Biomedical

Researchers at the Massachusetts Institute of Technology and Friedrich-Alexander University of Erlangen–Nuremberg in Germany have developed novel magnetic nanodiscs that could provide a less invasive way of stimulating parts of the brain, paving the way for stimulation therapies without implants or genetic modification. Deep brain stimulation (DBS) is a common clinical procedure that uses electrodes implanted in the target brain regions to treat symptoms of neurological and psychiatric conditions.

Researchers from Johns Hopkins University and the National Institute of Standards and Technology have developed a new blood test that diagnoses heart attacks in minutes rather than hours. The heart of the invention is a tiny chip with a groundbreaking nanostructured surface on which blood is tested. The chip's "metasurface" enhances electric and magnetic signals during Raman spectroscopy analysis, making heart attack biomarkers visible in seconds. The tool is sensitive enough to flag heart attack biomarkers that might not be detected with current tests.

Researchers from the University of Texas at Dallas and Vanderbilt University have found that X-rays of the kidneys using gold nanoparticles as a contrast agent might be more accurate in detecting kidney disease than standard laboratory blood tests. Based on their study in mice, the researchers also realized that caution may be warranted in using renal-clearable nanomedicines to patients with compromised kidneys.

Using a ventilator-on-a-chip developed at The Ohio State University, researchers have found that shear stress from the collapse and reopening of the air sacs is the most harmful type of damage. This miniature organ-on-a-chip model simulates lung injury during mechanical ventilation, said Samir Ghadiali, one of the scientists involved in this study. The ventilator-on-a chip’s measurement of real-time changes to cells was enabled by an innovative approach: growing human lung cells on a synthetic nanofiber membrane mimicking the complex lung matrix.

Researchers from New York University have begun to explore exosomes, tiny membrane-bound vesicles, as promising tools for wound healing. These nanovesicles carry various biological materials – nucleic acids, proteins, and lipids – allowing them to mediate intercellular communication and influence processes such as tissue repair.

Researchers from Texas A&M University have developed molybdenum disulfide nanoflowers that can stimulate mitochondrial regeneration, helping cells generate more energy. According to Akhilesh Gaharwar, one of the researchers involved in this study, the nanoflowers could offer new treatments for muscle dystrophy, diabetes, and neurodegenerative disorders by increasing ATP production, mitochondrial DNA, and cellular respiration. "This discovery is unique," said Vishal Gohil, another researcher involved in the study.

Researchers at the University of Hawaiʻi at Manoa in Honolulu have unveiled a new technique that could make the manufacture of wearable health sensors more accessible and affordable. Producing these devices often requires specialized facilities and technical expertise, limiting their accessibility and widespread adoption. So, the researchers introduced a low-cost, stencil-based method for producing sensors made from laser-induced graphene, a key material used in wearable sensing.

Researchers from the University of Pennsylvania, Temple University in Philadelphia, the University of Delaware, and the University of Electronic Science and Technology of China have discovered a novel means of directing lipid nanoparticles to target specific tissues. The engineers demonstrated how subtle adjustments to the chemical structure of an ionizable lipid, a key component of a lipid nanoparticle, allow for tissue-specific delivery to the liver, lungs, and spleen.

Researchers from the University of California San Diego have created an array of nanopillars that can breach the nucleus of a cell – the compartment that houses our DNA – without damaging the cell's outer membrane. This new “gateway into the nucleus” could open new possibilities in gene therapy, where genetic material needs to be delivered directly into the nucleus, as well as drug delivery and other forms of precision medicine. The nucleus is impenetrable by design.

Engineers at the University of Virginia have created a drug nanocarrier designed to cure chronic or deadly respiratory diseases by slipping past the lungs' natural defenses. The engineers successfully demonstrated the nanocarrier's effectiveness using a device that captures the geometric and biological features of human airways.