in the risks of these outcomes between infected versus uninfected groups suggested that COVID was playing a role.

“The health outcomes that represent long COVID showed a significant increase in both early and late phases,” the investigators wrote. These outcomes included anosmia and dysgeusia, cognitive impairment, dyspnea, weakness, and palpitations. In contrast, chest pain, myalgia, arthralgia, cough, and dizziness were associated with patients who were in the early phase, but not the late phase of long COVID.

“Vaccinated patients with a breakthrough SARS-CoV-2 infection had a lower risk for dyspnea and similar risk for other outcomes compared with unvaccinated infected patients,” the investigators noted.

For the long COVID outcomes, plots of risk differences over time showed that symptoms tended to get milder or resolve within a few months to a year. Patients 41-60 years were most likely to be impacted by long COVID outcomes, and show least improvement at 1 year, compared with other age groups.

“We believe that these findings will shed light on what is ‘long COVID’, support patients and doctors, and facilitate better and more efficient care,” Mr. Mizrahi and coauthor Maytal Bivas-Benita, PhD said in a joint written comment. “Primary care physicians (and patients) will now more clearly understand what are the symptoms that might be related to COVID and for how long they might linger. This would help physicians monitor the patients efficiently, ease their patients’ concerns and navigate a more efficient disease management.”

They suggested that the findings should hold consistent for future variants, although they could not “rule out the possibility of the emergence of new and more severe variants which will be more virulent and cause a more severe illness.”

One “major limitation” of the study, according to Monica Verduzco-Gutierrez, MD, a physiatrist and professor and chair of rehabilitation medicine at the University of Texas Health Science Center, San Antonio, is the lack of data for fatigue and dysautonomia, which are “the major presentations” that she sees in her long COVID clinic.

“The authors of the article focus on the primary damage being related to the lungs, though we know this is a systemic disease beyond the respiratory system, with endothelial dysfunction and immune dysregulation,” Dr. Verduzco-Gutierrez, who is also director of COVID recovery at the University of Texas Health Science Center, said in an interview.

Although it was reassuring to see that younger adults with long COVID trended toward improvement, she noted that patients 41-60 years “still had pretty significant symptoms” after 12 months.

“That [age group comprises] probably the majority of my patients that I’m seeing in the long COVID clinic,” Dr. Verduzco-Gutierrez said. “If you look at the whole thing, it looks better, but then when you drill down to that age group where you’re seeing patients, then it’s not.”

Dr. Verduzco-Gutierrez is so busy managing patients with long COVID that new appointments in her clinic are now delayed until May 31, so most patients will remain under the care of their primary care providers. She recommended that these physicians follow guidance from the American Academy of Physical Medicine and Rehabilitation, who offer consensus statements based on clinical characteristics, with separate recommendations for pediatric patients.

Our understanding of long COVID will continue to improve, and with it, available recommendations, she predicted, but further advances will require persistent effort.

“I think no matter what this [study] shows us, more research is needed,” Dr. Verduzco-Gutierrez said. “We can’t just forget about it, just because there is a population of people who get better. What about the ones who don’t?”

The investigators and Dr. Verduzco-Gutierrez disclosed no conflicts of interest.

Long COVID is typically characterized by anosmia and dysgeusia, cognitive impairment, dyspnea, weakness, and palpitations, with younger patients showing greatest improvements at 1 year, according to a nationwide cohort study conducted in Israel.

These findings help define long COVID, guiding providers and patients through the recovery process, Barak Mizrahi, MSc, of KI Research Institute, Kfar Malal, Israel, and colleagues reported.

“To provide efficient continuous treatment and prevent adverse events related to potential long term effects and delayed symptoms of COVID-19, determining the magnitude and severity of this phenomenon and distinguishing it from similar clinical manifestations that occur normally or following infections with other pathogens is essential,” the investigators wrote in The BMJ.

To this end, they conducted a retrospective, nationwide cohort study involving 1,913,234 people who took a polymerase chain reaction test for SARS-CoV-2 between March 1, 2020, and Oct. 1, 2021. They compared a range of long-term outcomes at different intervals post infection, and compared these trends across subgroups sorted by age, sex, and variant. Outcomes ranged broadly, including respiratory disorders, cough, arthralgia, weakness, hair loss, and others.

The investigators compared hazard ratios for each of these outcomes among patients who tested positive versus those who tested negative at three intervals after testing: 30-90 days, 30-180 days, and 180-360 days. Statistically significant differences in the risks of these outcomes between infected versus uninfected groups suggested that COVID was playing a role.

“The health outcomes that represent long COVID showed a significant increase in both early and late phases,” the investigators wrote. These outcomes included anosmia and dysgeusia, cognitive impairment, dyspnea, weakness, and palpitations. In contrast, chest pain, myalgia, arthralgia, cough, and dizziness were associated with patients who were in the early phase, but not the late phase of long COVID.

“Vaccinated patients with a breakthrough SARS-CoV-2 infection had a lower risk for dyspnea and similar risk for other outcomes compared with unvaccinated infected patients,” the investigators noted.

For the long COVID outcomes, plots of risk differences over time showed that symptoms tended to get milder or resolve within a few months to a year. Patients 41-60 years were most likely to be impacted by long COVID outcomes, and show least improvement at 1 year, compared with other age groups.

“We believe that these findings will shed light on what is ‘long COVID’, support patients and doctors, and facilitate better and more efficient care,” Mr. Mizrahi and coauthor Maytal Bivas-Benita, PhD said in a joint written comment. “Primary care physicians (and patients) will now more clearly understand what are the symptoms that might be related to COVID and for how long they might linger. This would help physicians monitor the patients efficiently, ease their patients’ concerns and navigate a more efficient disease management.”

They suggested that the findings should hold consistent for future variants, although they could not “rule out the possibility of the emergence of new and more severe variants which will be more virulent and cause a more severe illness.”

One “major limitation” of the study, according to Monica Verduzco-Gutierrez, MD, a physiatrist and professor and chair of rehabilitation medicine at the University of Texas Health Science Center, San Antonio, is the lack of data for fatigue and dysautonomia, which are “the major presentations” that she sees in her long COVID clinic.

“The authors of the article focus on the primary damage being related to the lungs, though we know this is a systemic disease beyond the respiratory system, with endothelial dysfunction and immune dysregulation,” Dr. Verduzco-Gutierrez, who is also director of COVID recovery at the University of Texas Health Science Center, said in an interview.

Although it was reassuring to see that younger adults with long COVID trended toward improvement, she noted that patients 41-60 years “still had pretty significant symptoms” after 12 months.

“That [age group comprises] probably the majority of my patients that I’m seeing in the long COVID clinic,” Dr. Verduzco-Gutierrez said. “If you look at the whole thing, it looks better, but then when you drill down to that age group where you’re seeing patients, then it’s not.”

Dr. Verduzco-Gutierrez is so busy managing patients with long COVID that new appointments in her clinic are now delayed until May 31, so most patients will remain under the care of their primary care providers. She recommended that these physicians follow guidance from the American Academy of Physical Medicine and Rehabilitation, who offer consensus statements based on clinical characteristics, with separate recommendations for pediatric patients.

Our understanding of long COVID will continue to improve, and with it, available recommendations, she predicted, but further advances will require persistent effort.

“I think no matter what this [study] shows us, more research is needed,” Dr. Verduzco-Gutierrez said. “We can’t just forget about it, just because there is a population of people who get better. What about the ones who don’t?”

The investigators and Dr. Verduzco-Gutierrez disclosed no conflicts of interest.

Long COVID is typically characterized by anosmia and dysgeusia, cognitive impairment, dyspnea, weakness, and palpitations, with younger patients showing greatest improvements at 1 year, according to a nationwide cohort study conducted in Israel.

These findings help define long COVID, guiding providers and patients through the recovery process, Barak Mizrahi, MSc, of KI Research Institute, Kfar Malal, Israel, and colleagues reported.

“To provide efficient continuous treatment and prevent adverse events related to potential long term effects and delayed symptoms of COVID-19, determining the magnitude and severity of this phenomenon and distinguishing it from similar clinical manifestations that occur normally or following infections with other pathogens is essential,” the investigators wrote in The BMJ.

To this end, they conducted a retrospective, nationwide cohort study involving 1,913,234 people who took a polymerase chain reaction test for SARS-CoV-2 between March 1, 2020, and Oct. 1, 2021. They compared a range of long-term outcomes at different intervals post infection, and compared these trends across subgroups sorted by age, sex, and variant. Outcomes ranged broadly, including respiratory disorders, cough, arthralgia, weakness, hair loss, and others.

The investigators compared hazard ratios for each of these outcomes among patients who tested positive versus those who tested negative at three intervals after testing: 30-90 days, 30-180 days, and 180-360 days. Statistically significant differences in the risks of these outcomes between infected versus uninfected groups suggested that COVID was playing a role.

“The health outcomes that represent long COVID showed a significant increase in both early and late phases,” the investigators wrote. These outcomes included anosmia and dysgeusia, cognitive impairment, dyspnea, weakness, and palpitations. In contrast, chest pain, myalgia, arthralgia, cough, and dizziness were associated with patients who were in the early phase, but not the late phase of long COVID.

“Vaccinated patients with a breakthrough SARS-CoV-2 infection had a lower risk for dyspnea and similar risk for other outcomes compared with unvaccinated infected patients,” the investigators noted.

For the long COVID outcomes, plots of risk differences over time showed that symptoms tended to get milder or resolve within a few months to a year. Patients 41-60 years were most likely to be impacted by long COVID outcomes, and show least improvement at 1 year, compared with other age groups.

“We believe that these findings will shed light on what is ‘long COVID’, support patients and doctors, and facilitate better and more efficient care,” Mr. Mizrahi and coauthor Maytal Bivas-Benita, PhD said in a joint written comment. “Primary care physicians (and patients) will now more clearly understand what are the symptoms that might be related to COVID and for how long they might linger. This would help physicians monitor the patients efficiently, ease their patients’ concerns and navigate a more efficient disease management.”

They suggested that the findings should hold consistent for future variants, although they could not “rule out the possibility of the emergence of new and more severe variants which will be more virulent and cause a more severe illness.”

One “major limitation” of the study, according to Monica Verduzco-Gutierrez, MD, a physiatrist and professor and chair of rehabilitation medicine at the University of Texas Health Science Center, San Antonio, is the lack of data for fatigue and dysautonomia, which are “the major presentations” that she sees in her long COVID clinic.

“The authors of the article focus on the primary damage being related to the lungs, though we know this is a systemic disease beyond the respiratory system, with endothelial dysfunction and immune dysregulation,” Dr. Verduzco-Gutierrez, who is also director of COVID recovery at the University of Texas Health Science Center, said in an interview.

Although it was reassuring to see that younger adults with long COVID trended toward improvement, she noted that patients 41-60 years “still had pretty significant symptoms” after 12 months.

“That [age group comprises] probably the majority of my patients that I’m seeing in the long COVID clinic,” Dr. Verduzco-Gutierrez said. “If you look at the whole thing, it looks better, but then when you drill down to that age group where you’re seeing patients, then it’s not.”

Dr. Verduzco-Gutierrez is so busy managing patients with long COVID that new appointments in her clinic are now delayed until May 31, so most patients will remain under the care of their primary care providers. She recommended that these physicians follow guidance from the American Academy of Physical Medicine and Rehabilitation, who offer consensus statements based on clinical characteristics, with separate recommendations for pediatric patients.

Our understanding of long COVID will continue to improve, and with it, available recommendations, she predicted, but further advances will require persistent effort.

“I think no matter what this [study] shows us, more research is needed,” Dr. Verduzco-Gutierrez said. “We can’t just forget about it, just because there is a population of people who get better. What about the ones who don’t?”

The investigators and Dr. Verduzco-Gutierrez disclosed no conflicts of interest.

The newest subvariant of Omicron, XBB.1.5, is so transmissible that everybody is at risk of catching it, even if they’ve already been infected and are fully vaccinated, a health expert told USA Today.

“It’s crazy infectious,” said Paula Cannon, PhD, a virologist at the University of Southern California, Los Angeles. “All the things that have protected you for the past couple of years, I don’t think are going to protect you against this new crop of variants.” 

XBB.1.5 is spreading quickly in the United States. It accounted for 27.6% of cases in the country in the week ending on Jan. 7, up from about 1% of cases at one point in December, according to the Centers for Disease Control and Prevention. It’s especially prevalent in the Northeast, now accounting for more than 70% of the cases in that region.

It’s spreading across the globe, too. Maria Van Kerkhove, PhD, technical lead of the World Health Organization, has called XBB.1.5 is “the most transmissible subvariant that has been detected yet.” 

Ashish Jha, MD, the White House COVID-19 response coordinator, tweeted a few days ago that the spread of XBB.1.5 is “stunning” but cautioned that it’s unclear if the symptoms of infection will be more severe than for previous variants.

“Whether we’ll have an XBB.1.5 wave (and if yes, how big) will depend on many factors including immunity of the population, people’s actions, etc.,” he tweeted. 

He urged people to get up to date on their boosters, wear a snug-fitting mask, and avoid crowded indoor spaces. He noted that people who haven’t been infected recently or haven’t gotten the bivalent booster likely have little protection against infection.

The symptoms for XBB.1.5 appear to be the same as for other versions of COVID-19. However, it’s less common for people infected with XBB.1.5 to report losing their sense of taste and smell, USA Today reported.

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

The newest subvariant of Omicron, XBB.1.5, is so transmissible that everybody is at risk of catching it, even if they’ve already been infected and are fully vaccinated, a health expert told USA Today.

“It’s crazy infectious,” said Paula Cannon, PhD, a virologist at the University of Southern California, Los Angeles. “All the things that have protected you for the past couple of years, I don’t think are going to protect you against this new crop of variants.” 

XBB.1.5 is spreading quickly in the United States. It accounted for 27.6% of cases in the country in the week ending on Jan. 7, up from about 1% of cases at one point in December, according to the Centers for Disease Control and Prevention. It’s especially prevalent in the Northeast, now accounting for more than 70% of the cases in that region.

It’s spreading across the globe, too. Maria Van Kerkhove, PhD, technical lead of the World Health Organization, has called XBB.1.5 is “the most transmissible subvariant that has been detected yet.” 

Ashish Jha, MD, the White House COVID-19 response coordinator, tweeted a few days ago that the spread of XBB.1.5 is “stunning” but cautioned that it’s unclear if the symptoms of infection will be more severe than for previous variants.

“Whether we’ll have an XBB.1.5 wave (and if yes, how big) will depend on many factors including immunity of the population, people’s actions, etc.,” he tweeted. 

He urged people to get up to date on their boosters, wear a snug-fitting mask, and avoid crowded indoor spaces. He noted that people who haven’t been infected recently or haven’t gotten the bivalent booster likely have little protection against infection.

The symptoms for XBB.1.5 appear to be the same as for other versions of COVID-19. However, it’s less common for people infected with XBB.1.5 to report losing their sense of taste and smell, USA Today reported.

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

The newest subvariant of Omicron, XBB.1.5, is so transmissible that everybody is at risk of catching it, even if they’ve already been infected and are fully vaccinated, a health expert told USA Today.

“It’s crazy infectious,” said Paula Cannon, PhD, a virologist at the University of Southern California, Los Angeles. “All the things that have protected you for the past couple of years, I don’t think are going to protect you against this new crop of variants.” 

XBB.1.5 is spreading quickly in the United States. It accounted for 27.6% of cases in the country in the week ending on Jan. 7, up from about 1% of cases at one point in December, according to the Centers for Disease Control and Prevention. It’s especially prevalent in the Northeast, now accounting for more than 70% of the cases in that region.

It’s spreading across the globe, too. Maria Van Kerkhove, PhD, technical lead of the World Health Organization, has called XBB.1.5 is “the most transmissible subvariant that has been detected yet.” 

Ashish Jha, MD, the White House COVID-19 response coordinator, tweeted a few days ago that the spread of XBB.1.5 is “stunning” but cautioned that it’s unclear if the symptoms of infection will be more severe than for previous variants.

“Whether we’ll have an XBB.1.5 wave (and if yes, how big) will depend on many factors including immunity of the population, people’s actions, etc.,” he tweeted. 

He urged people to get up to date on their boosters, wear a snug-fitting mask, and avoid crowded indoor spaces. He noted that people who haven’t been infected recently or haven’t gotten the bivalent booster likely have little protection against infection.

The symptoms for XBB.1.5 appear to be the same as for other versions of COVID-19. However, it’s less common for people infected with XBB.1.5 to report losing their sense of taste and smell, USA Today reported.

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

The SARS-CoV-2 virus can be found throughout the entire body and remain present for more than 7 months, researchers discovered.

A study on the subject was published in the journal Nature. The researchers completed autopsies from April 2020 to March 2021 of 44 unvaccinated people who had severe COVID-19. The median age was 62.5 years old, and 30% were female. Extensive brain sampling was done for 11 cases.

Because of its nature as a respiratory illness, SARS-CoV-2 was most widespread in the respiratory system such as in the lungs. But it was also found in 79 other body locations, including the heart, kidneys, liver, muscles, nerves, reproductive tract, and eyes. 

The researchers said their work shows the SARS-CoV-2 “is capable of infecting and replicating within the human brain.” They also said their results indicate the virus spreads via the blood early during infection, which “seeds the virus throughout the body following infection of the respiratory tract.”

The authors noted that, while the virus was found outside the respiratory tract, they did not find signs of inflammation beyond the respiratory system.

The results will help narrow down treatments for long COVID, and particularly support the idea of using the antiviral drug Paxlovid to treat long COVID, according to a blog post from the National Institute of Allergy and Infectious Diseases. A clinical trial is already underway examining the treatment, and results are expected in January 2024.

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

The SARS-CoV-2 virus can be found throughout the entire body and remain present for more than 7 months, researchers discovered.

A study on the subject was published in the journal Nature. The researchers completed autopsies from April 2020 to March 2021 of 44 unvaccinated people who had severe COVID-19. The median age was 62.5 years old, and 30% were female. Extensive brain sampling was done for 11 cases.

Because of its nature as a respiratory illness, SARS-CoV-2 was most widespread in the respiratory system such as in the lungs. But it was also found in 79 other body locations, including the heart, kidneys, liver, muscles, nerves, reproductive tract, and eyes. 

The researchers said their work shows the SARS-CoV-2 “is capable of infecting and replicating within the human brain.” They also said their results indicate the virus spreads via the blood early during infection, which “seeds the virus throughout the body following infection of the respiratory tract.”

The authors noted that, while the virus was found outside the respiratory tract, they did not find signs of inflammation beyond the respiratory system.

The results will help narrow down treatments for long COVID, and particularly support the idea of using the antiviral drug Paxlovid to treat long COVID, according to a blog post from the National Institute of Allergy and Infectious Diseases. A clinical trial is already underway examining the treatment, and results are expected in January 2024.

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

The SARS-CoV-2 virus can be found throughout the entire body and remain present for more than 7 months, researchers discovered.

A study on the subject was published in the journal Nature. The researchers completed autopsies from April 2020 to March 2021 of 44 unvaccinated people who had severe COVID-19. The median age was 62.5 years old, and 30% were female. Extensive brain sampling was done for 11 cases.

Because of its nature as a respiratory illness, SARS-CoV-2 was most widespread in the respiratory system such as in the lungs. But it was also found in 79 other body locations, including the heart, kidneys, liver, muscles, nerves, reproductive tract, and eyes. 

The researchers said their work shows the SARS-CoV-2 “is capable of infecting and replicating within the human brain.” They also said their results indicate the virus spreads via the blood early during infection, which “seeds the virus throughout the body following infection of the respiratory tract.”

The authors noted that, while the virus was found outside the respiratory tract, they did not find signs of inflammation beyond the respiratory system.

The results will help narrow down treatments for long COVID, and particularly support the idea of using the antiviral drug Paxlovid to treat long COVID, according to a blog post from the National Institute of Allergy and Infectious Diseases. A clinical trial is already underway examining the treatment, and results are expected in January 2024.

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

Participation in the first 2 years of Maryland’s Advanced Primary Care Program (MDPCP) was associated with better COVID-19 outcomes compared with a matched group not involved with the program, new data indicate.

The better outcomes were seen in higher vaccination rates and fewer infections, hospitalizations, and deaths from the disease, according to study authors, led by Emily Gruber, MBA, MPH, with the Maryland Primary Care Program, Maryland Department of Health in Baltimore.

The results were published online in JAMA Network Open.

The study population was divided into MDPCP participants (n = 208,146) and a matched cohort (n = 37,203) of beneficiaries not attributed to MDPCP practices but who met eligibility criteria for study participation from Jan. 1, 2020, through Dec. 31, 2021.
 

More vaccinations, more antibody treatments

Researchers broke down the comparisons of better outcomes: 84.47% of MDPCP beneficiaries were fully vaccinated vs. 77.93% of nonparticipating beneficiaries (P less than .001). COVID-19–positive program beneficiaries also received monoclonal antibody treatment more often (8.45% vs. 6.11%; P less than .001).

Plus, program participants received more care via telehealth (62.95% vs. 54.53%; P less than .001) compared with those not participating.

Regarding secondary outcomes, MDPCP beneficiaries had lower rates of COVID cases (6.55% vs. 7.09%; P less than .001), lower rates of COVID-19 hospitalizations (1.81% vs. 2.06%; P = .001), and lower rates of death due to COVID-19 (0.56% vs. 0.77%; P less than .001).
 

Program components

Enrollment in the MDPCP is voluntary, and primary care practices can apply each year to be part of the program.

The model integrates primary care and public health in the pandemic response. It was created by the Maryland Department of Health (MDH) and the Centers for Medicare & Medicaid Services (CMS).

It expands the role of primary care to include services such as expanded care management, integrated behavioral health, data-driven care, and screenings and referrals to address social needs.

Coauthor Howard Haft, MD, MMM, with the Maryland Department of Public Health, said in an interview that among the most important factors in the program’s success were giving providers vaccines to distribute and then giving providers data on how many patients are vaccinated, and who’s not vaccinated but at high risk, and how those rates compare to other practices.

As to whether this could be a widespread model, Dr. Haft said, “It’s highly replicable.”

“Every state in the nation overall has all of these resources. It’s a matter of having the operational and political will to put those resources together. Almost every state has the technological ability to use their health information exchange to help tie pieces together.”
 

Vaccines and testing made available to providers

Making ample vaccines and testing available to providers in their offices helped patients get those services in a place they trust, Dr. Haft said.

The model also included a payment system for providers that included a significant amount of non–visit-based payments when many locations were closed in the height of the pandemic.

“That helped financially,” as did providing free telehealth platforms to practices with training on how to use them, Dr. Haft said.
 

‘Innovative and important’

Renu Tipirneni, MD, an assistant professor of internal medicine at the University of Michigan and at the Institute for Healthcare Policy and Innovation in Ann Arbor, said Maryland is out front putting into practice what practices nationwide aspire to do – coordinating physical and mental health and social needs and integrating primary and public health. Dr. Tipirneni, who was not involved with the study, said she was impressed the researchers were able to show statistically significant improvement with COVID-19 outcomes in the first 2 years.

“In terms of health outcomes, we often have to wait longer to see good outcomes,” she said. “It’s a really innovative and important model.”

She said states can learn from each other and this model is an example.

Integrating primary care and public health and addressing social needs may be the biggest challenges for states, she said, as those realms typically have been siloed.

“But they may be the key components to achieving these outcomes,” she said.
 

Take-home message

The most important benefit of the program is that data suggest it saves lives, according to Dr. Haft. While the actual difference between COVID deaths in the program and nonprogram groups was small, multiplying that savings across the nation shows substantial potential benefit, he explained.

“At a time when we were losing lives at an unconscionable rate, we were able to make a difference in saving lives,” Dr. Haft said.

Authors report no relevant financial disclosures.

The study received financial support from the Maryland Department of Health.

Dr. Tiperneni is helping evaluate Michigan’s Medicaid contract.
 

Participation in the first 2 years of Maryland’s Advanced Primary Care Program (MDPCP) was associated with better COVID-19 outcomes compared with a matched group not involved with the program, new data indicate.

The better outcomes were seen in higher vaccination rates and fewer infections, hospitalizations, and deaths from the disease, according to study authors, led by Emily Gruber, MBA, MPH, with the Maryland Primary Care Program, Maryland Department of Health in Baltimore.

The results were published online in JAMA Network Open.

The study population was divided into MDPCP participants (n = 208,146) and a matched cohort (n = 37,203) of beneficiaries not attributed to MDPCP practices but who met eligibility criteria for study participation from Jan. 1, 2020, through Dec. 31, 2021.
 

More vaccinations, more antibody treatments

Researchers broke down the comparisons of better outcomes: 84.47% of MDPCP beneficiaries were fully vaccinated vs. 77.93% of nonparticipating beneficiaries (P less than .001). COVID-19–positive program beneficiaries also received monoclonal antibody treatment more often (8.45% vs. 6.11%; P less than .001).

Plus, program participants received more care via telehealth (62.95% vs. 54.53%; P less than .001) compared with those not participating.

Regarding secondary outcomes, MDPCP beneficiaries had lower rates of COVID cases (6.55% vs. 7.09%; P less than .001), lower rates of COVID-19 hospitalizations (1.81% vs. 2.06%; P = .001), and lower rates of death due to COVID-19 (0.56% vs. 0.77%; P less than .001).
 

Program components

Enrollment in the MDPCP is voluntary, and primary care practices can apply each year to be part of the program.

The model integrates primary care and public health in the pandemic response. It was created by the Maryland Department of Health (MDH) and the Centers for Medicare & Medicaid Services (CMS).

It expands the role of primary care to include services such as expanded care management, integrated behavioral health, data-driven care, and screenings and referrals to address social needs.

Coauthor Howard Haft, MD, MMM, with the Maryland Department of Public Health, said in an interview that among the most important factors in the program’s success were giving providers vaccines to distribute and then giving providers data on how many patients are vaccinated, and who’s not vaccinated but at high risk, and how those rates compare to other practices.

As to whether this could be a widespread model, Dr. Haft said, “It’s highly replicable.”

“Every state in the nation overall has all of these resources. It’s a matter of having the operational and political will to put those resources together. Almost every state has the technological ability to use their health information exchange to help tie pieces together.”
 

Vaccines and testing made available to providers

Making ample vaccines and testing available to providers in their offices helped patients get those services in a place they trust, Dr. Haft said.

The model also included a payment system for providers that included a significant amount of non–visit-based payments when many locations were closed in the height of the pandemic.

“That helped financially,” as did providing free telehealth platforms to practices with training on how to use them, Dr. Haft said.
 

‘Innovative and important’

Renu Tipirneni, MD, an assistant professor of internal medicine at the University of Michigan and at the Institute for Healthcare Policy and Innovation in Ann Arbor, said Maryland is out front putting into practice what practices nationwide aspire to do – coordinating physical and mental health and social needs and integrating primary and public health. Dr. Tipirneni, who was not involved with the study, said she was impressed the researchers were able to show statistically significant improvement with COVID-19 outcomes in the first 2 years.

“In terms of health outcomes, we often have to wait longer to see good outcomes,” she said. “It’s a really innovative and important model.”

She said states can learn from each other and this model is an example.

Integrating primary care and public health and addressing social needs may be the biggest challenges for states, she said, as those realms typically have been siloed.

“But they may be the key components to achieving these outcomes,” she said.
 

Take-home message

The most important benefit of the program is that data suggest it saves lives, according to Dr. Haft. While the actual difference between COVID deaths in the program and nonprogram groups was small, multiplying that savings across the nation shows substantial potential benefit, he explained.

“At a time when we were losing lives at an unconscionable rate, we were able to make a difference in saving lives,” Dr. Haft said.

Authors report no relevant financial disclosures.

The study received financial support from the Maryland Department of Health.

Dr. Tiperneni is helping evaluate Michigan’s Medicaid contract.
 

Participation in the first 2 years of Maryland’s Advanced Primary Care Program (MDPCP) was associated with better COVID-19 outcomes compared with a matched group not involved with the program, new data indicate.

The better outcomes were seen in higher vaccination rates and fewer infections, hospitalizations, and deaths from the disease, according to study authors, led by Emily Gruber, MBA, MPH, with the Maryland Primary Care Program, Maryland Department of Health in Baltimore.

The results were published online in JAMA Network Open.

The study population was divided into MDPCP participants (n = 208,146) and a matched cohort (n = 37,203) of beneficiaries not attributed to MDPCP practices but who met eligibility criteria for study participation from Jan. 1, 2020, through Dec. 31, 2021.
 

More vaccinations, more antibody treatments

Researchers broke down the comparisons of better outcomes: 84.47% of MDPCP beneficiaries were fully vaccinated vs. 77.93% of nonparticipating beneficiaries (P less than .001). COVID-19–positive program beneficiaries also received monoclonal antibody treatment more often (8.45% vs. 6.11%; P less than .001).

Plus, program participants received more care via telehealth (62.95% vs. 54.53%; P less than .001) compared with those not participating.

Regarding secondary outcomes, MDPCP beneficiaries had lower rates of COVID cases (6.55% vs. 7.09%; P less than .001), lower rates of COVID-19 hospitalizations (1.81% vs. 2.06%; P = .001), and lower rates of death due to COVID-19 (0.56% vs. 0.77%; P less than .001).
 

Program components

Enrollment in the MDPCP is voluntary, and primary care practices can apply each year to be part of the program.

The model integrates primary care and public health in the pandemic response. It was created by the Maryland Department of Health (MDH) and the Centers for Medicare & Medicaid Services (CMS).

It expands the role of primary care to include services such as expanded care management, integrated behavioral health, data-driven care, and screenings and referrals to address social needs.

Coauthor Howard Haft, MD, MMM, with the Maryland Department of Public Health, said in an interview that among the most important factors in the program’s success were giving providers vaccines to distribute and then giving providers data on how many patients are vaccinated, and who’s not vaccinated but at high risk, and how those rates compare to other practices.

As to whether this could be a widespread model, Dr. Haft said, “It’s highly replicable.”

“Every state in the nation overall has all of these resources. It’s a matter of having the operational and political will to put those resources together. Almost every state has the technological ability to use their health information exchange to help tie pieces together.”
 

Vaccines and testing made available to providers

Making ample vaccines and testing available to providers in their offices helped patients get those services in a place they trust, Dr. Haft said.

The model also included a payment system for providers that included a significant amount of non–visit-based payments when many locations were closed in the height of the pandemic.

“That helped financially,” as did providing free telehealth platforms to practices with training on how to use them, Dr. Haft said.
 

‘Innovative and important’

Renu Tipirneni, MD, an assistant professor of internal medicine at the University of Michigan and at the Institute for Healthcare Policy and Innovation in Ann Arbor, said Maryland is out front putting into practice what practices nationwide aspire to do – coordinating physical and mental health and social needs and integrating primary and public health. Dr. Tipirneni, who was not involved with the study, said she was impressed the researchers were able to show statistically significant improvement with COVID-19 outcomes in the first 2 years.

“In terms of health outcomes, we often have to wait longer to see good outcomes,” she said. “It’s a really innovative and important model.”

She said states can learn from each other and this model is an example.

Integrating primary care and public health and addressing social needs may be the biggest challenges for states, she said, as those realms typically have been siloed.

“But they may be the key components to achieving these outcomes,” she said.
 

Take-home message

The most important benefit of the program is that data suggest it saves lives, according to Dr. Haft. While the actual difference between COVID deaths in the program and nonprogram groups was small, multiplying that savings across the nation shows substantial potential benefit, he explained.

“At a time when we were losing lives at an unconscionable rate, we were able to make a difference in saving lives,” Dr. Haft said.

Authors report no relevant financial disclosures.

The study received financial support from the Maryland Department of Health.

Dr. Tiperneni is helping evaluate Michigan’s Medicaid contract.