Researchers have reported a new patch—a combination of advanced electronics, living cells, and hydrogel—that is proving effective in mouse experiments.
Researchers from Xi'an Jiaotong University have made a significant breakthrough in biosensor technology, as reported in a recent study published in the journal Engineering.
Researchers in Nature Communications introduced an innovative design for soft robots that mimic skeletal muscles and sensory skins. These robots, integrating sensing and actuation capabilities, demonstrated potential in medical implants, dynamically responding to various stimuli for tasks such as drug delivery and cardiovascular monitoring.
Innovative multichannel microneedle dry electrode patches offer superior electrophysiological signal recording with high spatial resolution and reduced skin impedance. This technology promises significant improvements in clinical diagnostics and organ electrophysiology research.
Fabric-type wearable electronics offer comfort and adaptability, integrating flexible materials for advanced functionality. Recent studies highlight innovations in stability, energy storage, and dynamic features, paving the way for practical applications.
Researchers in China have developed a reprogrammable adhesive device patch that integrates advanced materials and laser processing for high-sensitive biosensing. This multifunctional patch aims to revolutionize personalized health monitoring and disease management through innovative, skin-interfaced electronics.
In a recent study published in ACS Sensors, researchers from the University of Chinese Academy of Science set out to design a TENG-based sensor that could be integrated into an MRI machine.
In a recent study published in Science, researchers from the University of Chicago have developed a prototype referred to as “living bioelectronics”- a gel, electronics, and living cell combination that can be integrated with living tissue.
A team of Penn State researchers has developed an adhesive sensing device that seamlessly attaches to human skin to detect and monitor the wearer's health.
Researchers in the United Kingdom have developed organic bioelectronic fibers that integrate seamlessly with biological tissues, aiming to create non-invasive platforms for health monitoring and environmental sensing.
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