2019
DOI: 10.1002/mrm.27694
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High‐dimensionality undersampled patch‐based reconstruction (HD‐PROST) for accelerated multi‐contrast MRI

Abstract: Purpose To develop a new high‐dimensionality undersampled patch‐based reconstruction (HD‐PROST) for highly accelerated 2D and 3D multi‐contrast MRI. Methods HD‐PROST jointly reconstructs multi‐contrast MR images by exploiting the highly redundant information, on a local and non‐local scale, and the strong correlation shared between the multiple contrast images. This is achieved by enforcing multi‐dimensional low‐rank in the undersampled images. 2D magnetic resonance fin… Show more

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Cited by 94 publications
(148 citation statements)
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References 60 publications
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“…The singular images x estimated with this method can still present remaining undersampling artefacts and lead to noisy parametric maps. HD‐PROST reconstruction proposes to further exploit local (within a patch), non‐local (between patches in a neighborhood), and spectral (between contrasts) redundancies through high‐order low‐rank regularization . HD‐PROST reconstructs the multi‐contrast Dixon‐cMRF singular images x i for each echo i , by jointly solvingLtruex^i,trueT^b:=argminboldxi,scriptTb12∥∥AURFCxi-boldk22+λfalse∑b∥∥scriptTbbolds.boldt.scriptTb=bold-italicPbfalse(xifalse),where P b (·) is the operator that assembles a third order tensor Tb for the patch centered on voxel b by concatenating the K most similar patches along the non‐local similarity dimension (similar patches within a neighborhood), and the R contrasts reconstructed along the spectral dimension (singular images), whereas λ is the corresponding parameter promoting low‐rank regularization.…”
Section: Methodsmentioning
confidence: 99%
“…The singular images x estimated with this method can still present remaining undersampling artefacts and lead to noisy parametric maps. HD‐PROST reconstruction proposes to further exploit local (within a patch), non‐local (between patches in a neighborhood), and spectral (between contrasts) redundancies through high‐order low‐rank regularization . HD‐PROST reconstructs the multi‐contrast Dixon‐cMRF singular images x i for each echo i , by jointly solvingLtruex^i,trueT^b:=argminboldxi,scriptTb12∥∥AURFCxi-boldk22+λfalse∑b∥∥scriptTbbolds.boldt.scriptTb=bold-italicPbfalse(xifalse),where P b (·) is the operator that assembles a third order tensor Tb for the patch centered on voxel b by concatenating the K most similar patches along the non‐local similarity dimension (similar patches within a neighborhood), and the R contrasts reconstructed along the spectral dimension (singular images), whereas λ is the corresponding parameter promoting low‐rank regularization.…”
Section: Methodsmentioning
confidence: 99%
“…After data selection, the highly undersampled 3D radial data is reconstructed over multiple T 1 contrasts by combining a dictionary‐based low‐rank inversion to efficiently reduce the number of T 1 contrasts to be reconstructed with a recently proposed high‐dimensionality 3D patch‐based undersampled reconstruction (HD‐PROST), exploiting local (within a patch), non‐local (between similar patches), and contrast redundancies . The reconstruction for the proposed technique can be formulated as the following unconstrained LagrangianLI,T,Y=∥∥EI-D3.33333ptKF2+λfalse∑p∥∥scriptTp+μfalse∑p∥∥Tp-Pp)(I-Pp)(YF2,where ||·|| F and ||·|| * denote the Frobenius norm and nuclear norm respectively; I is the compressed T 1 image series to be reconstructed ; E=DAUrFS is the encoding operator, with S being sensitivity maps, F being Fourier transform, U r being the low‐rank operator obtained by truncating the singular value decomposition (SVD) of a dictionary generated by Bloch simulation, A being the convolutional gridding operator, transforming Cartesian data back to 3D radial, and D being the non‐Cartesian density compensation function; K is the undersampled data; P p (·) is the patch selection operator at pixel p of a 3D multi‐contrast image set. This operator selects patches on local (patch for a given pixel location and contrast), non‐local (similar patches within a neighborhood for a given contrast) and contrast (patches from all the contrasts) scales and Tp is a 3D tensor built by the selected patches centered at pixel p ; T represents the denoised multi‐contrast images constructed by folding and aggregating the tensors Tp for each pixel p (see the step 2 below); Y is the Augmented Lagrangian multiplier; λ is the sparsity‐promoting regularization parameter and µ is the penalty parameter.…”
Section: Methodsmentioning
confidence: 99%
“…The details to solve the above equation can be found in Bustin et al Generally speaking, Tp is obtained by thresholding the singular values obtained via high‐order singular value decomposition of the 3D tensor built by the patches selected from the multi‐contrast images. The thresholding parameter is defined by λμ.…”
Section: Methodsmentioning
confidence: 99%
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