Determination of the complex refractive index segments of turbid sample with multispectral spatially modulated structured light and models approximation

Abstract: Spectral data enabling the derivation of a biological tissue sample's complex refractive index (CRI) can provide a range of valuable information in the clinical and research contexts. Specifically, changes in the CRI reflect alterations in tissue morphology and chemical composition, enabling its use as an optical marker during diagnosis and treatment. In the present work, we report a method for estimating the real and imaginary parts of the CRI of a biological sample using Kramers-Kronig (KK) relations in the … Show more

“…According to the Kramers-Kronig (K-K) relation [25,26] , the reflective phase shift Θ λ can be expressed as [27]…”

“…The real parts (n λ ) and imaginary parts (k λ ) of the complex refractive index values m λ (m λ = n λ ik λ ) can be obtained by [27]…”

Analysis of extinction characteristics of non-spherical biological particle aggregates [Invited]

“…According to the Kramers-Kronig (K-K) relation [25,26] , the reflective phase shift Θ λ can be expressed as [27]…”

“…The real parts (n λ ) and imaginary parts (k λ ) of the complex refractive index values m λ (m λ = n λ ik λ ) can be obtained by [27]…”

Analysis of extinction characteristics of non-spherical biological particle aggregates [Invited]

Parametric handheld optical probe (HOPE) for biological tissue characterization in the near-infrared spectral range

Extraction of the anisotropy factor and refractive index of biological tissue in the near-infrared region from diffusion approximation in the spatial frequency domain