Financial Times reporter Clive Cookson writes that MIT researchers have developed an ingestible pill that can deliver insulin directly to a patient’s stomach. “This discovery has the potential to transform not only drug delivery but drug discovery as well,” explains Prof. Robert Langer, “since most current drug discovery efforts are aimed at creating small molecule drugs that patients can take orally.”
MIT researchers have developed a new ingestible capsule that can release insulin directly into the stomach and could be used to treat type 2 diabetes, reports Joe Palca for NPR. "We chose the stomach as the site of delivery because we recognized that the stomach is a thick and robust part of the GI tract," explains visiting scientist Giovanni Traverso.
Wired reporter Megan Molteni writes that MIT researchers have developed an ingestible capsule that could be used to deliver insulin to diabetes patients. The researchers were inspired by the leopard tortoise to create a self-orienting device that can position itself to deliver medication directly into the stomach. “The result was a roly-poly-pill that autonomously rights itself to be needle-down,” Molteni explains.
Associated Press reporter Lauran Neergaard writes that MIT researchers have created a pea-sized pill that, once swallowed, can deliver medications such as insulin directly to the stomach. “The way this works is it travels down the esophagus in seconds, it’s in the stomach within a few minutes, and then you get the drug,” explains visiting scientist Giovanni Traverso.
Inspired by the shell of a leopard tortoise, MIT researchers have developed a self-orienting ingestible capsule that can deliver doses of medication to the stomach, writes Megan Thielking for STAT. “If we’re able to deliver large molecules orally, it would not only change drug delivery but also drug discovery,” says Prof. Robert Langer.
A team of MIT researchers has created a tiny ingestible device that deliver medications such as insulin directly to the stomach and could replace the daily injections used to treat diabetes patients, reports Alice Park for TIME. “We see no reason why someday this couldn’t be used to deliver any protein to the body,” says Prof. Robert Langer.
Boston Globe reporter Martin Finucane writes that MIT researchers have developed an ingestible capsule that contains a small needle that injects insulin directly into the stomach. Finucane writes that the researchers “designed the pill with a special shape to ensure that it will fall and then orient itself at the bottom of the stomach so that the needle is facing toward the stomach lining rather than the stomach’s inside.”
In this video, graduate student Nima Fazeli speaks with the BBC News about his work developing a robot that uses sensors and cameras to learn how to play Jenga. “It’s using these techniques from AI and machine learning to be able to predict the future of its actions and decide what is the next best move,” explains Fazeli.
CBS This Morning spotlights how MIT researchers have developed a new robot that can successfully play Jenga. “It is an automated system that has had a learning period first,” explains Prof. Alberto Rodriguez. “It uses the information from the camera and the force sensor to interpret its interactions with the Jenga tower.”
WCVB-TV’s Mike Wankum visits the Edgerton Center’s Area 51 machine shop to see how MIT students are developing cutting-edge technologies such as solar-powered vehicles, electric racing cars and other innovative devices in a space that Wankum calls “classic MIT.” “It’s really cool,” says third-year student Serena Grown-Haeberl. “You get to see those math equations really come to life.”
Writing for Forbes, Jeff Kart highlights how MIT researchers have developed a new technique to process samples of bacteria and gauge whether the bacteria can produce electricity. “The vision is to harness the most-powerful bacteria for tasks like running fuel cells or purifying sewage water,” Kart explains.
MIT researchers found that the silicone gloves football players wear are 20 percent stickier than a human hand, reports David Waldstein for The New York Times. Prof. Anette Hosoi explained that the “key to their performance was how soft and deformable the silicone is, meaning it covers and adheres to the tiniest variations on the surface of the ball,” writes Waldstein.
WCVB-TV’s Mike Wankum visits MIT to learn more about Prof. Nicholas Fang’s work developing a new film that can be coated on windows and can block up to 70 percent of incoming solar heat. Wankum explains that the film “could lead to a future with less need for air conditioning.”
MIT researchers have developed a remote-controlled ingestible capsule that can be operated by a user’s smartphone, reports the Xinhua news agency. “The researchers envisioned that this type of sensor could be used to diagnose early signs of disease and then respond with the appropriate medication,” Xinhua explains.
HealthDay News reporter E.J. Mundell writes that MIT researchers have developed an ingestible capsule that can be used to monitor health a patient’s health. “The capsule could deliver drugs as well as sense the condition of its surroundings in the gut, including infections or allergic reactions,” Mundell explains.