This overview introduces smart insulin delivery systems and more innovations that help patients and doctors guide decision-making in diabetes care.
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The microneedles pierce the biofilm layer of a wound and deliver the medicine to oxygenate the tissue.
Purdue University engineers and physIQ have developed a viral detection algorithm for smartwatches.
Electronic skins will play a significant role in monitoring, personalized medicine, prosthetics, and robotics.
A 3D printed microneedle vaccine patch delivers stronger immune response than a vaccine shot.
Graphene represents incredible opportunities for advancement in many fields, including medical science.
Bioprinted 3D cardiac patches could reverse scar formation and promote myocardial regeneration after heart attacks.
Scientists have developed a new generation of microneedles technology which allows the intradermal delivery of living cells in a minimally invasive manner.
Researchers have developed a biobattery-powered device capable of both delivering large molecule pharmaceuticals across the skin barrier and extracting interstitial fluid for diagnostic purposes.
The patch, which can be folded around surgical tools, may someday be used in robotic surgery to repair tissues and organs.
Xsensio has been awarded CHF 1.8 million in EU funding to adapt its Lab-on-Skin sensing patches so that they can detect when a viral illness like the flu or COVID-19 is about to get worse.
Researchers have developed a microneedle patch for monitoring glucose levels using a paper sensor.
Artificial intelligence is developing at an enormous speed and intelligent instruments will profoundly change surgery and medical interventions.
Researchers have developed a wearable solution that allows a patient to receive treatment of antibiotic-resistant infections and woundswithout leaving home.
Researchers have developed a new form of electronics known as “drawn-on-skin electronics,” allowing multifunctional sensors and circuits to be drawn on the skin with an ink pen.
The Fraunhofer IBMT is developing the miniaturized ultrasound system for automated monitoring of bladder irrigation.
A deep learning powered single-strained electronic skin sensor can capture human motion from a distance.
Pathologists who examined the computationally stained images could not tell them apart from traditionally stained slides.
A way to incorporate electronic sensors into stretchy fabrics allows scientists to create shirts or other garments that could be used to monitor vital signs such as temperature, respiration, and heart rate.
Researchers used a skin cream infused with microscopic particles, named STAR particles, for therapy of Skin diseases
A wearable sensor could help doctors remotely detect critical changes in heart failure patients days before a health crisis occurs and could prevent hospitalization.
An AI has successfully found features in pathology images from human cancer patients, without annotation, that could be understood by human doctors.
NanoEDGE research project aims at converging production techniques for functionalized electrodes with expertise in nanomaterial fabrication and characterization.
An algorithm did better than experts radiologists at finding tiny brain hemorrhages in head scans — an advance that one day may help doctors treat patients with strokes.
Scientists have successfully used microneedle biosensors to accurately detect changes in antibiotic levels in the body, for the first time.
The first demonstration of a fully print-in-place electronics technique is gentle enough to work on surfaces as delicate as human skin and paper.
An AI tool identified breast cancer with approximately 90 percent accuracy when combined with analysis by radiologists.
Scientists created a 3D printed a wearable kirigami sensor patch for shoulders that could improve injury recovery and athletic training.
Scientists have developed a robot that looks and moves like a jellyfish; the aim is for Jellyfishbot to be applied in the treatment of cancer.
Machine enhanced humans – or cyborgs as they are known in science fiction – could be one step closer to becoming a reality.
Researchers have demonstrated that their technique can stop the catheter at the right target and identify the source type with a 95.25 percent success rate.
Researchers have have developed a multifaceted measuring technology that is able to detect a number of conditions in the human body.
The clinical trial to determine whether a smartwatch app that analyzes pulse-rate data can screen for a heart-rhythm disorder has enrolled more than 400,000 participants.
According to researchers in Sweden, a microneedle patch prototype proved to be a more comfortable and reliable blood-sugar monitoring system for people with diabetes.
Scientists created a flexible ultrasonic patch that non-invasively monitors the blood pressure in major vessels such as the jugular vein and carotid artery.
“The digital transformation will make healthcare even more human. It will enable us to provide preventive and personalized healthcare,” says Prof. Dr. Koen Kas, Professor of Oncology at Ghent University, Belgium.
By drawing in a bit of sweat, a patch developed in the lab of Alberto Salleo can reveal how much cortisol a person is producing. Cortisol is known as the stress hormone but is involved in many important physiological functions.