Ricki Lewis's Blog, page 22

Events have collided in a way that even the most imaginative fiction writer couldn't have conjured up: a global assault by an enemy that no one can see, and a nearly-9-minute-long murder of a black man by a white police officer captured on video for the world to see.

At the protests that the killing of George Floyd triggered, responses as global as COVID-19, many people are wearing masks and distancing themselves as they march, kneel, or lie down chanting "I can't breathe." But some are not following public health recommendations. And many are shouting, as police hurl chemicals that make people cough. What will the consequences of the massive and necessary Black Lives Matter protests be on public health?

The mathematical models used to predict the next stages of the pandemic may factor in the expected – Memorial Day celebrations and phased reopenings. But they couldn't have foreseen the events of the past two and a half weeks. How can people in close proximity for extended periods of time, moving and outdoors but hollering and crying, even if masked, affect transmissibility of the coronavirus? That seems like too many variables to model, but some recent technical articles might provide some insight.

Mask Math

To continue reading, go to my blog DNA Science, where this post first appeared.

Some medical conditions can't be ethically investigated in humans, so researchers are finding interesting ways to grow people parts in the bodies of other types of animals. Jian Feng and colleagues at the University at Buffalo recently engineered prenatal mice that have human cells in key parts of their anatomy. Their report appears in Science Advances.

The humanized mice may one day incubate human cells needed for treatments of chronic diseases like kidney failure and diabetes, and provide new and improved models of how the human body succumbs to various conditions, from cancer to degenerative conditions to COVID-19.

To continue reading, go to Genetic Literacy Project, where this post first appeared.

There's no shortage of research efforts looking for ways to stop, or at least slow down, the novel coronavirus. Of course, those strategies involving cutting edge techniques, including CRISPR gene editing, tend to get most of the attention. If it's new, it must better, after all.

But what if we could reach back 100 years for a solution? That's essentially what we've done with the recent decision by the US Food and Drug Administration to authorize the emergency use of an old technique — convalescent plasma — for patients severely ill with COVID-19. The idea is that plasma from people who have recovered can transfer protective antibodies to a still-sick recipient. Donors must have been symptom-free for 14 days with a negative test or for 28 days without one.

"We think it shows promise, and we're going to be starting that this week," said New York governor Andrew Cuomo just before the announcement. 

Natural antibody cocktails

The rich history of convalescent plasma meanders through the plagues of the twentieth century. Hearing about it in the context of COVID awakened memories of receiving a similar treatment, in the 1960s.

To continue reading, go to Genetic Literacy Project, where this post first appeared.

The coronavirus pandemic has unleashed a wave of repurposing efforts, from old malaria drugs prescribed off-label to anti-virals stalled in development from past scourges, like remdesivir for Ebola, SARS, and MERS. Stem cells are finding new niches too, in helping to heal the devastation the novel coronavirus can leave in its wake.

It's understandable in the face of such a swift killer as COVID-19 to desperately try any treatment that makes even a bit of sense. But as many experts have insisted, only a controlled clinical trial can produce reliable information on efficacy.

"One advantage of a randomized controlled clinical trial is that if you find something that doesn't work, you get it off the table quickly. I've been through this before in the early HIV years, when there wasn't any therapy at all. There was the tension between doing a trial and just giving someone something," said Anthony Fauci, MD, director of the National Institute of Allergy and Infectious Disease and unofficial guru of the pandemic, on a recent JAMA Network webinar.

To continue reading, go to Genetic Literacy Project, where this post first appeared.

Dividing groups of people into "us" and "them" isn't usually a good idea, but in the scary new world of COVID-19, it makes a certain sense. Issuing "immunity licenses" – aka passports or certificates – to people whose blood contains neutralizing antibodies against the novel coronavirus may be a safer way to reopen parts of the economy than letting unchecked crowds spill onto beaches, pack into subway cars, and fill eateries, stadiums, and concert venues.

Immunity licenses would "give holders certain time-limited work and social freedoms, joining larger gatherings or returning to nonessential jobs," wrote Mark A. Hall, of the Wake Forest University Schools of Law and Medicine and David M. Studdert, from Stanford University Schools of Law and Medicine, in a recent Viewpoint in JAMA.

License holders could safely:

     Serve pizza, make lattes, scoop ice cream.
     Visit hospitalized loved ones or care for patients.
     Work in nursing homes, assisted living facilities, day care centers, schools, and fitness centers.
     Cut hair, trim nails, fill cavities, and fit eyeglasses

To continue reading, go to Genetic Literacy Project, where this post first appeared.
 

Families that have members with rare diseases may face challenging situations during the pandemic. They're experts in navigating complex medical situations, but they must now weigh the risks and benefits of taking a loved one with a complication from a rare disease to a hospital.

"We have experience living with uncertainty, for years or even decades. Many of us have experience with isolation, and medically fragile people have always needed to be careful of exposure to people with illnesses. And many of us haven't been able to do things other families do," said Albert Freedman, PhD, a clinical psychologist and caregiver for a 24-year-old son who has spinal muscular atrophy (SMA). He spoke at a webinar that the National Organization for Rare Disorders (NORD) convened March 31, "A Rare Response: Addressing the COVID 19 Pandemic."

To continue reading, go to my blog DNA Science, at Public Library of Science (PLOS). 

Recently in my endless email about COVID-19 popped up a new paper analyzing the health of two Italian sisters who lived to remarkably old ages.

"The Phenotypic Characterization of the Cammalleri Sisters, an Example of Exceptional Longevity," from Calogero Caruso M.D. of the University of Palermo, Italy, and colleagues, is published in Rejuvenation Research.

Filippa was a "semi-supercentenarian" of 106 years, born December 12, 1911 and who died July 6, 2018. Her sister Diega, born October 23, 1905 and who died June 15, 2019, was a supercentenarian, living until age 113. Among centenarians – those who see their 100th birthdays – only 1 in 1,000 makes it to 110. Only 27 supercentenarians are known in the world.

To continue reading, go to my DNA Science blog at Public Library of Science. 

In moments when I am not obsessively reading technical reports on COVID-19, my mind drifts to science fiction plots involving invaders. Do these films offer clues to how we can defeat the novel coronavirus SARS-CoV-2?

With the government-ordered CDC guidance for reopening delayed, dumbed-down, cut by an order of magnitude, and ignored, we need help, from anywhere, in protecting the vulnerable while restoring some economic normalcy.

The space invaders of the classic depictions either succumb to slowly-emerging natural weaknesses or we blow them up. But the scariest sci-fi theme to me isn't about monsters or microbes at all.

In the film Logan's Run, people over age 30 sacrifice themselves to save resources for the others.

To continue reading, go to my DNA Science blog at Public Library of Science. 

Sometimes it can be difficult to distinguish who left a pile of poop.

Humans who live in multi-cat or multi-canine households might run into this problem when trying to discover which diarrhea-stricken pet to haul off to the vet.

Similarly, a deposit of scat on a hiking trail can inspire vivid conversations on the origin of the feces. But an intrigued hiker without a phone or camera who wants to bring a friend back for a viewing may find the excrement dispersed beyond recognition from weather conditions and trampling. Only a DNA test might be able to identify the species of animal that left the deposit if contextual clues, like a nearby moose, aren't there.

CoproID

The microbial species found within excrement – the fecal microbiome – can reveal a lot about an animal.

To continue reading, go to my blog DNA Science, at Public Library of Science. 

One of the most terrifying aspects of the COVID-19 pandemic is that we don't know what makes one person die, another suffer for weeks, another have just a cough and fatigue, and yet another have no symptoms at all. Even the experts are flummoxed.

"I've been puzzled from the beginning by the sharp dichotomy of who gets sick. At first it was mostly older people with chronic disease, and then a young person with low risk would show up. It can be devastating and rapid in one individual but mild in another," said Anthony Fauci, MD, director of the National Institute of Allergy and Infectious Disease on a media webinar.

What lies behind susceptibility to COVID-19? Gender? Genetics? Geography? Behavior? Immunity? All of these factors may be at play, and they overlap.

To continue reading, go to Genetic Literacy Project, where this post first appeared.