Researchers in Canada have developed a cost-effective colorimetric indicator using electrospun nanofibers and anthocyanins to detect beef spoilage, providing a visual freshness cue in smart packaging.
This study introduces advanced biosensors using bismuth film-modified electrodes and dsDNA to accurately detect heavy metals in soils, crucial for environmental and human health protection.
Italian researchers developed a highly selective, enzyme-free electrochemical glucose sensor using carbon nanofibers functionalized with aromatic diamine, showing significant potential for healthcare and food industry applications.
A group of researchers from McMaster and the University of Waterloo have created a painless wearable sensor that can track blood sugar, lactate levels, and other vital health markers continuously and send the data to a smartphone or other device.
Researchers from Japan and China presented an innovative approach to integrate human trajectory data from cameras with sensor data from wearable devices in a study published in Sensors. Utilizing deep learning techniques like SyncScore, Fusion Feature, and SecAttention modules, the method significantly improves the accuracy of matching these data types, promising advancements in wearable sensor technology and comprehensive data analysis.
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.
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