Abstract
The measurement of soft tissue fiber orientation is fundamental to pathophysiology and biomechanical function in a multitude of biomedical applications. However, many existing techniques for quantifying fiber structure rely on transmitted light, limiting general applicability and often requiring tissue processing. Herein, we present a novel wide-field reflectance-based imaging modality, which combines polarized light imaging (PLI) and spatial frequency domain imaging (SFDI) to rapidly quantify preferred fiber orientation on soft collagenous tissues. PLI utilizes the polarization dependent scattering property of fibers to determine preferred fiber orientation; SFDI imaging at high spatial frequency is introduced to reject the highly diffuse photons and to control imaging depth. As a result, photons scattered from the superficial layer of a multi-layered sample are highlighted. Thus, fiber orientation quantification can be achieved for the superficial layer with optical sectioning. We demonstrated on aortic heart valve leaflet that, at spatial frequency of f = 1mm(-1) , the diffuse background can be effectively rejected and the imaging depth can be limited, thus improving quantification accuracy.
Highlights
Many types of soft biological tissues primarily consist of aligned fibrous structures [1, 2]
The higher peak is located at 30 degrees, which corresponds to true local fiber orientation, and the lower peak is 90 degrees away from the higher peak
The perpendicular detection removes the specular reflection and photons from superficial layer; the signal from deeper tissue can be highlighted as suggested by Morgan et al [26], which is the main difference compared with superficial detection in polarized light SFDI (pSFDI)
Summary
Many types of soft biological tissues primarily consist of aligned fibrous structures [1, 2]. The anisotropic fiber organization in soft tissues results in distinct mechanical properties and functions, directed towards optimal physiological function. Understanding these structure-function relationships and integrating this knowledge into predictions of the resulting tissue behavior remains an ongoing challenge for a wide range of tissue applications [3]. SALS has an advantage of directly quantifying the angular distribution of fibers rapidly and over large areas of tissue. It is a transmitted light technique and remains limited to either thin sections or tissue that have undergone some type of optical clearing (e.g. glycerol immersion). For transmission-based techniques, to reduce this scattering, the sample is normally
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Talk to us
Join us for a 30 min session where you can share your feedback and ask us any queries you have
Schedule a call
