In an article for The Wall Street Journal about efforts to help repair or prevent cartilage damage before osteoarthritis sets in, Laura Landro spotlights how MIT researchers are developing “ways to get drugs into the cartilage tissue and keep them there. They are using microscopic particles called nanocarriers to deliver IGF-1, an insulin like growth factor, to the tight mesh that holds cartilage in joints.”
TechCrunch reporter Devin Coldewey writes that MIT researchers have created a new nanoengineered material that could prove tougher than Kevlar or steel. “Made of interconnected carbon ‘tetrakaidecahedrons,’ the material absorbed the impact of microscopic bullets in spectacular fashion,” writes Coldewey.
MIT researchers have developed new programmable fibers that could help transform clothing into wearable computers, reports Kyle Mizokami for Popular Mechanics. “The polymer fibers contain hundreds of tiny silicon microchips that, once electrified, can sustain a digital connection across tens of meters,” Mizokami writes.
Forbes contributor Eric Tegler spotlights how MIT researchers are developing a fiber with digital capabilities. “Individuals wearing garments with digital fibers could be alerted to vital information about their physiology and environmental exposures, and share health/injury and location data with support forces,” Tegler explains.
Mashable spotlights how MIT’s baseball pitching coach is using motion capture technology to help analyze and teach pitching techniques. Using the technology, Coach Todd Carroll can “suggest real-time adjustments as a player is pitching so that just one session using the technology improves their game.”
UPI reporter Brooks Hays writes that researchers from MIT and other institutions have developed a programmable digital fiber that can capture, store and analyze data. The technology could “be paired with machine learning algorithms and used to make smart fabrics to record health data and aid medical diagnosis,” writes Hays.
The Economist spotlights how Colgate will be using the super slippery, food-safe coating developed by LiquiGlide, an MIT startup, to create a new line of toothpastes “that promise to deliver every last drop.” The Economist notes: “Besides pleasing customers who like to get their money’s worth, the new, slippery toothpaste tubes should help with recycling.”
LiquiGlide, an MIT startup, has announced several new partnerships aimed at developing sustainable, zero-waste packaging solutions, reports Janelle Nanos for The Boston Globe. “LiquiGlide wants to fix one of life’s longstanding frustrations: trying to squeeze out the end of a toothpaste tube,” writes Nanos. “Since it’s often difficult to empty out sticky pastes, gels, and creams, hundreds of millions of dollars worth of those substances are discarded annually, still stuck to the insides of their containers.”
Prof. Kripa Varanasi speaks with Boston 25 reporter Jim Morelli about a food-safe coating, called LiquiGlide, that makes it possible to squeeze every drop out of containers of items like ketchup and toothpaste. “It’s a universal kind of a problem,” Varanasi says. “The interface between the liquid and the solid is what makes these products stick to containers.”
Gizmodo reporter Andrew Liszewski writes that LiquiGlide, an MIT startup, is working with Colgate to introduce a “new recyclable toothpaste container that leverages LiquiGlide so that every last drop of the product can be squeezed out with minimal effort.”
Singapore-MIT Alliance for Research and Technology (SMART) researchers have developed a new lab-free immune profiling assay that can be used “to better profile aggressive, rapidly changing host immune response in cases of infection, for example COVID-19,” reports HealthCare Asia Daily.
A new assay developed by researchers from the Critical Analytics for Manufacturing Personalized-Medicine (CAMP), an Interdisciplinary Research Group (IRG) at the Singapore-MIT Alliance for Research and Technology (SMART), can profile the “rapidly changing host immune response in case of infection, in a departure from existing methods that focus on detecting the pathogens themselves,” reports the Scientific Inquirer.
Axios reporter Bryan Walsh spotlights how MIT researchers have developed a new way for chemical signals in spinach leaves to transmit emails. “The system could help provide an early warning system for explosives or pollution, but really, we just want to know what the spinach are thinking,” writes Walsh.
Fast Company reporter Adele Peters spotlights Prof. Michael Strano’s work exploring how to embed nanoparticles into plant leaves, as part of an effort to see if they could serve as sensors. “We started asking the question, can we make living plants to do some of the functions that humans do by stamping things out of plastic and circuit boards—things that go into landfills?” says Strano.
MIT researchers have developed a way to embed spinach leaves with sensors, which would allow them to serve as sensors that could monitor groundwater for contaminates, reports The Guardian. “Plants are very environmentally responsive,” explains Prof. Michael Strano. “If we tap into those chemical signaling pathways, there is a wealth of information to access.”