Researchers have developed a first-of-its-kind small, flexible, stretchable bandage that accelerates healing by delivering electrotherapy directly to the wound site. The bandage also actively monitors the healing process and then harmlessly dissolves into the body after it is no longer needed.
Researchers have developed a twin-bioengine yeast micro/nanorobot with self-propelling and self-adaptive capabilities that can autonomously navigate to inflamed sites to provide gastrointestinal inflammation therapy via enzyme-macrophage switching.
Researchers develop a new method to keep dust from sticking to surfaces. The result is the ability to make many types of materials dust resistant, from spacecraft to solar panels to household windows.
Scientists demonstrated that when the nanomaterial - a double-atom catalyst - is mixed with a peroxide-based disinfectant, the disinfectant is two-to-four times more effective in disabling a coronavirus strain compared to when the disinfectant is used alone.
Development of ultrafast PCR technology using materials that generate heat when exposed to light. Expected for rapid diagnosis in pharmacies and clinics due to miniaturized device use.
Researchers have developed new technology that could usher in the next generation of thinner, higher-resolution and more energy efficient screens and electronic devices.
The study shows that the solvent in which the nanoparticles are suspended before the coating is applied determines the way in which the particles arrange themselves in the resulting layer. This means that the properties of the coating can be adapted to its intended use.
Researchers have developed principles and technologies of nanofluidic devices to freely manipulate nanomaterials, biomaterials, and molecules at the single-molecule level using fundamental technologies such as nanofluidic processing, functional integration, and fluidic control and measurement, which has pioneered the way to integrate various fields under nanofluidics.
