Sheng-Hao Tseng

Quantitative spectroscopy of superficial turbid media.

Determination of optical properties of superficial volumes of layered tissue phantoms.

In vivo determination of skin near-infrared optical properties using diffuse optical spectroscopy.

Chromophore concentrations, absorption and scattering properties of human skin in-vivo.

Investigation of a probe design for facilitating the uses of the standard photon diffusion equation at short source-detector separations: Monte Carlo simulations.

Analysis of a diffusion-model-based approach for efficient quantification of superficial tissue properties.

Efficient determination of the epidermal optical properties using a diffusion model-based approach: Monte Carlo studies.

Noninvasive evaluation of collagen and hemoglobin contents and scattering property of in vivo keloid scars and normal skin using diffuse reflectance spectroscopy: pilot study.

Breast cancer detection of large size to DCIS by hypoxia and angiogenesis using NIRS.

Higher-order modulations of fs laser pulses for GHz frequency domain photon migration system.

Reliable recovery of the optical properties of multi-layer turbid media by iteratively using a layered diffusion model at multiple source-detector separations.

A linear gradient line source facilitates the use of diffusion models with high order approximation for efficient, accurate turbid sample optical properties recovery.

Non-invasive evaluation of therapeutic response in keloid scar using diffuse reflectance spectroscopy.

Broadband absorption and reduced scattering spectra of in-vivo skin can be noninvasively determined using δ-P1 approximation based spectral analysis.

Efficient construction of robust artificial neural networks for accurate determination of superficial sample optical properties.

Toward reliable retrieval of functional information of papillary dermis using spatially resolved diffuse reflectance spectroscopy.

Portable handheld diffuse reflectance spectroscopy system for clinical evaluation of skin: a pilot study in psoriasis patients.

Holographic polymer networks formed in liquid crystal phase modulators via a He-Ne laser to achieve ultra-fast optical response.

Light distribution modulated diffuse reflectance spectroscopy.

Artificial neural networks for retrieving absorption and reduced scattering spectra from frequency-domain diffuse reflectance spectroscopy at short source-detector separation.