Deep in your muscles, an enzyme called AMPD1 helps turn chemical fuel into usable energy. When it does not work well, muscles tire faster.

A research team led by Associate Professor Shinpei Yamaguchi and the late Professor Masako Tada of the Faculty of Science, together with Professor Yojiro Anzai and Lecturer Yohei Iizaka of the Faculty ...

Specific glycans attached to the GnT-IVa and GnT-IVb can bind to the enzyme’s ligand-binding site, interfering with recognition and binding to the glycosylation proteins’ normal glycoprotein ...

New review highlights evolving Pompe disease management, from screening to next-generation therapies and monitoring. Read ...

Researchers overcome key challenges in the mass production of enzymatic biofuel cells, paving the way for self-powered ...

Creative Enzymes stands as a leading provider of enzyme-related services and solutions. Committed to innovation and excellence, the organization supports research in enzymology and biotechnology by ...

Printable sweat-powered biofuel cells could replace bulky batteries in thin, flexible wearable health sensors.

It is now possible to obtain three-dimensional, high-resolution images of enzyme activity in tissue samples or whole organs -- thanks to probe molecules that anchor fluorescent dyes within tissue as ...

Researchers from Drexel University’s College of Arts and Sciences and College of Medicine have found a potential new therapeutic target for Alzheimer’s disease. Expanding on their previous research on ...