运动补偿的自监督深度学习在超高加速 3D 超短回波时间肺部 MRI 中的应用。

Motion compensated self supervised deep learning for highly accelerated 3D ultrashort Echo time pulmonary MRI.

机构信息

Department of Biomedical Engineering, University of Wisconsin, Madison, Wisconsin, USA.

Department of Medical Physics, University of Wisconsin School of Medicine and Public Health, Madison, Wisconsin, USA.

出版信息

Magn Reson Med. 2023 Jun;89(6):2361-2375. doi: 10.1002/mrm.29586. Epub 2023 Feb 6.

DOI:10.1002/mrm.29586

PMID:36744745

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC10590257/

Abstract

PURPOSE

To investigate motion compensated, self-supervised, model based deep learning (MBDL) as a method to reconstruct free breathing, 3D pulmonary UTE acquisitions.

THEORY AND METHODS

A self-supervised eXtra dimension MBDL architecture (XD-MBDL) was developed that combined respiratory states to reconstruct a single high-quality 3D image. Non-rigid motion fields were incorporated into this architecture by estimating motion fields from a lower resolution motion resolved (XD-GRASP) reconstruction. Motion compensated XD-MBDL was evaluated on lung UTE datasets with and without contrast and compared to constrained reconstructions and variants of self-supervised MBDL that do not account for dynamic respiratory states or leverage motion correction.

RESULTS

Images reconstructed using XD-MBDL demonstrate improved image quality as measured by apparent SNR (aSNR), contrast to noise ratio (CNR), and visual assessment relative to self-supervised MBDL approaches that do not account for dynamic respiratory states, XD-GRASP and a recently proposed motion compensated iterative reconstruction strategy (iMoCo). Additionally, XD-MBDL reduced reconstruction time relative to both XD-GRASP and iMoCo.

CONCLUSION

A method was developed to allow self-supervised MBDL to combine multiple respiratory states to reconstruct a single image. This method was combined with graphics processing unit (GPU)-based image registration to further improve reconstruction quality. This approach showed promising results reconstructing a user-selected respiratory phase from free breathing 3D pulmonary UTE acquisitions.

摘要

目的

研究运动补偿、自我监督、基于模型的深度学习 (MBDL) 作为一种重建自由呼吸、3D 肺部 UTE 采集的方法。

理论和方法

开发了一种自我监督的额外维度 MBDL 架构 (XD-MBDL)，该架构将呼吸状态结合起来重建单个高质量的 3D 图像。通过从低分辨率运动分辨 (XD-GRASP) 重建中估计运动场，将非刚性运动场纳入到该架构中。对具有和不具有对比剂的肺部 UTE 数据集评估了运动补偿 XD-MBDL，并与不考虑动态呼吸状态或利用运动校正的约束重建和自我监督 MBDL 变体进行了比较。

结果

使用 XD-MBDL 重建的图像在表观信噪比 (aSNR)、对比噪声比 (CNR) 和视觉评估方面显示出更好的图像质量，与不考虑动态呼吸状态的自我监督 MBDL 方法、XD-GRASP 和最近提出的运动补偿迭代重建策略 (iMoCo) 相比。此外，XD-MBDL 与 XD-GRASP 和 iMoCo 相比，减少了重建时间。

结论

开发了一种方法，使自我监督的 MBDL 能够结合多个呼吸状态来重建单个图像。该方法与基于图形处理单元 (GPU) 的图像配准相结合，以进一步提高重建质量。这种方法在从自由呼吸 3D 肺部 UTE 采集重建用户选择的呼吸阶段方面显示出了有前途的结果。

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