Zhang Xirang, Yang Yongyi, Pretorius P Hendrik, Slomka Piotr J, King Michael A
Medical Imaging Research Center, Department of Electrical and Computer Engineering, Illinois Institute of Technology, Chicago, IL, USA.
Medical Imaging Research Center, Department of Electrical and Computer Engineering, Illinois Institute of Technology, Chicago, IL, USA.
J Nucl Cardiol. 2025 Jan;43:102071. doi: 10.1016/j.nuclcard.2024.102071. Epub 2024 Nov 2.
In myocardial perfusion imaging (MPI) with single-photon emission computed tomography (SPECT), ungated studies are used for evaluation of perfusion defects despite motion blur. We investigate the potential benefit of motion correction using a deep-learning (DL) network for evaluating perfusion defects.
We employed a DL network for cardiac motion correction in ECG-gated SPECT-MPI images, wherein the image data from different cardiac phases are combined with respect to a reference gate to reduce motion blur. For training the DL network, 197 cases were used. Given the variability of gated images during the cardiac cycle, we investigated the detectability of perfusion defects in two distinct reference gates. To assess perfusion defect detection, we performed receiver-operating characteristic (ROC) analyses on the motion-corrected images using a separate test dataset of clinical 194 subjects, in which studies were created from actual patient data with inserted simulated-lesions as ground truth. The reconstructed images were assessed by the quantitative-perfusion SPECT (QPS) software. We also evaluated the performance on reduced-count studies (by two and four folds).
The quantitative results, measured by area-under-the-ROC curve (AUC), demonstrated that DL motion correction improves the detectability of perfusion defects significantly on both standard- and reduced-count studies, and that the detectability can vary with reference cardiac phases. A joint assessment from two reference phases achieved AUC = 0.841 on the quarter-count data, higher than with ungated full-count data (AUC = 0.795, P-value = 0.0054).
DL motion correction can benefit assessment of perfusion defects in standard- and reduced-count SPECT-MPI studies. It can also be beneficial to evaluate perfusion images over multiple cardiac phases.
在单光子发射计算机断层扫描(SPECT)心肌灌注成像(MPI)中,非门控研究用于评估存在运动模糊情况下的灌注缺损。我们研究了使用深度学习(DL)网络进行运动校正对评估灌注缺损的潜在益处。
我们采用一个DL网络对心电图门控SPECT-MPI图像进行心脏运动校正,其中来自不同心动周期阶段的图像数据相对于一个参考门控进行合并,以减少运动模糊。为训练该DL网络,使用了197例病例。鉴于心动周期期间门控图像的变异性,我们在两个不同的参考门控中研究了灌注缺损的可检测性。为评估灌注缺损检测,我们使用一个包含194名临床受试者的单独测试数据集,对运动校正后的图像进行了受试者操作特征(ROC)分析,其中研究是根据实际患者数据并插入模拟病变作为金标准创建的。通过定量灌注SPECT(QPS)软件评估重建图像。我们还评估了在减少计数研究(减少两倍和四倍)中的性能。
通过ROC曲线下面积(AUC)测量的定量结果表明,DL运动校正显著提高了标准计数和减少计数研究中灌注缺损的可检测性,并且可检测性会随参考心动周期阶段而变化。在四分之一计数数据上,来自两个参考阶段的联合评估达到AUC = 0.841,高于非门控全计数数据(AUC = 0.795,P值 = 0.0054)。
DL运动校正有助于标准计数和减少计数SPECT-MPI研究中灌注缺损的评估。评估多个心动周期阶段的灌注图像也可能有益。
