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A practical evaluation of measures derived from compressed sensing diffusion spectrum imaging.

Hamsanandini Radhakrishnan1,2, Chenying Zhao1,2,3,4, Valerie J Sydnor1,2

  • 1Lifespan Informatics and Neuroimaging Center, University of Pennsylvania, Philadelphia, Pennsylvania, USA.

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Compressed sensing Diffusion Spectrum Imaging (CS-DSI) significantly reduces scan time for brain imaging. This study confirms CS-DSI provides accurate and reliable in vivo white matter measures, making it promising for clinical and research use.

Keywords:
MRI acquisitioncompressed sensingdiffusion‐weighted imagingwhite matter

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Area of Science:

  • Neuroimaging
  • Biomedical Engineering
  • Radiology

Background:

  • Diffusion Spectrum Imaging (DSI) excels at modeling white matter architecture but requires long scan times.
  • Compressed Sensing (CS) with sparser q-space sampling offers reduced DSI acquisition time.
  • Previous CS-DSI evaluations were limited to non-human or post-mortem data, leaving in vivo accuracy uncertain.

Purpose of the Study:

  • To evaluate the accuracy and inter-scan reliability of Compressed Sensing DSI (CS-DSI) for in vivo human brain white matter analysis.
  • To compare various CS-DSI schemes with up to 80% scan time reduction against a full DSI acquisition.
  • To determine the feasibility of CS-DSI for clinical and research applications.

Main Methods:

  • Developed and tested six CS-DSI schemes by subsampling data from a full DSI acquisition in 26 participants across eight sessions.
  • Compared accuracy and reliability of white matter bundle segmentation and scalar maps derived from CS-DSI versus full DSI.
  • Validated CS-DSI accuracy in a separate prospective dataset of 20 participants.

Main Results:

  • CS-DSI demonstrated nearly equivalent accuracy and reliability to full DSI for both bundle segmentation and voxel-wise scalar maps.
  • Accuracy and reliability of CS-DSI were higher in white matter bundles that were more consistently segmented by the full DSI.
  • Prospective data replication confirmed the accuracy of CS-DSI.

Conclusions:

  • CS-DSI is a viable technique for accurate and reliable in vivo delineation of white matter architecture.
  • Significant scan time reduction is achievable with CS-DSI without compromising data quality.
  • CS-DSI holds substantial promise for advancing clinical neuroimaging and neuroscience research.