Wech Tobias, Ankenbrand Markus Johannes, Bley Thorsten Alexander, Heidenreich Julius Frederik
Department of Diagnostic and Interventional Radiology, University Hospital Würzburg, Würzburg, Germany.
Comprehensive Heart Failure Center, University Hospital Würzburg, Würzburg, Germany.
Magn Reson Med. 2022 Feb;87(2):972-983. doi: 10.1002/mrm.29017. Epub 2021 Oct 5.
Image acquisition and subsequent manual analysis of cardiac cine MRI is time-consuming. The purpose of this study was to train and evaluate a 3D artificial neural network for semantic segmentation of radially undersampled cardiac MRI to accelerate both scan time and postprocessing.
A database of Cartesian short-axis MR images of the heart (148,500 images, 484 examinations) was assembled from an openly accessible database and radial undersampling was simulated. A 3D U-Net architecture was pretrained for segmentation of undersampled spatiotemporal cine MRI. Transfer learning was then performed using samples from a second database, comprising 108 non-Cartesian radial cine series of the midventricular myocardium to optimize the performance for authentic data. The performance was evaluated for different levels of undersampling by the Dice similarity coefficient (DSC) with respect to reference labels, as well as by deriving ventricular volumes and myocardial masses.
Without transfer learning, the pretrained model performed moderately on true radial data [maximum number of projections tested, P = 196; DSC = 0.87 (left ventricle), DSC = 0.76 (myocardium), and DSC =0.64 (right ventricle)]. After transfer learning with authentic data, the predictions achieved human level even for high undersampling rates (P = 33, DSC = 0.95, 0.87, and 0.93) without significant difference compared with segmentations derived from fully sampled data.
A 3D U-Net architecture can be used for semantic segmentation of radially undersampled cine acquisitions, achieving a performance comparable with human experts in fully sampled data. This approach can jointly accelerate time-consuming cine image acquisition and cumbersome manual image analysis.
心脏电影磁共振成像(MRI)的图像采集及后续手动分析耗时较长。本研究旨在训练并评估一个用于对径向欠采样心脏MRI进行语义分割的三维人工神经网络,以加速扫描时间和后处理过程。
从一个可公开访问的数据库中收集了笛卡尔短轴心脏MR图像数据库(148,500幅图像,484次检查),并模拟了径向欠采样。采用三维U-Net架构对欠采样的时空电影MRI进行分割预训练。然后使用来自第二个数据库的样本进行迁移学习,该数据库包含108个心室中层心肌的非笛卡尔径向电影序列,以优化真实数据的性能。通过与参考标签相关的骰子相似系数(DSC)以及推导心室容积和心肌质量,对不同欠采样水平的性能进行评估。
在没有迁移学习的情况下,预训练模型在真实径向数据上的表现一般[测试的最大投影数,P = 196;DSC = 0.87(左心室),DSC = 0.76(心肌),DSC = 0.64(右心室)]。在使用真实数据进行迁移学习后,即使对于高欠采样率(P = 33,DSC = 0.95、0.87和0.93),预测结果也达到了人类水平,与从全采样数据得出的分割结果相比无显著差异。
三维U-Net架构可用于径向欠采样电影采集的语义分割,在全采样数据中的性能与人类专家相当。这种方法可以共同加速耗时的电影图像采集和繁琐的手动图像分析。
