Your search keyword '"Jacob, Mathews"' showing total 27 results

1. Deep learning for accelerated and robust MRI reconstruction

Author

Heckel, Reinhard, Jacob, Mathews, Chaudhari, Akshay, Perlman, Or, and Shimron, Efrat

Published

2024

2. Joint Cardiac T 1 Mapping and Cardiac Cine Using Manifold Modeling.

Author

Zou, Qing, Priya, Sarv, Nagpal, Prashant, and Jacob, Mathews

Subjects

CONVOLUTIONAL neural networks, CHROMOSOME inversions, NONLINEAR functions, TIME series analysis, CARDIAC magnetic resonance imaging

Abstract

The main focus of this work is to introduce a single free-breathing and ungated imaging protocol to jointly estimate cardiac function and myocardial T 1 maps. We reconstruct a time series of images corresponding to k-space data from a free-breathing and ungated inversion recovery gradient echo sequence using a manifold algorithm. We model each image in the time series as a non-linear function of three variables: cardiac and respiratory phases and inversion time. The non-linear function is realized using a convolutional neural networks (CNN) generator, while the CNN parameters, as well as the phase information, are estimated from the measured k-t space data. We use a dense conditional auto-encoder to estimate the cardiac and respiratory phases from the central multi-channel k-space samples acquired at each frame. The latent vectors of the auto-encoder are constrained to be bandlimited functions with appropriate frequency bands, which enables the disentanglement of the latent vectors into cardiac and respiratory phases, even when the data are acquired with intermittent inversion pulses. Once the phases are estimated, we pose the image recovery as the learning of the parameters of the CNN generator from the measured k-t space data. The learned CNN generator is used to generate synthetic data on demand by feeding it with appropriate latent vectors. The proposed approach capitalizes on the synergies between cine MRI and T 1 mapping to reduce the scan time and improve patient comfort. The framework also enables the generation of synthetic breath-held cine movies with different inversion contrasts, which improves the visualization of the myocardium. In addition, the approach also enables the estimation of the T 1 maps with specific phases, which is challenging with breath-held approaches. [ABSTRACT FROM AUTHOR]

Published

2023

3. Variational Manifold Learning From Incomplete Data: Application to Multislice Dynamic MRI.

Author

Zou, Qing, Ahmed, Abdul Haseeb, Nagpal, Prashant, Priya, Sarv, Schulte, Rolf F., and Jacob, Mathews

Subjects

CARDIAC magnetic resonance imaging, MACHINE learning, MAGNETIC resonance imaging, DEEP learning, IMAGE registration, IMAGE reconstruction

Abstract

Current deep learning-based manifold learning algorithms such as the variational autoencoder (VAE) require fully sampled data to learn the probability density of real-world datasets. However, fully sampled data is often unavailable in a variety of problems, including the recovery of dynamic and high-resolution magnetic resonance imaging (MRI). We introduce a novel variational approach to learn a manifold from undersampled data. The VAE uses a decoder fed by latent vectors, drawn from a conditional density estimated from the fully sampled images using an encoder. Since fully sampled images are not available in our setting, we approximate the conditional density of the latent vectors by a parametric model whose parameters are estimated from the undersampled measurements using back-propagation. We use the framework for the joint alignment and recovery of multi-slice free breathing and ungated cardiac MRI data from highly undersampled measurements. Experimental results demonstrate the utility of the proposed scheme in dynamic imaging alignment and reconstructions. [ABSTRACT FROM AUTHOR]

Published

2022

4. Dynamic Imaging Using Deep Bi-Linear Unsupervised Representation (DEBLUR).

Author

Ahmed, Abdul Haseeb, Zou, Qing, Nagpal, Prashant, and Jacob, Mathews

Subjects

DEEP learning, CARDIAC magnetic resonance imaging, CONVOLUTIONAL neural networks, NOISE measurement, MAGNETIC resonance imaging, REGULARIZATION parameter

Abstract

Bilinear models such as low-rank and dictionary methods, which decompose dynamic data to spatial and temporal factor matrices are powerful and memory-efficient tools for the recovery of dynamic MRI data. Current bilinear methods rely on sparsity and energy compaction priors on the factor matrices to regularize the recovery. Motivated by deep image prior, we introduce a novel bilinear model, whose factor matrices are generated using convolutional neural networks (CNNs). The CNN parameters, and equivalently the factors, are learned from the undersampled data of the specific subject. Unlike current unrolled deep learning methods that require the storage of all the time frames in the dataset, the proposed approach only requires the storage of the factors or compressed representation; this approach allows the direct use of this scheme to large-scale dynamic applications, including free breathing cardiac MRI considered in this work. To reduce the run time and to improve performance, we initialize the CNN parameters using existing factor methods. We use sparsity regularization of the network parameters to minimize the overfitting of the network to measurement noise. Our experiments on free-breathing and ungated cardiac cine data acquired using a navigated golden-angle gradient-echo radial sequence show the ability of our method to provide reduced spatial blurring as compared to classical bilinear methods as well as a recent unsupervised deep-learning approach. [ABSTRACT FROM AUTHOR]

Published

2022

5. Deep Tomographic Image Reconstruction: Yesterday, Today, and Tomorrow—Editorial for the 2nd Special Issue “Machine Learning for Image Reconstruction”.

Author

Wang, Ge, Jacob, Mathews, Mou, Xuanqin, Shi, Yongyi, and Eldar, Yonina C.

Subjects

*IMAGE reconstruction, *MACHINE learning, *TOMOGRAPHY, *DEEP learning, *ARTIFICIAL intelligence, *COMPUTER programming education

Abstract

As a follow-up to the first IEEE Transactions on Medical Imaging (TMI) special issue on the theme of deep tomographic reconstruction, the second special issue is assembled to reflect the status and momentum of this rapidly emerging field. In this editorial, we provide a brief background illustrating the motivation for the development of network-based, data-driven, and learning-oriented reconstruction methods, summarize the included papers, and report our verification of the shared deep learning codes. Finally, we discuss several important research topics to facilitate further investigation and collaboration. [ABSTRACT FROM AUTHOR]

Published

2021

6. Dynamic Imaging Using a Deep Generative SToRM (Gen-SToRM) Model.

Author

Zou, Qing, Ahmed, Abdul Haseeb, Nagpal, Prashant, Kruger, Stanley, and Jacob, Mathews

Subjects

PROBABILISTIC generative models, CONVOLUTIONAL neural networks, IMAGE reconstruction, ALGORITHMS, COST functions, COMPUTATIONAL complexity

Abstract

We introduce a generative smoothness regularization on manifolds (SToRM) model for the recovery of dynamic image data from highly undersampled measurements. The model assumes that the images in the dataset are non-linear mappings of low-dimensional latent vectors. We use the deep convolutional neural network (CNN) to represent the non-linear transformation. The parameters of the generator as well as the low-dimensional latent vectors are jointly estimated only from the undersampled measurements. This approach is different from traditional CNN approaches that require extensive fully sampled training data. We penalize the norm of the gradients of the non-linear mapping to constrain the manifold to be smooth, while temporal gradients of the latent vectors are penalized to obtain a smoothly varying time-series. The proposed scheme brings in the spatial regularization provided by the convolutional network. The main benefit of the proposed scheme is the improvement in image quality and the orders-of-magnitude reduction in memory demand compared to traditional manifold models. To minimize the computational complexity of the algorithm, we introduce an efficient progressive training-in-time approach and an approximate cost function. These approaches speed up the image reconstructions and offers better reconstruction performance. [ABSTRACT FROM AUTHOR]

Published

2021

7. Compressed sensing MRI using an interpolation‐free nonlinear diffusion model.

Author

Joy, Ajin, Jacob, Mathews, and Paul, Joseph Suresh

Subjects

COMPRESSED sensing, MAGNETIC resonance imaging, INTERPOLATION, DIFFUSION, IMAGE reconstruction

Abstract

Purpose: Constraints in extended neighborhood system demand the use of a large number of interpolations in directionality‐guided compressed‐sensing nonlinear diffusion MR image reconstruction technique. This limits its practical application in terms of computational complexity. The proposed method aims at multifold improvement in its runtime without compromising the image quality. Theory and Methods: Conventional approach to extended neighborhood computation requires 108 linear interpolations per pixel for 10 sets of neighborhoods. We propose a neighborhood stretching technique that systematically extends the location of neighboring pixels such that 66% to 100% fewer interpolations are required to compute the gradients along multiple directions. A spatial frequency–based deviation measure is then used to choose the most reliable edges from the set of images generated by diffusion along different directions. Results: The semi‐interpolated and interpolation‐free diffusion techniques proposed in this paper are compared with the fully interpolated diffusion‐based reconstruction by reconstruing multiple multichannel in vivo datasets, undersampled using different sampling patterns at various sampling rates. Results indicate a two‐ to fivefold increase in reconstruction speed with a potential to generate 1 to 2 dB improvement in peak SNR measure. Conclusion: The proposed method outperforms the state‐of‐the‐art fully interpolated diffusion model and generates high‐quality reconstructions for different sampling patterns and acceleration factors with a two‐ to fivefold increment in reconstruction speed. This makes it the most suitable candidate for edge‐preserving penalties used in the compressed sensing MRI reconstruction methods. [ABSTRACT FROM AUTHOR]

Published

2021

8. Deep Generalization of Structured Low-Rank Algorithms (Deep-SLR).

Author

Pramanik, Aniket, Aggarwal, Hemant Kumar, and Jacob, Mathews

Subjects

K-spaces, CONVOLUTIONAL neural networks, LOW-rank matrices, IMAGE reconstruction, ALGORITHMS, IMAGE reconstruction algorithms

Abstract

Structured low-rank (SLR) algorithms, which exploit annihilation relations between the Fourier samples of a signal resulting from different properties, is a powerful image reconstruction framework in several applications. This scheme relies on low-rank matrix completion to estimate the annihilation relations from the measurements. The main challenge with this strategy is the high computational complexity of matrix completion. We introduce a deep learning (DL) approach to significantly reduce the computational complexity. Specifically, we use a convolutional neural network (CNN)-based filterbank that is trained to estimate the annihilation relations from imperfect (under-sampled and noisy) k-space measurements of Magnetic Resonance Imaging (MRI). The main reason for the computational efficiency is the pre-learning of the parameters of the non-linear CNN from exemplar data, compared to SLR schemes that learn the linear filterbank parameters from the dataset itself. Experimental comparisons show that the proposed scheme can enable calibration-less parallel MRI; it can offer performance similar to SLR schemes while reducing the runtime by around three orders of magnitude. Unlike pre-calibrated and self-calibrated approaches, the proposed uncalibrated approach is insensitive to motion errors and affords higher acceleration. The proposed scheme also incorporates image domain priors that are complementary, thus significantly improving the performance over that of SLR schemes. [ABSTRACT FROM AUTHOR]

Published

2020

9. Free-Breathing and Ungated Dynamic MRI Using Navigator-Less Spiral SToRM.

Author

Ahmed, Abdul Haseeb, Zhou, Ruixi, Yang, Yang, Nagpal, Prashant, Salerno, Michael, and Jacob, Mathews

Subjects

LOW-rank matrices, K-spaces, MISSING data (Statistics), FOUR-dimensional imaging, RESPIRATION, SPIRAL computed tomography, ALGORITHMS, EXPLORERS

Abstract

We introduce a kernel low-rank algorithm to recover free-breathing and ungated dynamic MRI from spiral acquisitions without explicit k-space navigators. It is often challenging for low-rank methods to recover free-breathing and ungated images from undersampled measurements; extensive cardiac and respiratory motion often results in the Casorati matrix not being sufficiently low-rank. Therefore, we exploit the non-linear structure of the dynamic data, which gives the low-rank kernel matrix. Unlike prior work that rely on navigators to estimate the manifold structure, we propose a kernel low-rank matrix completion method to directly fill in the missing k-space data from variable density spiral acquisitions. We validate the proposed scheme using simulated data and in-vivo data. Our results show that the proposed scheme provides improved reconstructions compared to the classical methods such as low-rank and XD-GRASP. The comparison with breath-held cine data shows that the quantitative metrics agree, whereas the image quality is marginally lower. [ABSTRACT FROM AUTHOR]

Published

2020

10. J-MoDL: Joint Model-Based Deep Learning for Optimized Sampling and Reconstruction.

Author

Aggarwal, Hemant Kumar and Jacob, Mathews

Abstract

Modern MRI schemes, which rely on compressed sensing or deep learning algorithms to recover MRI data from undersampled multichannel Fourier measurements, are widely used to reduce the scan time. The image quality of these approaches is heavily dependent on the sampling pattern. In this article, we introduce a continuous strategy to optimize the sampling pattern and the network parameters jointly. We use a multichannel forward model, consisting of a non-uniform Fourier transform with continuously defined sampling locations, to realize the data consistency block within a model-based deep learning image reconstruction scheme. This approach facilitates the joint and continuous optimization of the sampling pattern and the CNN parameters to improve image quality. We observe that the joint optimization of the sampling patterns and the reconstruction module significantly improves the performance of most deep learning reconstruction algorithms. The source code of the proposed joint learning framework is available at https://github.com/hkaggarwal/J-MoDL. [ABSTRACT FROM AUTHOR]

Published

2020

11. MoDL-MUSSELS: Model-Based Deep Learning for Multishot Sensitivity-Encoded Diffusion MRI.

Author

Aggarwal, Hemant K., Mani, Merry P., and Jacob, Mathews

Subjects

ECHO-planar imaging, DIFFUSION magnetic resonance imaging, ARTIFICIAL neural networks, FILTER banks, COMPUTATIONAL complexity, MAGNETIC resonance imaging, DEEP learning, DATABASES

Abstract

We introduce a model-based deep learning architecture termed MoDL-MUSSELS for the correction of phase errors in multishot diffusion-weighted echo-planar MR images. The proposed algorithm is a generalization of the existing MUSSELS algorithm with similar performance but significantly reduced computational complexity. In this work, we show that an iterative re-weighted least-squares implementation of MUSSELS alternates between a multichannel filter bank and the enforcement of data consistency. The multichannel filter bank projects the data to the signal subspace, thus exploiting the annihilation relations between shots. Due to the high computational complexity of the self-learned filter bank, we propose replacing it with a convolutional neural network (CNN) whose parameters are learned from exemplary data. The proposed CNN is a hybrid model involving a multichannel CNN in the k-space and another CNN in the image space. The k-space CNN exploits the annihilation relations between the shot images, while the image domain network is used to project the data to an image manifold. The experiments show that the proposed scheme can yield reconstructions that are comparable to state-of-the-art methods while offering several orders of magnitude reduction in run-time. [ABSTRACT FROM AUTHOR]

Published

2020

12. Hyperspectral Image Recovery Using Nonconvex Sparsity and Low-Rank Regularizations.

Author

Hu, Yue, Li, Xiaodi, Gu, Yanfeng, and Jacob, Mathews

Subjects

IMAGE quality analysis, IMAGE reconstruction algorithms, MATHEMATICAL regularization, IMAGE reconstruction, ALGORITHMS

Abstract

Hyperspectral image (HSI) restoration is an important preprocessing step in HSI data analysis to improve the image quality for subsequent applications of HSI. In this article, we introduce a spatial–spectral patch-based nonconvex sparsity and low-rank regularization method for HSI restoration. In contrast to traditional approaches based on convex penalties or nonconvex spectral penalty alone, we consider the sparsity of HSI in the spatial–spectral domain and combine the nonconvex low-rank penalty and the nonconvex 3-D total variation (TV)-like sparsity regularization to fully exploit the correlations in both spatial–spectral dimensions of the HSI data set. In addition, we propose a fast iterative variable splitting-based algorithm to effectively solve the corresponding optimization problem. Numerical experiments on both simulated and real HSI data sets demonstrate that the proposed nonconvex low-rank and TV (NonLRTV) method significantly improves the recovered image quality compared with the state-of-the-art algorithms. [ABSTRACT FROM AUTHOR]

Published

2020

13. Directionality guided non linear diffusion compressed sensing MR image reconstruction.

Author

Joy, Ajin, Jacob, Mathews, and Paul, Joseph Suresh

Subjects

IMAGE reconstruction, MAGNETIC resonance imaging, DIFFUSION, NATURE reserves, SIGNAL-to-noise ratio

Abstract

Purpose: Address the shortcomings of edge‐preserving filters to preserve the complex nature of edges, by adapting the direction of diffusion to the local variations in intensity function on a subpixel level, thereby achieving a reconstruction accuracy superior to that of data‐driven learning‐based approaches. Theory and Methods: Rate of diffusion for edges is found to vary in accordance with their gradient direction. Therefore, the edge preservation is strongly dependent on the direction in which the gradient is computed. Since the directionality of edges varies at different regions of the image, the proposed technique computes the gradients in all possible angular directions and uses a spatial‐frequency‐based deviation measure to choose the most reliable edges from the images diffused along different directions. Results: The proposed method is compared with the state‐of‐the‐art data‐driven learning‐based techniques of block matching and 3D filtering (BM3D), patch‐based nonlocal operator (PANO), and dictionary learning MRI (DLMRI). Best results are obtained when directionality of edges is estimated from a prior optimized k‐space and shows an improvement in peak signal‐to‐noise ratio (PSNR) measures by a factor of 2.36 dB, 1.92 dB, and 1.59 dB over BM3D, PANO, and dictionary learning MRI, respectively. Conclusion: The proposed technique prevents the emphasis of false edges and better captures the structural details by a locally varying directionality‐guided diffusion to make the error lower than that of the state‐of‐the‐art reconstruction techniques. In addition, a highly parallelizable form of the proposed model promises a significant gain in the reconstruction speed for practical implementations. [ABSTRACT FROM AUTHOR]

Published

2019

14. Free-Breathing & Ungated Cardiac MRI Using Iterative SToRM (i-SToRM).

Author

Mohsin, Yasir Q., Poddar, Sunrita, and Jacob, Mathews

Subjects

CARDIOGRAPHIC tomography, COST functions, MATHEMATICAL optimization

Abstract

We introduce a local manifold regularization approach to recover dynamic MRI data from highly undersampled measurements. The proposed scheme relies on the manifold structure of local image patches at the same spatial location in a free-breathing cardiac MRI dataset; this approach is a generalization of the SmooThness Regularization on Manifolds (SToRM) scheme that exploits the global manifold structure of images in the dataset. Since the manifold structure of the patches varies depending on the spatial location and is often considerably simpler than the global one, this approach significantly reduces the data demand, facilitating the recovery from shorter scans. Since the navigator-based estimation of manifold structure pursued in SToRM is not feasible in this setting, a reformulation of SToRM is introduced. Specifically, the regularization term of the cost function involves the sum of robust distances between images sub-patches in the dataset. The optimization algorithm alternates between updating the images and estimating the manifold structure of the image patches. The utility of the proposed scheme is demonstrated in the context of $\textit {in-vivo}$ prospective free-breathing cardiac CINE MRI imaging with multichannel acquisitions and simulated phantoms. The new framework facilitates a reduction in scan time, as compared to the SToRM strategy. [ABSTRACT FROM AUTHOR]

Published

2019

15. A Generalized Structured Low-Rank Matrix Completion Algorithm for MR Image Recovery.

Author

Hu, Yue, Liu, Xiaohan, and Jacob, Mathews

Subjects

PIECEWISE constant approximation, LOW-rank matrices, MATHEMATICAL regularization, ORTHOGONAL matching pursuit, MAGNETIC resonance imaging, ALGORITHMS, HANKEL functions

Abstract

Recent theory of mapping an image into a structured low-rank Toeplitz or Hankel matrix has become an effective method to restore images. In this paper, we introduce a generalized structured low-rank algorithm to recover images from their undersampled Fourier coefficients using infimal convolution regularizations. The image is modeled as the superposition of a piecewise constant component and a piecewise linear component. The Fourier coefficients of each component satisfy an annihilation relation, which results in a structured Toeplitz matrix. We exploit the low-rank property of the matrices to formulate a combined regularized optimization problem. In order to solve the problem efficiently and to avoid the high-memory demand resulting from the large-scale Toeplitz matrices, we introduce a fast and a memory-efficient algorithm based on the half-circulant approximation of the Toeplitz matrix. We demonstrate our algorithm in the context of single and multi-channel MR images recovery. Numerical experiments indicate that the proposed algorithm provides improved recovery performance over the state-of-the-art approaches. [ABSTRACT FROM AUTHOR]

Published

2019

16. MoDL: Model-Based Deep Learning Architecture for Inverse Problems.

Author

Aggarwal, Hemant K., Mani, Merry P., and Jacob, Mathews

Subjects

DEEP learning, INVERSE problems, IMAGE reconstruction, ARTIFICIAL neural networks, MATHEMATICAL regularization

Abstract

We introduce a model-based image reconstruction framework with a convolution neural network (CNN)-based regularization prior. The proposed formulation provides a systematic approach for deriving deep architectures for inverse problems with the arbitrary structure. Since the forward model is explicitly accounted for, a smaller network with fewer parameters is sufficient to capture the image information compared to direct inversion approaches. Thus, reducing the demand for training data and training time. Since we rely on end-to-end training with weight sharing across iterations, the CNN weights are customized to the forward model, thus offering improved performance over approaches that rely on pre-trained denoisers. Our experiments show that the decoupling of the number of iterations from the network complexity offered by this approach provides benefits, including lower demand for training data, reduced risk of overfitting, and implementations with significantly reduced memory footprint. We propose to enforce data-consistency by using numerical optimization blocks, such as conjugate gradients algorithm within the network. This approach offers faster convergence per iteration, compared to methods that rely on proximal gradients steps to enforce data consistency. Our experiments show that the faster convergence translates to improved performance, primarily when the available GPU memory restricts the number of iterations. [ABSTRACT FROM AUTHOR]

Published

2019

17. Recovery of Damped Exponentials Using Structured Low Rank Matrix Completion.

Author

Balachandrasekaran, Arvind, Magnotta, Vincent, and Jacob, Mathews

Subjects

LOW-rank matrices, EXPONENTIAL functions, IMAGE reconstruction, COMPUTER algorithms, PIXELS, FOURIER analysis, COMPUTATIONAL complexity

Abstract

We introduce a structured low rank matrix completion algorithm to recover a series of images from their under-sampled measurements, where the signal along the parameter dimension at every pixel is described by a linear combination of exponentials. We exploit the exponential behavior of the signal at every pixel, along with the spatial smoothness of the exponential parameters to derive an annihilation relation in the Fourier domain. This relation translates to a low-rank property on a structured matrix constructed from the Fourier samples. We enforce the low-rank property of the structured matrix as a regularization prior to recover the images. Since the direct use of current low rank matrix recovery schemes to this problem is associated with high computational complexity and memory demand, we adopt an iterative re-weighted least squares algorithm, which facilitates the exploitation of the convolutional structure of the matrix. Novel approximations involving 2-D fast Fourier transforms are introduced to drastically reduce the memory demand and computational complexity, which facilitates the extension of structured low-rank methods to large scale 3-D problems. We demonstrate our algorithm in the MR parameter mapping setting and show improvement over the state-of-the-art methods. [ABSTRACT FROM PUBLISHER]

Published

2017

18. Off-the-Grid Recovery of Piecewise Constant Images from Few Fourier Samples.

Author

Ongie, Greg and Jacob, Mathews

Subjects

PIECEWISE constant approximation, LOCALIZATION (Mathematics), HIGH resolution imaging, IMAGE reconstruction, MATHEMATICAL domains, DERIVATIVES (Mathematics)

Abstract

We introduce a method to recover a continuous domain representation of a piecewise constant twodimensional image from few low-pass Fourier samples. Assuming the edge set of the image is localized to the zero set of a trigonometric polynomial, we show that the Fourier coefficients of the partial derivatives of the image satisfy a linear annihilation relation. We present necessary and sufficient conditions for unique recovery of the image from finite low-pass Fourier samples using the annihilation relation. We also propose a practical two-stage recovery algorithm that is robust to model-mismatch and noise. In the first stage we estimate a continuous domain representation of the edge set of the image. In the second stage we perform an extrapolation in Fourier domain by a least squares twodimensional linear prediction, which recovers the exact Fourier coefficients of the underlying image. We demonstrate our algorithm on the superresolution recovery of MRI phantoms and real MRI data from low-pass Fourier samples, which shows benefits over standard approaches for single-image superresolution MRI. [ABSTRACT FROM AUTHOR]

Published

2016

19. Deformation Corrected Compressed Sensing (DC-CS): A Novel Framework for Accelerated Dynamic MRI.

Author

Lingala, Sajan Goud, DiBella, Edward, and Jacob, Mathews

Subjects

COMPRESSED sensing, MAGNETIC resonance imaging, ESTIMATION theory, COMPACT spaces (Topology), FOURIER analysis, MATHEMATICAL decoupling

Abstract

We propose a novel deformation corrected compressed sensing (DC-CS) framework to recover contrast enhanced dynamic magnetic resonance images from undersampled measurements. We introduce a formulation that is capable of handling a wide class of sparsity/compactness priors on the deformation corrected dynamic signal. In this work, we consider example compactness priors such as sparsity in temporal Fourier domain, sparsity in temporal finite difference domain, and nuclear norm penalty to exploit low rank structure. Using variable splitting, we decouple the complex optimization problem to simpler and well understood sub problems; the resulting algorithm alternates between simple steps of shrinkage-based denoising, deformable registration, and a quadratic optimization step. Additionally, we employ efficient continuation strategies to reduce the risk of convergence to local minima. The decoupling enabled by the proposed scheme enables us to apply this scheme to contrast enhanced MRI applications. Through experiments on numerical phantom and in vivo myocardial perfusion MRI datasets, we observe superior image quality of the proposed DC-CS scheme in comparison to the classical k-t FOCUSS with motion estimation/correction scheme, and demonstrate reduced motion artifacts over classical compressed sensing schemes that utilize the compact priors on the original deformation uncorrected signal. [ABSTRACT FROM AUTHOR]

Published

2015

20. A blind compressive sensing frame work for accelerated dynamic MRI.

Author

Lingala, Sajan Goud and Jacob, Mathews

Abstract

We propose a novel blind compressive sensing (BCS) frame work to recover dynamic images from under-sampled measurements. This scheme models the the dynamic signal as a sparse linear combination of temporal basis functions, chosen from a large dictionary. The dictionary and the sparse coefficients are simultaneously estimated from the under-sampled measurements. Since the number of degrees of freedom of this model is much smaller than that of current low-rank methods, this scheme is expected to provide improved reconstructions for datasets with considerable inter-frame motion. We develop an efficient majorize-minimize algorithm to solve for the dynamic images. We use a continuation strategy to minimize the convergence of the algorithm to local minima. Numerical comparisons of the BCS scheme with low-rank methods demonstrate the significant improvement in performance in the presence of motion. [ABSTRACT FROM PUBLISHER]

Published

2012

21. Robust non-local regularization framework for motion compensated dynamic imaging without explicit motion estimation.

Author

Yang, Zhili and Jacob, Mathews

Abstract

We introduce an regularized reconstruction scheme to recover dynamic imaging datasets with significant inter frame motion from undersampled Fourier data. The proposed nonlocal regularization penalty is an unweighted sum of distances between image patch pairs in the 3-D dataset. We use robust distance metrics to compute the distance between image patches; these metrics encourage the smoothing between similar patches, while discouraging the averaging of dissimilar patches. Hence, this algorithm is capable of exploiting the similarities between patch pairs in adjacent frames even when they are well separated due to motion, eventhough it does not perform explicit motion estimation. Unlike current non-local regularization schemes, the proposed penalty does not need good initial guesses to estimate the weights. Hence, this approach is readily applicable to accelerated dynamic imaging problems, where good initial guesses are challenging to obtain. The validation of the proposed scheme on numerical phantoms and dynamic MRI datasets demonstrate the superior performance of the proposed scheme over current dynamic imaging schemes. [ABSTRACT FROM PUBLISHER]

Published

2012

22. Improved higher degree total variation (HDTV) regularization.

Author

Hu, Yue and Jacob, Mathews

Abstract

The main focus of this paper is to further improve the performance of the recently introduced higher degree total variation (HDTV) penalties, which are L1-Lp; p ≥ 1 norms of directional image derivatives. We generalize this class as the L1-Lp norms of image responses to rotated versions of an arbitrary derivative operator. We show that several penalties proposed by other researchers are special cases of the generalized isotropic penalties (p = 2), when the derivative operator is chosen appropriately; our experiments show that the anisotropic (p = 1) versions of these penalties provide improved reconstructions. In addition, we optimize the derivative operator for improved orientation selectivity, thus further improving the ability of the resulting penalties to provide high quality image reconstructions. We also focus on the efficient discretization of HDTV penalties, which are specified in the continuous domain. Specifically, we approximate the derivative operators as the sum of partial derivatives of an almost isotropic B-spline window. Our numerical experiments confirm the benefit of the improved discretization and the optimization of the operator. [ABSTRACT FROM PUBLISHER]

Published

2012

23. Accelerating non-Cartesian sense for large coil arrays: Application to motion compensation in multishot DWI.

Author

Mani, Merry, Jacob, Mathews, Guidon, Arnaud, Magnotta, Vincent, and Zhong, Jianhui

Abstract

Multi-shot sequences are often combined with techniques such as parallel imaging to achieve high fidelity images. For non-Cartesian sampling schemes, the reconstruction of such data becomes extremely computationally intensive. The problem of motion compensated SENSE reconstruction of non-Cartesian diffusion weighted images falls into a similar setting, when phase corrections are involved. Here we propose a new pipeline for the fast reconstruction of such data. The large array of composite sensitivity functions are replaced by a low-dimensional set of virtual sensitivity functions using a principal component analysis, thus enabling the evaluation of very few Fourier transforms. The time consuming gridding steps are replaced by a more efficient multiplication in the k-space, enabling further simplifications. Significant acceleration of reconstruction time is shown to be achieved with the new scheme. The algorithm in the general setting can accelerate SENSE reconstruction for large coil arrays. [ABSTRACT FROM PUBLISHER]

Published

2012

24. Mean square optimal NUFFT approximation for efficient non-Cartesian MRI reconstruction.

Author

Yang, Zhili and Jacob, Mathews

Subjects

*MEAN square algorithms, *MAGNETIC resonance imaging, *ITERATIVE methods (Mathematics), *IMAGE quality in imaging systems, *GRAPHICS processing units, *IMAGE reconstruction

Abstract

Highlights: [•] Novel NUFFT approximations for iterative non-Cartesian MRI reconstruction. [•] Better reconstructed image quality with less approximation error. [•] Considerably less memory demand compared to current algorithms, enabling implementations on GPUs. [Copyright &y& Elsevier]

Published

2014

25. Quantitative Comparison of Reconstruction Methods for Intra-Voxel Fiber Recovery From Diffusion MRI.

Author

Daducci, Alessandro, Canales-Rodriguez, Erick Jorge, Descoteaux, Maxime, Garyfallidis, Eleftherios, Gur, Yaniv, Lin, Ying-Chia, Mani, Merry, Merlet, Sylvain, Paquette, Michael, Ramirez-Manzanares, Alonso, Reisert, Marco, Rodrigues, Paulo Reis, Sepehrband, Farshid, Caruyer, Emmanuel, Choupan, Jeiran, Deriche, Rachid, Jacob, Mathews, Menegaz, Gloria, Prckovska, Vesna, and Rivera, Mariano

Subjects

DIFFUSION magnetic resonance imaging, ALGORITHMS, SPECTRUM analysis, COMPRESSED sensing, PHYSICIANS, DATA analysis, COMPARATIVE studies

Abstract

Validation is arguably the bottleneck in the diffusion magnetic resonance imaging (MRI) community. This paper evaluates and compares 20 algorithms for recovering the local intra-voxel fiber structure from diffusion MRI data and is based on the results of the “HARDI reconstruction challenge” organized in the context of the “ISBI 2012” conference. Evaluated methods encompass a mixture of classical techniques well known in the literature such as diffusion tensor, Q-Ball and diffusion spectrum imaging, algorithms inspired by the recent theory of compressed sensing and also brand new approaches proposed for the first time at this contest. To quantitatively compare the methods under controlled conditions, two datasets with known ground-truth were synthetically generated and two main criteria were used to evaluate the quality of the reconstructions in every voxel: correct assessment of the number of fiber populations and angular accuracy in their orientation. This comparative study investigates the behavior of every algorithm with varying experimental conditions and highlights strengths and weaknesses of each approach. This information can be useful not only for enhancing current algorithms and develop the next generation of reconstruction methods, but also to assist physicians in the choice of the most adequate technique for their studies. [ABSTRACT FROM AUTHOR]

Published

2014

26. Blind Compressive Sensing Dynamic MRI.

Author

Lingala, Sajan Goud and Jacob, Mathews

Subjects

*COMPRESSED sensing, *COEFFICIENTS (Statistics), *IMAGE reconstruction, *MAGNETIC resonance imaging, *MACHINE learning, *DIAGNOSTIC imaging

Abstract

We propose a novel blind compressive sensing (BCS) frame work to recover dynamic magnetic resonance images from undersampled measurements. This scheme models the dynamic signal as a sparse linear combination of temporal basis functions, chosen from a large dictionary. In contrast to classical compressed sensing, the BCS scheme simultaneously estimates the dictionary and the sparse coefficients from the undersampled measurements. Apart from the sparsity of the coefficients, the key difference of the BCS scheme with current low rank methods is the nonorthogonal nature of the dictionary basis functions. Since the number of degrees-of-freedom of the BCS model is smaller than that of the low-rank methods, it provides improved reconstructions at high acceleration rates. We formulate the reconstruction as a constrained optimization problem; the objective function is the linear combination of a data consistency term and sparsity promoting \ell1 prior of the coefficients. The Frobenius norm dictionary constraint is used to avoid scale ambiguity. We introduce a simple and efficient majorize–minimize algorithm, which decouples the original criterion into three simpler subproblems. An alternating minimization strategy is used, where we cycle through the minimization of three simpler problems. This algorithm is seen to be considerably faster than approaches that alternates between sparse coding and dictionary estimation, as well as the extension of K-SVD dictionary learning scheme. The use of the \ell1 penalty and Frobenius norm dictionary constraint enables the attenuation of insignificant basis functions compared to the \ell0 norm and column norm constraint assumed in most dictionary learning algorithms; this is especially important since the number of basis functions that can be reliably estimated is restricted by the available measurements. We also observe that the proposed scheme is more robust to local minima compared to K-SVD method, which relies on greedy sparse coding. Our phase transition experiments demonstrate that the BCS scheme provides much better recovery rates than classical Fourier-based CS schemes, while being only marginally worse than the dictionary aware setting. Since the overhead in additionally estimating the dictionary is low, this method can be very useful in dynamic magnetic resonance imaging applications, where the signal is not sparse in known dictionaries. We demonstrate the utility of the BCS scheme in accelerating contrast enhanced dynamic data. We observe superior reconstruction performance with the BCS scheme in comparison to existing low rank and compressed sensing schemes. [ABSTRACT FROM AUTHOR]

Published

2013

27. Accelerated Dynamic MRI Exploiting Sparsity and Low-Rank Structure: k-t SLR.

Author

Lingala, Sajan Goud, Hu, Yue, DiBella, Edward, and Jacob, Mathews

Subjects

MAGNETIC resonance imaging, IMAGE compression, IMAGE reconstruction, DYNAMICS, ALGORITHMS, MATHEMATICAL optimization, HEURISTIC algorithms, SPARSE matrices

Abstract

We introduce a novel algorithm to reconstruct dynamic magnetic resonance imaging (MRI) data from under-sampled k-t space data. In contrast to classical model based cine MRI schemes that rely on the sparsity or banded structure in Fourier space, we use the compact representation of the data in the Karhunen Louve transform (KLT) domain to exploit the correlations in the dataset. The use of the data-dependent KL transform makes our approach ideally suited to a range of dynamic imaging problems, even when the motion is not periodic. In comparison to current KLT-based methods that rely on a two-step approach to first estimate the basis functions and then use it for reconstruction, we pose the problem as a spectrally regularized matrix recovery problem. By simultaneously determining the temporal basis functions and its spatial weights from the entire measured data, the proposed scheme is capable of providing high quality reconstructions at a range of accelerations. In addition to using the compact representation in the KLT domain, we also exploit the sparsity of the data to further improve the recovery rate. Validations using numerical phantoms and in vivo cardiac perfusion MRI data demonstrate the significant improvement in performance offered by the proposed scheme over existing methods. [ABSTRACT FROM AUTHOR]

Published

2011