Constrained optimization of gradient waveforms for generalized diffusion encoding.

Jens Sjölund; Filip Szczepankiewicz; Markus Nilsson; Daniel Topgaard; Carl-Fredrik Westin; Hans Knutsson

doi:10.1016/j.jmr.2015.10.012

Constrained optimization of gradient waveforms for generalized diffusion encoding.

Jens Sjölund, Filip Szczepankiewicz, Markus Nilsson, Daniel Topgaard, Carl-Fredrik Westin, Hans Knutsson

Research output: Contribution to journal › Article › peer-review

Abstract

Diffusion MRI is a useful probe of tissue microstructure. The conventional diffusion encoding sequence, the single pulsed field gradient, has recently been challenged as more general gradient waveforms have been introduced. Out of these, we focus on q-space trajectory imaging, which generalizes the scalar b-value to a tensor valued entity. To take full advantage of its capabilities, it is imperative to respect the constraints imposed by the hardware, while at the same time maximizing the diffusion encoding strength. We provide a tool that achieves this by solving a constrained optimization problem that accommodates constraints on maximum gradient amplitude, slew rate, coil heating and positioning of radio frequency pulses. The method's efficacy and flexibility is demonstrated both experimentally and by comparison with previous work on optimization of isotropic diffusion sequences.

Original language	English
Pages (from-to)	157-168
Journal	Journal of Magnetic Resonance
Volume	261
DOIs	https://doi.org/10.1016/j.jmr.2015.10.012
Publication status	Published - 2015

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Radiology and Medical Imaging

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10.1016/j.jmr.2015.10.012

http://www.ncbi.nlm.nih.gov/pubmed/26583528?dopt=Abstract

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title = "Constrained optimization of gradient waveforms for generalized diffusion encoding.",

abstract = "Diffusion MRI is a useful probe of tissue microstructure. The conventional diffusion encoding sequence, the single pulsed field gradient, has recently been challenged as more general gradient waveforms have been introduced. Out of these, we focus on q-space trajectory imaging, which generalizes the scalar b-value to a tensor valued entity. To take full advantage of its capabilities, it is imperative to respect the constraints imposed by the hardware, while at the same time maximizing the diffusion encoding strength. We provide a tool that achieves this by solving a constrained optimization problem that accommodates constraints on maximum gradient amplitude, slew rate, coil heating and positioning of radio frequency pulses. The method's efficacy and flexibility is demonstrated both experimentally and by comparison with previous work on optimization of isotropic diffusion sequences.",

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AU - Szczepankiewicz, Filip

AU - Nilsson, Markus

AU - Topgaard, Daniel

AU - Westin, Carl-Fredrik

AU - Knutsson, Hans

PY - 2015

Y1 - 2015

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AB - Diffusion MRI is a useful probe of tissue microstructure. The conventional diffusion encoding sequence, the single pulsed field gradient, has recently been challenged as more general gradient waveforms have been introduced. Out of these, we focus on q-space trajectory imaging, which generalizes the scalar b-value to a tensor valued entity. To take full advantage of its capabilities, it is imperative to respect the constraints imposed by the hardware, while at the same time maximizing the diffusion encoding strength. We provide a tool that achieves this by solving a constrained optimization problem that accommodates constraints on maximum gradient amplitude, slew rate, coil heating and positioning of radio frequency pulses. The method's efficacy and flexibility is demonstrated both experimentally and by comparison with previous work on optimization of isotropic diffusion sequences.

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SP - 157

EP - 168

JO - Journal of Magnetic Resonance

JF - Journal of Magnetic Resonance

ER -

Constrained optimization of gradient waveforms for generalized diffusion encoding.

Abstract

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