Maxwell-compensated design of asymmetric gradient waveforms for tensor-valued diffusion encoding
Filip Szczepankiewicz, Carl-Fredrik Westin, Markus Nilsson

TL;DR
This paper introduces a Maxwell-compensated design for asymmetric gradient waveforms in tensor-valued diffusion encoding, effectively eliminating signal bias caused by concomitant gradients and improving imaging accuracy.
Contribution
The study develops a novel Maxwell index constrained optimization method for designing asymmetric waveforms that are robust against concomitant gradient effects.
Findings
Maxwell-compensated waveforms show no signal bias in experiments.
Waveforms from literature exhibit significant bias affecting image quality.
The design accurately predicts and mitigates signal bias in diffusion imaging.
Abstract
Purpose: Asymmetric gradient waveforms are attractive for diffusion encoding due to their superior efficiency, however, the asymmetry may cause a residual gradient moment at the end of the encoding. Depending on the experiment setup, this residual moment may cause significant signal bias and image artifacts. The purpose of this study was to develop an asymmetric gradient waveform design for tensor-valued diffusion encoding that is not affected by concomitant gradient. Methods: The Maxwell index was proposed as a scalar invariant that captures the effect of concomitant gradients and was constrained in the numerical optimization to 100 (mT/m)ms to yield Maxwell-compensated waveforms. The efficacy of this design was tested in an oil phantom, and in a healthy human brain. For reference, waveforms from literature were included in the analysis. Simulations were performed to investigate if…
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