Forbes contributor Bruce Y. Lee writes that MIT researchers have found that lack of sleep can affect a person’s gait and that catching up on sleep can improve gait control for those who are chronically sleep deprived. Lee writes that the findings demonstrate how, “lack of sleep may affect your ability to move your body and navigate in subtle ways.”
Reporting for the PBS NewsHour, Miles O’Brien visits alumnus Dexter Ang ‘05 to learn more about how his startup, Pison, is developing a wrist-worn sensor that detects the faint electrical signals controlling simple hand gestures, allowing users to control digital interfaces using brain signals. “The device is connected to a smartphone, allowing control of it or other devices, conveyor belts in factories, drones, even pinball machines, to name a few,” notes O’Brien. He adds that Ang was inspired by his late mother, who contracted ALS, as “he wanted to make her life easier.”
Professor Xuanhe Zhao and his colleagues have developed a new soft robotic prosthetic hand that offers the wearer more tactile control. “You can use it to grab something as thin and fragile as a potato chip, or grasp another hand in a firm-but-safe handshake,” writes Mark Wilson for Fast Company. “By design, this rubbery, air-filled hand is naturally compliant.”
Matthew Shifrin writes for The Boston Globe about his personal experience using the TRANSFORM device created by the Tangible Media Group, an interactive display that fuses technology and design to render 3-D models in real-time. Shifrin, who is blind, notes that TRANSFORM allowed him “to track facial expressions like a sighted person would, and its larger size lets me feel the nuances that I can’t feel on a real face.”
Dezeen reporter Rima Sabina Aouf writes that MIT researchers have created an inflatable prosthetic hand that can be produced for a fraction of the cost of similar prosthetics. “The innovation could one day help some of the 5 million people in the world who have had an upper-limb amputation but can't afford expensive prostheses.”
Engineers at MIT have developed a soft, inflatable, neuroprosthetic hand that allows users to carry out a variety of tasks with ease, reports Emmett Smith for Mashable. “People who tested out the hand were able to carry out quite complex tasks, such as zipping up a suitcase and pouring a carton of juice.”
CBS Boston’s Liam Martin visits with Dianne Vitkus, a surgical physical assistant who was paralyzed in a fall last summer and recently received a Freedom Chair, an off-roading wheelchair developed by GRIT, an MIT startup. “The technology is simple. There’s a lever on each side that connects to a bike chain and allows Dianne to propel the chair,” says Martin. “It also has heavy-duty tires and a front wheel for stability.”
Boston Globe reporter Nate Weitzer spotlights the GRIT Freedom Chair, an all-terrain wheelchair developed by Global Research Innovation and Technology, an MIT startup. “The GRIT Freedom Chair can go where regular wheelchairs can’t – including grass, mud, or rocky terrain,” writes Weitzer. “For athletes who use wheelchairs, it offers the opportunity to compete in events such as a Spartan Race, or the ability to join friends on a hike or a beach day.”
7 News spotlights how MIT researchers have developed a new wearable sensor that can be used to help people with ALS communicate. “The wearable technology, known as Comfortable Decoders, recognizes tiny facial movements that can help patients communicate simple statements, like ‘I’m hungry’ or ‘I love you.’”
Smithsonian reporter Emily Matchar spotlights AlterEgo, a device developed by MIT researchers to help people with speech pathologies communicate. “A lot of people with all sorts of speech pathologies are deprived of the ability to communicate with other people,” says graduate student Arnav Kapur. “This could restore the ability to speak for people who can’t.”
TechCrunch reporter Darrell Etherington writes that MIT researchers have developed a system that can predict a perso's trajectory. The tool could allow “robots that typically freeze in the face of anything even vaguely resembling a person walking in their path to continue to operate and move around the flow of human foot traffic."
WCVB-TV’s Mike Wankum visits the Media Lab to learn more about a new wearable device that allows users to communicate with a computer without speaking by measuring tiny electrical impulses sent by the brain to the jaw and face. Graduate student Arnav Kapur explains that the device is aimed at exploring, “how do we marry AI and human intelligence in a way that’s symbiotic.”
Fast Company reporter Eillie Anzilotti highlights how MIT researchers have developed an AI-enabled headset device that can translate silent thoughts into speech. Anzilotti explains that one of the factors that is motivating graduate student Arnav Kapur to develop the device is “to return control and ease of verbal communication to people who struggle with it.”
Quartz reporter Anne Quito spotlights how graduate student Arnav Kapur has developed a wearable device that allows users to access the internet without speech or text and could help people who have lost the ability to speak vocalize their thoughts. Kapur explains that the device is aimed at augmenting ability.
Axios reporter Ina Fried spotlights how graduate student Arnav Kapur has developed a system that can detect speech signals. “The technology could allow those who have lost the ability to speak to regain a voice while also opening up possibilities of new interfaces for general purpose computing,” Fried explains.