Patent Document ID: 10133045
Application ID: 15223624
Patent Status: 1

Claim One:
1. A method of producing 3D images of a fibrous target tissue sample, the method comprising: focusing a polarized incident light with one or more optical polarizations in a first direction on one or more surface locations of a fibrous target tissue sample, whereby at each surface location of the incident light in the first direction the incident light propagates inside the fibrous target tissue sample and comes out from different depths within the fibrous target tissue sample to provide a first signal resulting from the incident light in the first direction; analyzing polarization characteristics of the of first signal to derive fiber orientation data within the fibrous target tissue sample at each depth relative to a first projection plane defined by the first direction of the incident light and a 3D position of the fibrous target tissue sample; constructing a first 3D image volume of fiber orientation of the fibrous target tissue sample utilizing the fiber orientation data derived at each depth relative to the first projection plane at each of the surface locations of the incident light in the first direction; focusing the polarized incident light with one or more optical polarizations at at least one additional direction that is different than the first direction on one or more additional surface locations of the fibrous target tissue sample, whereby at each surface location of the incident light in the at least one additional direction the incident light propagates inside the fibrous target tissue sample and comes out from different depths within the fibrous target tissue sample to provide an additional signal resulting from the incident light in the at least one additional direction; analyzing polarization characteristics of the additional signal to derive fiber orientation data at each depth within the fibrous target tissue sample relative to at least one additional projection plane defined by the at least one additional direction of the incident light and the 3D position of the fibrous target tissue sample; constructing at least one additional 3D image volume of the fiber orientation of the fibrous target tissue sample utilizing the fiber orientation data derived at each of the depths relative to the at least one additional projection plane at each of the additional incident light surface locations; registering the first 3D image volume of fiber orientation of the fibrous target tissue sample and the at least one additional 3D image volume of fiber orientation of the fibrous target tissue sample to construct a combined 3D image volume of 3D fiber orientation of the fibrous target tissue sample at the intersection of the first projection plane and the at least one additional projection plane; determining 3D image properties of the fibrous target tissue sample utilizing the combined 3D image volume of the 3D fiber orientation of the fibrous target tissue sample; and transmitting the 3D image properties of the fibrous target tissue sample to a processor to produce 3D images of the fibrous target tissue sample.