Lifeboat Foundation

Network partner Ben Angel previews the second season of his series, ‘Becoming Unstoppable.’

Smart watches. Pacemakers. Internet-connected glasses. These are devices designed to make life easier. And yet, all this wearable technology can be hacked. The devices send personal health information to your smartphone over the airways, so anyone with the know-how could scoop it up and steal it. But now, researchers at Northeastern have a better, more secure idea: Send data through your body.

Associate professor Kaushik Chowdhury worked with a team of researchers from the Draper Laboratory in Cambridge, Massachusetts, and the Federal University of Paraná in Brazil to develop a safe, hacker-proof method to transmit sensitive data.

“The truth is, no matter what I do when it comes to wireless devices, I’m radiating the signal through the air,” Chowdhury says. “There is the danger that the signal can be jammed, or analyzed by someone else. Our method secures this sensitive information so it can’t be leaked.”

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Circa 2015

Echo Labs uses light and a clever algorithm to measure oxygen and CO₂ in the blood stream.

We’re used to the security risks posed by someone hacking into our computers, tablets, and smartphones, but what about pacemakers and other implanted medical devices? To help prevent possible murder-by-hacker, engineers at Purdue University have come up with a watch-like device that turns the human body into its own network as a way to keep personal technology private.

A team of researchers led by Dr. Nazmul Karim and Prof Sir Kostya Novoselov at The University of Manchester have developed a method to produce scalable graphene-based yarn.

Multi-functional wearable e-textiles have been a focus of much attention due to their great potential for healthcare, sportswear, fitness and aerospace applications.

Graphene has been considered a potentially good material for these types of applications due to its high conductivity, and flexibility. Every atom in graphene is exposed to its environment allowing it to sense changes in its surroundings, making it an ideal material for sensors.

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Michelle Khine is a professor of biomedical engineering at the University of California, Irvine. Nine months ago, her newborn son was hospitalized for complications during childbirth and was admitted to the neonatal intensive care unit (NICU). While in the NICU, her son was connected to several machines that were supplying oxygen and monitoring his breathing.

A biomedical engineering research team from the University of California has developed a new wearable respiratory sensor to monitor children with chronic pulmonary conditions. The design was built with inspiration from a favorite childhood toy, Shrinky Dinks.

Recently University of Glasgow developed a Graphene based E-Skin for prosthetic limbs. The research started with making a prosthetic arm that could sense even the minutest of pressure for gripping soft objects. It eventually yielded a prosthetic limb that was also self powering.

This was because of the development of Graphene based supercapacitors.

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Circa 2016

UNIVERSITY PARK, Pa. — Electronic materials have been a major stumbling block for the advance of flexible electronics because existing materials do not function well after breaking and healing. A new electronic material created by an international team, however, can heal all its functions automatically even after breaking multiple times. This material could improve the durability of wearable electronics.

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The portable, wearable peritoneal dialysis device by Singapore-based AWAK Technologies is intended for patients with end-stage renal disease as an alternative to long hours of connection to large dialysis machines.