Optical Coherence Elastography Techniques

Tissue mechanical properties determine the relationship between an applied mechanical load and the resulting deformation of the sample. In optical coherence elastography (OCE), the objective is to spatially resolve tissue mechanical properties from often incomplete and noisy measurements of the load and deformation. This is achieved by solving an inverse problem, using a model of elasticity that reasonably describes the behavior of tissue. Incorporating more parameters into the model (such as heterogeneity, anisotropy, nonlinearity, or viscoelasticity) than are needed in a given application can unnecessarily complicate the inverse problem. Also, how the load is applied can enhance certain tissue responses, and the validity of an elasticity model, and, thus, allow for the characterization of tissue in different regimes. A successful OCE technique offers a good match between the load application method, and the tissue mechanical properties of interest, and employs a reasonably complete but simplified mechanical model that provides a noise-robust inversion. OCE techniques can be classified into two broad categories: those inducing and subsequently tracking propagating mechanical waves, and those applying and assuming a uniaxial load, and tracking the deformation in response. With a brief introduction to the former, this chapter focuses on the latter group, describes the most prominent of these techniques, and presents an overview of studies that have successfully extracted mechanical properties in tissue-like media.