Researchers at Seoul National University of Science and Technology (SEOULTECH) have developed a groundbreaking tactile sensing platform using 3D-printed auxetic mechanical metamaterials (AMMs), which could significantly enhance the performance of wearable pressure sensors. Auxetic materials are known for their unusual […]
3D-Printed Metamaterials Power Next-Gen Pressure Sensors for Wearables Read More »
A research team at Waseda University has developed a new class of wearable sweat sensors that mimic the microtexture of rose petals—offering improved comfort, stability, and reusability for health monitoring. These bio-inspired sensors could transform how we track hydration, electrolyte
Rose-Inspired Sweat Sensors Offer Comfortable, Reusable Health Monitoring Read More »
Researchers at Radboud University Medical Center have developed a wearable device that could significantly improve mobility and independence for people living with ataxia—a neurological condition that impairs coordination and balance. The device, called the “Gyropack”, is a backpack equipped with gyroscopic
Gyroscopic Backpack Improves Balance for People with Ataxia Read More »
A research team at the University of Minnesota has developed a groundbreaking approach to spinal cord injury treatment by combining 3D printing, stem cell biology, and lab-grown tissues. Their innovation centers on a specially designed 3D-printed scaffold that guides nerve
3D-Printed Scaffolds Help Regrow Nerves After Spinal Cord Injury Read More »
Harvard University researchers have developed a soft, wearable robotic device that adapts to the unique movement patterns of individuals with upper-limb impairments—such as those caused by stroke or ALS. This next-generation assistive robot uses machine learning and physics-based modeling to
Wearable Robot Learns to Support Stroke and ALS Patients Read More »
Researchers at the Fraunhofer Institute for Machine Tools and Forming Technology (IWU) have developed a highly personalized hand exoskeleton designed to help people regain mobility after injuries, strokes, or neurological conditions. Unlike generic rehabilitation devices, this exoskeleton is custom-built to
Custom Hand Exoskeletons Help Patients Regain Movement and Independence Read More »
A comprehensive review published in Advanced Science has mapped the evolution of implantable brain-computer interfaces (iBCIs), which decode brain signals to control external devices like robotic limbs or communication tools. The study identified 112 trials involving 80 participants, nearly half published since
Global Review Maps the Future of Implantable Brain-Computer Interfaces Read More »
MIT researchers have unveiled a new bionic knee system that could redefine prosthetic integration for people with above-the-knee amputations. Unlike traditional socket-based prostheses, which often feel like external tools, this system is anchored directly into the user’s bone and muscle
MIT’s Tissue-Integrated Prosthesis Restores Natural Movement Read More »
Researchers at Penn State have developed a flexible, skin-like sensor that can monitor both physical movement and electrical signals—internally and externally. Designed to mimic the properties of human skin, the device combines electrical and ionic conductivity, allowing it to interface
Skin-Like Biosensor Monitors Both Physical Movement and Electrical Signals in the Body Read More »
Joint health is notoriously difficult to track outside of clinical settings. Traditional methods for measuring joint torque—how much force a joint exerts—are often bulky, lab-bound, or too imprecise for real-world use. Now, researchers from the University of Oxford and University
AI-Enabled Piezoelectric Wearable Monitors Joint Torque Read More »
