This course treats "Tissue Optics", how light propagates in scattering and absorbing media such as biological tissue. The basics of radiometry are introduced to facilitate laboratory experiments. The wave nature of light is presented with practical examples of coherent measurements such as interferometry. The origins and definitions of optical properties of tissues are discussed and illustrated by laboratory measurements. Light transport is modeled using a variety of theories and computational techniques, including Monte Carlo simulations and approximate solutions of the radiative transport equation. Steady-state and time-dependent problems are handled in a computer laboratory. Students learn the basics of optical transport required for later courses (ECE 533, ECE 534) which consider design of optical protocols and devices for therapy and diagnostics.
Nanocrystals make dentures shine
Research team develops advanced live-imaging approach (w/ video)
Tunable nano-suspensions for light harvesting
Tagging tumors with gold: Scientists use gold nanorods to flag brain tumors
Laser Hardware/Control Software Engineer I (209) - Hanscom AFB, MA
Postdoctoral Position - La Jolla, CA
Research Engineer position in Super-resolution microscopy - Castelldefels (Barcelona), Spain
Physicist/Physical Chemist/Research Engineer (We Sponsor Clearances) - Lexington, MA
AACR 103rd Annual Meeting 2012
Conference on Lasers and Electro-Optics and the...
