The optical properties of white matter human brain, canine prostate and pig liver were
measured in the wavelength range 330-1100 nm. The measurements were carried out in …

The optical properties of white matter human brain, canine prostate and pig liver were
measured in the wavelength range 330-1100 nm. The measurements were carried out in …

The optical properties of different types of tissue were measured in the wavelength range
330-1100 nm. The measurements were carried out in native as well as in coagulated …

The detection of interactions between light and tissue can be used to characterize the optical
properties of the tissue. The development is described of a method that determines optical …

The optical properties (absorption and scattering coefficients and the scattering anisotropy
factor) were measured in vitro for cartilage, liver, lung, muscle, myocardium, skin, and …

Knowledge of tissue optical properties, in particular the absorption μa and the reduced
scattering coefficient μ s′, is required for diagnostic and therapeutic applications in which …

A rigorous technique using a Monte Carlo model has been developed to determine the
optical properties of biological tissue from goniometer and integrating sphere …

The absorption coefficient μ a, the scattering coefficient μ s, and the scattering anisotropy
factor g of porcine liver were studied in vitro using the integrating sphere technique and …

Extensive research in biomedical optics essentially requires the determination of optical
properties of various biological tissues. Quantitative characterization of biological tissues in …

Integrating sphere remains a valuable tool for biomedical optics research. Specifically, it has
been used to determine the optical properties (ie, absorption coefficient, scattering …