Two observables of one wall: how surface relaxivity can bias the diffusion intra-axonal fraction and the myelin water fraction

Abstract

Surface relaxivity and time-dependent diffusion are two readouts of the same wall collisions on one substrate: the transverse rate that microstructure imaging fits is a bulk rate plus a surface rate ρ\,(S/V), and intra- and extra-axonal water carry different S/V, so their T2 differ and any compartment estimate that normalises by a TE-weighted b=0 is biased. We derive closed forms for the interior (Brownstein-Tarr) and exterior (Novikov-Burcaw) surface rates over myelinated cylinders, validate them with wall-counting Monte Carlo, and quantify the resulting bias on the diffusion intra-axonal signal fraction fintra and on the myelin water fraction (MWF). The interior/exterior S/V ratio is (1-VF)/(g\,VF), independent of the calibre distribution and crossing unity at fibre volume fraction VF=1/(1+g). Physiological white matter sits above this crossover, so surface relaxivity over-weights the intra-axonal signal, biasing fintra by ≈ 12\% at clinical PGSE (TE=80\,ms). That fractions are TE-dependent is known; new here are the surface-relaxivity and packing attribution, a closed-form sign law, and a testable packing-dependent TE drift. The same physics reads through relaxometry as a smaller MWF bias: the thinnest axons' water crosses below the myelin window and is counted as myelin, so fine white matter reads myelin-richer ( 0.33\,pp, beneath single-voxel noise but super-linear in the uncertain ρ), while in primary lumen-preserving demyelination this bias is nearly constant and cancels in the longitudinal change. One S/V physics thus biases both diffusion and relaxometry microstructure estimates, the fintra bias being first-order and packing-dependent, the MWF bias small and structural.

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