Complete characterization of biological samples is of potential interest in different industrial and research areas, as for instance, in biomedical applications, for the recognition of organic structures or for the early detection of some diseases. During the last decades, polarimetric methods are experiencing an increase of attention in the study of biomedical tissues, and they are nowadays used in such framework to provide qualitative (polarimetric imaging) and quantitative (data processing) information for the studied samples. Polarimetric methods are based on the analysis of polarization modifications produced by light matter interactions which can be triggered by a number of complex internal processes but can be roughly understood as the result of the combination of three pure polarimetric features of the sample: its diattenuation, retardance and depolarization. To describe the depolarization sample behavior, we use the Indices of Polarimetric Purity (IPP): related with the randomness of the scattering processes, IPPs provide more information of depolarizing systems than the widely used depolarization index, 𝑃∆, which further synthetizes the depolarization content of samples. As a result, IPPs allow the revelation of some structures from tissue samples (animal and vegetal) hidden in regular intensity images of even in the 𝑃∆ channel, leading to better tissue classification results.

Complete characterization of biological samples is of potential interest in different industrial and research areas, as for instance, in biomedical applications, for the recognition of organic structures or for the early detection of some diseases. During the last decades, polarimetric methods are experiencing an increase of attention in the study of biomedical tissues, and they are nowadays used in such framework to provide qualitative (polarimetric imaging) and quantitative (data processing) information for the studied samples. Polarimetric methods are based on the analysis of polarization modifications produced by light matter interactions which can be triggered by a number of complex internal processes but can be roughly understood as the result of the combination of three pure polarimetric features of the sample: its diattenuation, retardance and depolarization. To describe the depolarization sample behavior, we use the Indices of Polarimetric Purity (IPP): related with the randomness of the scattering processes, IPPs provide more information of depolarizing systems than the widely used depolarization index, 𝑃∆, which further synthetizes the depolarization content of samples. As a result, IPPs allow the revelation of some structures from tissue samples (animal and vegetal) hidden in regular intensity images of even in the 𝑃∆ channel, leading to better tissue classification results.