Bionics, clinical engineering, medical imaging, rehabilitation engineering, systems physiology, bionanotechnology, and neural engineering are among other key biomedical engineering disciplines. The ...

Biomedical engineering focuses on the advances that improve human ... You can find out the relationship between smart polymers and stimuli. Medical imaging covers the physical nature of the ...

The core curriculum provides the necessary training in medical science, modeling and simulation and biomedical engineering applications. Students may focus their scholarly efforts on advanced ...

Backed by NIH funding, Muyinatu 'Bisi' Bell's innovative work is enhancing diagnostic accuracy, improving surgical precision, ...

Our research spans many different disciplines, all with the central goal of enhancing the capabilities and usability of biomedical imaging and instrumentation.

The undergraduate degree in biomedical engineering provides a well-rounded education ... interdisciplinary education Explore therapeutics, biomechanics, medical devices, imaging and diagnostics ...

Biophotonics research focuses on the development of optical imaging and sensing technologies to study biomolecule, cell, and tissue structure and function at nanoscopic and microscopic scales. The ...

VCSELs offer a third option compared with conventional light emitting diodes (LEDS) and edge-emitting laser diodes (EELs).

Researchers led by the University of Waterloo have discovered how to turn common bacteria into high-efficiency factories capable of producing tiny, powerful particles for drug delivery, cancer therapy ...

biomedical engineering. Biomedical engineers contribute to medical technologies in a variety of areas including diagnostics, therapeutics, imaging, bioinformatics and rehabilitation.

Rigorous lecture courses provide students the knowledge necessary to succeed in biomedical engineering careers, medical school and graduate school. Laboratory courses engage students to solve complex ...