Exploring Structural Sparsity of Coil Images from 3-Dimensional Directional Tight Framelets for SENSE Reconstruction

IF 2.1 3区数学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

SIAM Journal on Imaging Sciences Pub Date : 2024-04-11 DOI:10.1137/23m1571150

Yanran Li, Raymond H. Chan, Lixin Shen, Xiaosheng Zhuang, Risheng Wu, Yijun Huang, Junwei Liu

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引用次数: 0

Abstract

SIAM Journal on Imaging Sciences, Volume 17, Issue 2, Page 888-916, June 2024.
Abstract. Each coil image in a parallel magnetic resonance imaging (pMRI) system is an imaging slice modulated by the corresponding coil sensitivity. These coil images, structurally similar to each other, are stacked together as 3-dimensional (3D) image data, and their sparsity property can be explored via 3D directional Haar tight framelets. The features of the 3D image data from the 3D framelet systems are utilized to regularize sensitivity encoding (SENSE) pMRI reconstruction. Accordingly, a so-called SENSE3d algorithm is proposed to reconstruct images of high quality from the sampled [math]-space data with a high acceleration rate by decoupling effects of the desired image (slice) and sensitivity maps. Since both the imaging slice and sensitivity maps are unknown, this algorithm repeatedly performs a slice step followed by a sensitivity step by using updated estimations of the desired image and the sensitivity maps. In the slice step, for the given sensitivity maps, the estimation of the desired image is viewed as the solution to a convex optimization problem regularized by the sparsity of its 3D framelet coefficients of coil images. This optimization problem, involving data from the complex field, is solved by a primal-dual three-operator splitting (PD3O) method. In the sensitivity step, the estimation of sensitivity maps is modeled as the solution to a Tikhonov-type optimization problem that favors the smoothness of the sensitivity maps. This corresponding problem is nonconvex and could be solved by a forward-backward splitting method. Experiments on real phantoms and in vivo data show that the proposed SENSE3d algorithm can explore the sparsity property of the imaging slices and efficiently produce reconstructed images of high quality with reduced aliasing artifacts caused by high acceleration rate, additive noise, and the inaccurate estimation of each coil sensitivity. To provide a comprehensive picture of the overall performance of our SENSE3d model, we provide the quantitative index (HaarPSI) and comparisons to some deep learning methods such as VarNet and fastMRI-UNet.

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从用于 SENSE 重构的三维定向紧密小帧探索线圈图像的结构稀疏性

SIAM 影像科学杂志》，第 17 卷第 2 期，第 888-916 页，2024 年 6 月。摘要并行磁共振成像（pMRI）系统中的每个线圈图像都是由相应线圈灵敏度调制的成像切片。这些线圈图像在结构上彼此相似，被堆叠在一起成为三维（3D）图像数据，其稀疏性可以通过三维定向哈尔紧帧小帧来探索。三维小帧系统的三维图像数据特征可用于正则化灵敏度编码（SENSE）pMRI 重建。因此，提出了一种所谓的 SENSE3d 算法，通过解耦所需图像（切片）和灵敏度图的影响，以高加速度从采样[数学]空间数据重建高质量图像。由于成像切片和灵敏度图都是未知的，该算法通过使用对所需图像和灵敏度图的最新估计，反复执行切片步骤和灵敏度步骤。在切片步骤中，对于给定的灵敏度图，所需图像的估计值被视为一个凸优化问题的解，该问题通过线圈图像的三维小帧系数的稀疏性进行正则化。该优化问题涉及复数场数据，采用基元-双三运算符分割（PD3O）方法求解。在灵敏度步骤中，灵敏度图的估算被模拟为有利于灵敏度图平滑性的 Tikhonov 型优化问题的解决方案。这个相应的问题是非凸的，可以用前向-后向分割法来解决。在真实模型和活体数据上的实验表明，所提出的 SENSE3d 算法可以探索成像切片的稀疏性，并有效地生成高质量的重建图像，减少了由高加速度、加性噪声和对每个线圈灵敏度的不准确估计引起的混叠伪影。为了全面展示 SENSE3d 模型的整体性能，我们提供了定量指标（HaarPSI），并与 VarNet 和 fastMRI-UNet 等深度学习方法进行了比较。

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来源期刊

SIAM Journal on Imaging Sciences COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-COMPUTER SCIENCE, SOFTWARE ENGINEERING

CiteScore

3.80

自引率

4.80%

发文量

审稿时长

>12 weeks

期刊介绍： SIAM Journal on Imaging Sciences (SIIMS) covers all areas of imaging sciences, broadly interpreted. It includes image formation, image processing, image analysis, image interpretation and understanding, imaging-related machine learning, and inverse problems in imaging; leading to applications to diverse areas in science, medicine, engineering, and other fields. The journal’s scope is meant to be broad enough to include areas now organized under the terms image processing, image analysis, computer graphics, computer vision, visual machine learning, and visualization. Formal approaches, at the level of mathematics and/or computations, as well as state-of-the-art practical results, are expected from manuscripts published in SIIMS. SIIMS is mathematically and computationally based, and offers a unique forum to highlight the commonality of methodology, models, and algorithms among diverse application areas of imaging sciences. SIIMS provides a broad authoritative source for fundamental results in imaging sciences, with a unique combination of mathematics and applications. SIIMS covers a broad range of areas, including but not limited to image formation, image processing, image analysis, computer graphics, computer vision, visualization, image understanding, pattern analysis, machine intelligence, remote sensing, geoscience, signal processing, medical and biomedical imaging, and seismic imaging. The fundamental mathematical theories addressing imaging problems covered by SIIMS include, but are not limited to, harmonic analysis, partial differential equations, differential geometry, numerical analysis, information theory, learning, optimization, statistics, and probability. Research papers that innovate both in the fundamentals and in the applications are especially welcome. SIIMS focuses on conceptually new ideas, methods, and fundamentals as applied to all aspects of imaging sciences.