Acquisition Acceleration of Ultra-low Field MRI with Parallel Imaging and Compressed Sensing in Microtesla Fields.

IF 4.4 2区医学 Q2 ENGINEERING, BIOMEDICAL

IEEE Transactions on Biomedical Engineering Pub Date : 2024-09-24 DOI:10.1109/TBME.2024.3466929

Huaiming Wang, Wenlong Feng, Xue Ren, Quan Tao, Liangliang Rong, Yiping P Du, Hui Dong

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引用次数: 0

Abstract

Objective: In recent years, ultra-low field (ULF) magnetic resonance imaging (MRI) has gained widespread attention due to its advantages, such as low cost, light weight, and portability. However, the low signal-to-noise ratio (SNR) leads to a long scan time. Herein, we study the acceleration performance of parallel imaging (PI) and compressed sensing (CS) in different kspace sampling strategies at 0.12 mT.

Methods: This study employs phantoms to assess the efficiency of acceleration methods at ULF MRI, in which signals are detected by ultra-sensitive superconducting quantum interference devices (SQUIDs). We compare the performance of fast Fourier transform (FFT), generalized auto-calibrating partially parallel acquisitions (GRAPPA), and eigenvector-based SPIRiT (ESPIRiT) in Cartesian sampling, while also evaluating non-uniform FFT (NUFFT), GRAPPA operator gridding, and ESPIRiT in nonCartesian sampling. We design a resolution phantom to investigate the effectiveness of these methods in maintaining image resolution.

Results: In Cartesian sampling, GRAPPA and ESPIRiT jointly regularized by total variation and ℓ1-norm (TVJℓ1 -ESPIRiT) methods reconstructed good-quality phantom images with an acceleration factor of R = 2. In contrast, TVJℓ1-ESPIRiT exhibited improved image quality and much less signal loss even for R = 4. In radial sampling, TVJℓ1-ESPIRiT reduced the acquisition time to 1.69 minutes at R = 4, with a respective improvement of 12.26 dB in peak SNR compared to NUFFT. The resolution phantom imaging showed that the reconstructions by PI and CS maintained the original resolution of 2 mm.

Conclusion and significance: This study improves the practicality of ULF MRI at microtesla fields by implementing imaging acceleration with PI and CS in different k-space sampling.

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在微特斯拉场中利用并行成像和压缩传感加速超低场磁共振成像的采集。

目的：近年来，超低磁场（ULF）磁共振成像（MRI）因其成本低、重量轻、便于携带等优点而受到广泛关注。然而，低信噪比（SNR）导致扫描时间较长。在此，我们研究了平行成像（PI）和压缩传感（CS）在 0.12 mT 的不同 kspace 采样策略下的加速性能：本研究利用模型来评估超低频磁共振成像加速方法的效率，其中信号由超灵敏超导量子干涉装置（SQUID）检测。我们比较了快速傅立叶变换 (FFT)、广义自动校准部分并行采集 (GRAPPA) 和基于特征向量的 SPIRiT (ESPIRiT) 在笛卡尔采样中的性能，同时还评估了非均匀 FFT (NUFFT)、GRAPPA 算子网格化和 ESPIRiT 在非笛卡尔采样中的性能。我们设计了一个分辨率模型，以研究这些方法在保持图像分辨率方面的有效性：在笛卡尔采样中，GRAPPA 和通过总变异和 ℓ1-norm 正则化的 ESPIRiT（TVJℓ1 -ESPIRiT）方法在加速因子为 R = 2 时重建了高质量的幻影图像。在径向采样中，与 NUFFT 相比，TVJℓ1-ESPIRiT 在 R = 4 时将采集时间缩短到 1.69 分钟，峰值信噪比提高了 12.26 dB。分辨率模型成像显示，PI 和 CS 重建保持了 2 毫米的原始分辨率：这项研究通过在不同的 k 空间采样中使用 PI 和 CS 进行成像加速，提高了超低频磁共振成像在微特斯拉场中的实用性。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

IEEE Transactions on Biomedical Engineering 工程技术-工程：生物医学

CiteScore

9.40

自引率

4.30%

发文量

880

审稿时长

2.5 months

期刊介绍： IEEE Transactions on Biomedical Engineering contains basic and applied papers dealing with biomedical engineering. Papers range from engineering development in methods and techniques with biomedical applications to experimental and clinical investigations with engineering contributions.