The findings hold promise for developing targeted treatments for the lung complications of Long COVID.

Researchers at Pennington Biomedical Research Center have revealed critical insights into how impaired mitochondrial dynamics and quality control mechanisms in skeletal muscle influence insulin sensitivity in patients with Type 2 Diabetes, or T2D. The study, titled "Deubiquitinating Enzymes Regulate Skeletal Muscle Mitochondrial Quality Control and Insulin Sensitivity in Patients with Type 2 Diabetes," was recently published in the Journal of Cachexia, Sarcopenia and Muscle.​

The research team, led by Pennington Biomedical Executive Director Dr. John Kirwan, focused on the significance of deubiquitinating enzymes, or DUBs, in regulating mitochondrial dynamics within skeletal muscle. Findings suggest that mitochondrial fragmentation can bypass defects in mitophagy, the process by which cells remove damaged mitochondria, to sustain skeletal muscle quality control in patients with T2D. This adaptation may help maintain mitochondrial function despite impaired mitophagy.​

A team of researchers from Penn State created a hairlike device for long-term, non-invasive monitoring of the brain’s electrical activity. The lightweight and flexible electrode attaches directly to the scalp and delivers stable, high-quality electroencephalography (EEG) recordings.

A new analysis of a group of all-women extreme divers off the coast of Korea has uncovered genetic differences that could help them survive the intense physiological stresses of free-diving—and could ultimately lead to better treatments for blood pressure disorders.

The Haenyeo, a group of all-female divers from the Korean island of Jeju, are renowned for their ability to dive in frigid waters without the aid of breathing equipment — even while pregnant. A study publishing on May 2 in the Cell Press journal Cell Reports shows that the divers’ remarkable abilities are due to both training and genetic adaptation, including gene variants associated with cold tolerance and decreased blood pressure. The divers also showed pronounced bradycardia, or slowing of the heart rate, when they dived, but this trait is likely due to a lifetime of training, not genetics.