Wearable sensors are evolving from watches and electrodes to bendable devices that provide far more precise biometric measurements and comfort for users. Now, an international team of researchers has taken the evolution one step further by printing sensors directly on human skin without the use of heat.
Led by Huanyu “Larry” Cheng, Dorothy Quiggle Career Development Professor in the Penn State Department of Engineering Science and Mechanics, the team published their results in ACS Applied Materials & Interfaces.
“In this article, we report a simple yet universally applicable fabrication technique with the use of a novel sintering aid layer to enable direct printing for on-body sensors,” said first author Ling Zhang, a researcher in the Harbin Institute of Technology in China and in Cheng’s laboratory.
Cheng and his colleagues previously developed flexible printed circuit boards for use in wearable sensors, but printing directly on skin has been hindered by
The two women who developed the CRISPR gene-editing technique have won the 2020 Nobel Prize in Chemistry, the Nobel Committee announced today. The French scientist Emmanuelle Charpentier and American scientist Jennifer A. Doudna were awarded the world’s most prestigious science recognition “for the development of a method for genome editing.” It’s the first time that two women have shared the Nobel Prize.
BREAKING NEWS: The 2020 #NobelPrize in Chemistry has been awarded to Emmanuelle Charpentier and Jennifer A. Doudna “for the development of a method for genome editing.” pic.twitter.com/CrsnEuSwGD
Charpentier and Doudna discovered the CRISPR “genetic scissors” editing technique in 2012. Since then there has been an explosion of research around the world using their discovery. Already their technique has allowed scientists to create crops that can withstand drought and pests, and it is believed that one day CRISPR will allow for
Northvale, NJ, Oct. 06, 2020 (GLOBE NEWSWIRE) — via NewMediaWire — ADM Tronics Unlimited, Inc. (OTCQB: ADMT) has been advised that Origin, Inc. filed an Investigational Device Exemption (“IDE”) application with the FDA to conduct clinical studies to treat patients diagnosed with COVID-19 with its plasma-generated nitric oxide (“NO”) technology. ADMT has been developing and has manufactured for Origin, Inc. the IonoJet™, which allows for targeted delivery of NO generated by a thermal plasma, produced from room air at the point of therapy.
Michael Preston, Chairman and President of Origin, Inc., stated, “Like other nitric oxide companies, we have recognized the potential ability of NO to stop the replication of corona viruses. We believe there may be limitations with other approaches, and we have worked to address these in a novel system that is designed to allow NO to be administered effectively. ADMT has been key to our development and
Through the development of new technology, University of Minnesota researchers have developed a method that allows scientists to understand how a fruit fly’s brain responds to seeing color. Prior to this, being able to determine how a brain responds to color was limited to humans and animals with slower visual systems. A fruit fly, when compared to a human, has a visual system that is five times faster. Some predatory insects see ten times faster than humans.
“If we can understand how seeing color affects the brain, we will be able to better understand how different animals react to certain stimuli,” said Trevor Wardill, the study’s lead author and assistant professor in the College of Biological Sciences. “In doing so, we will know what interests them most, how it impacts their behavior, and what advantages different color sensitivities may give to an individual’s or a species’ survival.”
Researchers from RMIT University have developed an eco-friendly zero-cement concrete, which all but eliminates corrosion.
Concrete corrosion and fatbergs plague sewage systems around the world, leading to costly and disruptive maintenance.
But now RMIT engineers have developed concrete that can withstand the corrosive acidic environment found in sewage pipes, while greatly reducing residual lime that leaches out, contributing to fatbergs.
Fatbergs are gross globs of congealed mass clogging sewers with fat, grease, oil and non-biodegradable junk like wet wipes and nappies, some growing to be 200 metres long and weighing tonnes.
These build-ups of fat, oil and grease in sewers and pipelines, as well as general corrosion over time, costs billions in repairs and replacement pipes.
The RMIT researchers, led by Dr Rajeev Roychand, created a concrete that eliminates free lime — a chemical compound that promotes corrosion and fatbergs.
Researchers from NUS have developed a smartphone-powered suit that is capable of providing athletes with physiological data, including information on their posture, running gait, and body temperature while they are performing. The team says athletes are always looking for new ways to push human performance and to be able to improve the need to know their current limits objectively so they can overcome them. Current ways that athletes can track performance include wearables, such as the Apple Watch or Fitbit.
Better performing systems are available, but typically include tangles of wire and are too bulky to be used outdoors. The researchers sat about developing a system optimized for collecting data on athletes in the outdoor environment during performance using multiple sensors at different points on the body. One major goal was to reduce the system’s bulk, weight, and wires to an absolute minimum.
The colloidal diamond has been a dream of researchers since the 1990s. These structures — stable, self-assembled formations of miniscule materials — have the potential to make light waves as useful as electrons in computing, and hold promise for a host of other applications. But while the idea of colloidal diamonds was developed decades ago, no one was able to reliably produce the structures. Until now.
Researchers led by David Pine, professor of chemical and biomolecular engineering at the NYU Tandon School of Engineering and professor of physics at NYU, have devised a new process for the reliable self-assembly of colloids in a diamond formation that could lead to cheap, scalable fabrication of such structures. The discovery, detailed in “Colloidal Diamond,” appearing in the September 24 issue of Nature, could open the door to highly efficient optical circuits leading to advances in optical computers and lasers, light filters that