Scientists report preliminary results on a sweat sensor that acts as an early warning system for an impending cytokine storm, which could help doctors more effectively treat patients.
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Engineers have created a tiny wireless implant that can provide real-time measurements of tissue oxygen levels deep underneath the skin.
Researchers have created a machine learning model that helps identify bipolar disorder at earlier stages.
Many patients use their inhalers and insulin pens wrong. Researchers have developed a system to reduce those numbers for some types of medications.
World-first 3D printed oesophageal stents developed by the University of South Australia could revolutionize the delivery of chemotherapy drugs.
A deep learning model that can predict how human genes and medicines will interact has identified at least 10 compounds that may hold promise as treatments for COVID-19.
Scientists have developed an easy way to make millirobots by coating objects with a glue-like magnetic spray.
With the advent of pharmacogenomics, machine learning research is well underway to predict patients' drug response that varies by individual from the algorithms derived from previously collected data on drug responses.
Researchers have created a wearable sensor printed on microbial nanocellulose, a natural polymer.
Engineers have demonstrated that drug levels inside the body can be tracked in real time using a custom smartwatch that analyzes the chemicals found in sweat.
Akili announced that the U.S. Food and Drug Administration (FDA) has granted clearance for EndeavorRxTM (AKL-T01) as a prescription treatment for children with attention deficit hyperactivity disorder (ADHD).
Neurolutions IpsiHand exoskeleton uniquely leverages brain-computer interface technology for chronic stroke rehabilitation
The combination of a 2Photon 3D-printer with an innovative hydrogel-based bioink allows the direct printing of 3D structures containing living cells at both the meso- and microscale.
EPFL spin-off Readily3D has developed a novel system that can print biological tissue in just 30 seconds.
Artificial intelligence could help to optimise the development of antibody drugs. This leads to active substances with improved properties, also with regard to tolerability in the body.
Researchers have created life forms that self-assemble a body from single cells and do not require muscle cells to move. They're faster, live longer, and can now record information.
Researchers have shown that lab-created heart valves implanted in young lambs for a year were capable of growth within the recipient.
Researchers have developed a structurally representative liver-on-a-chip model which mimics the full progression sequence of NAFLD.
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.
A subset of wearables are the so-called hearables – in-ear devices that are well suited for long-term monitoring as they are non-invasive, inconspicuous and easy to fasten.
A small, wearable heart monitor can detect atrial fibrillation in high-risk patients ten times more frequently than standard tests.
Researchers have now developed and optimised a process for the isolation and purification of magnetic nanoparticles from bacterial cells.
Physicians who follow AI advice may be considered less liable for medical malpractice than is commonly thought, according to a new study of potential jury candidates in the U.S.
Revealing details of the internal structure of 'mini-brains' could help accelerate drug studies and may offer alternatives to some animal testing.
Scientists have developed a machine learning method that crunches massive amounts of data to help determine which existing medications could improve outcomes in diseases for which they are not prescribed.
The new device can continuously sense levels of virtually any protein or molecule in the blood. The researchers say it could be transformative for disease detection, patient monitoring and biomedical research.
NIH BRAIN Initiative scientists used machine learning to redesign a bacterial ‘Venus flytrap’ protein that can monitor brain serotonin levels in real time.
An AI platform derives an optimal combination of available therapies against SARS-CoV-2 - the optimal drug therapy was a combination of the drugs remdesivir, ritonavir, and lopinavir at specific doses.
Researchers have invented a high-throughput cell separation method that can be used in conjunction with droplet microfluidics.
Scientists have demonstrated a VR technique which should help in developing drugs against the SARS-CoV-2 virus – and enable researchers to share models and collaborate in new ways.
Researchers mechanically reprocess silk into a biologically compatible component of bioinks that improves the structural fidelity of 3D-printed hydrogels containing cells for use in drug development and regrowing lost or damaged body
A new algorithm that fast forwards simulations could bring greater use ability to current and near-term quantum computers.
Radiator-like fluid systems adjust the genetic wiring inside human liver cells in preliminary work toward artificial organ-tissue engineering.
Researchers have designed a wearable device that monitors sweat for biomarkers that could signal flare-ups of inflammatory bowel disease (IBD).
Researchers have created a machine learning algorithm that can detect subtle signs of osteoarthritis on an MRI scan taken years before symptoms even begin.
Researchers make the case that Artificial Intelligence tools have the potential to help researchers separate the wheat from the chaff.
Artificial intelligence is developing at an enormous speed and intelligent instruments will profoundly change surgery and medical interventions.
For the first time doctors have shown that measuring changes in 24-hour heart rate can reliably indicate whether or not someone is depressed.
AI is playing a key role in the Covid-19 response, but it could also be exacerbating inequalities within our health systems – a critical concern that is dragging the technology’s limitations back into the spotlight.
The development of new medical technologies based on cutting-edge discoveries has accelerated during the coronavirus pandemic.
Researchers have invented a new type of surgical glue that can help join blood vessels and close wounds faster and may also serve as a platform to deliver pain relief drugs.
Robotic surgery for patients with early stage, oropharyngeal squamous cell cancer is associated with improved health outcomes, including better long-term survival.
Researchers have shown that federated learning is successful in the context of brain imaging, by being able to analyze MRI scans of brain tumor patients and distinguish healthy brain tissue from cancerous regions.
Since mid-2019, the Fraunhofer IBMT has been developing an analysis platform as an alternative to animal experiments in drug development.
Researchers have developed a smart surface that can actively and repeatedly release and reabsorb substances by environmental stimuli.
Scientists have developed an experimental diagnostic test for COVID-19 that can visually detect the presence of the virus in 10 minutes.
Pathologists who examined the computationally stained images could not tell them apart from traditionally stained slides.
Researchers have developed a framework that will help data scientists and other researchers use better digital health tools for clinical purposes.
Researchers at the Max Planck Institute for Intelligent Systems in Germany have developed powerful nanopropellers that can be steered into the interior of cells to deliver gene therapy.
Radiologists are investigating people's medical conditions and pregnancies remotely thanks to an ESA-backed robotic technology.
Using machine learning, a team of Western computer scientists and biologists have identified an underlying genomic signature for 29 different COVID-19 DNA sequences.
3D printing fuels efforts to rapidly increase ventilator capacity while providing each patient on vent support with individually tailored gas pressures and pressure monitoring.
Researchers have developed a new approach to early diagnosis of lung cancer: a urine test that can detect the presence of proteins linked to the disease.
Researchers used a skin cream infused with microscopic particles, named STAR particles, for therapy of Skin diseases
Researchers have created a material with a unique set of properties, which could act as a replacement for human tissue in medical procedures.
“AI is the biggest technological breakthrough of our lifetime. It will boost the entire healthcare ecosystem and will eventually re-invent the way we deliver medicine entirely.”
Researchers demonstrated a methodology that combines the bioprinting and imaging of glioblastoma cells in a way that more closely models what happens inside the human body.
A coronavirus app coupled with machine intelligence will soon enable an individual to get an at-home risk assessment based on how they feel and where they've been in about a minute.
Rutgers University have devised a way to integrate microneedles with backward facing barbs, so that microneedle arrays can stay in place as long as needed.
Researchers developed a bullet-shaped, synthetic miniature robot which is acoustically propelled forward – a speeding bullet, in the truest sense of the word.
Using a computer algorithm, scientists at Uppsala University have identified a promising new treatment for neuroblastoma.
Researchers are using laser scalpels and precision robotics to make tattoo removal faster, more accurate and less painful.
An AI platform can analyze genomic data extremely quickly, picking out key patterns to classify different types of colorectal tumors and improve the drug discovery process.
Researchers have developed a novel methodology to provide non-invasive analysis of meniscal implants.
Researchers have developed a way to 3D print custom microswimmers that can transport drugs and nanotherapeutic agents, as well as potentially manipulate tissue directly inside the body.
Using machine learning, researchers have built a tool that detects genetic mutations that trigger the immune system, helping identify which cancer patients are likely to benefit from immunotherapy.
Scientists have successfully used microneedle biosensors to accurately detect changes in antibiotic levels in the body, for the first time.
Medical implants of the future may feature reconfigurable electronic platforms that can morph in shape and size dynamically.
Using a game, researchers are rehabilitating children who suffer from cognitive impairment after surviving life-threatening diseases such as malaria and HIV.
Scientists have now produced tiny diamonds, so-called "nanodiamonds", which could serve as a platform for both the therapy and diagnosis of brain diseases.
Researchers have developed an organ-on-an-electronic-chip platform, which uses bioelectrical sensors to measure the electrophysiology of the heart cells in three dimensions.
Researchers have developed biodegradable microresonators that could soon be used in implants to control the release of painkillers within tissue.
Scientists have found the perfect geometry: on a newly developed 3D silicone lattice, human stem cells will grow and behave in the same way as they do inside the human body.
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.
Using AI, researchers have succeeded in making the mass analysis of proteins from any organism significantly faster than before and almost error-free.
VR can identify early Alzheimer’s disease more accurately than ‘gold standard’ cognitive tests currently in use, suggests new research from the University of Cambridge.
A simple innovation the size of a grain of sand means we can now analyse cells and tiny particles as if they were inside the human body.
The current innovation process for medical technologies risks stifling the development of new devices, a leading researcher has argued.
Scientists have developed a new technique for the decontamination of organs before transplantation using ultraviolet and red light irradiation.
Engineers have combined CRISPR with electronic transistors made from graphene to create a new hand-held device that can detect specific genetic mutations in a matter of minutes.
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.
Researchers have built a device that could protect your pacemaker, other medical tech from remote hacks before they happen.
A machine learning algorithm was able to sort children with arthritis into distinct categories based on their patterns of inflamed joints in the body in a way that was also predictive of disease outcome.
Prototype web portal shows technology’s potential to protect and streamline the clinical trials process.
Researchers have developed an app that uses sonar to monitor someone's breathing rate and sense when an opioid overdose has occurred.
Researchers have developed a system using artificial intelligence to quickly diagnose and classify brain hemorrhages and to provide the basis of its decisions from relatively small image datasets.
Researchers have created a novel 3D printing workflow that allows cardiologists to evaluate how different valve sizes will interact with each patient's unique anatomy, before the medical procedure is actually performed.
Searching through the mountains of published cancer research could be made easier for scientists, thanks to a new AI system.
“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.
Scientists have developed machine learning algorithms that can predict yeast metabolism from its protein content.