Prof. Lydia Bourouiba has modeled how droplets are formed after a person sneezes, reports Jonathan Webb for BBC News. “The process is important to understand because it determines the various sizes of the final droplets - a critical factor in how a sneeze spreads germs,” writes Webb.
MIT researchers have found that the high-velocity cloud created by the average human sneeze can contaminate a room in minutes, writes Robert Preidt for U.S. News & World Report. Sneeze droplets "undergo a complex cascading breakup that continues after they leave the lungs, pass over the lips and churn through the air," explains Prof. Lydia Bourouiba.
Lincoln Lab researcher Albert Swiston speaks on NPR’s All Things Considered about the new sensor developed by MIT researchers that monitors vital signs through the gastrointestinal tract. “There are some bits of information from the body—namely the temperature of the body—that can only be monitored from inside the body,” explains Swiston.
Researchers at MIT and Massachusetts General Hospital have developed an ingestible device that monitors vital signs, reports Dialynn Dwyer of Boston.com. Dwyer explains that the device is a “pill-sized stethoscope with a microphone that, once swallowed, transmits data from inside the body.”
Writing for Popular Science, Lindsey Kratochwill reports that MIT researchers have discovered that the hundreds of eyes on a chiton's shell can see. Kratochwill explains that the researchers hope that by “understanding how these eyes work and the materials that make them up could lead to manmade materials that are both protective and perceptive of their environments.”
Atlantic reporter Ed Yong writes that MIT researchers have found that chitons, a type of mollusk, have a suit of armor dotted with hundreds of eyes that can perceive objects. The researchers found that chitons could “detect the shape of a 20-centimeter fish from a few meters away.”
LiveScience reporter Megan Gannon writes that MIT conservator Jana Dambrogio will virtually unfold a trove of unopened letterlocked notes from the 17th century. The researchers will use techniques like “3D X-ray microtomography to scan the letters and reconstruct the letterlocking strategies,” Gannon explains. “They'll also use scans to detect the ink and reconstruct the text inside.”
Nidhi Subbaraman reports for BetaBoston that MIT researchers have devised an ingestible microphone that allows doctors to monitor a patient’s vital signs. “A key innovation was developing algorithms that would distinguish important signals…from the noisy gurgling of the gut, and then translate them into numbers a physician can read and understand,” writes Subbaraman.
Researchers at MIT have developed an ingestible sensor that can measure vital signs without any external contact, reports Emily Reynolds for Wired. “The sensor works by using microphones—like ones found in mobile phones—that are able to pick up sound waves from the heart and lungs,” writes Reynolds.
Writing for The Boston Globe, Nancy Shohet West highlights Prof. Erik Demaine and Martin Demaine’s paper sculptures, which are on display at the Concord Center for the Visual Arts. “We started getting interested a number of years ago in curve creases and what was possible mathematically,” explains Prof. Demaine. “We started making models and then turned those into sculpture.”
Emily Reynolds reports for Wired that NASA has awarded an R5 “Valkyrie” humanoid robot to a team led by Prof. Russ Tedrake. Reynolds explains that the team “will develop algorithms to make the robot more dexterous” so that they could potentially take the place of humans during extreme space missions.
A team led by Prof. Russ Tedrake has been awarded one of NASA’s R5 “Valkyrie” robots to develop software that could allow humanoid machines to assist astronauts in space, reports Rachel Feltman for The Washington Post. Feltman writes that Tedrake’s team was awarded the robot based on its strong performance in the DARPA Robotics Challenge.
NASA has awarded two humanoid robots to research groups at MIT and Northeastern, reports Brian Mastroianni for CBS News. The robots “are seen as potential tools to aid astronauts in future Mars expeditions,” writes Mastroianni. “They could potentially assist or even replace humans in extreme environments.”
Alexandra Ossola of Popular Science reports on an ingestible sensor that allows doctors to monitor vital signs by listening to the body’s gastrointestinal tract. The device could help treat “chronic illnesses, monitor soldiers in battle, or even help athletes train more effectively,” writes Ossola.
MIT researchers have developed an ingestible sensor that can monitor vital signs, reports Rae Ellen Bichell for NPR. "Trauma patients are a really clear winner here, because we can do vital sign monitoring without touching the skin," says Albert Swiston of Lincoln Laboratory.