Combat, cancer and accidents can all cause devastating nerve injuries. Now, with help from the National Science Foundation, researchers at the University of Florida are working to use the latest technology to help the body regrow nerves.
On this episode of The Pulse, brought to you by MDT TV, we are regenerating limbs, building better brain implants, engineering 3D tissue, and measuring consciousness.
Atherosclerosis is a major cardiovascular disease involving accumulations of lipids, white blood cells, and other materials on the inside of artery walls. Since the calcification found in the advanced stage of atherosclerosis dramatically enhances the mechanical properties of the plaque, restoring the original lumen of the artery remains a challenge.
University of Washington engineers have created a new wireless communication system that allows devices to interact with each other without relying on batteries or wires for power. The new communication technique, which the researchers call “ambient backscatter,” takes advantage of the TV and cellular transmissions that already surround us around the clock.
Graduates of the Hebrew University’s Biodesign program revealed a robotic intubation device that automatically identifies the lungs using an infrared source and navigates toward it. The device was successfully tested on cadavers at Hadassah Medical Center, and clinical trials will begin as soon as next year.
As a child, Christina Stephens filled her parents' home with castles and pirate ships made of Legos. When she put her Lego-building skills to work to make a prosthetic leg out of the children's toy, she became an Internet sensation.
About 90% of successful cancer treatment is done through damaging, invasive procedures. The Italian Centro Nazionale di Adroterapia Oncologica (CNAO) is changing this. This video explains how hadron therapy allows, in many cases, the treatment of tumors that otherwise could not be treated.
During a Formula 1 race, a car sends hundreds of millions of data points to its garage for real-time analysis and feedback. So why not use this detailed and rigorous data system elsewhere, like ... at children’s hospitals?
Welcome to the Pulse, brought to you by MDT TV. Today, we're implanting an MRI-safe spinal cord stimulator, sorting blood with a microchip, building robots out of biocompatible hydrogel, and making hydrogel move with light.
Today, United Hatzlah uses a smartphone app and a fleet of “ambucycles” to help nearby patients until an ambulance arrives. With an average response time of 3 minutes, last year, they treated 207,000 people in Israel. And the idea is going global.
The handheld biosensor was developed by researchers at the University of Illinois, Urbana-Champaign. A series of lenses and filters in the cradle mirror those found in larger, more expensive laboratory devices. Together, the cradle and app transform a smartphone into a tool that can detect toxins and bacteria, spot water contamination and identify allergens in food.
Polyurethane studded with gold nanoparticles can conduct electricity even when stretched, Michigan engineers have discovered. This feat could pave the way for flexible electronics and gentler medical devices. The nanoparticles start out randomly arranged, but they drift into wire-like formations as the material is stretched.
U-M engineers have developed a new robotic tool which will make performing minimally invasive surgery cheaper and easier, but provides higher functionality over existing low-cost tools. The tool, called Flex Dex, acts as an extension of the surgeon's arm, allowing the doctor to control it with just a turn of the wrist.
At the Walter Reed National Military Medical Center, custom prosthetic attachments, cranial-facial implants, and surgical models are constantly being churned out, layer by layer, in an additive manufacturing process commonly referred to as 3D printing.
These digital musical instruments are designed in the form of prostheses to make music by utilizing the performer's movements in a non-traditional way. They were designed and created by Joe Malloch and Ian Hattwick at the Input Devices and Music Interaction Laboratory at McGill University.