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Magnetic resonance in medicine
Feb, 2025;93 (2): 828-841.

An Eulerian formulation for the computational modeling of phase-contrast MRI.

Tomohiro Otani, Tetsuro Sekine, Yu Sato, Ellen Cavalcante Alves, Shigeo Wada
Author Information
  1. Tomohiro Otani: Department of Mechanical Science and Bioengineering, Osaka University Graduate School of Engineering Science, Osaka, Japan. ORCID
  2. Tetsuro Sekine: Department of Radiology, Nippon Medical School Musashi-Kosugi Hospital, Kanagawa, Japan. ORCID
  3. Yu Sato: Department of Mechanical Science and Bioengineering, Osaka University Graduate School of Engineering Science, Osaka, Japan.
  4. Ellen Cavalcante Alves: Department of Mechanical Science and Bioengineering, Osaka University Graduate School of Engineering Science, Osaka, Japan.
  5. Shigeo Wada: Department of Mechanical Science and Bioengineering, Osaka University Graduate School of Engineering Science, Osaka, Japan. ORCID
PMID: 39270130 DOI: 10.1002/mrm.30302

Abstract

PURPOSE: Computational simulation of phase-contrast MRI (PC-MRI) is an attractive way to physically interpret properties and errors in MRI-reconstructed flow velocity fields. Recent studies have developed PC-MRI simulators that solve the Bloch equation, with the magnetization transport being modeled using a Lagrangian approach. Because this method expresses the magnetization as spatial distribution of particles, influences of particle densities and their spatial uniformities on numerical accuracy are well known. This study developed an alternative method for PC-MRI modeling using an Eulerian approach in which the magnetization is expressed as a spatially smooth continuous function.
METHODS: The magnetization motion was described using the Bloch equation with an advection term and computed on a fixed grid using a finite difference method, and k-space sampling was implemented using the spoiled gradient echo sequence. PC-MRI scans of a fully developed flow in straight and stenosed cylinders were acquired to provide numerical examples.
RESULTS: Reconstructed flow in a straight cylinder showed excellent agreement with input velocity profiles and mean errors were less than 0.5% of the maximum velocity. Numerical cases of flow in a stenosed cylinder successfully demonstrated the velocity profiles, with displacement artifacts being dependent on scan parameters and intravoxel dephasing due to flow disturbances. These results were in good agreement with those obtained using the Lagrangian approach with a sufficient particle density.
CONCLUSION: The feasibility of the Eulerian approach to PC-MRI modeling was successfully demonstrated.

Keywords

Eulerian formulation high‐performance computing modified Bloch equation phase‐contrast MRI

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Grants

  1. /Nakatani Foundation for Advancement of Measuring Technologies in Biomedical Engineering
  2. 23K11830/Japan Society for the Promotion of Science
  3. 24K02408/Japan Society for the Promotion of Science
  4. /Osaka University Graduate School of Engineering Science
  5. JPMXP1020230118/Ministry of Education, Culture, Sports, Science and Technology

MeSH Term

Computer Simulation
Magnetic Resonance Imaging
Algorithms
Humans
Blood Flow Velocity
Reproducibility of Results
Image Interpretation, Computer-Assisted
Journal Article

Word Cloud

Created with Highcharts 10.0.0usingPC-MRIflowvelocitymagnetizationapproachEulerianMRIdevelopedBlochequationmethodmodelingphase-contrasterrorsLagrangianspatialparticlenumericalstraightstenosedcylinderagreementprofilessuccessfullydemonstratedformulationPURPOSE:ComputationalsimulationattractivewayphysicallyinterpretpropertiesMRI-reconstructedfieldsRecentstudiessimulatorssolvetransportmodeledexpressesdistributionparticlesinfluencesdensitiesuniformitiesaccuracywellknownstudyalternativeexpressedspatiallysmoothcontinuousfunctionMETHODS:motiondescribedadvectiontermcomputedfixedgridfinitedifferencek-spacesamplingimplementedspoiledgradientechosequencescansfullycylindersacquiredprovideexamplesRESULTS:Reconstructedshowedexcellentinputmeanless05%maximumNumericalcasesdisplacementartifactsdependentscanparametersintravoxeldephasingduedisturbancesresultsgoodobtainedsufficientdensityCONCLUSION:feasibilitycomputationalhigh‐performancecomputingmodifiedphase‐contrast

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