Mueller matrix approach for determination of optical rotation in chiral turbid media in backscattering geometry

Abstract: For in vivo determination of optically active (chiral) substances in turbid media, like for example glucose in human tissue, the backscattering geometry is particularly convenient. However, recent polarimetric measurements performed in the backscattering geometry have shown that, in this geometry, the relatively small rotation of the polarization vector arising due to the optical activity of the medium is totally swamped by the much larger changes in the orientation angle of the polarization vector due to scat… Show more

“…The scattering-induced diattenuation is due mainly to the weakly scattered photons [17]. This effect is even more important in the backscattering geometry as compared to forward scattering geometry.…”

Physical model of differential Mueller matrix for depolarizing uniform media

“…The scattering-induced diattenuation is due mainly to the weakly scattered photons [17]. This effect is even more important in the backscattering geometry as compared to forward scattering geometry.…”

Physical model of differential Mueller matrix for depolarizing uniform media

“…Note that all the metrics describe the Mueller matrix as associated with a partial depolarizing system, as was reported by the authors of Ref. [15]. Figures 1(a) and 1(b) represent the DoPðM; SÞ and the gain, respectively, when all the incident Stokes vectors are taken from the Poincarè sphere [10].…”

Q(M) and the depolarization index scalar metrics

“…Theoretically, there are multiple possible decomposition families [19]. In this study, we applied the original method introduced by Lu and Chipman [8] and used by others [9][10][11] for tissue characterizations. The specific procedures applied in this study are described below.…”

“…According to the method described in [10,11], the linear retardance can be further derived by representing the retardance matrix M R as a combination of optical rotation (R C ) and linear retardance (R L ). The linear retardance R L can be obtained from the retardance submatrix m R as [11] R L ¼ cos …”

“…Swami et al [9] explored a simplified decomposition algorithm for use in a subset (3 × 3) of the Mueller matrix measured with only linearly polarized light. Manhas et al [10] and Ghosh et al [11] recently extended Lu and Chipman's original method by further decomposing the total retardance into linear retardance and optical rotation.…”

Mueller matrix decomposition of diffuse reflectance imaging in skeletal muscle