2014
DOI: 10.1371/journal.pone.0107159
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Dual-Phase Cardiac Diffusion Tensor Imaging with Strain Correction

Abstract: PurposeIn this work we present a dual-phase diffusion tensor imaging (DTI) technique that incorporates a correction scheme for the cardiac material strain, based on 3D myocardial tagging.Methods In vivo dual-phase cardiac DTI with a stimulated echo approach and 3D tagging was performed in 10 healthy volunteers. The time course of material strain was estimated from the tagging data and used to correct for strain effects in the diffusion weighted acquisition. Mean diffusivity, fractional anisotropy, helix, trans… Show more

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Cited by 78 publications
(125 citation statements)
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References 58 publications
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“…In clinical diffusion imaging, non‐Gaussian models have the potential to help in assessing myocardial perfusion 19. However, gradient hardware in clinical scanners typically limit b‐values to 500 s/mm 2 46, 47, 48, reducing sensitivity to non‐Gaussian diffusion arising from finer tissue structures as demonstrated here. Stimulated echo approaches afford higher b‐values for a given maximum gradient amplitude due to long diffusion times.…”
Section: Discussionmentioning
confidence: 93%
See 1 more Smart Citation
“…In clinical diffusion imaging, non‐Gaussian models have the potential to help in assessing myocardial perfusion 19. However, gradient hardware in clinical scanners typically limit b‐values to 500 s/mm 2 46, 47, 48, reducing sensitivity to non‐Gaussian diffusion arising from finer tissue structures as demonstrated here. Stimulated echo approaches afford higher b‐values for a given maximum gradient amplitude due to long diffusion times.…”
Section: Discussionmentioning
confidence: 93%
“…Longer Δ would increase the interactions of water molecules with cellular restrictions and likely enhance non‐Gaussian effects, particularly in the directions of the second and third eigenvectors. However, stimulated echo sequences are subject to myocardial strain, necessitating strain correction 48 or limiting imaging to temporal “sweet spots” 49. Higher b‐values result in lower signal, thus higher SNR is needed to avoid noise floor bias.…”
Section: Discussionmentioning
confidence: 99%
“…Acquisition parameters were field of view of 360 × 200 mm, resolution 2.5 × 2.5 mm, section thickness of 8 mm, in-plane generalized autocalibrating partially parallel acquisition rate 2 (12), echo time of 34 msec, b values of 0 and 500 sec/mm 2 , 10 diffusion-encoding directions, and eight magnitude averages (repetitions). Twelve short-axis sections were acquired at the systolic sweet spot (160 msec after the R wave) to mitigate strain effects (3, 13). SMS excitation was followed by a blipped-CAIPI readout by using a section-phase-section zonal excitation scheme (Fig 1a).…”
Section: Methodsmentioning
confidence: 99%
“…The entire left ventricle (LV) was imaged without slice gaps by acquiring 12 contiguous short‐axis slices from base to apex 23. Images were acquired in the systolic and diastolic sweet spots of the cardiac cycle to mitigate strain effects 18, 22…”
Section: Methodsmentioning
confidence: 99%