Stanching the free flow of blood from an injury remains a holy grail of clinical medicine. Controlling blood flow is a primary concern and first line of defense for patients and medical staff in many situations, from traumatic injury to illness to surgery. If control is not established within the first few minutes of a hemorrhage, further treatment and healing are impossible.
What began as research into a method to...
Lab-grown tissues could one day provide new treatments for injuries and damage to the joints,...
Tiny, soapy bubbles can reorganize their membranes to let material flow in and out in response to the surrounding environment, according to new research. This behavior could be exploited in creating microbubbles that deliver drugs or other payloads inside the body, and could help us understand how the very first living cells on Earth might have survived billions of years ago.
Researchers at the New York Univ. Polytechnic School of Engineering have broken new ground in the development of proteins that form specialized fibers used in medicine and nanotechnology. For as long as scientists have been able to create new proteins that are capable of self-assembling into fibers, their work has taken place on the nanoscale. For the first time, this achievement has been realized on the microscale.
Platelets, the tiny cell fragments whose job it is to stop bleeding, are very simple. They don’t have a cell nucleus. But they can “feel” the physical environment around them, researchers at Emory Univ. and Georgia Tech have discovered. Platelets respond to surfaces with greater stiffness by increasing their stickiness, the degree to which they “turn on” other platelets and other components of the clotting system, the researchers found.
Shellfish such as mussels and barnacles secrete very sticky proteins that help them cling to rocks or ship hulls, even underwater. Inspired by these natural adhesives, a team of Massachusetts Institute of Technology engineers has designed new materials that could be used to repair ships or help heal wounds and surgical incisions.
For detecting cancer, manual breast exams seem low-tech compared to other methods such as MRI. But scientists are now developing an “electronic skin” that “feels” and images small lumps that fingers can miss. Knowing the size and shape of a lump could allow for earlier identification of breast cancer, which could save lives.
Artificial membranes mimicking those found in living organisms have many potential applications ranging from detecting bacterial contaminants in food to toxic pollution in the environment to dangerous diseases in people. Now a group of scientists in Chile has developed a way to create these delicate, ultra-thin constructs through a "dry" process, by evaporating two commercial, off-the-shelf chemicals onto silicon surfaces.
A new class of synthetic platelet-like particles could augment natural blood clotting for the emergency treatment of traumatic injuries. The clotting particles, which are based on soft and deformable hydrogel materials, are triggered by the same factor that initiates the body’s own clotting processes.
The physical properties of the ultra-white scales on certain species of beetle could be used to make whiter paper, plastics and paints, while using far less material than is used in current manufacturing methods. Current technology is not able to produce a coating as white as these beetles can in such a thin layer, and spectroscopic analyses are revealing how this colorization is achieved through a dense complex network of chitin.
An Israeli and German research team have succeeded in creating a tiny screw-shaped propeller that can move in a gel-like fluid, mimicking the environment inside a living organism. The filament that makes up the propeller, made of silica and nickel, is only 70 nm in diameter. The entire propeller is just 400 nm long.
When a foreign material like a medical device or surgical implant is put inside the human body, the body usually reacts negatively. For the first time ever, researchers at Northwestern Univ. have created a biodegradable biomaterial that is inherently antioxidant. The material can be used to create elastomers, liquids that turn into gels, or solids for building devices that are more compatible with cells and tissues.
Vibrate a solution of rod-shaped metal nanoparticles in water with ultrasound and they'll spin around their long axes like tiny drill bits. Why? No one yet knows exactly. But researchers at the NIST have clocked their speed, and it's fast. At up to 150,000 revolutions per minute, these nanomotors rotate 10 times faster than any nanoscale object submerged in liquid ever reported.
A Univ. of Alabama start-up company, 525 Solutions, has received about $1.5 million from the federal government to refine an invention to extract uranium from the ocean for use as fuel. It is an adsorbent, biodegradable material made from the compound chitin, which is found in crustaceans and insects. The researchers have developed transparent sheets, or mats, comprised of tiny chitin fibers, which pull uranium from the water.
The common pencil squid may hold the key to a new generation of medical technologies that could communicate more directly with the human body. Materials science researchers in California have discovered that reflectin, a protein in the tentacled creature’s skin, can conduct positive electrical charges, or protons, making it a promising material for building biologically inspired devices.
Confined water exists widely and plays important roles in natural environments, particularly inside biological nanochannels. After several years of work, scientists in China have developed a series of biomimetic nanochannels that can serve as the base for confined transportation of water. The technology suggests a potential use in energy conversion systems.
Current drug delivery systems used to administer chemotherapy to cancer patients typically release a constant dose of the drug over time, but a new study challenges this "slow and steady" approach and offers a novel way to locally deliver the drugs "on demand," as reported in the Proceedings of the National Academy of Sciences.
When stem cells are used to regenerate bone tissue, many wind up migrating away from the repair site, which disrupts the healing process. But a technique employed by a Univ. of Rochester research team keeps the stem cells in place, resulting in faster and better tissue regeneration. The keyis encasing the stem cells in polymers that attract water and disappear when their work is done.
Artificial joints have a limited lifespan. After a few years, many hip and knee joints have to be replaced. More problematic are intervertebral disc implants, which cannot easily be replaced after they “expire” and are usually reinforced, which restrict a patient’s movement. Researchers in Switzlernad have now succeeded in coating mobile intervertebral disc implants so that they show no wear and will now last for a lifetime.
Traumatic bone injuries are often so severe that the body can’t effectively repair the damage on its own. To aid the recovery, clinicians inject patients with growth factors. The treatment is costly, requiring large amounts of expensive growth factors. The growth factors also disperse, creating unwanted bone formation around the injury. A new technology could provide more efficient delivery of the bone regenerating growth factors.
Crowding has notoriously negative effects at large size scales, blamed for everything from human disease and depression to community resource shortages. But relatively little is known about the influence of crowding at the cellular level. A new JILA study shows that a crowded environment has dramatic effects on individual biomolecules.
The mechanical properties of natural joints are considered unrivalled. Cartilage is coated with a special polymer layer allowing joints to move virtually friction-free, even under high pressure. Using simulations, scientists in Europe have developed a new process that technologically imitates biological lubrication and even improves it using two different types of polymers.
Rice Univ. bioengineers have created a hydrogel that instantly turns from liquid to semisolid at close to body temperature—and then degrades at precisely the right pace. The gel shows potential as a bioscaffold to support the regrowth of bone and other 3-D tissues in a patient’s body using the patient’s own cells to seed the process.
Researchers in Pennsylvania have created an artificial chemical sensor based on one of the human body’s most important receptors, one that is critical in the action of painkillers and anesthetics. In these devices, the receptors’ activation produces an electrical response rather than a biochemical one, allowing that response to be read out by a computer.
Researchers in New York have been able to, for the first time, generate fully functional human cartilage from mesenchymal stem cells by mimicking, in vitro, the developmental process of mesenchymal condensation. While there has been great success in engineering pieces of cartilage using young animal cells, no one has, until now, been able to reproduce these results using adult human stem cells from bone marrow or fat.
In the fight against “superbugs,” scientists have discovered a class of agents that can make some of the most notorious strains vulnerable to the same antibiotics that they once handily shrugged off. Recently discovered metallopolymers, when paired with the same antibiotics MRSA normally dispatches with ease, helped evade the bacteria’s defensive enzymes and destroyed its protective walls, causing the bacteria to burst.
Synthetic collagen invented at Rice Univ. may help wounds heal by directing the natural clotting of blood. The material, KOD, mimics natural collagen, a fibrous protein that binds cells together into organs and tissues. It could improve upon commercial sponges or therapies based on naturally derived porcine or bovine-derived collagen now used to aid healing during or after surgery.
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