Some “broken” nanomachines better sense their environment while others gain the ability to control their activity over time, Canadian researchers at Université de Montréal find.
Researchers at Nagoya University in Japan have used a new device to identify a key membrane protein in urine that indicates whether the patient has a brain tumor.
Gold nanorod probes combined with an optical microscope can now be used to detect signs of a highly contagious and lethal virus that poses a major threat to the swine industry worldwide.
Cedars-Sinai Cancer investigators have developed a new nanotechnology-based test that can detect and profile prostate cancers—even in microscopic amounts.
RUDN University biologist with colleagues from Iran and Thailand discovered the negative consequences of nanotechnology. Manufactured nanoparticles that help us produce new products are toxic to fish.
JMIR Publications is pleased to announce the expansion of their journal portfolio with JMIR Neurotechnology (JNT) a gold open access, peer-reviewed journal focused on the intersection between clinical neuroscience and technology to prevent, diagnose, and treat neurological disorders.
It’s ‘lights out’ for antibiotic-resistant superbugs as next-generation light-activated nanotech proves it can eradicate some of the most notorious and potentially deadly bacteria in the world.
UPTON, NY—Scientists at the U.S. Department of Energy’s (DOE) Brookhaven National Laboratory have successfully demonstrated that autonomous methods can discover new materials. The artificial intelligence (AI)-driven technique led to the discovery of three new nanostructures, including a first-of-its-kind nanoscale “ladder.
Morteza Mahmoudi, an assistant professor in MSU’s Department of Radiology, explains why addressing disagreements with stronger standards will help ensure future nanomedicines are safe, effective and successful.
A team at Ohio University used the Pittsburgh Supercomputing Center’s Bridges-2 system to carry out a series of simulations showing how coal might eventually be converted to valuable — and carbon-neutral — materials like graphite and carbon nanotubes.
Researchers at Columbia Engineering’s Lipson Nanophotonics Group have created visible lasers of very pure colors from near-ultraviolet to near-infrared that fit on a fingertip. The colors of the lasers can be precisely tuned and extremely fast – up to 267 petahertz per second, which is critical for applications such as quantum optics. The team is the first to demonstrate chip-scale narrow-linewidth and tunable lasers for colors of light below red -- green, cyan, blue, and violet.
As semiconductor devices become ever smaller, researchers are exploring two-dimensional materials for potential applications in transistors and optoelectronics. Controlling the flow of electricity and heat through these materials is key to their functionality, but first we need to understand the details of those behaviors at atomic scales. Now, researchers have discovered that electrons play a surprising role in how energy is transferred between layers of 2D semiconductor materials tungsten diselenide and tungsten disulfide.
Carnegie Mellon University’s Yongxin (Leon) Zhao and the Chinese University of Hong Kong’s Shih-Chi Chen have a big idea for manufacturing nanodevices.
Researchers at the Georgia Institute of Technology have developed a new graphene-based nanoelectronics platform that could be the key to finding a successor to silicon. The team may have also discovered a new quasiparticle. Their discovery could lead to manufacturing smaller, faster, more efficient, and more sustainable computer chips, and has potential implications for quantum and high-performance computing.
The way that silkworms wind their cocoons is now helping scientists more easily make new biomedical materials. Researchers in ACS’ Nano Letters have mimicked the seemingly simple head bobbing of silkworms to create more consistent micro- and nanofibers with less equipment than other approaches.
Researchers have developed a new method for discovering and making new crystalline materials with two or more elements. Such materials would be applicable to developing next-generation superconductors, microelectronics, batteries, magnets and more.
In new research published in Nature Communications, University of Sussex scientists demonstrate how a highly conductive paint coating that they have developed mimics the network spread of a virus through a process called 'explosive percolation' – a mathematical process which can also be applied to population growth, financial systems and computer networks, but which has not been seen before in materials systems.
Scientists from the Immanuel Kant Baltic Federal University found out that gold nanoparticles, covered by thin layer of silica, disperse light better than those that have thick “coat”
A new study involving researchers at the University of Illinois Chicago achieved a milestone in the synthesis of multifunctional photonic nanomaterials.
Argonne, along with five other national laboratories and 15 companies, has signed a pledge to double the energy efficiency of microelectronics every two years for 10 generations.
Columbia researchers invent new method to treat obesity by using cationic nanomaterials that can target specific areas of fat and inhibit the unhealthy storage of enlarged fat cells. “Our studies highlight an unexpected strategy to treat visceral adiposity and suggest a new direction of exploring cationic nanomaterials for treating metabolic diseases,” said Columbia Engineering’s Biomedical Engineering Prof Kam Leong, a pioneer in using polycation to scavenge pathogens.
When neurons are damaged by degenerative disease or injury, they have little, if any, ability to heal on their own. Restoring neural networks and their normal function is therefore a significant challenge in the field of tissue engineering. Prof. Orit Shefi and doctoral student Reut Plen from the Kofkin Faculty of Engineering at Bar-Ilan University have developed a novel technique to overcome this challenge using nanotechnology and magnetic manipulations, one of the most innovative approaches to creating neural networks.
NIBIB-funded researchers are fine-tuning a wearable, cuffless blood pressure monitor. Made of graphene, one of the thinnest materials in the world, the device is worn on the underside of the wrist and can measure blood pressure with comparable accuracy to a standard blood pressure cuff.
Researchers have built a unique, long-sought structure from gold nanoparticles. Alex Travesset of Iowa State and the Ames National Laboratory has the equations and illustrations to explain how it all happened. This new nanomaterial could have useful optical, mechanical and electronic characteristics.
Nanoengineers at the University of California San Diego’s Jacobs School of Engineering have developed an AI algorithm that predicts the structure and dynamic properties of any material—whether existing or new—almost instantaneously. Known as M3GNet, the algorithm was used to develop matterverse.ai, a database of more than 31 million yet-to-be-synthesized materials with properties predicted by machine learning algorithms. Matterverse.ai facilitates the discovery of new technological materials with exceptional properties.
Scientists at Argonne National Laboratory created a novel testbed to explore the behavior of electrons in a special class of materials called topological insulators, which could see applications in quantum computing.
A collaborative team of scientists from the Terasaki Institute for Biomedical Innovation and the University of Nebraska Medical Center has developed a fibrous aerogel that promotes faster and more effective healing of diabetic wounds.
Scientists have developed a new way to guide the self-assembly of a wide range of novel nanoscale structures using simple layered block copolymers as starting materials.
Sandia National Laboratories mechanical engineer Frank DelRio likes to think small — microscopically small. His groundbreaking work in nanomechanics and nanotribology earned him a trip to Pasadena, California, recently for the 2022 Hispanic Engineer National Achievement Awards Conference, where he was honored for his technical achievements.
A team of researchers at The University of Texas MD Anderson Center has developed a nanotechnology platform that can change the way the immune system sees solid tumor cells, making them more receptive to immunotherapy. The preclinical findings suggest this adaptable immune conversion approach has the potential for broad application across many cancer types.
In the field of molecular magnetism, the design of devices with technological applications at the nanoscale —quantum computing, molecular spintronics, magnetic cooling, nanomedicine, high-density information storage, etc.— requires those magnetic molecules that are placed on the surface to preserve their structure, functionality and properties.
Canadian chemists specializing in nanotechnology draw inspiration from nature to create molecular transporters that optimize the release of therapeutic drugs.
Transmission Electron Microscopy is essential for studying the micro- and nanostructure of inorganic, organic and hybrid materials. In inorganic samples, the instrument reveals the orientation and internal structure of crystal lattices down to individual atoms, as well as defects, such as dislocations or
grain boundaries. Transmission Electron Microscopy is the preferred method to directly measure the size, grain size, size distribution, and morphology of nanomaterials.
A Ludwig Cancer Research study has developed a novel nanotechnology that triggers potent therapeutic anti-tumor immune responses and demonstrated its efficacy in mouse models of multiple cancers.
Researchers at MIT have developed a technique for precisely controlling the arrangement and placement of nanoparticles on a material, like the silicon used for computer chips, in a way that does not damage or contaminate the surface of the material.
A study led by an Oregon State University pharmaceutical sciences researcher has produced a proof of principle for a new “universal” means of treating COVID-19.
In a pair of recently published papers, two independent research teams successfully used a powerful X-ray beam technique at the APS to uncover new insights about the dynamics of materials such as toothpaste and hair gel.
Although nanotechnology and materials science are complicated topics for most of us, the research in these fields is of great importance to almost everyone. Your digital gadgets, for example, are completely dependent on it.
MD Anderson and ARTIDIS today announced a strategic alliance to investigate ARTIDIS nanotechnology platform as a treatment-optimization tool for patients with solid tumors.
Since the initial discovery of what has become a rapidly growing family of two-dimensional layered materials — called MXenes — in 2011, Drexel University researchers have made steady progress in understanding the complex chemical composition and structure, as well as the physical and electrochemical properties, of these exceptionally versatile materials.
Researchers from Trinity College Dublin have shed new light on the formation of increasingly precious rare earth elements (REEs) by creating synthetic rocks and testing their responses to varying environmental conditions.
UC San Diego engineers have developed microscopic robots, called microrobots, that can swim around in the lungs, deliver medication and be used to clear up life-threatening cases of bacterial pneumonia. In mice, the microrobots safely eliminated pneumonia-causing bacteria in the lungs and resulted in 100% survival. By contrast, untreated mice all died within three days after infection.
Researchers are working to develop nanocarriers that deliver drugs across the blood brain barrier. Successful nanocarriers could lead to treatments for brain disorders including Alzheimer's disease, Parkinson’s disease, ischemic stroke, epilepsy and seizures.