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Popular Science

MIT researchers have developed a new drug delivery capsule that can deliver medication over extended periods of time, reports Claire Maldarelli for Popular Science. Once in the stomach, the capsule opens into a star shape, which “prevents the pill from leaving the stomach and entering the small intestine.”

Boston Magazine

Researchers at MIT have developed a slow-release drug capsule that can last two weeks in a person’s stomach, writes Jamie Ducharme for Boston Magazine. “The capsule was tested for use in malaria prevention, but the researchers behind it say it could be used for virtually any condition that requires regular oral medication,” Ducharme explains.

Reuters

Reuters reporter Kate Kelland writes that MIT researchers have created a new drug-delivery capsule that can stay in the stomach for up to two weeks after being swallowed. The star-shaped device could be “a powerful weapon in fighting malaria, HIV and other diseases where successful treatment depends on repeated doses of medicine.”

Los Angeles Times

MIT researchers have developed a star-shaped, drug-delivery device that can stay in the stomach for up to two weeks, gradually releasing medication, reports Melissa Healy for The Los Angeles Times. The researchers believe the device could be useful in “delivering a wide range of medications for diseases in which patient non-adherence is a problem.”

Straits Times

Straits Times reporter Nadia Chevroulet writes that researchers from MIT and the Singapore-MIT Alliance for Research and Technology (SMART) have uncovered how certain bacteria evade the body’s defenses. The findings could provide “new ways to counter tuberculosis, and possibly a new generation of drugs to battle antibiotic resistance.”

Guardian

Ian Sample of The Guardian writes that the Human Cell Atlas project, which will be co-led by the Broad Institute, aims to map the cells in the human body . “This will have a substantial impact on our scientific understanding and as a result, on our ability to diagnose, monitor and treat disease,” says Prof. Aviv Regev. 

Reuters

Researchers from the Broad Institute will co-lead an initiative aimed at mapping and describing every cell in the human body, writes Kate Kelland of Reuters. "We now have the tools to understand what we are composed of, which allows us to learn how our bodies work, and uncover how all these elements malfunction in disease," explains Prof. Aviv Regev.

Boston Magazine

MIT researchers have developed a new technique to stop the spread of cancer cells through the body by delivering microRNAs to the site of the primary tumor, reports Hallie Smith for Boston Magazine. The technique “may correct gene disruptions that put a patient at risk of metastatic cancer,” Smith explains. 

ABC News

ABC News reporter Gillian Mohney writes that Prof. Lydia Bourouiba has captured footage of a person sneezing, showing how far sneeze droplets can travel. Bourouiba found that “large droplets tended to land within 1 to 2 meters (about 3 to 6 feet) and that small droplets could get as far as 6 to 8 meters away (19 to 26 feet).”

NPR

Prof. Lydia Bourouiba has published a new slow-motion video of a person sneezing as part of her research into how sneezes spread disease, reports Rae Ellen Bichell for NPR. Bichell explains that Bourouiba’s research is aimed at better understanding “how to prevent microbes from moving from a sick person or contaminated surface to somebody else.”

Reuters

MIT researchers have developed a portable system that could produce biotech drugs on demand, reports Lisa Rapaport for Reuters. “The table-top machine has the potential to one day produce proteins to treat any number of a wide range of conditions like cancer, diabetes, heart attacks, and hemophilia,” writes Rapaport. 

Associated Press

Prof. Susan Lindquist has been named a recipient of the Albany Medical Center Prize in Medicine and Biomedical Research, according to the AP. Lindquist’s research has raised hopes that “treatments could prevent protein ‘misfolding’ that drives degenerative conditions like Alzheimer's, Parkinson's and Lou Gehrig's disease.”

Boston Magazine

A portable device developed by MIT researchers uses programmable yeast to create drugs on demand, reports Jamie Ducharme for Boston Magazine. The device “could be a lifesaver for doctors working in vulnerable conditions, such as the battlefield, a remote village, or even an ambulance,” writes Ducharme. 

Bloomberg News

Prof. Polina Anikeeva speaks with Cory Johnson of Bloomberg West about the emerging field of bioelectronics. Concerning future applications of bioelectronics, Anikeeva says that she thinks “we will start seeing more and more devices coming in and being implanted into various parts of the nervous system to treat disorders we haven’t even thought of before as neurological.”

Reuters

MIT researchers have developed a programmable vaccine that could be used to respond to disease outbreaks, reports Ben Gruber for Reuters. The vaccine harnesses “messenger RNA, a genetic material that can be programmed to fight any viral, bacterial or parasitic disease by provoking an amplified immune response.”