Reduction in scattering, high absorption, and spectral features of tissue constituents above
1000 nm could help in gaining higher spatial resolution, penetration depth, and specificity …

The feasibility of in vivo measurements in the range of 1000 to 1100 nm and the potential
benefits of operation in that wavelength range for diagnostic applications are investigated …

In vivo absorption and reduced scattering spectra of the human calcaneous from 650 to
1000 nm were assessed using a laboratory system for time-resolved transmittance …

Tissue inhomogeneity is often neglected in the analysis of the spectral data collected in
tissues. We have measured the absorption and reduced scattering spectra of the human …

We present a review of short-wave infrared (SWIR, defined here as∼ 1000 to 2000 nm)
spectroscopy and imaging techniques for biological tissue optical property characterization …

The first, to our knowledge, in-vivo broadband spectroscopic characterization of breast
tissue using different interfiber distances as well as transmittance measurements is …

Near infrared diffuse optical spectroscopy and diffuse optical imaging are promising
methods that eventually may enhance or replace existing technologies for breast cancer …

The goal of frequency-domain optical absorption spectroscopy is the noninvasive
determination of the absorption coefficient of a specific tissue volume. Since this allows the …

We present a systematic characterization of the optical properties (µ_a and µ_s') of nine
representative ex vivo porcine tissues over a broadband spectrum (650-1100 nm). We …

Time-resolved and spatially resolved measurements of the diffuse reflectance from
biological tissue are two well-established techniques for extracting the reduced scattering …