Massive Science - COVID-19

How COVID-19's Delta variant upended the world's fall plans

Sara May Bergstresser — Thu, 26 Aug 2021 22:54:00 EST

Right now, the COVID-19 pandemic news is dominated by the Delta variant of the SARS-CoV-2 virus. Delta is driving a late-summer surge in COVID-19 infections in the US and globally. Delta is listed as a “variant of concern” for both WHO and the US CDC, and it is now the predominant strain worldwide, as of August 15 representing 87.1% of infections worldwide, including 99.8% in the UK and 98.6% in the US in the past four weeks.

The Delta variant, originally known as B.1.617.2, was first reported in India in October 2020. Since then, multiple “Delta Plus” variants ave been added to the variant category (B.1.617.2.x, also known as AY.x), and to the evolutionary clade (21A at Nextstrain). Delta is described by CDC as “more than 2x as contagious as previous variants.” The population most at risk by far consists of unvaccinated people, but some breakthrough infections do occur. Viral loads are also about 1000 times higher in Delta, and there is evidence that vaccinated people can also have high viral loads and shed virus. The Delta variant has mutations that may increase its immune evasion potential, but it is still unclear whether Delta makes people sicker than earlier variants.

The Delta variant has also prompted a new wave of public health policy shifts in the US and beyond. In the US and UK, COVID policy has followed a cyclical pattern where over-optimistic declarations of impending normalcy are followed by periods of panic and scrambling to keep up with outbreaks, which in turn is followed by new periods of broad optimism and relaxing precautions, and so on.

In the US, vaccines became widely available in the spring and summer of 2021, but many eligible people did not get vaccinated. Nevertheless, there were many optimistic declarations of an imminent return of normalcy, including by the CDC. In May, the CDC surprised many people by changing its mask policy, saying that for fully vaccinated people, masks need not be worn anymore in most situations, including indoors or for large gatherings. Vaccine status was rarely checked for the unmasked, and public confrontations were common in places where people were not wearing masks, and also when they were.

A map showing the dynamics of the Delta variant of COVID-19 arriving in the United States

GISAID

Then, as the Delta surge became apparent, CDC reversed its decision for vaccinated people, once again recommending mask wearing indoors and also for children. These shifts, in conjunction with differing state regulations and conflicting messages in the media, have resulted in confusion and mistrust.

And as if the Delta variant weren’t enough, new variants are constantly emerging. Globally about 85% of people, or about 6.5 billion, have not yet been able to access to a single vaccine dose. With the sheer numbers of potential hosts still available, the virus has many opportunities to evolve into even more variants, which could be more infectious, dangerous, and/or better able to evade the immune system. Even in the US, where vaccines are widely available, children under 12 still not eligible for vaccines, and many areas continue to have low rates of vaccination and high rates of infection.

Delta carries a mutation in amino acid L452 of the spike protein that helps the virus bind to host cells. This mutation is also present in the emerging strains Kappa, Epsilon, and Iota. Gamma (P.1) is listed as a CDC “Variant of Concern” that has multiple mutations that may result in reduced neutralization by monoclonal antibody therapies, convalescent sera, and post-vaccination sera. This would mean that it is less treatable with monoclonal antibodies and better able to evade the immune system, including post-vaccination. A preliminary report based on a laboratory study has identified Lambda as highly infectious and more resistant to vaccines than were earlier emerging strains. And there are even more variants that have not yet been given Greek letter designations, including B.1.346 (Clade 20C) in Japan and B.1.1.7, which is already found in at least 167 countries.

With many worrisome new variants to come, many more cycles of panic and over-optimism are foreseeable. This remains the case even though the FDA has just granted full approval to the Pfizer-BioNTech vaccine for ages 16 and above and third mRNA booster shots will soon be widely available to the US general population. Though there are reports of declining efficacy over time for the mRNA vaccines, there are also concerns that boosters are not needed for most people, and that inoculating more people is a better strategy, rather than re-vaccinating the already vaccinated.

A map showing the dynamics of the Delta variant of COVID-19 arriving in the United Kingdom

GISAID

The WHO expressed strong concern that more vaccines should not be given in wealthy countries since most people in lower income counties do not yet have any access. At the same time, large numbers of people in the US who do have access are simply not taking the vaccine. As a result, the vast numbers of people who remain unvaccinated make it more likely that new variants will emerge, some of which may be able to evade existing vaccines. As we have seen throughout the pandemic, strains that emerge in one place can spread across the globe rapidly, even with travel restrictions in place.

Unfortunately, boosters are also likely to lead to complacency, including relaxation of protective measures like masking and reducing gathering sizes, extensive re-opening of schools, businesses, and public areas, and more. The past six months in the US provides a clear example of how vaccine complacency works, showing how over-optimistic assumptions about vaccines can lead to the elimination of other precautions too quickly. Relying on “herd immunity,” which was already dubious even before Delta, is by now looking twice as unlikely, since the Delta variant is about twice as infectious as initial strains.

If public health policymaking remains as fickle as it has been so far, the US and UK might cycle through these extremes for months or even years to come, perhaps up until the virus becomes fully endemic and is no longer novel. As the fall approaches, with schools reopening, and considering the evidence for seasonality, another impending period of dire conditions and full panic is likely on winter's horizon.

There are already worrisome cases of school-related mass infections, including 69 outbreaks in Mississippi, where almost 1,000 students and 300 teachers and staff tested positive for COVID within the first two weeks of school reopening. In the past month, child cases have increased dramatically, rising from about 38,000 cases during the week ending July 22nd to 180,000 by August 19. According to the Policy Lab at the Children's Hospital of Philadelphia, "the risk of a fall resurgence is nearly certain in northern areas" and many schools will need to rethink and improve their mitigation strategies. Another prediction based on "COVID-19 Simulator" modeling shows as many as 1600 COVID-19 deaths across the U.S. per day by the end of 2021.

By springtime, when apparent infections are likely to wane yet again, US policymakers must not relapse into wishful thinking. Policymakers at all levels must insist on caution, keep vigilant for new strains, and extend precautionary measures until there is clear and ample evidence that they are no longer needed. It is by now quite clear that public complaints and cries of inconvenience do not magically make a pandemic disappear, and too many attempts to please the public have resulted in many examples of very poor public health policy.

Sara May Bergstresser studies

Bioethics, Public Health, and Biochemistry

at
Columbia University
.

We must reckon with our ableism if we want healthcare to work for people

Olivia Bernard — Thu, 10 Jun 2021 17:18:42 EST

Content warning: This article discusses ableism and gaslighting.

Two years ago, my doctor told me to stop calling. I fell silent, quickly reverting back to the 10-year-old who was taught to disbelieve herself. I explained that the headaches and episodes of vision loss were persisting, that she had sent me to a specialist who found some irregularities but no cause. They had recommended returning to my doctor. She gave me an insincere smile, “I have other patients who need help, too.”

Being dismissed by doctors isn't a rare experience for chronically ill patients. Only a month later, I had a consultation with a pain clinic about botox for migraines, a treatment recommended to me by other migraineurs. But I was told that they don’t treat patients with fibromyalgia, like me, regardless of what they come in for.

Fibromyalgia is a chronic disorder (likely) of the nervous system that causes widespread pain, fatigue, and cognitive disturbances. People with fibromyalgia may also experience a long list of other symptoms that can be so severe it prevents them from going to school or working. It may be genetic, since it can run in families, or the onset of symptoms can be triggered by stress, emotional or physical trauma, or even an acute viral infection. Yes, a viral infection can cause chronic, disabling conditions.

People with COVID-19 have an increased incidence of stroke, insomnia, and nerve and muscle disorders. Some patients develop auto-antibodies, increasing their risk of developing an autoimmune disorder. Researchers are studying the relationship between COVID-19 and multiple secondary conditions, like Guillain-Barrė Syndrome and parkinsonism. But long-term health consequences of the pandemic aren’t limited to COVID-19 patients. Healthcare workers are developing post- traumatic stress, the global pandemic is negatively impacting people’s mental health, and people are postponing preventative and acute care. To put it simply, the COVID-19 pandemic is disabling people and the US healthcare system is not prepared to manage their care.

engin akyurt on Unsplash

“Is fibromyalgia real?” If you type that phrase into Google you will get thousands of results. As the body of research into fibromyalgia continues to grow, the results are mostly researchers and hospitals saying yes, of course fibromyalgia is real. But this Google search represents a common sentiment held by the public and by healthcare professionals. This idea, that the illness isn't real or that patients are faking their symptoms, wasn’t just born from fibromyalgia’s complicated history, it reflects the deep-seated ableism that pervades healthcare.

The history behind COVID-19 isn’t so complicated. We know that it is a virus, we know what the most common symptoms are, and we have a test that can diagnose it. But the gaps in long-term care and research are already evident. A group of patients who have long COVID, symptoms of infection lasting more than 28 days, outlined the barriers to symptom management in a letter published in Pain Reports. The first demand that they make is something that I can strongly relate to: They need people, both healthcare workers and their own families, to acknowledge that long COVID is an illness.

There is plenty of research and anecdotal evidence of long COVID. So why aren’t these people believed? The answer is ableism and our propensity to dismiss the experiences of people with long-term symptoms. This disbelief is affecting symptom management and disability benefits claims. But I fear that long COVID patients and those that develop secondary conditions will learn another truth, that disbelief is traumatic.

...the dismissal of disabled voices is something that we can change

I had my first sick visit for muscular pain when I was ten years old. I wasn't diagnosed with fibromyalgia until I was 20 and had such severe symptoms that I couldn't leave my bed. After receiving my diagnosis from the rheumatologist, I eagerly had a follow-up visit with my pediatrician. See, I thought as I shared the news, it wasn't all in my head. But I quickly fell silent as my doctor explained that this an adult problem, I had to find a new doctor.

I'm 26 now, I've picked up a few other diagnoses along the way but I still have not found a doctor who will help me manage my fibromyalgia. I still have not found a therapist who can help me unravel the trauma caused by gaslighting and years of unmanaged pain.

Ableism is deadly, and there is so much more to say about how it corrupts healthcare. But I hope you can see that the dismissal of disabled voices is something that we can change. This may be as simple as believing your friend when they say they are in pain or it could mean changing the way that we do research.

In conservation biology, researchers produce data that doesn't reach the people who can use it. Similarly in medicine, researchers lack an understanding of what disabled people actually need to manage our care. The authors of the long COVID letter have a suggestion for solving this problem — patient-led research.

Long COVID patients have formed a group called the Patient-Led Research Collaborative and have since conducted two surveys with the goal of characterizing long COVID symptoms. The idea of patient-led research isn’t new, but it also hasn’t taken off yet. One criticism of patient-led research is that patients might not have advanced education in the appropriate field and may lack the scientific aptitude to conduct research. Well, the Patient-Led Research Collaborative puts it quite nicely, “It is clear, however, that as patients, we are intimately aware of what we are experiencing.”

Of course, ableism is just one of many factors that create a poor quality of care. Saying racism and implicit bias exacerbate gaps in care would be an understatement. Black women have a higher mortality rate from pregnancy-related complications than white women and they are underrepresented in clinical trials that require consent. LGBTQ+ people are discriminated against in healthcare, with Arkansas lawmakers passing a bill this April that bans doctors from providing gender-affirming surgery to trans youth. But the US healthcare system is also not optimized for chronic care. For example, the amount of time physicians have for patient care and literature review is extremely limited due to the amount of time they must spend on paperwork, and there is a lack of healthcare access in rural areas.

The US healthcare system cannot provide appropriate care to people with chronic conditions, and the amount of people with chronic conditions is increasing because of COVID-19. The thing is, disabled people know this and we’ve been saying it all year. We must reckon with our ableism if we want healthcare to work for people, if we want it to work into the future. Step back, let disabled people lead, or at the very least, listen.

The lab-leak hypothesis for COVID-19 is becoming a conspiracy theory

Dan Samorodnitsky — Wed, 26 May 2021 13:05:05 EST

No one knows for sure where SARS-CoV-2 came from. I don’t know, no one does. But there are two ideas. The first is the virus was harbored by an unknown animal, likely bats, where it mutated and picked up the ability to infect humans. Many pandemic viruses — Ebola, the 1918 flu — emerged this way. The other is that the virus was deliberately created in a lab at the Wuhan Institute of Virology, a research center near to where initial outbreaks were first detected in China.

Though there is no direct evidence for either idea, the natural origins hypothesis has scientific precedence. The coronavirus family of viruses, that SARS-CoV-2 is a part of, have spilled over into humans (SARS and MERS) and caused pandemics. Natural origin also takes into consideration natural phenomena that happen all the time in wild viruses — they reproduce rapidly, mutate frequently, acquire bits of DNA like a boat collecting barnacles, and change behavior, particularly when they shift from one host to another. These processes happen in all viruses.

But, the permanent uncertainty of SARS-CoV-2’s origins has made other explanations, no matter how complex, attractive. Now, the lab-leak hypothesis has taken on the rhythm and melody of conspiracy theory.

Chinese officials totally not acting like they have anything to hide here. https://t.co/V9N0hkb4oK pic.twitter.com/zRjDeR5ZGR
— Alec MacGillis (@AlecMacGillis) May 25, 2021

Article includes this 👀 statement from Biden’s National Security Council: “We continue to have serious questions about the earliest days of the Covid-19 pandemic, including its origins within the People’s Republic of China.” https://t.co/M9ZaLgZOYY
— Sahil Kapur (@sahilkapur) May 24, 2021

The huge “scoop” from the Wall Street Journal earlier this week is that three staffers at the Wuhan Institute for Virology had become ill in late 2019, during cold and flu season. The article quotes a Trump official who said it sounded fishy, and that’s it. There is no even indirect scientific evidence that the virus was created in a lab. Nevertheless, there seems to be some wish, some desire for China to be implicated in a cover-up.

In 2002, SARS spilled over from horseshoe bats into humans. MERS, caused by another coronavirus, spilled over from camels in 2012. Related coronaviruses within SARS-CoV-2’s subfamily have been identified in wild bats and pangolins. And, the virus's features that seem to scream out for the hand of a synthetic biologist are better explained by the kind of random, driftwood mutations that viruses pick up constantly.

SARS-CoV-2 uses its spike protein to bind tightly to ACE2, a protein on cell surfaces in humans and other animals. But, research has shown that this binding is actually not biochemically ideal, which makes the idea that it was synthetically created less likely; this ability to bind ACE2 could have easily arisen through common routes of mutation. The ballyhooed “furin cleavage site” — a site where the viral spike protein is cut, facilitating infection into a cell — was created by an out-of-sequence insertion of a small piece of DNA resulting in yet another non-ideal biochemical reaction.

New viruses emerge all the time. Constantly. The number of viral particles on the planet is more than the number of stars in the universe; the rate that viruses reproduce, their ability to quickly mutate and adapt to new environments and new hosts, means there are functionally an infinite number of viruses on the planet.

So, figuring out where this particular virus came from will be a challenge. It can take years, decades, or more to find the source of a virus. Ebola, for instance, was identified in 1976, has caused multiple epidemics, and we still don’t really know what animal it spilled over from. To confirm beyond a reasonable doubt the virus’s origins, we’d have to sample wild animals and sequence the viruses they carry to find a close genetic relative, an astronomical task, haystacks within haystacks. In the absence of a smoking gun, there's still good research that points in one direction. Take the phylogenetic analysis in preprint this week that, once again, suggests bats as a reservoir for SARS-CoV-2, with pangolins or civets as possible intermediate steps.

If the question is “are both hypotheses possible?” the answer is yes. Both are possible. If the question is “are they equally likely?” the answer is absolutely not. One hypothesis requires a colossal cover-up and the silent, unswerving, leak-proof compliance of a vast network of scientists, civilians, and government officials for over a year. The other requires only for biology to behave as it always has, for a family of viruses that have done this before to do it again. The zoonotic spillover hypothesis is simple and explains everything. It’s scientific malpractice to pretend that one idea is equally as meritorious as the other. The lab-leak hypothesis is a scientific deus ex machina, a narrative shortcut that points a finger at a specific set of bad actors. I would be embarrassed to stand up in front of a room of scientists, lay out both hypotheses, and then pretend that one isn’t clearly, obviously better than the other.

Besides the hazy science, there is an undeniable political aspect to this argument. When violence against Asian people in the US is spiking, it’s naive at best and violent gaslighting at worst to pretend that supporting an evidence-free hypothesis that clearly adds fuel to the idea that China inflicted COVID-19 upon the world, that they did this to us, is noble scientific dispassion. There’s a choice being made here between two ideas — one that falls neatly within the world of biology, and the other that knots together conspiracy theory, political intrigue, and xenophobia.

And since we will never be able to prove the exact moment that SARS-CoV-2 jumped from an animal to a human, this is instead going to devolve into a culture war. We are witnessing the real-time birth of a new axis of half-truths, convenient omissions, and quackery.

The most bothersome thing about all this is that it does not particularly matter where SARS-CoV-2 came from. Making a scapegoat out of China doesn’t do anything about the political and economic systems that allowed millions to die, especially in wealthy nations like the US that could easily afford muscular public health responses. In March, Marion Renault wrote in The New Republic:

“We have known for years that resource extraction and human expansion into wildlife habitats could lead to emergent zoonotic diseases. We have known that inadequate health coverage and sick leave policies could spread illness; countless reports and studies in recent years have chronicled the draining of public health resources, the erosion of science and public trust in it (anti-masking falls into this category), and the failures of the U.S. health care system to equitably provide affordable medical care to all.”

Creating a webbed story of cover-ups and conspiracy allows us to ignore how in many ways all humans caused the COVID-19 catastrophe. What if it wasn’t one bad Chinese government’s fault, but the whole world’s fault for destroying habitats, mining too deeply, and creating the perfect conditions for natural viral spillovers? The lab-leak hypothesis will soon be in league with climate change denialism — a conspiracy that absolves humanity of its mistakes, and lets us live our lives as if nothing had ever happened.

Dan Samorodnitsky studies
Senior Editor
.

How COVID-19 has worsened the lives of Alzheimer's and Parkinson's patients

Burcin Ikiz — Tue, 11 May 2021 23:41:40 EST

Alicia Del Blanco — a 68-year-old retired French teacher from Madrid, Spain — had big plans. She was about to become a grandmother for the second time, was going to spend the summer in her house in Huelva, and join a daily therapy program specially designed for people with Alzheimer’s. Like all of us, her plans upended with the pandemic.

On March 14th, 2020, Spain entered a nearly three-month lockdown where residents were not allowed to leave their houses unless for medical emergencies or getting groceries. Then came the closures of Del Blanco’s favorite past times — theaters, restaurants, and musical venues — along with the restrictions on social gatherings and the discontinuation of her Alzheimer's therapy program. Del Blanco struggled to comprehend the reason behind all these changes. While she was able to maintain her daily walks around Madrid’s largest park — El Retiro — after the lockdown ended, her accelerating cognitive decline became disturbingly noticeable to her husband, Armando Guerra.

“One day I asked [Del Blanco] to pour water in a glass,” Guerra said, “and realized that she no longer understood what a glass meant unless I pointed at it.” Her neurologist confirmed Guerra’s observations. Del Blanco’s cognitive decline in the last six months was equivalent to what was supposed to happen in two years. And hers was not the only case.

Researchers from Santa Maria University Hospital in Lleida, Spain, examined 40 patients with mild Alzheimer’s five weeks after the lockdown and compared their evaluations to the ones they did a month before the pandemic. They found that — following the lockdown — the patients showed a worsening of neuropsychiatric symptoms, including increased agitation, apathy, and aberrant motor activity.

Alicia Del Blanco and Armando Guerra take a daily walk in El Retiro park in Madrid, Spain

Courtesy of Armando Guerra

A study published in January from Columbia University showed similar effects on Parkinson’s patients. To assess the impact of COVID-19 and social distancing, the researchers sent out a survey in May 2020 to the mailing lists of the Parkinson’s Foundation and Columbia University Parkinson’s Disease Center of Excellence asking the patients about their physical and social activities and their moods. Of the 1,342 responses they received, half of the patients reported a negative change in their symptoms, along with mood disturbances, such as deepened anxiety and depression.

According to Roy Alcalay — an associate professor of Neurology at Columbia University and the principal investigator of the study — these results were not surprising. “There's no question that the lack of activity, the lack of services, and the emotional stress of not seeing the family take a toll,” he says, “and the toll for people with Parkinson's is the progression of the motor symptoms.”

Alcalay plans on following up his study with a survey to be sent out to the same people a year after the pandemic to determine the long-term effects of COVID-19 on these patients. He also believes that more needs to be done to make sure that the patients are not permanently harmed any further.

The question for us doctors and policymakers is what can we do to ease the chronic effects of the pandemic for people with Parkinson's,” Alcalay says. To him, the answer includes facilitating and improving telemedicine visits, promoting outdoor exercises, providing emotional and psychological assistance, and getting the patients vaccinated.

People with Alzheimer's and Parkinson’s depend on daily socialization, therapy, and physical activity for their disease management. So, it is no surprise that increased stress, social isolation, and confinement during the pandemic would be especially destructive to them. A recent analysis done by researchers from Case Western Reserve University in Cleveland, Ohio, shows, however, that the disruption of daily routines is not the only reason why COVID-19 has been so detrimental to these patients.

An infographic summarizing the results of the COVID-19 survey done by Alcalay's group at Columbia University in collaboration with the Parkison's Foundation

Courtesy of the Parkinson's Foundation

The analysis — which studied the electronic health records of 61.9 million patients in the US — found that people with dementia are twice as likely to get COVID-19 compared to patients without dementia even after adjusting for demographics and COVID-19 risk factors. This could explain the 16% increase in Alzheimer’s and dementia deaths observed in the U.S. alone since the beginning of the pandemic.

While the study does not say why these patients are more vulnerable, the researchers discuss two possible explanations. One is that — given the symptoms of the diseases, such as memory loss and motor impairment — the patients may not be able to comply with preventative behaviors for COVID-19, such as hand washing, wearing a mask, and social distancing. Another reason could be the patients’ damaged blood-brain barrier, which allows certain bacteria and viruses to access the brain more easily and make patients more susceptible to bacterial, viral, and fungal infection.

According to Alcalay, despite all its negative impact, the pandemic had one surprising change for the better — the uptick of patients and clinicians using telemedicine — which he hopes to be permanent. While in-person visits are still necessary for certain physical examinations, Alcalay thinks that there are several advantages to telemedicine, such as in the cases when a patient is disabled and cannot leave their house, or if they live in a different city from the best available doctor. “I don't think [telemedicine] is gonna replace in-person care,” says Alcalay, “but it's going to supplement it.”

The pandemic had a silver lining for Guerra and his wife as well. “This year taught me to prioritize what is really important in my life,” Guerra says. “Being with family and loved ones — no matter the circumstances — gives me the greatest joy.”

Burcin Ikiz studies
Neuroscience
.

An anonymous COVID-19 contact tracing app that warns you when your friends are sick

Dan Samorodnitsky — Sat, 08 May 2021 11:36:16 EST

COVID-19 contract tracing apps are a bit of a rage right now. The UK National Health Service has one. So does Germany. Half the states in the US have their own; North Carolina's alone has almost 800,000 downloads. These apps mostly work the same way: if you were in close contact with someone who was later diagnosed with COVID-19, you get alerted and asked to quarantine. This approach has drawbacks. First, it requires some amount of people to have and use the app, to make it useful at all. The second is that it relies on users' ability or desire to comply with an app that asks them to stay home.

Last year, Carnegie Mellon University scientist Po-Shen Loh published a paper with a different idea. He proposed an approach that "inverts the incentives." Instead of telling people they'd been exposed and, for other people's good, quarantining themselves to stop further spread, warning people ahead of time that danger was near. This, hopefully, makes the decision less altruistic and more about self-preservation. An app using this approach, NOVID, is available on app stores. Massive spoke with Loh about the mathematics behind this different form of contract tracing, and what he hopes to see change. This conversation has been edited for clarity.

Dan Samorodnitsky: Can you tell me how you ended up working on this app?

Po-Shen Loh: I am a person who grew up with math competitions. So it was in middle school, when I suddenly discovered that there were math problems that were harder than what you normally do in school, and therefore they were interesting. I like people, I like helping people. I like working with people and things. I like challenges, I like working on things that are supposed to be hard or impossible, or the fewer people in the world who can achieve them, the more interesting they are to work on.

In say, January 2020, I heard there was some COVID thing, and I wondered why everyone was overreacting about it. I didn't know. But then on March 14, which I can remember, because it's Pi Day, I got an email. And the reason I got it is because I'm a Hertz Foundation fellow. This is an important part of my history. The Hertz Foundation is a group that signs about 15 people every year who are about to start their PhDs. And if you get it, you get free funding for a PhD. But you also sign a moral commitment that if there's ever a moment of national emergency, you'll go to help.

And the idea of the Hertz Foundation was if you ever needed another Manhattan Project, would there be people to do it? I got the Hertz fellowship in 2004. By then nobody expected to build more bombs. In fact, the joke was, we'll probably be called to respond to some kind of bioterror.

That’s a hilarious joke.

Yeah. So on March 14, there was this email, detailing how COVID-19 wasn't just like some fluke. And it wasn't just something that would get old people sick. But actually, there was all these different aspects of it. This was stuff that I hadn't known at the time and we ended up ended up saying, “remember, the moral commitment?”

I remember when I was supposed to be giving feedback [for a grad student’s thesis], I only got through the first sentence of the introduction, I suddenly realized, oh my gosh, our area of research is network/graph theory. It's something that could be extremely powerful in fighting COVID. Because now we have smartphones. It's possible to go and anonymously figure out which devices were around which other devices, and then you have a big network.

And since they’re smartphones, you could also even label some of them as having various symptoms or like “got sick” and when, and with all of this anonymous information where you don't need to know anything about the person, you could actually possibly control the virus. That was the insight.

Let's pretend that I'm bad at math. Can you explain what network theory is? And how it connects to this use of phones and labeling people?

You've probably heard [for COVID social distancing] six feet for 15 minutes. Network theory, or graph theory, is where you say, look, let's not focus on that. Let's instead do this: if two people live with each other, connect them by a line and consider them linked. If two people work in the same office regularly, consider them linked. Effectively consider people linked if it is quite possible for them to transmit to each other due to their extended behaviors. But if you were in the supermarket checkout line, standing behind someone for 10 minutes today? And you'll never see the person again in your life? Don't even bother connecting them.

Interesting.

Now here's how I'm going to measure how dangerous it is for you. If you spend a lot of time around someone, who spends a lot of time around someone else, who spends a lot of time around someone else who has COVID, that's three distances away from you in the network. And I would say that COVID is three relationships away from you. It's a different way of quantifying distance. It's not like that was 25 meters over there. And we were in the same place for an hour. Instead, it's how many of these long term repeated relationships away are you? It’s like six degrees of Kevin Bacon.

Every other app [like apps released by the German and British governments] works only after you have already been around somebody else who has COVID. It tells you, “Hey, you know what? You were around somebody else with COVID. Maybe you have it now, too,” because they’re measuring physical distance

This is the “inversion of incentives” that you talked about in the arXiv paper?

That's correct. Because at that point, what does that app do for you? The only thing that app does for you is say, “Oh, no, you have been around somebody who has COVID.” Well, in that case, all you can do is quarantine to go and protect everyone else from you. Here’s a question: suppose you were around somebody else, for six feet for 15 minutes? Suppose that they had COVID? What's the chance that you get it?

Oh lord you’re quizzing me.

It actually turns out to be really low, less than 10%.

And 10% would be considered low in this kind of scenario?

So let's think about game theory and behavioral science here. Suppose that an app is asking you to quarantine voluntarily. And suppose that its threshold for triggering that command is when your chance of getting sick passes 10%. How many people will listen to that request?

A chart showing social circles intersecting with each other. The user is in the 1st circle, while someone with a COVID-19 infection three circles away

Courtesy of NOVID

[hems and haws for a moment] Probably not that many.

So that's my, that's my point. There's a huge difference between trying to make an anonymous app to do contact tracing, which non forcibly tells you, “Hey, you should go and quarantine” versus manual contact tracing, which is where somebody calls you up and says, Hey, hey, Dan, I know who you are. I know where you live, stay there.”

This is where a mathematician comes in. What breaks along the way, if there's a 10% chance that you're actually positive, is enforcement. Let's say non-anonymous changes to anonymous. Suddenly, as we know, on the internet, once people become anonymous, lots of different things happen. You know what I mean? Like, yeah, that's the entire thing about anonymous behavior.

Is “inverting people’s incentives” something that you identified at the beginning and then sought out? Or is it something that came out later?

It came out in the middle. At the beginning, we were making an app that was doing what every other app was doing. We were making a contact tracing app.

And then around the late summer and early fall [2020], I learned about the fact that if you are around somebody else who has COVID, the transmission probability is not extremely high. And then that raised some huge alarm bells of Wait a second. It's not compatible with human behavior.

This pandemic will have to end at some point. Do you see a use for this kind of technology down the road?

So what we've just invented is a new kind of feedback loop that will help humanity, forever. This could fundamentally affect how people avoid disease forever, they might not care to use this to avoid the common cold, because they're not afraid of it. But the moment that there is another bad disease, and there will only be more of these because of the interconnectivity of the human population.

My goal is that everyone says, you remember, you remember what happened with COVID, we learned that the radar was a way that you could just avoid getting sick. Will they use this app that I've made? Probably not. I mean, this is just one particular app that we've made. But will they use this paradigm? Yes.

NOVID’s user base is mostly around Georgia Tech in Atlanta and at CMU in Pittsburgh. Have you seen effects reducing COVID spread among people who are using the app?

There was actually a student who contacted me about almost two weeks ago. He said, “I saw on my radar that there was a case two away from me. I was going to hang out with my friend. He checked his radar. There was one away from him. My case was one away from him. So we chose not to hang out.”

Does this kind of technology have to have input from some governing body? Is there any way to avoid that?

Yes we avoid that. In some sense, Carnegie Mellon is not really a governing body, it's just a trusted entity. Whenever there's anyone who's actually sick, Carnegie Mellon gives that person a code, a password, if they use that password in their NOVID app to report positive, suddenly that shows up as a verified positive case.

But that person still has to take the initiative to report themselves.

So that’s a fundamental flaw, because maybe only about 10-20% of people will actually enter in voluntarily that they’re sick. That kills everything, that kind of a problem is a huge problem for all these apps. In our system, the person who's sick gets a passcode to enter that they’re sick, and every one of their contacts, traced contacts, gets another passcode that they can enter into the NOVID app to say “I was a contact.”

And if any one of those people enters in the passcode, that original person, the person who actually was exposed, gets verified?

Almost, but you're getting very close. This system is designed so that as long as one of these people does it, we're in good shape. But in order to protect privacy, they have no way actually of telling who that person was. Instead on the radar, it shows up as not a red, but as a pink. And so what happens is, you would find out on your radar, hey, somebody two relationships from you reported that they’re a contact of a positive case. Well, then there's a positive case within three of you. This is called the triangle inequality in graph theory.

What the triangle inequality says is, suppose that your radar tells you that four relationships away, there is a contact of a positive case, then the positive case is at most five relationships away, because four away from you is a contact of a positive case, at most one away from there. All that does is it shows up as a blip on the radar, where the blip might be off in its horizontal position, which is how many degrees away from you a positive COVID case is by at most one. But that's good enough.

Just seeing that there is a positive case no matter if it’s off by one degree of separation?

That's right.

This is not an app designed to close things. This is an app designed to hopefully open things. The exciting thing here is that if you have this system, whenever a person is around sickness, they are more careful out of self defensive instincts. That feedback loop reduces the ability of the disease to propagate.

Does the underlying mathematics change for different viruses if a virus is more infectious or less infectious?

If you think about what this is doing, it just makes a person more able to protect themselves against the disease the same way that radar on an aircraft carrier makes the aircraft carrier more able to protect itself.

If there were more dots on the radar, it doesn't really matter what the dots are, all you're doing is seeing the dots.

Yes.

Is there anything that there's anything that you wanted to mention that I hadn't asked?

The breakthrough is that we've actually found a way to realign incentives, so that actually the app is something that you want to use. But the only problem is that at the beginning, maybe no one's using it. It could be really useful for you, but there's no one around you're using it. So you need to just pass over this very low hump. The low hump is if we were using this to, for example, reopen schools, that's a really important thing right now, schools, how do you reopen schools safely? Well, one of the best ways to reopen schools safely is if you could give everyone a long range radar so that they could know when to be more protective of themselves as we start mixing all of the networks of all of our people in the city. Okay, in a school environment, yeah, when you get like 10% of the school on it, then suddenly, suddenly, you're past that hump. And everyone sees that, oh, if I joined the app, I'll have 1000s of people connected to me.

This is an app where the usage snowballs all the way down? And if I want to contrast that, the way that people were trying to do this before, it's uphill all the way.

Dan Samorodnitsky studies
Senior Editor
.

Demystifying the effects of COVID-19 variants on vaccines

Sara May Bergstresser — Mon, 19 Apr 2021 22:33:32 EST

In the past few months, senior public health officials in the US, including CDC (Centers for Disease Control and Prevention) director Rochelle Walensky and head of the National Institute of Allergy and Infectious Diseases Anthony Fauci, have warned of “disturbing," “tenuous,” and “precarious” new trends in the COVID-19 pandemic.

They caution that premature relaxation of restrictions could have devastating consequences because multiple emergent variants of SARS-CoV-2 virus still have the possibility to drive new surges of infection. These statements may at first seem counterintuitive or overly pessimistic. Many national mass vaccination campaigns are well underway (at least in wealthy countries), and recent research shows up to 90 percent effectiveness in real world settings for the Pfizer/BioNTech mRNA vaccine. So why should there still be so much concern?

Though enormous progress has been made in science and policy since the SARS-CoV-2 virus was first detected in late 2019, there remain valid warnings about emergence of viral variants. Global technology and human society are not the only things that have changed since December 2019. The virus itself has also evolved during this time, and with over 140 million global infections to date, there have been many opportunities for viral mutation. After over a year of the pandemic, people are tired. But as much as people wish to finally be done with this virus, we remain in something like a “race” between getting people vaccinated and new variant-driven surges.

S (spike) proteins are the main protein type used as a target in COVID-19 vaccines currently being used, regardless of underlying technology

It is not possible to know exactly how many variants there are out there, but there are many organizations working to sequence and catalogue them as fast as they can. Variants can now be tracked geographically, through evolutionary history, by particular mutation, and as reported in the world over time. Out of the many, the CDC has identified five variants of concern, which include B.1.351 (first identified in South Africa), B.1.1.7 (first identified in the UK), P.1 (first identified in Brazil and Japan), and B.1.427/B.1.429 (both first identified in California, USA). In order to reach this level of concern, a variant must show evidence of increased transmissibility, increased disease severity, or evidence of impact on diagnostics, treatments, and vaccines.

The most salient form of genetic mutation found in these variants involves changes to the spike protein (S protein), which is important because S proteins are the main protein type used as a target in COVID-19 vaccines currently being used, regardless of underlying technology, including vaccines based on mRNA (BioNTech/Pfizer, Moderna/NIAID), DNA and viral vectors (AstraZeneca/Oxford, Johnson & Johnson), or protein subunits (Novavax, others under development).

The most alarming variant may be the B.1.351 (S.501Y.V2), which was first identified in South Africa. A recent study reported on the preprint server medRxiv suggests that vaccinated people in Israel who were infected at least a week after the second dose were disproportionally infected with B.1.351 versus the more common B.1.1.7 variant.

This isn't a reason to panic; these results have not yet been peer reviewed, and only 1 percent of the study population was infected with the B.1.351 variant, which the authors describe as their “main caveat.” Nevertheless, there is also additional evidence to note, including a research finding that two doses of the AstraZeneca/Oxford vaccine are ineffective against mild-to-moderate infections with the B.1.351 variant, and real-world observations of the same phenomenon. More research is necessary to determine the extent to which this variant may evade current vaccines.

These troubling trends are associated with the particular combination of mutations found in B.1.351. The N501Y and K417 mutations are thought to help the virus latch on tighter to human cells, and one or both of these mutations appear in many different viral variants. The E484K mutation is also particularly concerning, because it is thought to help the virus evade the body’s immune defenses, which is likely to increase the risk of reinfection. This mutation might also explain an important mechanism of vaccine evasion, and it is also found in the P.1 variant, which was first identified in travelers from Brazil.

The news for the B.1.1.7 variant is more encouraging because there is increasing evidence that the mRNA vaccines are effective at inducing neutralizing antibodies against this strain. B.1.1.7 moved rapidly through the UK and beyond, suggesting it is more infectious than the original strain, and it has multiple mutations to the spike protein including N501Y, though it lacks the E484K mutation.

The B.1.427/B.1.429 variants, first identified in California, are eliciting increasing concern from scientists. Another preprint study reports that these variants are more transmissible and cause increased viral shedding (how much virus a person expels from their body) compared to early strains of SARS-CoV-2. The study also finds that they may interfere with vaccine efficacy and are behind multiple outbreaks in California. In these variants, a different spike protein mutation (L452R) may weaken the binding of antibodies to viral spike proteins.

...the eventual need for booster vaccines appears likely

With ongoing uncertainty about viral variants and their potential to lessen the impact of mass vaccination campaigns, public health officials still recommend precautions such as wearing masks and limiting the size of indoor gatherings, even for those already vaccinated. The potential for unexpected developments, such as the recent “pause” in the use of the Johnson & Johnson vaccine in the US, only increases the level of uncertainty.

Finally, it is important to remember that the virus is still evolving, and new variants may emerge at any time. New variants can proliferate in under-vaccinated groups including children, disabled people, and in the many countries that lack sufficient resources, where there is often little or no access to any vaccine. Possible plans to delay second doses in order to more rapidly vaccinate others with a first dose could have the unintended consequence of fostering the conditions in which viral evolution is favored, potentially leading to new variants of concern.

Based on the current situation, the eventual need for booster vaccines appears likely, though it is unclear if a booster would be required only occasionally, or if it would become a yearly routine. Moderna has already started work on a booster based on the B.1.351 variant, and the Pfizer CEO recently said he expects that boosters will be needed within 12 months of being fully vaccinated.

In a few years, coronavirus variant boosters may become routine, and eventually the virus may become endemic, and the future global population may merely have to endure a new type of common cold.

Sara May Bergstresser studies
Bioethics, Public Health, and Biochemistry
at
Columbia University
.

When can kids get the COVID-19 vaccine? A pediatrician answers parent questions

James B. Wood — Tue, 06 Apr 2021 23:05:02 EST

A big question among parents and teachers as more schools reopen is when their kids will be vaccinated against COVID-19. Some have wondered whether the vaccine is even necessary for children. There is news on that front. In a press release on March 31, 2021, vaccine maker Pfizer suggested its vaccine is as effective in children ages 12-15 as it is in young adults. However the results of Pfizer’s vaccine trials in adolescents have not been fully released or reviewed by the Food and Drug Administration, and that will take several weeks.

Dr. James Wood, a pediatrician and assistant professor of pediatric infectious diseases, explains what doctors know today about the risk children face of getting and spreading the coronavirus and when vaccines might be available.

Do kids really need to get the COVID-19 vaccine?

The short answer is yes. A lot of studies have shown that COVID-19 isn’t as severe in children, particularly younger kids – but that doesn’t mean kids aren’t at risk of getting infected and potentially spreading the virus.

Children under 12 who get COVID-19 do tend to have mild illnesses or no symptoms, while teenagers seem to have responses somewhere between what adults and younger kids have experienced. The Centers for Disease Control and Prevention found that teens were about twice as likely to be diagnosed with COVID-19 as children ages 5-11.

Researchers are still trying to understand why we’re seeing these differences between older and younger kids. Behavior probably plays a part. Teenagers are more likely to engage in social or group activities, and they may or may not be wearing masks. Immune differences and biologic factors may also play a role. Non-SARS-CoV-2 coronaviruses are common in children, often resulting in upper respiratory infection. Is their frequent exposure to other coronaviruses helping protect them from severe COVID-19? That is one hypothesis. We know younger kids’ immune responses in general are different from adults, and likely play a role in protection.

It’s important to remember that while most children get only mild symptoms, they still face risks. At least 226 U.S. children with COVID-19 have died, and thousands have been hospitalized.

The key to minimizing the risk is to make sure kids eventually get vaccinated, follow social distancing recommendations and wear masks.

Are kids spreading the virus?

In a setting like a school where mask-wearing and social distancing are enforced, young kids seem to not spread the virus very much when the rules and guidelines are being followed. One CDC review found little difference in community cases in counties with elementary schools open and those with remote learning.

If precautions aren’t being taken, children infected with the coronavirus very well could spread it to adults. What isn’t clear yet is how great that risk is.

To keep schools as safe as possible, continuing schoolwide mask and social distancing policies will be important. With teenagers in particular, mask rules can’t hinge on whether the person has been vaccinated or not. Until herd immunity within the whole community is at a good level, social distancing and masking is still going to be the recommendation.

Photo by Kelly Sikkema on Unsplash

So, when can kids get vaccinated?

Right now, the Pfizer vaccine is the only one in the U.S. authorized for teenagers as young as 16. Before kids under 16 can be vaccinated, clinical trials need to be completed in thousands of young volunteers to assess the vaccines’ safety and efficacy, and the results must be fully reviewed and then authorized by the Food and Drug Administration.

Pfizer said it expects to submit results from its adolescent trials for review soon. Vaccine manufacturer Moderna also has trials underway with adolescents. If their vaccines are shown to be safe and effective and regulators authorize them, kids 12 and up could be vaccinated before school starts in the fall.

Realistically, young children probably won’t be eligible for the vaccine until late fall or winter at the earliest. Moderna announced in mid-March that it had started testing its vaccine in children ages 6 months to 11 years. Pfizer said it is also starting testing in young children, but these trials take time.

What’s different about the vaccines kids will get?

The composition of the COVID-19 vaccines for children is the same as used in adults – the difference is that children may require a different dose.

The first step in vaccine trials is to figure out the right dose. The companies want to find the lowest possible dose that is both safe and produces a target level of antibodies. For example, Moderna uses a 100-microgram dose in adults. It is testing three different doses for children under age 2 – 25, 50 and 100 micrograms – and two doses for children over age 2, at 50 and 100 micrograms.

Once the company determines the optimal dose, it will launch a placebo-controlled trial to test its effectiveness, in which some children will get a placebo and some will get the vaccine.

A rigorous system for pediatric vaccine trials is well established in the U.S. These trials are key to assessing the safety and efficacy of vaccines in children, which can differ from adults.

I am optimistic that a safe and effective vaccine will be available for children. Thus far, there have not been any safety signals from either the adult or adolescent studies that have been worrying to me as a pediatrician, but the studies still need to be done in children.

Photo by Taylor Brandon on Unsplash

How can parents create safe playdates for kids?

When I talk to parents, I explain that it’s a risk-versus-benefit question. Each family has a different tolerance.

From a medical standpoint, the mental health of kids and having them play with other kids is an important part of childhood.

I would say that unvaccinated kids playing indoors without masks on is still not a great idea. The risk is just too high at this point. As weather warms up, I would encourage kids to play outside. Ride bikes, play and socialize – just do it in a safe manner.

We all have pandemic fatigue, including medical professionals. As the weather gets warmer, I think everyone just wants to get back to normal. The worst thing we can do, right as we start to see a light at the end, is fall backward again – because that would just make it that much longer for everyone.

James B. Wood studies
Pediatrics
at
Indiana University School of Medicine
.

Over-the-counter COVID tests are coming sooner rather than later

Hannah Norman — Fri, 02 Apr 2021 00:28:44 EST

But even as entrepreneurs race their products to market, armed with millions of dollars in venture capital and government investment, the demand for COVID testing has waned. Manufacturing and bureaucratic delays have also kept rapid tests from hitting store shelves in large numbers, though the industry was energized by the Food and Drug Administration’s greenlighting of two more over-the-counter tests Wednesday.

Corporate giants and startups alike plan to offer a dizzying array of test options, most costing between $10 and $110. Their screening accuracy varies, as does the way consumers get results: collection kits mailed back to a lab, devices synced with artificial intelligence-enabled apps on a smartphone that spit out results within 15 minutes, and credit card-sized tests with strips of paper that must be dipped into a chemical substance.

“At-home tests are one of the key steps to getting back to normal life,” said Andy Slavitt, a member of the White House COVID-19 Response Team, during a February briefing.

The Biden administration announced in March it will allocate $10 billion from the recently passed stimulus package for COVID testing to expedite school reopenings, and earlier said it would invoke the Defense Production Act to manufacture more at-home tests. Separately, the federal government has already sent millions of Abbott Laboratories’ BinaxNOW rapid tests to states, and California, for instance, is giving 3 million of them to its most disadvantaged school districts for free.

Large employers, like Google, sports leagues and the federal government, have already shelled out millions to regularly test their workers. Amazon just received emergency use authorization from the FDA for its own COVID test and home collection kit, which it intends to use for its employee screening program.

Individuals who want to buy over-the-counter tests can bill their health insurance plans, which are required by the federal government in most cases to fully cover COVID tests that have been authorized by the FDA.

Everlywell, based in Austin, Texas, is an at-home diagnostic company that already sells its collection kit to consumers through its website and Walgreens, and will soon offer same-day delivery via DoorDash in a dozen cities. Dr. Marisa Cruz, Everlywell’s executive vice president of regulatory and clinical affairs, said buyers can seek reimbursement from their insurance plans for the kit’s $109 cost. The tests are also eligible for purchase with pretax dollars from health savings or flexible spending accounts, she said.

Even with vaccines, epidemiologists say, rapid tests are desperately needed because more testing, along with mask-wearing and physical distancing, will get people back in offices and classrooms and help catch cases that go undetected. A report by the Centers for Disease Control and Prevention found that, of people with active infections, 44% reported no symptoms.

But the market for over-the-counter tests is risky. Demand for testing has plunged dramatically since the height of the winter surge and may not rebound as more people are vaccinated.

“You clearly are at risk of missing the market,” said Michael Greeley, co-founder and general partner at Flare Capital Partners, a venture capital firm focused on health care technology.

But Douglas Bryant, president and CEO of Quidel Corp., remains unfazed, even after the diagnostics manufacturer’s testing demand dropped by about one-third in the past two months.

“The level of testing for people with symptoms and the ‘worried well,’ who see others getting tested and think they should, too, is subsiding,” Bryant said. “But once we start to get more people vaccinated, the government will move from campaigning to get people vaccinated to saying, ‘Please test yourself regularly so we can get back to work.’”

Quidel, headquartered in San Diego, recently unveiled its latest test, the QuickVue A t-Home COVID-19 Test, which takes 10 minutes to detect the coronavirus by homing in on specific proteins, called antigens. The FDA authorized the test for over-the-counter use Wednesday, and Quidel plans to announce retail partners in the coming weeks.

The FDA said in mid-March it would speed the pipeline for “screening testing,” including at-home COVID tests that don’t require consumers to have symptoms or a prescription.

In February, the Biden administration cut a $232 million deal with Ellume, whose rapid antigen test was authorized by the FDA in December. Paired with an app, the test takes 15 minutes to analyze after a nose swab.

The Australian company currently ships hundreds of thousands of test kits a week to the U.S. from its factory in Brisbane to large companies and the Department of Defense. It plans to be on the shelves of multiple pharmacies by the second half of the year and in one major retailer in April, said Dr. Sean Parsons, the company’s founder and CEO.

“We are going as fast as we can possibly go,” he said.

The main holdup for Ellume has been getting enough swabs for its production line. The company is building a factory in the U.S. to reduce international shipping costs and increase production.

Abbott, which dominates the rapid-test market, said in January it expects to sell 120 million BinaxNOW antigen tests to consumers in the first half of the year. People who take the test now must do so under observation by telemedicine platform eMed. But Abbott received authorization from the FDA this week for an over-the-counter version that won’t require remote observation or a prescription. The test will be available in U.S. stores in the coming weeks, the company said.

Throughout the pandemic, the government has depended heavily on medical device behemoth Abbott’s testing options. The company’s rapid-diagnostics arm alone has snared $673 million in federal contracts to combat the coronavirus, according to a ProPublica database. This includes bulk purchases made by the Defense Department, the national prison system, Immigration and Customs Enforcement, the State Department and former President Donald Trump's office.

But antigen tests sometimes report false negatives, particularly among people without symptoms, noted Dr. Jac Dinnes, who co-authored a review of 64 COVID test studies. By comparison, polymerase chain reaction (PCR) tests — generally employed by commercial labs — are more sensitive. PCR tests search for the virus’s genetic material over multiple testing cycles, which magnifies what’s in the swab sample, requiring a much smaller viral load for detection.

Antigen tests are the basis for most at-home screening, but the FDA has also authorized two at-home options — made by Lucira Health and Cue Health — that use molecular processes similar to a PCR test.

Still, many experts support the widespread distribution of cheap, rapid tests, even if they aren’t as sensitive as lab-run alternatives, and see a demand. In Germany, the supermarket chain Aldi began selling rapid tests in early March, roughly $30 for a five-pack, and sold out within hours. One recent study found that if a pack of tests was mailed to every household in the U.S. — even assuming that up to 75% would go into the garbage — they would save thousands of lives and avert millions of infections.

“Don’t let perfect be the enemy of good,” said study co-author and Yale University professor A. David Paltiel. “This doesn’t have to work perfectly to make a huge difference.”

Some companies are working on rapid-testing options that more precisely read samples, such as Gauss.

The Menlo Park, California, health tech company, which before the pandemic created an artificial intelligence-based app to measure surgical blood loss in real time, aims to harness its expertise to improve on the basic antigen test. It took about a week for CEO Siddarth Satish to raise $30 million of venture capital last October.

Its COVID-testing app uses facial recognition software to confirm that test-takers correctly swab their noses. The app provides step-by-step instructions and timers. After 15 minutes, an algorithm based on thousands of sample tests interprets the result — which displays as a colored line, as with a pregnancy test — using the phone’s camera.

Gauss and Cellex, which manufactures the Gauss tests, await FDA authorization. In the meantime, they have produced more than 1.5 million kits and struck deals with supermarket chain Kroger and e-pharmacy site Truepill to sell them for about $30.

“A huge part of the accuracy issue with rapid tests is that you have to visually interpret them,” Satish said. “Sometimes you get really faint lines, just like with a pregnancy strip, and there’s some guesswork.”

Lucira Health, based in Emeryville, California, uses something called loop-mediated isothermal amplification technology, which is similar to PCR tests in precision. In February, the company went public, raising $153 million largely to fund the manufacturing of its all-in-one testing kit, currently prescribed by doctors across the country. The kit comes with a nose swab and a vial of chemicals analyzed by a hand-held device — taking up to 30 minutes for results.

Kelly Lewis Brezoczky, Lucira’s executive vice president, envisions the test kit on the shelf in local pharmacies, perched next to the NyQuil. “I always like to tell people that it is as easy to use as toothpaste,” she said.

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.

Immunocompromised people must be a priority in the COVID-19 vaccination effort

Francesco Zangari — Sun, 07 Mar 2021 22:16:04 EST

Vaccine prioritization is both necessary and important, with a demand for coronavirus vaccines much greater than supply. These policies assure the most at-risk populations are protected from COVID-19. This has included front-line workers (ie. patient-facing nurses and doctors), the elderly, and those with serious health complications. Other non-healthcare priorities are those employed in firefighting, retail, public transport and logistics.

We have needed these phased distribution efforts to ensure a compassionate framework for high-risk populations. These initial plans were adequate, but findings from two case studies of immunocompromised people highlight a new priority for vaccination. These emerging data highlight two poignant facts — immunocompromised people lack the ability to fight COVID-19, rendering poor health outcomes while also serving as an unintended launching pad for SARS-CoV-2 evolution.

Immunocompromised people have weakened immune systems, so the virus sticks around longer and copies itself to a high degree. Through this process, the virus adapts to its human cellular environment faster than normal, promoting mutations and potentially the formation of more transmissible variants. This is in some ways analogous to how incorrect or inconsistent dosing of antibiotics can cause the rise of antibiotic-resistant bacteria.

The first evidence for enhanced SARS-CoV-2 evolution within immunocompromised individuals was reported in the New England Journal of Medicine in late December 2020, from a 45-year-old man with an autoimmune disorder called catastrophic antiphospholipid syndrome (CAPS) who had contracted COVD-19. People with CAPS are often treated using combination therapy that suppresses the immune system to repress autoimmunity. The man battled the virus successfully at first and lowered levels of viral load were seen approximately 39 days after infection. One month later, however, he was hospitalized with symptoms of COVID-19 and again tested positive, one of three recurrences.

...the rapid evolution of the virus points to an urgent need to prioritize vaccinations for immunosuppressed patients

Over his 154-day battle with COVID-19, the research team continued taking samples from the patient to characterize the virus's evolution. Using sequencing technology, researchers monitored the viral genome through infection. The results were striking – they saw that the virus in his body had evolved substantially compared to existing strains in circulation at the time. Some strains contained the same mutations later found in circulating COVID-19 variants like E484K and N501Y that are associated with increased transmission.

A secondary piece of evidence for accelerated COVID-19 evolution was reported in early February 2021. A person undergoing chemotherapy for B cell lymphoma was in an immunocompromised state when they also contracted COVID-19. Through similar methods to the first study, researchers took samples from the person to assess how SARS-CoV-2 was evolving in their body.

Once again, they saw significant evolution of the virus. They detected many viral variants unique to this person through the 102 days of testing. One dominant viral variant in the population included deletion of amino acids 69/70, mutations also seen in circulating variants.

Further investigation showed the danger of these variants, as they were better able to avoid detection by antibodies known to neutralize original SARS-CoV-2. With mutations being concentrated in the spike region and thought to change the architecture of the spike, the rapid evolution of the virus points to an urgent need to prioritize vaccinations for immunosuppressed patients.

Despite this evidence, the urgency of prioritizing immunosuppressed people for vaccination has not been translated into public health plans. In the US and Canada, there has been mention to prioritize “those with underlying medical conditions,” but no focus on specifically targeting immunocompromised patients. The European Union and the UK’s focus is similar as well. Vaccination efforts remain focused on healthcare personnel and the elderly, although in some US states vaccine availability has rapidly expanded and other categories of people are now eligible.

Policymakers need to consider emerging data from the scientific community. A pivot towards vaccinating immunocompromised people could still use the existing framework of focusing on the most elderly and at-risk populations, requiring a minor deviation from current plans.

The generosity of the immunocompromised people who gave their samples for research – both of whom died from COVID-19 – cannot be understated. The samples taken throughout their treatments illuminated an overlooked aspect for more compassionate patient treatment. Even disregarding the public health perspective, immunocompromised people should be prioritized for COVID-19 vaccination to avoid serious health complications.

By drastically changing course and prioritizing immunocompromised people for vaccination, we can achieve two important goals by addressing public health concerns by limiting opportunity for viral evolution and protecting this group of more vulnerable people from serious COVID-19 complications.

Francesco Zangari studies
Molecular Biology
at
University of Toronto
.

Storytelling is the antidote to Americans' mistrust of science

Jamie L Peeler — Thu, 25 Feb 2021 00:11:49 EST

With a collective exhale, we watched the Biden-Harris administration transition to power in January. We have a lot of work ahead to transform our unjust systems and address the defining crises of our time. For climate change and COVID-19, science will be critical for creating positive outcomes for people and planet Earth. But the United States just spent four years with the Trump administration downplaying and promoting distrust in science.

How do we move on from Trump’s post-truth era and build back trust in science? We do it with storytelling.

The 2020 Johns Hopkins COVID-19 Civic Life and Public Health Survey, which surveyed nearly 1,500 United States adults, revealed that trust in science was split almost evenly. Fifty-four percent reported trusting science “a lot”, while 46 percent reported trusting science “some”, “not much”, or “not at all”. Critically, the survey highlighted how trust supports mitigation efforts. It was trust in science – not political affiliation or other socioeconomic factors – that was most associated with people supporting social distancing.

In 2018, the Wellcome Global Monitor polled over 140,000 people across 140 countries in the Global North and Global South. Its findings identified levers that bolster trust in science. At the country level, income inequality mattered the most: in wealthy, low-inequality countries like Iceland and Norway, on average 30 percent of people had high trust in scientists. Conversely, in wealthy countries with high income inequality like the United States and Argentina, the average was only 19 percent. At the individual level, people with confidence in major institutions and opportunities to learn about science were more likely to view scientists as trustworthy.

Vice President of the United States Kamala Harris receives her second dose of the Moderna, Inc., COVID-19 vaccine, at NIH on January 26, 2021.

NIH Image Gallery via Flickr.

We can pull these levers – especially at the individual level – to build back trust in science. When we are immersed in a story, our brains release a neurochemical called oxytocin. As oxytocin flows, we experience feelings of connectedness, generosity, and empathy. It's no wonder oxytocin is nicknamed the "love hormone". And that emotional stimulation is what gets us lost in a good story. Without a doubt, our brains are naturally tuned toward good storytelling.

Our affinity for storytelling transforms how audiences comprehend messages. As a result, storytelling allows scientists to deliver complex information in engaging and understandable ways. It takes audiences on a journey using characters and the scientific process. In focusing on people and process, storytelling moves science beyond data and help audiences comprehend why the work is important.

History tells us that, beyond just making us feel good and entertained, storytelling can effect change

And the impact of storytelling works in two directions. Stories not only affect how storytellers influence audiences, but also how audiences perceive storytellers. Audiences see storytellers as warmer and more competent when listening to stories – thanks in part to the oxytocin flowing in their brains. In short: stories garner trust. Moving forward, incorporating stories into science will build positive associations between scientists and trustworthiness.

Importantly, the movement toward incorporating stories into science must include diverse storytellers and experiences. A Pew Research Center survey showed that 21 percent of Black Americans had “not too much” or “no” confidence in scientists acting in the best interest of the public. Only 11 percent of White Americans and 12 percent of Hispanic Americans answered similarly.

The Tuskegee Syphilis Study targeted poor Black men, and denied them adequate medical treatment.

CDC via Wikimedia Commons.

Black Americans are more skeptical about intentions of scientists – and justifiably so. Black Americans like Henrietta Lacks endured historic abuses in scientific research that undermined confidence in major institutions. It's a reminder that we are not only dismantling distrust from the last four years, but also from a longer racist history. As we engage in storytelling, passing the microphone to diverse storytellers will be critical for building trust in science. By holding witness to a range of experiences, we can build trust across communities that were historically excluded from the scientific process.

History tells us that, beyond just making us feel good and entertained, storytelling can effect change. The 1960s were a tumultuous and divisive time for the United States, marked by political assassinations, the civil rights movement, and the Vietnam War. Simultaneously, a pesticide called DDT was poisoning wildlife and contaminating our soil and drinking water. And in 1962, Rachel Carson exposed the adverse environmental impacts through storytelling with her book Silent Spring. Ultimately, her stories catalyzed federal regulations that still exist today. Silent Spring is a testament to the power of storytelling in science and its ability to bring about positive change – even in times of crisis.

We have a long road ahead to dismantle the distrust from Trump’s post-truth era and our long racist history. It will take time, energy, and empathy. But with the power of storytelling, we can begin to build back trust in science. Let's get started.

Jamie L Peeler studies
Ecology
at
Pennsylvania State University
.

Community health workers, often overlooked, bring trust to the pandemic fight

Michele Cohen Marill — Tue, 16 Feb 2021 11:52:53 EST

For 11 months, Cheryl Garfield, a community health worker in West Philadelphia, has been a navigator of pandemic loss and hardship. She makes calls to people who are isolated in their homes, people who are sick and afraid and people who can’t afford their rent or can’t get an appointment with a doctor.

The conversations always start with a basic question: “Tell me about yourself.” She wants to know her clients before she figures out how she can help.

“Sometimes a patient just needs somebody to listen to them, so you just listen,” said Garfield, 52.

Public health authorities are relying on Garfield and her peers to be a bridge to communities that have been hardest hit by covid-19 and who are most skeptical about the new vaccines. African Americans and Hispanics have been hospitalized with covid at rates more than three times higher than for non-Hispanic white Americans, but they are among the most hesitant to get the vaccine. As the pandemic brings long-standing health disparities into sharper view, community health workers are coming to the forefront in the public health response.

Photo by Christopher Boswell on Unsplash

It is an about-face after their efforts were largely curtailed early in the pandemic, when “nonessential” health services came to a halt. Community health workers “were sidelined but the needs of the community weren’t sidelined,” said Lisa Hamilton Jones, co-president of the Florida Community Health Worker Coalition. “Now we’re seeing more hiring of community health workers than ever. If you look at the virus and the timeline, why did it take so long?”

President Joe Biden has endorsed a bigger role for these workers as part of his $1.9 trillion “American Rescue Plan.” The proposal includes the hiring of 100,000 people to help with “vaccine outreach and contact tracing in the near term, and to transition into community health roles” after the covid crisis is over.

With their deep roots in the community, many of these workers were disappointed when they were not called on to help initially in the pandemic. Community health workers often work on grant-funded projects with a specific goal, such as improving blood sugar control among people with diabetes. When the pandemic shutdown suspended those programs, many found themselves without a job.

They became marginalized workers within marginalized communities.

“We were hearing from our members across the country, ‘I’m trying to get in touch with my local health department to say I want to help,’” said Denise Octavia Smith, executive director of the National Association of Community Health Workers. “They couldn’t even get through to the [local covid] task force.”

‘Shared Life Experiences’

Garfield works for Penn Medicine, the health system of the University of Pennsylvania, but she isn’t a medical professional. She and other members of this fast-growing workforce help fill the gaps between health care providers and low-income communities by offering education, advocacy and outreach.

Before the pandemic, Garfield met with at-risk patients as they were discharged from the hospital and eased their path to care in the community. Her work often isn’t directly related to health care. In one case, she took a formerly homeless man bowling. The outing, which triggered joy and memories from his youth, helped him decide to turn his life around. He got a job, kept the doctors’ appointments he had been avoiding and took better care of himself.

Since the pandemic, her caseload has varied — and her encounters occur by phone. She helped a young woman with a high-risk pregnancy — and a positive test for covid — find a doctor. She assisted a homeless man in getting federal stimulus funds and care in a nursing home.

Juan Pablo Serrano Arenas / Pexels

Garfield is a grandmother who raised six children as a single mom, and she’s a survivor of domestic violence. She lost a nephew to gun violence, has friends who died of covid and has her own serious health problems — sickle cell disease and the inflammatory disorder sarcoidosis. She doesn’t hesitate to share those personal details. They help her relate to patients.

“You look at them like they’re a family member,” said Garfield. “We connect with our patients more because we’re from the community, and we have the shared life experiences that they have.”

Health care has always been most personal when it extends beyond the clinic or hospital. Community health workers often are employed in traditional health settings, but in recent years they also have served in community centers and churches or gone door to door, providing health education and connections to resources. They promote, among other health issues, HIV/AIDS prevention, prenatal care, immunizations and cancer screening.

Dr. Shreya Kangovi, founding executive director of the Penn Center for Community Health Workers at the University of Pennsylvania, helped demonstrate these workers’ effectiveness in a study published last year that followed 302 patients who were on Medicaid or were uninsured, lived in poor neighborhoods and had at least two chronic health conditions. Community health workers met one-on-one with half those people in 2013 and 2014 and helped them create plans to address their health and social needs. The patients who received help from community health workers had fewer and less costly hospital admissions than the rest of the group. Kangovi and her colleagues calculated an annual return on investment of $2.47 for every dollar spent.

Other studies similarly showed lower health costs.

Investing in Community Engagement

Covid’s unequal burden became obvious by May and June as demographic data emerged, documenting higher infection rates among African Americans and Hispanics.

The Trump administration awarded $40 million to Morehouse School of Medicine in Atlanta to lead a broad initiative to mitigate the impact of covid on minorities. Morehouse created the National COVID-19 Resiliency Network, which is hiring and training community health workers and building partnerships with organizations that represent a wide scope of vulnerable populations, including Native Americans, African Americans, Latinos, people with disabilities and those who are incarcerated.

In September, the National Institutes of Health launched the Community Engagement Alliance Against COVID-19 Disparities, or CEAL, in 11 states as an effort to improve outreach to high-risk communities and to combat misinformation about covid and the vaccines. The program offers community health workers an opportunity to express concerns they have heard from the people they serve.

Retha Ferguson from Pexels

For example, in a recent online “listening session” sponsored by the Georgia CEAL, a community health worker noted local fears about vaccine safety. “My folks are concerned if [electronic] chips are going to be in the vaccine,” she said.

No chips and no live virus, responded Dr. Lilly Immergluck, a Morehouse infectious disease physician. She explained how the vaccines work — information community health workers can share to counter misinformation.

“As a community health worker, I’m an advocate for vaccinations,” Adrianne Proeller, community engagement coordinator at Morehouse, later said. But she added, “I think we need to be very careful about not coming on too strong, and listening and taking people’s concerns seriously, and not just brushing them away.”

‘Support My Patients’

In Philadelphia on a December morning, Garfield reviewed her caseload and picked up her phone. “I’m just giving them a call to check on them in these stressful times of covid,” she said.

One patient rents a room in a house with five other people. She wanted to move out because she was worried about the risk of covid with so many housemates. Garfield told her she would help with the search, but they would need to wait until it was safer to visit potential apartments. Another client had run out of food. Garfield arranged three months of deliveries from a food bank.

Vaccines promise to end the isolation caused by covid. Garfield offers information and answers questions, and if people feel uncertain, she encourages them to talk to their doctor. Ultimately, they will make the decision about when or if to get a covid vaccine.

But if they tell her they want a vaccine, she said, “we’ll find a way to make it happen.”

KHN (Kaiser Health News) is a nonprofit news service covering health issues. It is an editorially independent program of KFF (Kaiser Family Foundation), which is not affiliated with Kaiser Permanente.

Women scientists are bearing the brunt of COVID-19's impacts

Kristen Vogt Veggeberg — Thu, 11 Feb 2021 10:25:45 EST

During the International Day of Women and Girls in Science, it should behoove all of us to remember the difficult climb of a career in STEM.

This is especially so in academia, and especially so for academics in the midst of the COVID-19 pandemic. I am no stranger to this: I finished my doctoral program at University of Illinois at Chicago in December 2019, a few months before the pandemic shuttered the world in March 2020. And I am lucky — I have been working my position as a director of a STEM program for a large nonprofit for years now, and my job is secure. I’m doubly lucky, as I also have a small child at home, but her tiny preschool is open (with a mask mandate), allowing my husband and me to avoid the concerns that millions of working-age women have right now: eight hours of guaranteed childcare a day. I daresay I'm triply lucky, as my career is in informal science education, and if my three-year-old comes along for a day, there's a good chance it's because I will be in the woods, at a festival, or at another place where a small child and her working mother will be welcome.

This triple home-run of parenting luck doesn't exist for the vast majority of my female colleagues in academia and laboratory science. They are juggling childcare, writing, and work, usually all from the same space within their homes.

For many of my friends who were seeking jobs right after graduation, or a transition into a new career, this has been a devastating year. This is especially true for women, who are often the caretakers in their house, whether it is a small child, elderly relatives, or even their siblings. Society expects them to bear the emotional labor of caretaking. It's not wholesome; it's insidious by nature. For many professional and academic women reading this, who is more likely to have to remember such functions as birthdays in the lab, ordering lunch during a crunch time, or organizing social events?

It is not a secret that women face harassment and barriers within STEM: I faced it as a first-year doctoral student, from my female advisor, no less. The harassment of women in STEM and academia came to an especially ugly head in 2020, with the breaking stories of BethAnn McLaughlin’s nasty treatment of her fellow STEM advocates, many of whom were women and/or early-career scientists. When paired with the high amounts of unemployment in academia, the ongoing harassment and barriers, and the societal expectations of women as caregivers before all other roles, the horizon of hope for women and girls within STEM seems to stay within the dark, rather than offer any beacons of hope.

As the COVID-19 pandemic reaches almost a year within the United States, it is clear that those who have suffered the most are working mothers, as well as beginning academics. For those who are in the middle of this unfortunate Venn diagram, the recently graduated scholars who happen to be mothers, this misfortune is especially telling. Many of the science careers outside of academic research — such as museums, informal science institutions, and government positions — have also been cut, if not completely eliminated. Sadly, there are few exceptions and alternatives at this time.

Will this generation of women in STEM ever recover from the setback? I do not have the answer. I do know that for those of us who graduated during the Great Recession, a decade ago, most of us will never make up the lost years of pay and experience that our slightly older, or slightly younger, peers have enjoyed. This, I fear, will be the same story for many women and girls within STEM during this harrowing time in our history.

Kristen Vogt Veggeberg studies
Science Education
at
University of Illinois at Chicago
.

COVID-19 is setting back the lives and careers of young scientists

Francesco Zangari — Sun, 03 Jan 2021 22:23:58 EST

Graduate students are the next generation of scientific leaders. However, to achieve their goals, graduate students must be happy and healthy — both physically and mentally. Often, the rigorous demands of academia encourage many to work until they burn out.

This culture has created a mental health crisis among graduate students. Now, a survey conducted by the Toronto Science Policy Network (TPSN) has highlighted how this pre-existing mental health crisis has been amplified during the COVID-19 pandemic. The lockdown strategies that countries took directly affected scientific research by halting almost all data collection, further exacerbating existing burdens on graduate students like securing future funding and finishing their degrees on time.

The TPSN survey assessed the effects of the early COVID-19 pandemic from April 22 - May 31, 2020, across Canada. Polling 1,431 doctoral and master's students across 45 Canadian institutions revealed the pandemic's negative impacts on productivity, health and wellness, graduation times, and professional development.

“And then you get forgotten about, but get asked why you are not doing work.”

While the COVID-19 pandemic has harmed all graduate students to a degree, it has brought about an additional set of challenges for students nearing graduation. For example, communication with their supervisor is essential for students nearing graduation to complete their research projects. This was especially vital — and challenging — through the period of confusion during the lockdown when many graduate students had to work remotely. However, the TPSN survey highlights that over 50% of students received little-to-no input from their departments or supervisor regarding any expectations for remote-based work.

“What's happened [in my case] is that there's less supervision but more expectation,” says Simon (name has been changed for privacy), a sixth-year PhD student and molecular biologist. “And then you get forgotten about, but get asked why you are not doing work.”

Simon adds that the shift to COVID-19 specific work has limited their supervisor's ability to communicate with students. To address this, the TPSN report recommends the development of accessible and robust communication lines, specifically that institutions need to define clear guidelines for meeting frequency between students and supervisors and provide additional departmental mentors as an alternative outlet for graduate students.

Through the COVID-19 crisis, Simon has felt alone. “This pandemic has exacerbated this existing problem in academia,” they said when I asked about their mental health. Simon’s feeling is in line with many students, with 72% of respondents to the TPSN survey reporting a decline in their mental well-being, leaving students exasperated with the existing infrastructure.

With graduate students reporting anxiety/panic attacks, depression, feelings of uncertainty, and reductions in motivation and focus, TPSN’s report highlights the need for rapid implementation of new mental health and wellness infrastructure. They recommend introducing flexible counseling hours and removing existing barriers for long-term leave of absence applications to stem rising mental health concerns, especially as the pandemic's effects have stretched well beyond the polling period.

This deterioration of graduate student well-being has compounded the issues for students near graduation. Concerns regarding hiring freezes and job prospects have left students like Simon wondering about the sustainability of pandemic hiring sprees.

“Certain fields related to science are booming like scicomm [science communication], medical writing, and pharma [pharmaceuticals],” explains Simon. “What I am worried about is when COVID-19 is over that all these opportunities will disappear...so, we'll see how the trend goes.”

Students looking to build their professional networks may struggle because of the cancellation of in-person professional development opportunities and conferences. TPSN calls on institutions to take a proactive role in assisting students with preparations for the new job market to ease the concerns of obtaining employment. With the rise of virtual meetings, it is now possible to hold more networking events, job fairs and mentorship programs with little to no cost to participants.

...the TPSN recommends the urgent development of physically distant childcare on-campus or emergency funding for graduate students with dependents

While Simon’s pandemic experience has been a difficult period marred by worries related to degree completion and future employment, they report a sustained level of personal growth. In particular, being forced to handle their own mental health has led to the development of coping skills that have helped Simon through these times. Despite the struggles, Simon believes these shared experiences will resonate in the future.

“Yes, I am [hopeful],” says Simon. “One thing I am hopeful for is that people will see value in the individual and see that people are people.” They hope that future hiring committees acknowledge the struggle many are going through this time and rely on interpersonal criteria more than traditional CV metrics when deciding who should get permanent science jobs.

The pandemic also has Boris Dyakov, a fifth-year graduate student at the University of Toronto’s Molecular Genetics program, feeling thankful. “I feel actually, all things considered, pretty lucky with how the pandemic has treated me...as our funding has not been affected” says Dyakov.

“If I didn’t live with my partner, it would have also been much more difficult…in some ways, I feel like I actually even benefited in a funny way because we got to spend more time together even if we were working.”

As Dyakov notes, his support network made the pandemic easier to navigate. However, with more lockdowns, there is a further concern of increasing feelings of loneliness than were reported in the TPSN survey, especially for international graduate students who are barred from traveling to see their families.

Through the time away from the lab bench, Dyakov feels a renewed sense of mastery in tackling his studies.

“Being a more senior student...I had tons of data that I've been sitting on, but I just really hadn't had time to sit down and analyze,” says Dyakov. It helped “really get into my data and make sense of it and figure out how to finish up my project."

“I spent a lot of time really researching different career paths and, like learning really what they're all about and seeing what opportunities are out there and reaching out to people in my network,” explains Dyakov. “When I started researching general management consulting, I realized this is an area of work that really interests me.”

Dyakov’s story represents a scenario where even the most troubling times can provide an avenue to achieve personal growth.

However, Dyakov's experience is a far cry from the experiences most graduate students have had throughout the pandemic. One prominent example highlighted in the TPSN survey surrounds those students with dependents like children or ill loved ones. With the pandemic further hindering those students' ability to carry on their research, the TPSN recommends the urgent development of physically distant childcare on-campus or emergency funding for graduate students with dependents. This would be a first step in leveling the playing field for these students (the majority of whom are women) facing extenuating circumstances.

COVID-19 will continue to be a problem long into 2021, until vaccination becomes widespread, and likely past then. With that in mind, institutions must adopt changes to current operation procedures and promote the well-being of junior researchers. While there are individual cases in which students can benefit from the time away from the lab, graduate students as a whole are worse off now than before the pandemic. Institutions now hold the power, armed with this knowledge, to change the current trajectory and mitigate the impacts of the COVID-19 pandemic for the scientific leaders of tomorrow.

Francesco Zangari studies
Molecular Biology
at
University of Toronto
.

How the COVID-19 vaccine is distributed determines how the pandemic will end

Sara May Bergstresser — Tue, 22 Dec 2020 13:10:56 EST

The news is now full of pictures of the first vaccinations for COVID-19. In the UK, 90-year-old Margaret Keenan was the first to get her “jab," and in the US, the first vaccines have been given to health care workers including New York nurse Sandra Lindsay.

In both the UK and the US, the COVID response over the past nine months has been haphazard, with many failed policies, soaring case numbers and deaths, controversy, and widespread social and economic disruption. The vaccine rollout represents a much needed promise of hope for the future, but it is important to remember that a lot more still needs to happen before the pandemic can be controlled. Not even the vaccine stories for Margaret Keenan and Sandra Lindsay are complete, since for full protection they will both need to take the second dose of the Pfizer/BioNTech vaccine after about three weeks.

On the surface, it may look like an organized global rollout process is getting underway, but there are still many uncertainties surrounding vaccine distribution internationally and within each country. How quickly vaccines can become widely available and who receives early priority are determined by national purchasing power, available supply, logistics, national priorities, and variations in health regulations and laws.

Countries with national health systems such as the UK and Canada have the opportunity to use existing care provision frameworks and facilities to help organize efficient population-wide vaccine initiatives. The US, on the other hand, does not have the same type of health system infrastructure, which means vaccine distribution may vary wildly from state to state. National priorities also dictate the order in which people will be able to receive the vaccine, and national policymakers must decide whether to focus on direct protection for vulnerable individuals or to prioritize those who are most likely to spread the disease to others.

The CDC has put out recommendations about which groups should get early vaccine priority. These recommendations were based on the Advisory Committee on Immunization Practices (ACIP) Interim Recommendation for Allocating Initial Supplies of COVID-19 Vaccine. The CDC cites its main goals to be: “Decrease death and serious disease as much as possible,” “Preserve functioning of society,” and “Reduce the extra burden COVID-19 is having on people already facing disparities.” Based on this, the two main groups recommended for early vaccination are Healthcare Personnel and residents of nursing homes (“Long Term Care Facilities”). After that, an approximate sense of where others may be in the queue can be calculated here. Nevertheless, recent history has shown that public health recommendations are not always followed in the US, and individual states may choose to allocate differently from ACIP recommendations.

Finally, as is typical for new pharmaceutical products, safety monitoring must continue after its rollout. This is even more important for COVID vaccines, because they were developed rapidly under atypical circumstances, and problems of public trust remain. ACIP and the CDC also recommend that any adverse events should be reported to the Vaccine Adverse Events Reporting System (VAERS), even if it is not clear that a vaccine caused the event. Vaccine data is difficult to track in the US due to its uneven health practices and regulations, so a new nationwide system is starting up to aid in that effort.

It is important to remember that health policy must account for human behavior in addition to the predictions of epidemiological models

In the UK, a more comprehensive plan for allocation has been released, with the explicit intent to inform future policy. These recommendations also prioritize older adults and healthcare providers, but they go on to elaborate on many subsequent priority categories based on age and risk due to underlying health conditions. The UK, due to its existing national health infrastructure and decision to purchase sufficient vaccine doses for its population, is starting its rollout efficiently so far.

In the US, director of the National Institute of Allergy and Infectious Diseases Anthony Fauci, predicts that a return to something close to normal can be achieved by the end of 2021, as long as the vaccination rollout goes well and 75-80% of the population are vaccinated by that time. There are a number of issues that may complicate this optimistic timeline including past health communication missteps, public mistrust, and vaccine hesitancy, states receiving fewer doses than promised, problems with Pfizer vaccine cold storage requirements in rural areas, and confusion over packaging leading to wasted doses. If these limitations cannot be overcome, the process will take longer than hoped.

There are also tensions between implementing some numerically sound strategies for stopping the spread of disease and the need to increase public trust. For example, some health economists and policy experts argue that people most likely to become “superspreaders” be prioritized over the more vulnerable, but this would mean that young people who are more likely to have asymptomatic or mild cases would be vaccinated before the elderly, those with preexisting health risks, and other vulnerable and underserved populations. It is important to remember that health policy must account for human behavior in addition to the predictions of epidemiological models; for communities at high risk whose members have disproportionately become infected and died, watching healthy college students at spring break parties after getting their vaccines first would likely further diminish trust in the public health system and its recommendations.

One main lesson that should be permanently learned from COVID is that infectious diseases that start anywhere across the globe can fast become global pandemics. It is a priority of ethics and justice that humans should have access to vaccines regardless of whether they live in economically powerful countries. Right now, wealthy countries are buying up most of the available doses, meaning that “nine out of 10 people in 70 low-income countries are unlikely to be vaccinated against COVID-19 next year.” Many people in low-income countries might have to wait until 2023 or 2024 for vaccination. In an attempt to counter this trend towards severe inequality, WHO has a plan to ensure equitable allocation, but it faces many implementation challenges. The arrival of vaccines from additional manufacturers is also promising for fairness in distribution because they have fewer technical limitations. The impending release of the Moderna vaccine is notable because it has less stringent cold chain requirements, and the Oxford–AstraZeneca vaccine is specifically aiming for “global supply, equity, and commitment to low-income and middle-income countries” and should be ready for use in 2021.

Finally, a second important lesson that must be learned is that for public health plans to succeed, it is not sufficient for scientists to work fast. Countries must design and implement sound public health policies, people must follow these policies, and the idea of vaccine as “magic bullet" must be replaced with a more nuanced understanding of the complexities of Covid and its spread. This means that preventative public health practices like social distancing and mask wearing must be continued throughout the vaccine process. Some of these health behaviors might even be here to stay within certain risky contexts, since coronaviruses may continue as seasonal outbreaks like influenzas, and new infections will continue to emerge into the human population.

Sara May Bergstresser studies
Bioethics, Public Health, and Biochemistry
at
Columbia University
.

Empathy is key to overcoming COVID-19 vaccine hesitancy

Shelby Bradford — Mon, 21 Dec 2020 11:31:08 EST

Following promising phase III clinical trials, the UK and Canada have approved Pfizer's novel vaccine against COVID-19. In the U.S., the FDA has given emergency use authorization (EUA) for the Pfizer vaccine and the first doses were administered on December 14. These are collectively tremendous accomplishments and suggest that the virus causing COVID-19 can be contained through an immunization program. However, that hinges on these vaccines actually getting administered to people. This may be an unanticipated hurdle to relief from the pandemic.

A poll from the Pew Research Center in mid-November shows that about 60 percent of Americans would get an approved COVID-19 vaccine. While this is up from September polls and a Gallup poll in October, which indicated only about 50 percent of Americans were planning to get a vaccine against COVID-19, this would be below the 70 percent of the population the FDA estimates would need to be immunized in order to meaningfully reduce spread of the virus.

Many of these people who have reservations about getting immunized, sometimes called "vaccine hesitant," are concerned about how safe and how effective a vaccine which has been produced so quickly can be. These concerns were reflected in a JAMA paper in published in October, where there was survey subjects indicated lowered faith in a vaccine licensed under an EUA from the FDA than one which went through the standard approval process. Furthermore, some groups, such as Black individuals, can be distrustful of American public health institutions because of historical abuses in medical science and maintained biases that impact health outcomes today. This highlights a need to strategize communication efforts amongst scientists and public health officials to address these specific concerns so people understand and trust the science behind these vaccines.

Most of us are not familiar with the details of clinical trials, but we understand that they are designed to ensure new medicine works and is safe. If we know anything else, it is that clinical trials usually take a long time. In the absence of good communication and transparency about how these trials are being accelerated, many people can become concerned that corners were cut or scientists don’t fully know if these vaccines are safe and effective. It is not enough to say “this is safe” as reason to accept a vaccine, nor will data transparency alone be helpful in convincing people of safety or efficacy. The data released will likely be densely laden with jargon and statistics most people can’t decipher.

Instead, a thorough network of public health officials, physicians, and the scientific community should take the advice outlined in a report jointly from the Center for Health Safety and the International Access Center. The report recommends the development of an approach centered on communicating these vaccines safety, risks, benefits, and availability to the public in a non-partisan and empathetic manner to the general public.

Examples, such as this video from University of Oxford, about how the process was sped up, that are condensed into convenient and understandable formats could be one tool to communicate how scientific integrity was maintained while meeting urgent needs for a product. Content which illustrates how the ability of the vaccine to prevent disease was assessed in clinical trials, and how it will continue to be monitored, would assure individuals of scientists’ basis for confidence in these vaccines. While recommendations from leading public health experts from the FDA, CDC, and WHO would boost confidence and trust as well, these come after or in association with seeing proof of these vaccines safety and efficacy to most individuals.

A widespread campaign to address concerns and provide clear information would establish trust between science bodies and communities, giving individuals the power to make their own informed decisions. Conversely, mandates that enforce immunization, which have been suggested as a way to boost vaccine compliance lowered acceptance of a COVID vaccine: 44 percent of a study group agreed they would take a vaccine proven safe and effective, but only 14 percent agreed when asked if they would take the vaccine were their employer to recommend or require it.

One rationale this study cited for this is that, while mandates are effective at ensuring vaccine compliance, these are more likely to lower actual confidence and trust in public health measures, driving concerned individuals toward seeking healthcare providers willing to overlook vaccine recommendations and pursue exemptions in school and work. This is observed in childhood vaccination rates, where school requirements often improve immunization status unless medical and non-medical exemptions are available that vaccine-hesitant parents seek.

In these instances, educating parents on vaccine safety and benefits and disease severity was shown to significantly increase immunization for MMR and DTaP, by 5.1 percent and 4.5 percent respectively, and reduce medical exemptions. However, where non-medical exemptions were permitted, immunization coverage was not affected by state interventions or mandates. This demonstrates the importance of not only communicating vaccine safety and importance, but also to listen to the specific concerns of the individual patient or group and cultivate an open dialogue to establish trust.

At the end of the day, even the most protective vaccine will not matter if not enough people take it

Individual demographics are a vital consideration in any communication strategy. It is not without reason, as has been discussed, that greater hesitation to vaccination may be highly prevalent among Black people. This is despite the fact that this demographic has experienced cases, hospitalizations, and deaths at a greater incidence than white, non-Hispanic individuals. Communication efforts must address the specific concerns people have and provide the trust that they will be protected throughout their acceptance of these vaccines.

At the end of the day, even the most protective vaccine will not matter if not enough people take it. Widespread vaccination can be achieved by organized efforts on the part of public health officials, physicians, and science communicators, to illustrate how scientists have still assessed safety and protection in these products even on this accelerated timeline. People want to understand how there is so much certainty in these vaccines; many are suggesting waiting until “they see the evidence." Scientists have the evidence, it is just a matter of communicating it.

Shelby Bradford studies
Immunology
at
West Virginia University
.

Why do the COVID-19 mRNA vaccines need to be kept so cold?

Joshua Peters — Sat, 19 Dec 2020 13:11:26 EST

Monday, December 14th, marked the first public vaccinations of the Pfizer-BioNTech vaccine in the US. It came 339 days after the release of the SARS-CoV-2 genome and months of clinical trials involving more than 43,000 people during a raging pandemic that has infected 73,600,000 and killed 1,640,000 people worldwide. Pfizer-BioNTech’s vaccine is among 23 vaccines in the final stages of testing and approval – phase 3 and/or nearing approval. In the United States, Moderna’s vaccine is expected to be distributed soon, after endorsement by an FDA panel, and emergency approval received, with similar efficacy results to Pfizer-BioNTech’s vaccine.

Both of these vaccines are RNA-based. Instead of priming the immune system with a dead virus or a piece of a virus, as vaccines in the past have done, these vaccines deliver a template – RNA – for our cells to make a single protein from SARS-CoV-2. The body creates the protein, generates a protective immune response, then throws away the RNA – much like kids passing notes in class, then crumpling them up and tossing them in the trash.

Each vaccine consists of two doses, given a few weeks apart. Manufacturing is expected to produce close to 2 billion doses in 2021 (up to 1.3 billion for Pfizer-BioNTech, up to 1 billion for Moderna), enough for almost 15% of the world’s population if these companies reach their maximum output. Despite unprecedented success in the development of these new vaccines, their extensive testing, and scaling up manufacturing, there remains another hill to climb before these vaccines can help protect people. These RNA vaccines require extremely cold temperatures.

A common ultracold freezer found in a lab. These types of freezers can cost $10,000 or more

Pleple2000 via Wikimedia

Pfizer-BioNTech’s vaccine requires -70°C (-94°F), colder than the South Pole, and only lasts around 5 days once placed in a refrigerator. Moderna’s vaccine is a bit more forgiving, shipped at -20°C (-4°F) and good for a month in a refrigerator. For comparison, inactivated or live attenuated vaccines (like the flu vaccine) are stored at typical refrigerator temperatures, about 2-8°C (46°F). While the Sputnik V vaccine also needs freezer-like temperatures, we can expect emerging vaccines from Novavax (NVX-CoV2373), AstraZeneca-University of Oxford (AZD1222), Johnson & Johnson (Ad26.COV2.S), and others to require only refrigerator temperatures.

RNA is notorious for its instability. Before working with RNA, it’s common for scientists working with it in a lab to clean their workspace of “RNases” or ubiquitous environmental enzymes that break down RNA quickly. Unlike DNA, which typically consists of two strands and contains a submolecule called deoxyribose (hence “DNA”), RNA is single-stranded and contains ribose (hence “RNA”), which makes RNA molecules more susceptible to degradation. Despite the chemical modifications and packaging these companies use to make it more resistant, it still suffers compared to DNA or protein.

The extreme temperatures slow down chemical and enzymatic degradation, allowing the RNA vaccines to maintain their efficacy from manufacturing to injection. RNA’s instability is good for our cells: many copies of RNA are transcribed from DNA templates, which are then used to create proteins. But as the proteins required by the cell are made, the instructions are degraded away.

These companies define these temperatures through testing the vaccine across a range of temperatures and storage durations. Protein vaccines have their own requirements as well. While they are typically stored in a refrigerator, freezing them can disfigure the proteins, rendering them ineffective. Pfizer-BioNTech has mentioned ongoing studies on storage conditions, but for now, ultracold transportation with GPS tracking it is.

The only chemical difference between RNA and DNA is the presence of a single oxygen atom (RNA carries a ribose, left, highlighted in red) that is missing in DNA, which carries a deoxyribose (right)

Miranda19983$! via Wikimedia

The transport of vaccines, and cold items more broadly, from a manufacturing site to a recipient is known as the cold chain. The cold chain can be divided into different temperature requirements, such as freezer temperatures (about -20°C) that the Moderna vaccine requires or ultracold temperatures for Pfizer-BioNTech’s, or even cryogenic temperatures which can reach -150°C (-238°F) for shipping biological materials. Over the course of the first week, 636 sites were expected to receive the vaccine through the Fedex and UPS shipping networks. Pfizer’s shipping containers can stay cold enough for 10 days unopened. After receiving these precious vaccines, sites need to maintain these temperatures in ultra-low freezers (good for six months), which cost well over $10,000 with enormous energy consumption, in the original shipping container by refilling with dry ice (-79°C, -109°F, good for 30 days) or storing in a refrigerator, where the vaccines must be used within 5 days.

This extreme cold chain has sprouted intense investment and concern. Perhaps most notably, India has projected needing millions of additional equipment to handle these various vaccines. The dramatic need for cold chain solutions across the globe has grabbed Wall Street’s attention, driving investment in one company, Cryoport, up over 200% year to date. Given the challenges in countries with developed healthcare infrastructures, it’s not hard to imagine the additional challenges in less developed countries. There’s some precedent before with the Ebola vaccine, but the scale of these infections are vastly different. Despite these challenges, perhaps the first issue is the availability of these vaccines, which was quickly cleared by Western countries.

The cold chain required for vaccines is not a new challenge. The WHO and PATH, among others, have been focusing on supply chain issues for decades, developing new technology like solar-powered refrigerators and calling for action in 2014. The overwhelming scale of COVID-19 and mass vaccination campaigns mixed with subfreezer temperatures is a new challenge. As we end 2020, we can hope more efficacious vaccines are approved early in 2021, allowing more people from more walks of life to have access to protection against COVID-19, ending the pandemic.

Joshua Peters studies
Biological Engineering
at
Massachusetts Institute of Technology
.

It's time to track city sewage for emerging diseases, not just COVID-19

Lauren Sara McKee — Thu, 10 Dec 2020 22:48:51 EST

Zeynep Çetecioğlu wants to create a cleaner, more sustainable society by finding better ways of dealing with the waste it creates.

Çetecioğlu's work focuses on the wastewater that flows through the city sewers. Wastewater and the semi-solid sludge that forms when it is cleaned are rich in organic molecules that can be used as fuel or feedstock for making bioplastics. Wastewater is also full of molecules and microbes that tell stories about how a society lives, and about the health of a city’s inhabitants. Monitoring wastewater can predict and prevent a variety of disease outbreaks. But despite a wealth of new scientific evidence, this potentially powerful epidemiological tool depends crucially on government support that often falls short.

In spring 2020, as the COVID-19 pandemic escalated, scientists around the world pivoted to working from home as best they could, often putting research projects on hold. Çetecioğlu and her colleagues at Stockholm’s KTH Royal Institute of Technology knew that the virus’s genetic material (RNA) could be detected in human waste, and had seen some exciting early results from a pioneering wastewater group in the Netherlands, who were the first to show they could detect RNA from SARS-CoV-2, the virus that causes COVID-19.

Çetecioğlu is co-lead on a project that’s tracking SARS-CoV-2 RNA in wastewater. The technology can give cities advance warning of an increase in COVID-19 cases before sufficient infected people can be tested. The second wave of infections in Stockholm was predicted by Çetecioğlu and her team, who saw a clear increase in RNA in wastewater sampled two to three weeks before positive tests started increasing. In a press release from early October, Çetecioğlu said, "The data from August and September show that...there’s more virus in the population."

The method for detecting viral material in wastewater uses simple molecular biology techniques. The RNA is extracted from the water, then detected by polymerase chain reaction, or PCR, the same test used to detect COVID-19 in human patients. Scientists use equipment that gives a real-time read-out of the RNA concentration in a sample being analyzed.

The tricky part is making sure you have enough virus to detect by PCR. Wastewater treatment plants process enormous volumes of liquid, so viral particles shed by a few people become very dilute. The method used to concentrate the viral material needs to be optimized depending on whether the virus is “enveloped” or not. (Like other coronaviruses, SARS-CoV-2's RNA genome is surrounded and protected by a membrane envelope.) Existing virus concentrating methods developed for non-enveloped viruses therefore had to be modified.

The group in Stockholm recently compared four different methods of concentrating viral RNA. The main differences between the methods are whether they use ultra-filtration — passing water samples through filters made from cellulose membranes that only allow tiny RNA particles through — or if they absorb the virus onto a solid material from which it can be collected by washing. They focused on using chemical reagents that are inexpensive and unlikely to run short in labs even if deliveries are delayed during the pandemic.

Their results showed that the ultra-fitration method consistently recovers the most virus, and that it can be applied to wastewater from different European cities. Çetecioğlu says that the scientific challenges involved in detecting and measuring SARS-CoV-2 RNA in wastewater are now largely settled, as the method has been validated in many places (follow COVIDPoops for updates). It has also been used to look for other viruses, including a mouse hepatitis strain and a plant virus used as a water quality indicator. In Gothenburg in 2017, PCR was used to track an outbreak of a winter vomiting virus, or Norovirus. That pathogen was detected in wastewater before the outbreak had been noticed by local healthcare providers, so hospitals and elder care homes had time to prepare.

A 2017 effort helped predict a Norovirus outbreak based on wastewater

Wikimedia

The SARS-CoV-2 genetic sequence was first released in January 2020. The research group in the Netherlands who started the first COVID-19 wastewater project were collecting and testing samples before there was ever a positive case in that country. This was possible because there had been advance investment in a wastewater epidemiology lab that could leap into action as soon as the sequence was known.

The Swedish team is generating high-quality data, but have not been able to release results weekly as they had hoped, due to frequent delays in sample testing. “We receive the samples every Monday and Tuesday, but we can’t share the data every Wednesday,” says Çetecioğlu. “It is partly about lack of personnel, but also because of the simplest things, like now we have no gloves, or now we have no filters.” Deliveries of small items that ordinarily arrive after a few days are now taking months to arrive.

Other scientists in the project have discussed the need for support if the method is to be scaled up to serve as the city’s early warning system. With full-time staff, and priority access to equipment, a dedicated wastewater epidemiology lab could release weekly statistics on the viral content of local wastewater, focusing on outflows from healthcare centers to monitor vulnerable groups, and adding novel viruses into their analytical panel as soon as a new sequence and extraction method were available. Researchers from Yale University have confirmed that wastewater testing can give public health organizations at least a week’s notice of an increase in cases of a known virus, and stressed the value of this in places with delayed patient testing.

“We need to scientifically approach each new viral outbreak as a new wastewater problem, optimizing extraction and detection methods everywhere, as soon as a new pathogen is discovered somewhere in the world,” says Çetecioğlu. But the potential power of wastewater monitoring as an early warning system requires us to be ready to implement it before a local outbreak takes hold. “I started this work for the public. I am not doing this for my career. We are producing data and methods for the city to use in the future.”

Biological testing supplies have limited the Swedish team's effort to report wastewater test result

U.S. Air Force photo by Richard Eldridge

Not everyone agrees about the value of wastewater epidemiology. Anders Tegnell, state epidemiologist, has been coordinating the Swedish response to COVID-19. He has become a pretty controversial character, taking Sweden down a different path than its European neighbors. In an interview with Swedish newspaper Dagens Nyheter, Tegnell said that wastewater testing was scientifically interesting, but offered no new information to help him manage the outbreak, as it only supported what he already knew from patient testing — that case numbers were rising.

Of course, with access to enough lab supplies, the Swedish team likely would have been able to show SARS-CoV-2 RNA in wastewater weeks before diagnoses started climbing. Samples collected in April couldn’t be analyzed until May, when case numbers already began rising. The same delays hit the lab in late summer, but SARS-CoV-2 RNA levels were high in wastewater collected a month before case numbers started rising in the autumn.

“Today the problem is Covid-19, tomorrow there will be a different problem”

Çetecioğlu and her colleagues were recently awarded funding from the city of Stockholm and some private Swedish foundations. These funds should pay the salary of a dedicated scientist to work on the environmental virus profiling project, help build a viral biobank for the future, and allow sequencing studies to track mutations.

“Today the problem is Covid-19,” Çetecioğlu says. “Tomorrow there will be a different problem.” We will face pandemic diseases increasingly often in the future, as they are made more likely by our destruction of the natural world. Governments need to focus on pandemic preparedness, and an element of this should be the establishment of well-resourced wastewater epidemiology labs in those areas that see the most rapid spread of pathogens, like densely populated cities. We need to be ready.

Disclosure: the author of this article is employed by KTH, Royal Institute of Technology, where the interviewee Zeynep Çetecioğlu is an Associate Professor. They work in different departments and do not share any resources or project funding.

Lauren Sara McKee studies
Microbiology, Biochemistry, and Biotechnology
at
KTH Royal Institute of Technology
.

How should a COVID-19 vaccine be distributed?

Jill Neimark — Sun, 22 Nov 2020 13:37:11 EST

If the book of nature is written in the language of mathematics, as Galileo once declared, the Covid-19 pandemic has brought that truth home for the world’s mathematicians, who have been galvanized by the rapid spread of the coronavirus.

So far this year, they have been involved in everything from revealing how contagious the novel coronavirus is, how far we should stand from each other, how long an infected person might shed the virus, how a single strain spread from Europe to New York and then burst across America, and how to ‘’flatten the curve’‘ to save hundreds of thousands of lives. Modeling also helped persuade the Centers for Disease Control and Prevention that the virus can be airborne and transmitted by aerosols that stay aloft for hours.

And at the moment many are grappling with a particularly urgent — and thorny — area of research: modeling the optimal rollout of a vaccine. Because vaccine supply will be limited at first, the decisions about who gets those first doses could save tens of thousands of lives. This is critical now that promising early results are coming in about two vaccine candidates — one from Pfizer and BioNTech and one from Moderna — that may be highly effective and for which the companies may apply for emergency authorization from the Food and Drug Administration.

But figuring out how to allocate vaccines — there are close to 50 in clinical trials on humans — to the right groups at the right time is “a very complex problem,” says Eva Lee, director of the Center for Operations Research in Medicine and Health Care at the Georgia Institute of Technology. Lee has modeled dispensing strategies for vaccines and medical supplies for Zika, Ebola, and influenza, and is now working on Covid-19. The coronavirus is “so infectious and so much more deadly than influenza,” she says. “We have never been challenged like that by a virus.”

Howard Forman, a public health professor at Yale University, says “the last time we did mass vaccination with completely new vaccines,” was with smallpox and polio. “We are treading into an area we are not used to.” All the other vaccines of the last decades have either been tested for years or were introduced very slowly, he says.

Because Covid-19 is especially lethal for those over 65 and those with other health problems such as obesity, diabetes, or asthma, and yet is spread rapidly and widely by healthy young adults who are more likely to recover, mathematicians are faced with two conflicting priorities when modeling for vaccines: Should they prevent deaths or slow transmission?

The consensus among most modelers is that if the main goal is to slash mortality rates, officials must prioritize vaccinating those who are older, and if they want to slow transmission, they must target younger adults.

“Almost no matter what, you get the same answer,” says Harvard epidemiologist Marc Lipsitch. Vaccinate the elderly first to prevent deaths, he says, and then move on to other, healthier groups or the general population. One recent study modeled how Covid-19 is likely to spread in six countries — the U.S., India, Spain, Zimbabwe, Brazil, and Belgium — and concluded that if the primary goal is to reduce mortality rates, adults over 60 should be prioritized for direct vaccination. The study, by Daniel Larremore and Kate Bubar of the University of Colorado Boulder, Lipsitch, and their colleagues, has been published as a preprint, meaning it has not yet been peer reviewed. Of course, when considering Covid-19’s outsized impact on minorities — especially Black and Latino communities — additional considerations for prioritization come into play.

Most modelers agree that “everything is changing with coronavirus at the speed of light,” as applied mathematician Laura Matrajt, a research associate at the Fred Hutchinson Cancer Research Center in Seattle, put it in an email. That includes our understanding of how the virus spreads, how it attacks the body, how having another disease at the same time might raise the risk, and what leads to super-spreader events.

So far, the research has yielded some surprising results. While children are usually prioritized for flu vaccine, for example, experts say the very young should be a lower priority for Covid-19 vaccines in the United States, because thus far young adults have been primary drivers of transmission. (This is not necessarily true across the globe; in India, for instance, where multiple generations often live together in smaller spaces, new research shows both children and young adults are spreading much of the virus in the two states studied.)

In addition, several models suggest that significant headway can be made against the pandemic even with lower deployment of a vaccine that is only partly effective. And several others emphasize the importance of local infection and transmission rates. According to Lee, whose early assessments of the pandemic’s origin, virulence, and probable global trajectory proved to be strikingly accurate, New York could potentially contain the virus if about 40 percent of the population were vaccinated, because local transmission of the virus is fairly low (a positivity rate of a little below 3 percent as of Nov. 16), and around 20 percent have already been infected.

“The higher the fraction of people in the population who already have antibodies, the more bang for your buck,” says Larremore, because you can prioritize giving vaccines to those who don’t have antibodies.

All these findings are important because, “at the end of the day, you will never have enough vaccines for the entire population,” says Lee — and not all Americans will take it. In fact, the World Health Organization recently predicted that healthy young adults may not even be able to get a vaccine until 2022, after the elderly, health care workers, and other high-risk groups are vaccinated.

To model the rollout of vaccines, mathematicians must build formulas that reflect the starburst of human life and our complex interactions, using data like housing and socioeconomic status, daily habits, age, and health risks. But first they establish how contagious the virus is — its reproductive rate, or “R-naught.” This represents the number of people that one infected person can be expected to transmit the infection to.

When some fraction (depending on R-naught) of people are immune (either by recovering from natural infection, if that grants immunity, or through vaccination), herd immunity has been achieved. That means that while small outbreaks may still occur, the pandemic will not take off globally again. Given the R-naught of SARS-CoV-2, the virus that causes Covid-19, the World Health Organization has estimated that 65 percent to 70 percent of the population needs to be immune before this can be achieved.

Vaccine rollout scenarios developed by Bubar et al. include five different ways of distributing the first doses of vaccines, presented in the left panel. The scenarios show the same pattern: to prevent deaths, vaccinate the elderly first, and then move on to other, healthier groups or the general population.

Bubar et al. / MedRxiv

Modeling vaccine rollout requires a complex acrobatics, and while the models to flatten the curve that mesmerized the public last spring took weeks to craft, vaccine distribution models take many months. There are innumerable practical challenges facing modelers. For one thing, many of the vaccines currently in the pipeline — including the two candidates from Pfizer and BioNTech and Moderna — require two shots, several weeks apart, which involve registries and follow-up to ensure that people get the second, critical booster shot. And as The New York Times noted in late September, “Companies may have to transport tiny glass vials thousands of miles while keeping them as cold as the South Pole in the depths of winter.”

There is also the question of vaccine efficacy. Will a given vaccine provide robust immunity, and in all groups? Or will it primarily shorten duration of infection and lessen symptoms, which would still be of great value in reducing mortality as well as transmission? And what if a vaccine is less effective among the elderly, as is often the case? At the moment, vaccines using messenger RNA (including those produced by Moderna and Pfizer and BioNTech) are “looking pretty good in older adults,” according to Kathleen Neuzil, director of the Center for Vaccine Development and Global Health at the University of Maryland School of Medicine. Preliminary analyses of both vaccine candidates show that they may be more than 90 percent effective.

Finally, there is also the vexing question of how long immunity might last after infection. For some viruses, such as the varicella-zoster virus that causes chickenpox, immunity can last for decades. For others, such as the family of coronaviruses that includes SARS-CoV-2 and the common cold, the virus has a relatively high mutation rate that may protect novel strains from our antibodies. That uncertainty is difficult to model precisely, so many modelers assume that, for the time being at least, those who have been infected are immune.

Matrajt, of the Fred Hutchinson Cancer Center in Seattle, remembers vividly how hard it was to begin to construct a model out of thin air when she began working with colleagues on a vaccination model this past April. There were “so many uncertainties,” she recalls. Together, the researchers developed algorithms based on an astonishing 440 or so combinations of parameters, from transmission to immunity to age groups and mortality. Their computers spent nearly 9,000 hours running equations, and their model, published in August as a preprint, shows that if there is only a low supply of vaccine at first, older adults should be prioritized if the goal is to reduce deaths.

But for vaccines that are at least 60 percent effective, once there is enough to cover at least half the population, switching to target healthy individuals ages 20 to 50 as well as children would minimize deaths. The model also predicts how many deaths can be averted with different amounts of vaccine coverage. For instance, if 20 percent of the population has already been infected and is immune, deaths could be halved by vaccinating just 35 percent of the remainder, if the vaccine is at least 50 percent effective.

In the model by Matrajt and her colleagues, herd immunity is achieved once 60 percent of the population is immune. “It is completely normal that different models will give different numbers,” she says, explaining why her estimate varies slightly from the WHO figure of 65 percent.

The model does “a really nice job looking at a large number of plausible cases,” says Michael Springborn, an environmental and resource economist at the University of California, Davis, who just finished his own model with Jack Buckner, a colleague at UC Davis, and Gerardo Chowell, a mathematical epidemiologist at Georgia State University. Their study, released in preprint, also suggests the power of careful initial targeting in reducing deaths.

The models suggest that even a partially-effective vaccine given to just part of the population, says Springborn, “can go a really long way to reducing infections and reducing deaths.”

A vaccine rollout model by Matrajt and her colleagues shows how availability and efficacy of the vaccine affects infections and deaths due to Covid-19.

Matrajt et al. / medRxiv

Lee’s modeling, created with software she first developed in 2003, in conjunction with the CDC, for dispensing of supplies in natural disasters and pandemics, analyzes how the disease might be contained in areas with different infection rates and initially scarce vaccine supplies. In New York City, which was hit so hard in the spring, her model predicts that roughly 60 percent of the population may need immunity to contain the pandemic. Assuming 20 percent are already infected, about 40 percent would need to be vaccinated. In San Diego, however, where infection rates have been lower, Lee’s model suggests that 65 percent will need to achieve immunity through infection or vaccination. In Houston, the figure may be as high as 73 percent because the infection has persisted at a “slow burn” and because of the city’s large, vulnerable Latino and African American populations, who have borne disproportionate risk.

Lee cautions that these results do not mean you can suddenly go to a football game in Houston or Broadway show in New York, but it does mean that with ongoing precautions, the virus might well be contained with the percentages given in her models, until more vaccine arrives.

Though their results vary, most models agree that certain factors are critical, notably age group, which changes the risk of contracting, spreading, and dying from a virus. It’s not always predictable: The swine flu, for instance, spared older adults to some degree, while SARS-CoV-2 has severely affected those over 65. Adults 65 and older compose 16 percent of the U.S. population but account for about 80 percent of Covid-19 deaths.

In addition, age indirectly influences transmission patterns. In 2009, Yale epidemiologists Alison Galvani and Jan Medlock published a mathematical model in Science, showing that targeting flu vaccines to children and young adults (in addition to the elderly) could have slashed swine flu infections from 59 million to 44 million; and for seasonal influenza, 83 million infections could plunge to 44 million. Children, it turns out, drive a disproportionate amount of flu transmission, and protecting them protects society at large.

The study, and others like it, inspired a change in CDC policy to prioritize vaccinating children. “It was a revolution in how we think about vaccines,” says Larremore. Vaccination models now routinely consider the power of indirect protection of the most vulnerable by vaccinating those most responsible for spread.

Age also intersects, in complex ways, with social connectivity in different regions. For instance, African American and Latino communities in the United States have been disproportionately hit by Covid-19, in part because of the prevalence of multiple generations living together: Older individuals are much more exposed to the young adults who might be the likeliest carriers of infection.

Modeling connectivity requires drawing grids that represent how we live and move among each other. In 2008, a landmark paper built a grid that epidemiologists everywhere still use today. It stratified people into groups based on age, from birth to 70 years old and up. In the study, more than 7,000 individuals kept a diary of their contacts — nearly 98,000 of them — over the course of one day. Contacts were sorted by place (home, school, work, leisure) and by nature (physical or nonphysical, brief or longer lasting). The model found that 5- to 19-year-olds tend to experience the highest incidence of infection when a new pathogen begins to spread in a completely susceptible population, possibly because of their more frequent and physical contact with others. It also showed how profoundly a society’s grids of connection influence transmission.

The model was expanded globally in 2017, with contact rates for 152 countries. “It’s what we all use,” says Matrajt, “because it’s the best thing we have to identify how people contact each other.” She incorporated the contact grid into her model.

For example, “if kids are really the hubs around which society is built,” Larremore says, “so that if you vaccinate the kids, you fragment that transmission network, then that’s going to give us a totally different way of rolling out this vaccine.”

The original grid relied on diaries. Today, our ability to gather data through real time cellphone and online activity may be even greater.

When social distancing became widespread this past spring, it dramatically altered the input into the typical transmission model, says Springborn. Data from the Institute for Health Metrics and Evaluation at the University of Washington shows the power of social distancing in reducing transmission. The contact grids in previous studies are “from pre-pandemic times,” Springborn wrote in an email. “We know that contact rates are very different under social distancing and we want to account for that. And we expect social distancing to soften as the number of infections falls. Human nature: As risk falls, so does risk-mitigating behavior.”

That needs to be modeled as well. And it will influence the expectations for a vaccine’s rollout and success. In fact, Lee maintains, if we had 90 percent compliance with face masks and social distancing right now, we could contain the virus without a vaccine.

In the study by Springborn, Buckner, and Chowell, social distancing is modeled by creating age-stratified categories for both essential and nonessential workers. Essential workers — health care workers, grocery workers, and many schoolteachers, among others — are at high risk for infection because they cannot socially distance. This model finds that deaths, as well as total years of life lost, are dramatically decreased when essential workers are prioritized to receive the vaccine. Older essential workers between 40 and 59 should be prioritized first if the goal is to minimize deaths, the authors maintain.

With no vaccine, about 179,000 people may die in the first six months of 2021, Springborn says. His team’s model suggests that deaths could decline to about 88,000 simply by introducing a vaccine gradually, giving it to 10 percent of the population each month, and distributing it uniformly without prioritizing any groups. But distributing vaccines in a targeted way, based on people’s ages and whether they are essential workers, could save another 7,000 to 37,000 lives, depending on the situation.

There are other methods of teasing out social connectivity beyond diaries and cellphone data. Census and other data reflect age, profession, and socioeconomic status, and Lee includes them in her models. “The zip code gives you a huge amount of information,” she says. Public health data on disease prevalence and hospitalizations can tease out the other unrelated diseases that Covid-19 patients have, as well as vulnerabilities in a given area. Even information on a city’s housing, whether skyscrapers or single-family homes, can give a clue to how closely people are packed together and how likely they are to interact. Inputting this kind of data allows for a vaccine rollout that is sensitive to local conditions. Lee would need to model about 500 representative cities around the U.S., she says, to cover the country accurately.

As powerful as the models can be, they are an imperfect guide. Inevitably they intersect with deep and broad social concerns. The pandemic has disproportionately harmed and killed minorities and those with lower incomes. For that reason, various groups are looking into the ethical principles that should frame vaccine allocation, according to Hanna Nohynek, deputy head of the Infectious Diseases Control and Vaccinations Unit at the Finnish Institute for Health and Welfare, and a member of the WHO’s SAGE Working Group on Covid-19 vaccines.

In the U.S., the National Academies of Sciences, Engineering, and Medicine has begun to model an equitable allocation of a vaccine. In addition, two other important models have emerged, one associated with University of Pennsylvania School of Medicine, and the other with Johns Hopkins University. Both are guided by concerns about ethics, fairness, maximizing benefits, building trust and the greater public good.

But building trust can be challenging in practice. For instance, it’s widely acknowledged that Black people have experienced hospitalization and death at disproportionately high rates compared to White people. Yet when ethicists begin to talk about prioritizing Black people for vaccines, it can be perceived as an intent to experiment on them by pushing them to the head of the line. If there is concern among African Americans, it’s a logical reaction to “a vast history of centuries of abuse of African Americans in the medical sphere,” says medical ethicist Harriet Washington, author of “Medical Apartheid.”

Ultimately, both ethical and mathematical models have to face real-world practicalities. “It’s hard because math essentially boils down to a utilitarian calculus,” says Lipsitch, the Harvard epidemiologist.

Nonetheless, says Larremore, the models will help guide us in the uncertain early days. “Vaccines take a while to roll out,” he says. “We can’t let our foot off the gas the moment a vaccine is announced.”

Jill Neimark studies
Science Journalism
.

What counts as 15 minutes of close contact?

Ryan Malosh — Wed, 04 Nov 2020 12:29:01 EST

The Centers for Disease Control and Prevention has new guidance clarifying what exactly “close contact” means when it comes to transmission of SARS-Cov-2, the virus that causes COVID-19.

The previous guidance suggested that a close contact occurred when a person was within six feet of an infectious individual for 15 consecutive minutes. Now, the CDC is acknowledging that even brief contact can lead to transmission. Specifically, the new guidance suggests that those spending a total of 15 minutes of contact with an infectious person over the course of a 24-hour period should be considered in close contact.

Despite the change, most public health professionals have been clear for months that there is nothing magic about six feet. In the same way, there is nothing magic about 15 minutes. These should be used as rough estimates to indicate the types of contact that are relatively higher risk.

This new guidance, then, is an important recognition of the ease with which this virus can spread. It is not a dramatic reversal of CDC guidance, like those related to masks and the back-and-forth on testing of asymptomatic individuals.

There is nothing magic about six feet

This change reflects new evidence that has emerged. This change is an example of how science works. As an epidemiologist who studies respiratory virus transmission, I actually don’t think this change will greatly impact how we live our lives during the pandemic, but it does represent continued evidence of how easily this virus spreads.

Why the change?

The new advice comes on the heels of an outbreak investigation published in the CDC’s Morbidity and Mortality Weekly Report. The investigation found that a prison employee in Vermont was infected, most likely during a series of brief contacts with infected but asymptomatic inmates.

A new @CDCMMWR found an employee at a correctional facility developed #COVID19 after brief, close contact with infected incarcerated people that added up to more than 15 minutes over the course of an 8-hour shift. Learn more: https://t.co/dMO4xyaINA. pic.twitter.com/pGPObhFmgM
— CDC (@CDCgov) October 21, 2020

The inmates were waiting on test results in a quarantine unit. The employee reported no close contacts outside of work and they hadn’t traveled outside the state. At the time Vermont was experiencing low levels of community spread. The outbreak investigation used video evidence from surveillance cameras in the prison to document the short interactions. Each interaction lasted about a minute, and in total the employee was in close contact with the infected inmates for about 17 minutes over the course of an eight-hour shift. For at least some of those interactions, the infected inmates weren’t wearing masks.

Documenting infectious contact is hard for respiratory viruses. After all, we can’t see the virus moving through the air. The video footage in this case represents pretty robust evidence. And so the CDC is recognizing the possibility that shorter interactions carry some risk.

This change is also an acknowledgment that the previous definition makes at least one explicit assumption that may not be true. The major assumption of the old rule is that there is a threshold effect of exposure. That is, once you’ve been exposed to a certain amount of virus (15 minutes’ worth), your risk of disease increases. The flip side of this assumption is that at levels below that threshold your risk remains low. That is why we’ve seen some schools mistakenly moving students around at 14-minute intervals.

The new guidance suggests that there is more of a dose-response relationship between viral exposure and risk of disease. Which is to say, the more virus you are exposed to, the higher your risk, even if the exposure doesn’t happen all at once.

But don't forget that there's nothing magic about six feet (or two meters)

Underway Studio via Unsplash

What does it mean?

While I don’t think this update will result in big changes, one thing it does do is expand the pool of people for contact tracing. In the ideal scenario, this change could mean that we catch more cases early after exposure. Those people can then begin to quarantine before they become infectious and spread it on to others.

Take, for example, the upcoming holidays. Having family over for Thanksgiving typically means sharing a meal, and likely spending several hours in close contact with others. That is still a risk, especially since those without symptoms can spread the disease.

We shouldn’t think to ourselves “This will only be a minute, I don’t need my mask.

The people who attend that gathering would all have been considered close contacts before, and they still are. But now, brief interactions that add up over time – for example, with a server at a restaurant – will be considered close contact.

This change by CDC suggests that we need to be more careful about brief interactions – for example, in the office or at school. We shouldn’t think to ourselves “This will only be a minute, I don’t need my mask.” The importance of wearing masks at all times to protect others has never been more clear. We may not know that we’re infected, and even a brief, unmasked encounter could spread the virus.

Ryan Malosh studies
Epidemiology
at
University of Michigan
.

Brain banks are key to understanding COVID's mysterious symptoms, but only if people are willing to donate

Kathryn Vaillancourt — Tue, 20 Oct 2020 14:13:02 EST

After 7 months and counting, we've all had first-hand experience with the stress and uncertainty that have hitched a ride with the COVID-19 pandemic.

This situation is pushing our mental health to its limits. Some patients have been reporting strange neurological symptoms that suggest that the virus might be able to hit the human brain directly. If we’ve learned anything from similar viruses in the past, it’s that the effects of COVID-19 on the human brain may last for months or years after the pandemic is over.

This is precisely why donations to brain banks are vitally important.

The method for preserving brains was created in the 1600s, and curious physicians and anatomists have been collecting brains ever since. But the systematic banking of brain tissue that exists today began in the early 20th century, arising from a need to study mysterious brain diseases. Today, there are brain banks throughout the US, Canada, Europe, and Australia that each focus on collecting and characterizing samples from specific brain disorders, and providing crucial resources to the research community. Although the details differ between platforms, people can agree to have their brains donated to a brain bank, or their next of kin may be approached by a brain bank team about the possibility of donation after they’ve died. Whether they’ve been diagnosed with an illness or not, each brain donation is meticulously categorized and preserved so that they can continue to be studied, sometimes decades later.

After the SARS pandemic in 2003, researchers used brain donations to discover that the virus could infect brain cells. This could explain why some SARS patients had symptoms like dizziness, confusion and anosmia (loss of the ability to smell). Curiously, reports have started to come out that COVID-19 can cause similar brain-related symptoms in some patients; the most common are headache, anosmia and brain fog, but COVID-19 can also cause seizures, strokes, or comas. There’s even some evidence that these symptoms are related to changes in brain structure, but without donated tissues it’s almost impossible to tell how the virus gets into the brain, or if it infects brain cells at all. It's possible that the virus infiltrates individual brain cells, causing them to malfunction, but the troubling symptoms that some patients experience could also be a side effect of the fever and inflammation that COVID-19 inflicts on the body as a whole. This means that for doctors struggling to find the right treatments and scientists looking for breakthroughs, brain banks might hold the answer.

doctors struggling to find the right treatments and scientists looking for breakthroughs, brain banks might hold the answer.

Naguib Mechawar, director of the Douglas Bell Canada Brain Bank (DBCBB) in Montreal, says that to truly understand COVID-19, brain banks are "more than useful, they’re essential." Whether the virus works through direct contact with brain cells, or through inflammation of the blood vessels in the brain, he adds that "access to human brain samples is required to understand the mechanisms underlying these symptoms. Models remain important, but there’s nothing like patient samples to understand this human illness."

Today, there are brain banks throughout the US, Canada, Europe, and Australia that each focus on collecting and characterizing samples from specific brain disorders, and providing crucial resources to the research community.

Wikimedia

For the virus to actively attack brain cells, it would have to get through the blood-brain barrier — the tight network of cells that plays bodyguard between the brain and the body — first. It turns out that some brain cells express the ACE2 protein that SARS-CoV-2 binds to in the respiratory tract, so it’s possible that they’d be vulnerable to such an attack. Plus, in the lab, the virus seems capable of infecting brain organoids — three dimensional cell cultures that are used to model brain biology — but we can't know if it holds true in humans unless we have access to human brains. Luckily, scientists have started to look at autopsied COVID-19 brains, and in one case, they’ve found bits of the virus inside some brain cells. Once inside, it's possible that the virus can reproduce and spread; but as Serena Spudich, a neurologist who wrote a review about these cases, said to the Guardian “It’s really hard to make firm conclusions based on one or two autopsies.”

Brain banks offer the solution to this problem. By collecting samples from people who were infected with the virus while they were alive, whether they had neurological symptoms or not, and from people who died from other causes, brain banks will be the steady, stable resource for COVID-19 brain research that they have been for other brain-related diseases. Banked brain samples have helped researchers understand how brain-specific immune cells react in Alzheimer’s disease, and how a specific group of cells could be a target for schizophrenia treatment. By accessing medical records, interviewing family members, and carefully examining tissues, brain banks are uniquely able to capture information about an illness before and after it has taken hold of a patient.

In 2000, brain bank scientists from Germany, Austria, and the US, banded together to understand how multiple sclerosis (MS) develops. One of the biggest challenges in treating MS is that the disease can present itself differently in different patients; according to the National Multiple Sclerosis Society, "no two people have the exact same symptoms, and each person's symptoms can change or fluctuate over time."

Together, the team led by Claudia Lucchinetti collected more than 80 patient brain samples, and although they found MS-related brain cell damage in all their samples, they noticed some interesting patterns. By carefully examining the distribution, size, and protein composition of the damaged cells, they found four distinct patterns that gave them clues about how the disease developed in each patient. These patterns could help doctors to diagnose and treat MS in living patients, and they would not have been found without donations to brain banks.

Brain banks will become even more important in the fight against COVID-19

Brain banks will become even more important in the fight against COVID-19 as we understand more about the behavior of the virus and the symptoms of COVID-19 patients. In addition to neurological symptoms experienced during their sickness, a troubling number of people have reported continued confusion and memory difficulties, called "brain fog", in the months after they've recovered.

Fortunately, efforts are underway to begin collecting COVID-19 brains, and Mechawar says "We [at the DBCBB] have been working actively to set up some mechanisms to collect such brains, but it has been difficult, namely because autopsy rooms have been shut down during the pandemic. But I’m glad to say that we’ve managed to establish new partnerships and purchase new equipment to facilitate things and that we will soon be able to initiate the collection process."

Although it’s not clear whether brain banks will help find a vaccine for SARS-CoV-2, they will continue to be an important pillar of COVID-19 research as the pandemic dies down. If they receive enough donations, that is.

Kathryn Vaillancourt studies
Neuroscience
at
McGill University
.

A virus-like COVID-19 vaccine is being grown in tobacco plants

Hayley McKay — Tue, 13 Oct 2020 22:47:41 EST

Currently, there are close to two hundred coronavirus vaccine candidates in development, 42 of which have entered clinical trials.

Out of these 42 candidates, one is unique: it is the only one to be produced in a plant. The Quebec City-based biopharmaceutical company, Medicago, has harnessed the speed and efficiency of plants to produce a virus-like protein (VLP) SARS-CoV-2 vaccine candidate. A VLP is like a virus. It has a similar outer shell but lacks a genome, which makes it completely harmless. It's like a water balloon with nothing in it. On July 14, it was the first SARS-CoV-2 vaccine candidate to enter clinical trials in Canada.

Plants can be used to quickly and ethically produce safe and effective vaccines, reducing the reliance on traditional chicken egg vaccine production technology. Flexible and versatile, this technology has the ability to adapt to fast changing virus landscapes and create new vaccines for emerging diseases, including SARS-CoV-2.

VLPs mimic the outer structure of viruses, which allows them to be easily recognized by the immune system

“Creating a sufficient supply of COVID-19 vaccines within the next year is a challenge which will require multiple approaches, with different technologies,” said Dr. Bruce Clark, president and CEO of Medicago in a release. “Our proven plant-based technology is capable of contributing to the collective solution to this public health emergency.”

Which is faster, the chicken egg or the plant?

Normally, vaccines take years to progress through development pipelines before they are approved for use. Many of the vaccines we use today were created more than 50 years ago using old technology. It is only in the past 20 years that scientists have begun working to harness the power of plants in order to produce vaccines and other pharmaceutical products – like enzyme replacement therapies, antibodies, proteins, and biosimilar drugs – to treat a variety of diseases.

Historically, vaccines targeting viruses like influenza are produced by injecting the virus of interest into fertilized chicken eggs, where it replicates for a couple of days. Fluid from the egg is then harvested to isolate the viral particles, which are used to make the vaccine. Huge amounts of eggs are required for this type of vaccine production: each vaccine dose needs at least one egg. More recently, other organisms have also been used to produce vaccine components, including cultured mammalian cells, bacteria, and yeast. Vaccines can also be produced without organisms at all – mRNA vaccines can be entirely synthesized in a test tube.

Producing VLP vaccines in plants is a complex process, but it may be surprising that it’s much quicker than the six months it takes to produce a vaccine in a chicken egg. It also eliminates ethical concerns surrounding reliance on animal products.

...once the plant is infected by the Agrobacterium, it will reliably produce the virus-like particles

With a six-to-eight week time-frame, Medicago’s plant produced vaccine technology, “seems to be a viable alternative for making vaccines,” says Dr. Daphne Goring, a professor at the University of Toronto who studies signal transduction in plants, and is not involved with Medicago.

In addition to their SARS-CoV-2 vaccine candidate, Medicago has used their plant produced VLP vaccine technology to create candidates for influenza, norovirus and rotavirus as well.

VLPs mimic the outer structure of viruses, which allows them to be easily recognized by the immune system. Unlike a real virus, VLPs do not contain genetic material, which means they cannot reproduce and spread inside the body. Without genetic material, it is impossible for VLPs to cause infection. But, they can still teach the immune system how to fight a real infection, leading to immunity against the virus.

Nicotiana benthamiana being injected with Agrobacterium

Via Wikimedia

In order to produce a VLP vaccine in a plant, scientists at Medicago have genetically engineered a special plant-infiltrating bacterium called Agrobacterium to turn plants into miniature VLP 'factories.' Specific sequences of viral DNA which produce the coronavirus’ outer structure proteins are inserted into the Agrobacterium genome. Then, Agrobacterium is allowed to infect the plant. Once inside the plant’s cells, the genetically modified Agrobacterium delivers the inserted viral DNA to the plant so it can use it as a template to produce the virus-like particle.

This system is very robust – once the plant is infected by the Agrobacterium, it will reliably produce the virus-like particles. All that’s left is harvesting the plant and purifying the VLPs from its tissue.

“It seems to be a very efficient system,” says Goring, “once they have a sequence, they can produce [the vaccine] very quickly.”

Medicago claims to produce a clinically viable vaccine in two months or less, similar to the estimated time-frame of Moderna's mRNA vaccine. Medicago's plant of choice, a relative of tobacco called Nicotiana benthamiana, grows quickly and easily and is highly susceptible to Agrobacterium infiltration.

In vast, bright growth rooms, thousands of plants are cultivated and exposed to cultures of Agrobacterium

In vast, bright growth rooms, thousands of plants are cultivated and exposed to cultures of Agrobacterium (in vacuums which helps the plants absorb as much bacteria as possible). Of the six to eight weeks spent developing the vaccine, the infected plants take about one week to produce VLPs inside their cells, after which their tissue is harvested. Then, the VLPs are purified from the harvested tissue and are subjected to quality control and safety steps to ensure they are safe and efficient for preventing viral infection.

Silver Linings

If all goes well in clinical trials, Medicago’s VLP vaccine will be able to contribute to the other coronavirus vaccines already in production. The best-case scenario for eliminating, or at least controlling COVID-19, will be successfully generating multiple vaccines that can be administered on a global scale.

Medicago’s vaccine has the potential to be the first plant produced vaccine to combat not only SARS-CoV-2, but many other time-sensitive viral diseases as well. Currently, none of the vaccines developed by Medicago or any other plant-based company have been approved for human use, despite successful clinical trial results. But Moderna is in the same boat: while they have also developed innovative mRNA vaccine technology, none of their therapies have been approved for human use.

The SARS-CoV-2 virus. A virus-like particle mimics the outside envelope but does not contain the genome within

Via NIH

Medicago's seasonal flu vaccine, which has completed phase three clinical trials, has the potential to adapt to the ever-changing seasonal influenza strain with their plant production technology.

“Each year they’ve got to come up with a new vaccine,” remarks Goring, “and with their system, they can do it quickly.”

Speed is of the essence when it comes to vaccine production, especially for combating influenza, a rapidly mutating virus. Once up to date viral target sequences are deciphered, plants can manufacture vaccines to fight them at a surprisingly rapid pace. Due to the proprietary nature of the vaccine production industry, there is currently not enough publicly available data to determine if plants definitively hold the title of fastest vaccine production platform. However, the two month time-frame is most certainly quicker than chicken egg vaccine production, and likely means plant-based vaccine production platforms are among the speediest.

In addition to speed, there's scalability. Vaccine platforms involving plants are less expensive than cell-based and are almost infinitely scalable: simply sow more seeds to increase yield. While mRNA vaccine production times are similar to plant based production, they are not as easy to scale. Although still uncertain, Medicago has estimated it could produce up to one billion doses of their SARS-CoV-2 vaccine annually, compared to Moderna's estimate at only half as much.

Another benefit of plant produced biopharmaceutical systems is decreased susceptibility of contamination from harmful viruses compared to platforms which use mammalian cells. While mammalian cells can play host to viruses that can also infect humans, plants have intrinsically different cellular architecture which doesn't allow a human virus to infect them. This means the plants and their biopharmaceutical products cannot pass on these unwanted viruses to the humans who use them.

Hayley McKay studies
Genetics
at
University of Toronto
.

No, you cannot pierce your brain with a COVID-19 swab test

Carl Philpott — Mon, 05 Oct 2020 10:01:31 EST

People who have had the COVID swab test say that it feels like their brain is being pierced by an oversized cotton bud. Recent lurid headlines will not put people at ease. “Woman’s nose ‘starts leaking brain and spinal fluid’ after she took a Covid swab test”, said the Daily Star. “Coronavirus swab test went so far up a woman’s nose it caused her brain to leak”, was the Mirror’s headline.

But where did this story come from – and should we give it any credence? The newspaper reports are based on a case study published in a respected medical journal, JAMA Otolaryngol Head & Neck Surgery. It tells of a woman in Iowa, USA, who was asked to self-swab for COVID before undergoing a hernia operation. Shortly after swabbing, fluid began leaking from her nose. She also developed a headache and started vomiting.

Please do not be afraid of having your nose swabbed

The doctors at the University of Iowa hospital, where she was treated, identified the fluid as cerebrospinal fluid – a fluid that is found in the protective lining around the brain and spine.

United Nations

So is this cause for alarm?

Not really. The 40-year-old woman had a pre-existing defect in the base of her skull (the bone at the top of the nose) and a sac of brain tissue had protruded out into the nasal cavity. This is a rare condition that we see in neurosurgery and in ear, nose and throat clinics.

About one in 10,000 babies are born with a defect like this, but the rate at which it occurs in adults is unknown. In this lady’s case it was probably because the pressure inside her skull around the brain was higher than normal, creating a weak spot.

It is extremely unlikely for any person who doesn’t have this pre-existing weakness in the nose to cause any damage with a swab. However, a good tip when swabbing the nose is to remember that the inside of the nose travels back, towards the back of the head, and not up. So any swabbing of the nose should involve pointing the swab towards the back of the head in the same direction as you would point the swab towards your tonsil when you swab your mouth – which is part of the same test.

BruceBlaus / CC BY-SA

Please do not be afraid of having your nose swabbed. It may be uncomfortable, but you cannot accidentally jab your brain. The swab test is our only way of telling who has and who hasn’t got COVID. It’s a vital public health tool to help us bring this pandemic under control.

Carl Philpott studies
Medicine
at
University of East Anglia
.

Can fitness bands predict COVID-19 infection before you show symptoms? Probably not

Matthew Bomkamp — Tue, 22 Sep 2020 23:18:06 EST

Wearable fitness technology companies claim to optimize athletic training, recovery, quality of sleep, and result in an overall increase in well-being. Although the accuracy of some of the devices have been called into question, studies have found that these wearable fitness trackers can promote behavioral changes associated with heart rate and daily step count that are linked in more active lifestyles.

However, what happens when one of these companies publicly claims to be able to predict the risk of infection from a disease?

WHOOP is a wearable fitness technology company that has received media interest for claims of being able to predict risk of COVID-19 earlier than the onset of noticeable symptoms. They claim that monitoring the user’s resting respiration rate (taken when the user's breathing rate is the lowest, at night) can help in early detection of the virus. COVID-19 is, first and foremost, a respiratory tract infection that can cause respiratory distress. If the WHOOP app notices any abnormal variation in the user’s resting breathing rate, wearers may receive a notice that they are at risk of being infected by COVID-19. By being able to identify any abnormality in respiration, users could potentially get tested and isolate themselves earlier than they would otherwise.

The company, which has financial backing from the co-founder of Twitter Jack Dorsey and NBA basketball player Kevin Durant, received even further attention when pro-golfer Nick Watney was alerted, accurately, via the WHOOP app that he may have COVID-19. This led to the PGA tour acquiring WHOOP straps for its employees and athletes. But besides anecdotal accounts, what is the scientific evidence that this fitness strap can accurately predict COVID-19 infection from respiration rate?

SARS-CoV-2, coronavirus (magenta), emerging from a cell (green) cultured in a lab

NIAID-RML

Only one study exists examining WHOOP’s claims regarding COVID and, despite media outlets reporting this paper as scientific evidence of the validity of the device, it has yet to be peer-reviewed. Incidentally, this study was funded by WHOOP, and was also a collaborative effort with researchers from Central Queensland University and WHOOP. Laying aside the bias of being conducted and funded by WHOOP, this study, at least on the surface, seems to have positive results. WHOOP's algorithm to track respiration rate was able to identify 20 percent of COVID-19 positive individuals two days before those users started reporting symptoms, and 80 percent of positive cases by day three of reported symptoms. Identifying a COVID-19 infection this early would allow patients to get tested and isolate themselves much earlier, potentially slowing the spread of the disease.

Unfortunately, the positive results seem less impressive when diving into the study's methods. WHOOP was tasked with creating an algorithm that could monitor nightly variation of respiration rate and identify abnormal readings as a possible COVID-19 infection. However, no long-term investigations studying nightly variation in respiratory rate have been conducted. The investigators’ solution was to use their own user’s data in order to create a baseline for normal nightly respiratory variation. This supplementary dataset used 25,000 users' nightly data, accounting for 750,000 nights of sleep. By doing so, WHOOP's study works under the assumption that their device is fully accurate in its ability to measure respiration rate.

No long-term investigations studying nightly variation in respiratory rate have been conducted.

Polina Zimmerman / Pexels

Since these devices were originally intended for promoting positive behavioral changes such as increased physical activity and improved quality of sleep, precise accuracy (as required in clinical medicine) was not necessary. Currently, only one peer-reviewed paper validating the WHOOP strap’s accuracy in measuring respiration rate at night exists. The results were positive and conclude that WHOOP is accurate compared to the gold standard, inductance plethysmography, which measures the movement of the chest and abdominal wall to calculate respiratory rate. However, the number of participants in this study was low, and the researchers only used one night of sleep to evaluate the strap’s accuracy. A larger, more extensive clinical study would likely be required to validate the accuracy of the WHOOP strap.

Potential problems also exist in the inclusion criteria for subjects. For this investigation, all subjects were already WHOOP customers and either had already begun self-reporting COVID-19 symptoms or had been tested for COVID-19 infection. This choice in inclusion criteria represents a methodological problem as the population used in this study may not be representative of the general population as a whole. Using only WHOOP users could affect the sensitivity of the algorithm as the demographics may not accurately reflect the general populace. And by only including subjects that were already self-reporting COVID-19 symptoms or had already undergone testing, subjects experienced a much higher rate of infection than the general population. Although the algorithm identified many of the COVID-19 positive cases in their investigation, its ability to predict infection in much larger populations with lower rates of infection, as well as ailments with similar symptoms, remains untested.

its ability to predict infection in much larger populations with lower rates of infection, as well as ailments with similar symptoms, remains untested.

Indeed, monitoring respiration rate in a population that likely has been exposed to COVID-19 may in fact be a potential tool for early detection. However, variation of respiratory rate is also a common symptom for many ailments such as mild infections. Unfortunately, WHOOP’s algorithm shows no ability to discriminate between a possible COVID-19 infection from any other pathological condition that features a variation in respiration, likely limiting any potentially useful application.

WHOOP's studies leave many unanswered questions regarding their strap's relative accuracy, as well as ability to predict risk of COVID-19 infection in a clinically useful way. And yet it is entirely possible that the fitness band does everything that it is purported to do. However, when a brand or company takes a step into the realm of clinical medicine — by claiming ability to predict risk of infection from disease, for instance — such claims need to be rigorously investigated.

Unfortunately for WHOOP, there is a lack of empirical evidence that would likely prevent this type of technology from being widely used in the fight against the spread of COVID-19 infection. WHOOP represents a useful reminder to maintain a healthy skepticism when dealing with claims from a company, especially in regards to the health and wellbeing of the consumer.

Matthew Bomkamp studies
Physiology and Applied Physiology and Kinesiology
at
University of Florida
.

Don't bank on herd immunity to save us from COVID-19

Sara May Bergstresser — Fri, 28 Aug 2020 10:04:46 EST

There has recently been some speculation that the human population, or at least some segments of it, may already have had sufficient COVID-19 infections to achieve the protective effect of “herd immunity.” There are also new studies using computational modeling that suggest that the population levels of immunity needed for broad protection are lower than the most common estimates of 60-66% immune. While these new and hypothetical constructs of infection-acquired herd immunity show useful directions for the future of public health research for both COVID-19 and other infectious diseases, there are still too many unknowns to use these numbers to design active health policy.

As I wrote earlier this year:

Herd immunity refers to the protection that an at-risk individual can gain by being surrounded by others who are already immune to a disease. It relies on a proportion of individuals within a population already having immunity to an infection, but the exact proportion of individuals needed for herd immunity depends on the characteristics of each particular infection. In addition, the understanding of the concept has been developed mainly as related to vaccination, where immunity is produced in a person by giving a vaccine, rather than that person having to develop and recover from the disease.

Many hard hit communities, such as the Hasidic community in the Borough Park neighborhood of Brooklyn and other urban neighborhoods in London and Mumbai, have already had a substantial number of infections within distinct spatially contained groups, leading people to speculate that they may have established a protective level of immunity within these areas. In addition, many researchers have developed mathematical models of the outbreak and have come up with values lower than the typical estimates of the population needed for herd immunity for COVID-19, ranging from about 43% to as low as 10-20%.

Our current knowledge about SARS-CoV-2 (the virus that causes COVID-19) is incomplete, including a lack of information about how we may develop immunity and how long immunity will typically last.

The classical calculation of herd immunity is based on the infectivity of the virus in question, defined by the mathematical expression, 1-(1/R0). R0 (“R-naught”) is the “basic reproductive number” of the virus, which is an indicator of how easily an infection is transmitted. This is an estimate of the number of secondary cases generated by an infectious individual at the start of a novel outbreak, when the rest of the population is susceptible. There are many difficulties in estimating R0 during an active outbreak, resulting in some wide variations in estimates over time and data coming from different geographic locations. Early WHO estimates turned out to be too low, but the most widely used estimates R0 for SARS-CoV-2 now remain at around 2.5 to 3, meaning that one infectious person will infect 2.5 to 3 others. The calculated estimate based on an R0 of 2.5 to 3 results in 60-66% percent of people needing to have immunity before there is any “herd” immunity effect for the population.

Herd immunity helps reduce the likelihood of disease transmission from infected individuals to non-immune individuals. Immunity can be acquired from vaccines or, in many cases, previous infection and recovery from the infection.

U.S. Government Accountability Office on Flickr.

A mathematical model recently published by Tom Britton and colleagues in Science suggests that because population groups vary by factors including age and rates of social activity and contact, herd immunity could be established through illness and recovery with only around 43% of the population, instead of the 60% required using a classical model assuming an R0 of 2.5.

While this type of mathematical model for herd immunity is theoretically interesting since it attempts to capture contextual factors and elements of population heterogeneity, it is still too early to be directly applied to public policy. Our current knowledge about SARS-CoV-2 (the virus that causes COVID-19) is incomplete, including a lack of information about how we may develop immunity and how long immunity will typically last. Mathematical modeling is also based on broad assumptions that are often untested in the real world. Much more research is needed before we know if these new ideas about herd immunity should be applied to public health interventions and planning.

There are generally two broad categories of infectious disease models: mechanistic models, which use scientific understanding of disease dynamics and human behavior, and statistical models, which rely only on patterns in the data

U.S. Government Accountability Office on Flickr.

The most striking example of how fast our understanding can change is the recent confirmation of reinfection with a second case of COVID-19 after four and a half months in Hong Kong. Unlike earlier reports of reinfection, which were mainly anecdotal, this case was confirmed based on viral genome sequencing, showing that the second infection was from a genetically distinct strain. This suggests that reinfection is an important possibility and that immunity acquired through illness and recovery may last only months. This new case adds additional elements of uncertainty to Britton and colleagues’ model, since the authors state that their current model was designed based on the assumption that “infection with and subsequent clearance of the virus leads to immunity against further infection for an extended period of time.”

Reinfection and the typical duration of immunity are not the only uncertainties. It also remains unclear to what degree immunity is antibody-mediated versus cell-mediated, which kinds of antibodies are most important, whether immunity might prevent future disease or only make reinfections less severe, and whether prior exposure to common cold coronaviruses offer any protection. The immune response also may depend on characteristics beyond age, including biological sex and individual genetic variation, and other factors. The data available is often incomplete, meaning that mathematical models may be based on biased samples; underreporting of data has been high, and areas without sufficient testing do not provide adequate data.

There are also a number of difficulties inherent in using the basic reproductive rate to predict disease spread, and it is difficult to disentangle the basic rate R0 from the actual transmission rate (Rt), which is impacted by changes in behavior and in population immunity over time. If done properly, all of the measures meant to control the virus, including lockdowns, social distancing, business closures, travel bans, mask-wearing, and contact tracing, will reduce the transmission. While this is a good thing for the public’s health, it makes the data collected ambiguous: has disease transmission has been slowed by public health measures, or is it waning naturally?

Current estimates suggest that a person infected with COVID-19 will, on average, pass the virus to 2-3 other people.

United Nations COVID-19 Response on Unsplash.

There are also speculations that the amount of virus a person contacts impacts the severity of illness (this is known as a dose-response relationship), potentially explaining why masking is effective. It is still unclear to what degree seasonality plays a role in transmission, and more research is needed on the exact mechanisms of virus spread and persistence in the air and the role of indoor conditions such as humidity, temperature, and ventilation. Finally, once a vaccine becomes available, it will impact herd immunity, though the results will depend both on the effectiveness and the distribution of any future vaccines as well as whether people are willing to get the vaccine at all.

Throughout this pandemic, the concept of herd immunity has been frequent fodder for wishful thinking.

Throughout this pandemic, the concept of herd immunity has been frequent fodder for wishful thinking. Some countries, including Britain and Sweden, attempted to rely on herd immunity rather than implementing broad control measures. Now Britain has reconsidered this plan, and Sweden has sustained much larger spread of the disease and greater number of deaths than its neighbors.

In the United States, wishful thinking about the virus disappearing on its own has delayed needed intervention and prompted premature reopening. Pandemic control measures have many unpleasant side effects, and herd immunity can be an appealing concept for those who seek reassurance that the world will eventually return to normal, but our best way forward requires an understanding that conducting quality research and applying it effectively to policy take time and a great deal of work.

Sara May Bergstresser studies
Bioethics, Public Health, and Biochemistry
at
Columbia University
.

Is artificial intelligence worsening COVID-19's toll on Black Americans?

Rod McCullom — Thu, 13 Aug 2020 07:38:00 EST

The power of artificial intelligence has transformed health care by using massive datasets to improve diagnostics, treatment, records management, and patient outcomes. Complex decisions that once took hours — such as making a breast or lung cancer diagnosis based on imaging studies, or deciding when patients should be discharged — are now resolved within seconds by machine learning and deep learning applications.

Any technology, of course, will have its limitations and flaws. And over the past few years, a steady stream of evidence has demonstrated that some of these AI-powered medical technologies are replicating racial bias and exacerbating historic health care inequities. Now, amid the SARS-CoV-2 pandemic, some researchers are asking whether these new technologies might be contributing to the disproportionately high rates of virus-related illness and death among African Americans. African Americans aged 35 to 44 experience Covid-19 mortality rates that are nine times higher than their White counterparts. Many African Americans also say they have limited access to Covid-19 testing.

During the early weeks of the pandemic, there were few — if any — Covid-19 testing locations in African American communities. Public health officials in states such as California, Illinois, Tennessee, and Texas have said that decisions about whom and where to test were data-driven and reflected the demographics of early cases. Yet the initial focus on affluent White communities allowed thousands of infections to quickly spread across cities and towns whose residents experience disproportionately high rates of underlying health conditions.

African American communities should have been prioritized for testing locations, says Alondra Nelson, a sociologist and president of the Social Science Research Council, an almost 100-year-old independent research organization that advances better understanding of social science. When algorithms overlooked health disparities as a risk factor, Nelson says, public health officials issued an implicit statement to African American communities: “We’re not going to triage and treat you.”

Those who study the problem say that the extent of racial bias in AI medical technologies is unknown. This is, in part, due to a lack of transparency: The software is often proprietary, which means the intellectual property — the process, inputs, and source coding — is protected and copyrighted. Independent researchers have very little, if any, access to the data. “We’re in a new space,” says Nelson. In many instances, big data is now a business product. This is why she and others say that fixing racial bias in AI may involve addressing not just science, but also policy and law.

When algorithms overlooked health disparities as a risk factor, Nelson says, public health officials issued an implicit statement to African American communities: “We’re not going to triage and treat you.”

The stakes are high. Algorithms affect the lives of virtually all Americans, making rapid, automated decisions in credit, finance, employment, compensation, housing, courts and sentencing, health, medicine, and other areas. These decisions are critical to our daily lives, and they are largely automated.

Last fall, a research team published a paper in the journal Science that for the first time attempted to quantify the extent of racial bias in patient care and outcomes. The researchers studied an algorithm developed by Optum, a subsidiary of the world’s largest health care company, UnitedHealth Group. Other companies, such as 3M Health Information Systems and Verisk Health, produce similar algorithms, as do some universities and the Centers for Medicare and Medicaid Services.

The algorithm under study was used to identify patients with complex medical needs and assign each what is known as a “risk score.” Patients with the highest scores are eligible for additional resources, such as home visits by a nurse, expedited primary care visits, and automatic prescription refills. The research team looked at how the algorithm performed at an unnamed medical center, which provided the health care records for nearly 50,000 patients. Almost 44,000 were White and about 6,000 were Black. Researchers compared the patients’ risk scores with their actual health data, including illness history and test results.

The way the medical center used the algorithm, the researchers concluded, was not neutral and unbiased. African Americans, for example, comprised just 18 percent of the medical center’s high-risk group when assessed using the algorithm. But when looking at actual patient health data, the Science researchers concluded the high-risk group should have been 47 percent African American. The discrepancy meant that White patients were granted access to resources ahead of African American patients who were less healthy.

The five-year survival rate among Whites for melanoma is 94 percent, according to the American Cancer Society. The rate is only 66 percent among Blacks.

The reason: The algorithm was trained to identify patients with higher anticipated future health care costs. It may seem reasonable to equate higher anticipated costs with deteriorating health, says the study’s lead author, Ziad Obermeyer, an emergency medicine physician and an associate professor at the University of California, Berkeley School of Public Health. But the formula privileges patients with higher incomes and top tier health insurance plans that cover preventive care, more doctor visits, higher cost prescriptions and such. It also ignores the reality that many low-income patients — who are disproportionately African American — are more likely to seek medical care only when their symptoms are severe.

The result: Poorer Black patients appear healthier than they actually are.

What’s “so striking” and “sadly very familiar” are that these algorithms are mimicking the structural racism evident across American society and in health care, says Obermeyer. These types of screening algorithms should “identify people who have the same health needs irrespective of the color of their skin,” Obermeyer adds. “That turns out not to be the case.”

In an email to Undark, Optum spokesperson Tyler Mason took issue with the Science analysis. “The study in question grossly mischaracterized a cost-prediction algorithm… based on one health system’s incorrect use of it, which was completely inconsistent with any recommended use of the tool.” That recommended use, according to Optum, is to model potential future health care costs for individual patients based on past health care experiences. It is not intended to assist doctors in making care decisions. The algorithm “does not result in racial bias when used for that purpose,” Mason added.

Obermeyer agreed that the algorithm is not racially biased when used as a predictor of cost. “It predicts cost equally well for Black and White patients,” he wrote in an email. But he disagreed with the implication that just one hospital was misusing the algorithm. “On the one hand, everyone knew it was a cost predictor; on the other hand, everyone was very obviously using it to predict risk,” he wrote. As Obermeyer sees it, the problem was systemic: Software developers, hospitals, insurers, researchers — “we were all just thinking about this… in a way that was subtly but importantly wrong.”

Because risk-prediction algorithms are widely used, some researchers are now asking if their use contributed to the significant racial disparities seen in Covid-19 treatment and access to testing.

The narrative around Covid-19 and African Americans has largely been about comorbidities, says Nelson. As a group, African Americans experience higher rates of many serious health problems, including hypertension and diabetes. These conditions make people more vulnerable to Covid-19. “If we know that African Americans are more likely to have poor health outcomes because they have these comorbidities,” says Nelson, then they, as well as Latinos and Indigenous people, should have been prioritized for testing.

But that doesn’t appear to have happened. Nelson points to “lots of stories of people who have gone to the hospitals and emergency rooms two, three, four times,” and still testing was denied because “it was not believed that they were sick enough. These were African Americans who had Covid-19” and some later died, she adds.

Obermeyer recently spent time working at a hospital in Navajo Nation, a Native American reservation with some of the highest per capita Covid-19 infection rates in the United States. Navajo Nation’s health care infrastructure is “under-resourced,” says Obermeyer, and that can create a vicious cycle, similar to the one his team uncovered in their study of the AI-powered algorithm: If an underserved population lacks access to Covid-19 testing, then that population might look like it’s doing relatively well, even when it isn’t. This, in turn, may lead to fewer resources being allocated — and a delayed understanding of the full scope of the problem.

Racial bias has also been demonstrated in AI-powered medical diagnostic applications with a very particular nuance: The algorithms are less accurate diagnosing conditions on darker skin.

The algorithms are less accurate diagnosing conditions on darker skin

The phenomenon is not new. Facial recognition systems used by law enforcement, for example, are notoriously less accurate at identifying African American faces. Some of the relatively few studies documenting the problem have suggested up to 10 percent less accuracy compared to White faces. Self-driving auto technologies are also less accurate at recognizing pedestrians with darker skin — a situation that could have fatal consequences.

In medicine, machine learning has been used to create programs capable of distinguishing between images of benign and malignant moles. But a 2018 paper in JAMA Dermatology warned that “no matter how advanced the [machine learning] algorithm, it may underperform on images of lesions in skin of color.” This is because the training sets for the algorithms are not diverse, says Adewole Adamson, a dermatologist and assistant professor at the University of Texas at Austin Dell Medical School.

For the JAMA Dermatology paper, Adamson and his co-author studied sample data from the International Skin Imaging Collaboration: Melanoma Project, an open source dataset of more than 20,000 images of skin lesions. Collected from Australia, Europe, and the United States, the overwhelming majority of these images are from people with lighter complexions, according to Adamson.

Melanomas are relatively rare among African Americans. But they are often diagnosed at later stages — as is the case with most cancers — and their melanoma mortality rates are relatively high compared to Whites. The five-year survival rate among Whites for melanoma is 94 percent, according to the American Cancer Society. The rate is only 66 percent among Blacks.

Clinically-validated AI-powered apps that diagnose melanoma are not yet available to the average physician, but that may change soon. Numerous programmers are trying to develop and market the technology. “If you’re going to create such a program, you’re going to have to make sure that the skin images represented are representative of the different skin types that exist in the world,” said Adamson, who has conducted extensive research on racial disparities in dermatology.

Researchers believe almost one-third of the world’s stored data is health care related

Michael Dziedzic on Unsplash

Absent that, “you’re going to have to have some type of black box warning,” he continues: “Training sets are very important and it is critical in having a training set that represents what reality is.”

Some researchers are developing new mobile health applications with these realities in mind. For example, a team based at the University of California, San Francisco is developing a smartphone app that screens for diabetes. Users turn on the phone’s flashlight, place their fingertip over the phone’s camera lens, and then an optical technique known as photoplethysmography (PPG) allows the algorithm to extract features such as blood pressure and heart rate. The team is developing the application with Azumio, a mobile health technology company.

The algorithm was originally developed with data from about 54,000 participants enrolled in an online heart study. The participants were familiar with using smartphones to monitor their health, but they were less racially diverse than the broader U.S. population, says Robert Avram, a cardiologist and adjunct instructor at the University of California, San Francisco, and the lead author of a developing paper on this application. To ensure the algorithm is just as effective on darker complexions, the researchers are conducting extra rounds of clinical trials on African Americans and Asian Americans. Both groups have higher rates of diabetes than the general population.

To ensure the algorithm is just as effective on darker complexions, the researchers are conducting extra rounds of clinical trials on African Americans and Asian Americans

Researchers across disciplines agree that broadening training sets is crucial to developing medical algorithms that perform equally well for all patients. “If Blacks, or Hispanics or other underrepresented groups are not included as a part of that training set, there may be unique features that are not going to be recognized by those algorithms,” says Renã A.S. Robinson, associate professor of chemistry at Vanderbilt University who is researching, among other things, a possible molecular basis for some racial disparities in Alzheimer’s disease. If those unique features go unnoticed, she adds, that could hinder physicians’ ability to detect disease early and provide the best treatment.

Researchers believe almost one-third of the world’s stored data is health care related. New “training data” is created each second, in the form of updated prescriptions, imaging reports, insurance bills, and more. All of this gets sorted and added to the archive created by various software developers. Developers generally block third parties — such as researchers — from accessing their programming code.

“There are a lot of frictions that prevent researchers from the outside from studying these things in a hospital or a health system where the data inevitably lives,” says Obermeyer. In his case, he was fortunate to be at a health system that purchased Optum’s algorithm. The health system allowed Obermeyer to use the software and access the data without cost for research purposes. The institutional review board approved the research.

For businesses, sharing a proprietary algorithm with an outside researcher also raises “the real issue of privacy and civil liberties,” says Nelson. It’s important for the company not to release personally identifiable data.

After the publication of the paper in Science, two agencies in the New York state government — the Departments of Financial Services and Health — announced investigations into UnitedHealth Group. Currently, there is no regulation or public oversight of algorithms, but a number of policy proposals have emerged in recent months.

Some politicians want federal agencies and health care companies to provide information on how they are responding to racial bias in algorithms. Sens. Cory Booker and Ron Wyden, along with U.S. Rep. Yvette Clarke, have co-sponsored the Algorithmic Accountability Act. The bill would compel certain companies to investigate many of their AI applications for bias. The bill would generally target larger companies, such as those with revenue in excess of $50 million per year, or those that collect personal data on 1 million or more consumers. The bill would also apply to data brokers such as Experian.

There have also been policy recommendations in recent months toward reducing algorithmic bias in health and medical applications. One of the more innovative suggestions: modernizing the Civil Rights Act of 1964 and making the case that it already applies to decisions made by artificial intelligence. The proposal was made in congressional testimony by Nicol Turner Lee, a sociologist and director of the Center for Technology Innovation at the Brookings Institution who conducts research at the intersections of race, social justice, and technology.

“The tech companies were operating in the ‘wild, wild west’ without any guard rails,” Turner Lee tells Undark. “So without risking the types of innovations that we’re seeing, it was important to [find] settled laws that define what you can and cannot do to a protected group or class.” She also adds: “I’ve been saying to legislators … that it’s very important to make a statement that the civil rights laws that have already been previously litigated apply to AI. Don’t let there be a gap.”

All of the sources interviewed for this article believe that the private sector has a critical role in innovation and developing technologies. But they all agreed that changes have to be made to reduce racial bias.

Obermeyer and his team take a slightly different approach from Turner Lee. Obermeyer believes that, at least for now, many health and medical stakeholders can develop best practices to reduce racial bias. Obermeyer says his team has been approached by health care systems, insurers, software developers, as well as state and federal regulators.

The researchers have offered to audit their algorithms on a pro-bono basis, and deliver recommendations on how to mitigate any biases that are discovered. This likely is the first time that stakeholders’ AI have been audited for fairness. Hopefully, says Obermeyer, this can “begin a conversation” to “share methods and best practices.”