Abstract
In this article, we consider how differing approaches that characterize biological microstructure with diffusion weighted magnetic resonance imaging intersect. Without geometrical boundary assumptions, there are techniques that make use of power law behavior which can be derived from a generalized diffusion equation or intuited heuristically as a time dependent diffusion process. Alternatively, by treating biological microstructure (e.g., myelinated axons) as an amalgam of stick-like geometrical entities, there are approaches that can be derived utilizing convolution-based methods, such as the spherical means technique. Since data acquisition requires that multiple diffusion weighting sensitization conditions or b-values are sampled, this suggests that implicit mutual information may be contained within each technique. The information intersection becomes most apparent when the power law exponent approaches a value of 12, whereby the functional form of the power law converges with the explicit stick-like geometric structure by way of confluent hypergeometric functions. While a value of 12 is useful for the case of solely impermeable fibers, values that diverge from 12 may also reveal deep connections between approaches, and potentially provide insight into the presence of compartmentation, exchange, and permeability within heterogeneous biological microstructures. All together, these disparate approaches provide a unique opportunity to more completely characterize the biological origins of observed changes to the diffusion attenuated signal.
Highlights
Diffusion is a fundamental transport process in many biological systems and is known to be sensitive to structure and inhomogeneity in the environment
Since the length scales probed by diffusing particles are orders of magnitude smaller than a typical scan voxel, measurements of diffusion contain quantitative microstructural information that is unique in comparison to other magnetic resonance (MR) modalities that measure relaxation, flow, or changes in blood oxygenation [4]
The most common application of diffusion-weighted magnetic resonance imaging (DWI) is in the human brain, where it has been well-established that there is a distribution of diffusivities within the neural tissue microstructure [5]
Summary
Diffusion is a fundamental transport process in many biological systems and is known to be sensitive to structure and inhomogeneity in the environment. The CTRW formalism has been applied to neural tissue to connect a model of diffusion-weighted signal with a physical interpretation of generalized diffusion dynamics that encode power law behavior [22,23,24,25] Presentation of these differing approaches is often designed to test or showcase feasibility, instead of investigating which technique is most appropriate for a particular application. One of the possible approaches to higher-order diffusion image analysis is the assumption of diffusion in an explicit structure This approach dates back to the work of Stanisz [30], who constructed a model of bovine optic nerve containing differently-shaped elliptical compartments defining geometrical boundary constraints in the diffusion equation.
Sign-in/Register to view highlights & summary Sign-in/Register to access full text options 
Free) 
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
