Video: An overview of the monkeypox virus

Video: An overview of the monkeypox virus

Kalpana Pot walks us through the latest information on the monkeypox outbreak.

Leaps.org

Click below for an overview of everything you need to know about the latest status of monkeypox - in 58 seconds.



An Overview of Monkeypox with Kalpana Pot

An Overview of the Monkeypox Virus youtube.com

Kalpana Pot
Kalpana Pot is the youngest of three girls in a family full of doctors. Science and education were always of great value in her home. But performing arts was another passion for her, which is why she moved to LA to pursue acting after decades of dancing and singing. She’s appeared on numerous TV shows and national commercials, and will soon be co-hosting Wheel of Fortune Live. At the same time, Kalpana got to express her nerd love of astronomy by working weekends at Griffith Observatory. It was there that she found her love and skill in communicating science to people from all over the world, and has since continued to host space/science series. She has translated that onto digital platforms as well- running an outspoken space-page on TikTok, called TokNerdyToMe, and style and science page on Instagram. Unfortunately, much of her science communication these days is about debunking anti-science conspiracies. But she’s confident that the rise of educational content on social media will help this unfortunate problem in society. Outside of work, Kalpana loves her dogs and volunteers for animal organizations.
Scientists are making machines, wearable and implantable, to act as kidneys

Recent advancements in engineering mean that the first preclinical trials for an artificial kidney could happen soon.

Photo by Pavel Neznanov on Unsplash

Like all those whose kidneys have failed, Scott Burton’s life revolves around dialysis. For nearly two decades, Burton has been hooked up (or, since 2020, has hooked himself up at home) to a dialysis machine that performs the job his kidneys normally would. The process is arduous, time-consuming, and expensive. Except for a brief window before his body rejected a kidney transplant, Burton has depended on machines to take the place of his kidneys since he was 12-years-old. His whole life, the 39-year-old says, revolves around dialysis.

“Whenever I try to plan anything, I also have to plan my dialysis,” says Burton says, who works as a freelance videographer and editor. “It’s a full-time job in itself.”

Many of those on dialysis are in line for a kidney transplant that would allow them to trade thrice-weekly dialysis and strict dietary limits for a lifetime of immunosuppressants. Burton’s previous transplant means that his body will likely reject another donated kidney unless it matches perfectly—something he’s not counting on. It’s why he’s enthusiastic about the development of artificial kidneys, small wearable or implantable devices that would do the job of a healthy kidney while giving users like Burton more flexibility for traveling, working, and more.

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Carrie Arnold
Carrie Arnold is an independent public health journalist from Virginia.
With this new technology, hospitals and pharmacies could make vaccines and medicines onsite

New research focuses on methods that could change medicine-making worldwide. The scientists propose bursting cells open, removing their DNA and using the cellular gears inside to make therapies.

Adobe Stock

Most modern biopharmaceutical medicines are produced by workhorse cells—typically bacterial but sometimes mammalian. The cells receive the synthesizing instructions on a snippet of a genetic code, which they incorporate into their DNA. The cellular machinery—ribosomes, RNAs, polymerases, and other compounds—read and use these instructions to build the medicinal molecules, which are harvested and administered to patients.

Although a staple of modern pharma, this process is complex and expensive. One must first insert the DNA instructions into the cells, which they may or may not uptake. One then must grow the cells, keeping them alive and well, so that they produce the required therapeutics, which then must be isolated and purified. To make this at scale requires massive bioreactors and big factories from where the drugs are distributed—and may take a while to arrive where they’re needed. “The pandemic showed us that this method is slow and cumbersome,” says Govind Rao, professor of biochemical engineering who directs the Center for Advanced Sensor Technology at the University of Maryland, Baltimore County (UMBC). “We need better methods that can work faster and can work locally where an outbreak is happening.”

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Lina Zeldovich

Lina Zeldovich has written about science, medicine and technology for Popular Science, Smithsonian, National Geographic, Scientific American, Reader’s Digest, the New York Times and other major national and international publications. A Columbia J-School alumna, she has won several awards for her stories, including the ASJA Crisis Coverage Award for Covid reporting, and has been a contributing editor at Nautilus Magazine. In 2021, Zeldovich released her first book, The Other Dark Matter, published by the University of Chicago Press, about the science and business of turning waste into wealth and health. You can find her on http://linazeldovich.com/ and @linazeldovich.