NIBIB has established the Center for Biomedical Engineering Technology Acceleration—BETA Center, a new intramural research program to solve a range of medicine’s most pressing problems. The BETA Center will serve the wider NIH intramural research program as a biotechnology resource and catalyst for NIH research discoveries.

After years of research, an NIH-funded team has developed a wearable cardiac ultrasound imager that can non-invasively capture real-time images of the human heart. The prototype patch, which is about the size of a postage stamp, can be worn during exercise, providing valuable cardiac information when the heart is under stress.

Researchers have developed a new tool and technique that uses 'vortex ultrasound' -- a sort of ultrasonic tornado -- to break down blood clots in the brain. The new approach worked more quickly than existing techniques to eliminate clots formed in an in vitro model of cerebral venous sinus thrombosis (CVST). Source: North Carolina State University/Science Daily

Using state-of-the-art imaging technology, NIH-funded researchers have found the secret behind the glassfrog’s ability to become transparent, an effective form of camouflage. Future research may provide insights into disorders related to blood clotting or stroke in humans.

NIBIB-funded researchers at Northwestern Universtiy have created the first highly mature neurons from human induced pluripotent stem cells, a feat that opens new opportunities for medical research and potential transplantation therapies for neurodegenerative diseases and traumatic injuries. Source: Science Daily.

NIH has launched the Home Test to Treat program, an entirely virtual community health intervention that will provide free COVID-19 health services—at-home rapid tests, telehealth sessions and at-home treatments—in selected communities.

Researchers report that they have developed a new experimental pipeline to combine bacterial therapy with current cancer drugs. Their study, which explores resistance to bacterial therapy at the molecular level, has achieved better treatment efficacy without additional toxicity in laboratory models. Source: Columbia University School of Engineering and Applied Science/Science Daily

Using a specialized MRI sensor, engineers have shown that they can detect light deep within tissues such as the brain. Source: Massachusetts Institute of Technology/Science Daily

A team of engineers has developed a photoacoustic patch that can monitor biomolecules in deep tissues, including hemoglobin. It can perform 3D mapping of hemoglobin with a submillimeter spatial resolution in deep tissues, down to centimeters below the skin, versus other wearable electrochemical devices that only sense the biomolecules on the skin surface. Source: University of California - San Diego/Science Daily