Time-efficient and flexible design of optimised multi-shell HARDI diffusion

Jana Hutter; J. Donald Tournier; Anthony N. Price; Lucilio Cordero-Grande; Emer J. Hughes; Shaihan Malik; Johannes Steinweg; Matteo Bastiani; Stamatios N. Sotiropoulos; Saad Jbabdi; Jesper Andersson; A. David Edwards; Joseph V. Hajnal

doi:10.1002/mrm.26765

Time-efficient and flexible design of optimised multi-shell HARDI diffusion

Jana Hutter, J. Donald Tournier, Anthony N. Price, Lucilio Cordero-Grande, Emer J. Hughes, Shaihan Malik, Johannes Steinweg, Matteo Bastiani, Stamatios N. Sotiropoulos, Saad Jbabdi, Jesper Andersson, A. David Edwards, Joseph V. Hajnal

School of Biomedical Engineering & Imaging Sciences (BMEIS), St Thomas' Hospital, King's College London, UK.

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

75 Citations (Scopus)

238 Downloads (Pure)

Abstract

Purpose: Advanced diffusion magnetic resonance imaging benefits from collecting as much data as is feasible but is highly sensitive to subject motion and the risk of data loss increases with longer acquisition times. Our purpose was to create a maximally time-efficient and flexible diffusion acquisition capability with built-in robustness to partially acquired or interrupted scans. Our framework has been developed for the developing Human Connectome Project, but different application domains are equally possible.
Methods: Complete flexibility in the sampling of diffusion space combined with free choice of phase-encode-direction and the temporal ordering of the sampling scheme was developed taking into account motion robustness, internal consistency, and hardware limits. A split-diffusion-gradient preparation, multiband acceleration, and a restart capacity were added.
Results: The framework was used to explore different parameters choices for the desired high angular resolution diffusion imaging diffusion sampling. For the developing Human Connectome Project, a high-angular resolution, maximally time-efficient (20 min) multishell protocol with 300 diffusion-weighted volumes was acquired in >400 neonates. An optimal design of a high-resolution (1.2 × 1.2 mm2) two-shell acquisition with 54 diffusion weighted volumes was obtained using a split-gradient design.
Conclusion: The presented framework provides flexibility to generate time-efficient and motion-robust diffusion magnetic resonance imaging acquisitions taking into account hardware constraints that might otherwise result in sub-optimal choices.

Original language	English
Pages (from-to)	1276-1292
Journal	Magnetic Resonance in Medicine
Volume	79
Issue number	3
Early online date	30 May 2017
DOIs	https://doi.org/10.1002/mrm.26765
Publication status	Published - 30 Jan 2018

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Time-efficient and flexible design_HUTTER_ Accepted 3May 2017 GOLD VoR (CC-BY_NC)Final published version, 1.55 MBLicence: CC BY

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title = "Time-efficient and flexible design of optimised multi-shell HARDI diffusion",

abstract = "Purpose: Advanced diffusion magnetic resonance imaging benefits from collecting as much data as is feasible but is highly sensitive to subject motion and the risk of data loss increases with longer acquisition times. Our purpose was to create a maximally time-efficient and flexible diffusion acquisition capability with built-in robustness to partially acquired or interrupted scans. Our framework has been developed for the developing Human Connectome Project, but different application domains are equally possible. Methods: Complete flexibility in the sampling of diffusion space combined with free choice of phase-encode-direction and the temporal ordering of the sampling scheme was developed taking into account motion robustness, internal consistency, and hardware limits. A split-diffusion-gradient preparation, multiband acceleration, and a restart capacity were added. Results: The framework was used to explore different parameters choices for the desired high angular resolution diffusion imaging diffusion sampling. For the developing Human Connectome Project, a high-angular resolution, maximally time-efficient (20 min) multishell protocol with 300 diffusion-weighted volumes was acquired in >400 neonates. An optimal design of a high-resolution (1.2 × 1.2 mm2) two-shell acquisition with 54 diffusion weighted volumes was obtained using a split-gradient design. Conclusion: The presented framework provides flexibility to generate time-efficient and motion-robust diffusion magnetic resonance imaging acquisitions taking into account hardware constraints that might otherwise result in sub-optimal choices.",

author = "Jana Hutter and Tournier, {J. Donald} and Price, {Anthony N.} and Lucilio Cordero-Grande and Hughes, {Emer J.} and Shaihan Malik and Johannes Steinweg and Matteo Bastiani and Sotiropoulos, {Stamatios N.} and Saad Jbabdi and Jesper Andersson and Edwards, {A. David} and Hajnal, {Joseph V.}",

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AU - Hutter, Jana

AU - Tournier, J. Donald

AU - Price, Anthony N.

AU - Cordero-Grande, Lucilio

AU - Hughes, Emer J.

AU - Malik, Shaihan

AU - Steinweg, Johannes

AU - Bastiani, Matteo

AU - Sotiropoulos, Stamatios N.

AU - Jbabdi, Saad

AU - Andersson, Jesper

AU - Edwards, A. David

AU - Hajnal, Joseph V.

PY - 2018/1/30

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N2 - Purpose: Advanced diffusion magnetic resonance imaging benefits from collecting as much data as is feasible but is highly sensitive to subject motion and the risk of data loss increases with longer acquisition times. Our purpose was to create a maximally time-efficient and flexible diffusion acquisition capability with built-in robustness to partially acquired or interrupted scans. Our framework has been developed for the developing Human Connectome Project, but different application domains are equally possible. Methods: Complete flexibility in the sampling of diffusion space combined with free choice of phase-encode-direction and the temporal ordering of the sampling scheme was developed taking into account motion robustness, internal consistency, and hardware limits. A split-diffusion-gradient preparation, multiband acceleration, and a restart capacity were added. Results: The framework was used to explore different parameters choices for the desired high angular resolution diffusion imaging diffusion sampling. For the developing Human Connectome Project, a high-angular resolution, maximally time-efficient (20 min) multishell protocol with 300 diffusion-weighted volumes was acquired in >400 neonates. An optimal design of a high-resolution (1.2 × 1.2 mm2) two-shell acquisition with 54 diffusion weighted volumes was obtained using a split-gradient design. Conclusion: The presented framework provides flexibility to generate time-efficient and motion-robust diffusion magnetic resonance imaging acquisitions taking into account hardware constraints that might otherwise result in sub-optimal choices.

AB - Purpose: Advanced diffusion magnetic resonance imaging benefits from collecting as much data as is feasible but is highly sensitive to subject motion and the risk of data loss increases with longer acquisition times. Our purpose was to create a maximally time-efficient and flexible diffusion acquisition capability with built-in robustness to partially acquired or interrupted scans. Our framework has been developed for the developing Human Connectome Project, but different application domains are equally possible. Methods: Complete flexibility in the sampling of diffusion space combined with free choice of phase-encode-direction and the temporal ordering of the sampling scheme was developed taking into account motion robustness, internal consistency, and hardware limits. A split-diffusion-gradient preparation, multiband acceleration, and a restart capacity were added. Results: The framework was used to explore different parameters choices for the desired high angular resolution diffusion imaging diffusion sampling. For the developing Human Connectome Project, a high-angular resolution, maximally time-efficient (20 min) multishell protocol with 300 diffusion-weighted volumes was acquired in >400 neonates. An optimal design of a high-resolution (1.2 × 1.2 mm2) two-shell acquisition with 54 diffusion weighted volumes was obtained using a split-gradient design. Conclusion: The presented framework provides flexibility to generate time-efficient and motion-robust diffusion magnetic resonance imaging acquisitions taking into account hardware constraints that might otherwise result in sub-optimal choices.

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Time-efficient and flexible design of optimised multi-shell HARDI diffusion

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