Alfredo Lucas, Chetan Vadali, Sofia Mouchtaris, T. Campbell Arnold, James J Gugger, Catherine V. Kulick-Soper, Mariam Josyula, Nina Petillo, Sandhitsu Das, Jacob Dubroff, John A. Detre, Joel M. Stein, Kathryn A. Davis
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引用次数: 0
Abstract
Background and Significance: Positron Emission Tomography (PET) using fluorodeoxyglucose (FDG-PET) is a standard imaging modality for detecting areas of hypometabolism associated with the seizure onset zone (SOZ) in temporal lobe epilepsy (TLE). However, FDG-PET is costly and involves the use of a radioactive tracer. Arterial Spin Labeling (ASL) offers an MRI-based quantification of cerebral blood flow (CBF) that could also help localize the SOZ, but its performance in doing so, relative to FDG-PET, is limited. In this study, we seek to improve ASL's diagnostic performance by developing a deep learning framework for synthesizing FDG-PET-like images from ASL and structural MRI inputs. Methods: We included 68 epilepsy patients, out of which 36 had well lateralized TLE. We compared the coupling between FDG-PET and ASL CBF values in different brain regions, as well as the asymmetry of these values across the brain. We additionally assessed each modality's ability to lateralize the SOZ across brain regions. Using our paired PET-ASL data, we developed FlowGAN, a generative adversarial neural network (GAN) that synthesizes PET-like images from ASL and T1-weighted MRI inputs. We tested our synthetic PET images against the actual PET images of subjects to assess their ability to reproduce clinically meaningful hypometabolism and asymmetries in TLE. Results: We found variable coupling between PET and ASL CBF values across brain regions. PET and ASL had high coupling in neocortical temporal and frontal brain regions (Spearman's r > 0.30, p < 0.05) but low coupling in mesial temporal structures (Spearman's r < 0.30, p > 0.05). Both whole brain PET and ASL CBF asymmetry values provided good separability between left and right TLE subjects, but PET (AUC = 0.96, 95% CI: [0.88, 1.00]) outperformed ASL (AUC = 0.81; 95% CI: [0.65, 0.96]). FlowGAN-generated images demonstrated high structural similarity to actual PET images (SSIM = 0.85). Globally, asymmetry values were better correlated between synthetic PET and original PET than between ASL CBF and original PET, with a mean correlation increase of 0.15 (95% CI: [0.07, 0.24], p<0.001, Cohen's d = 0.91). Furthermore, regions that had poor ASL-PET correlation (e.g. mesial temporal structures) showed the greatest improvement with synthetic PET images. Conclusions: FlowGAN improves ASL's diagnostic performance, generating synthetic PET images that closely mimic actual FDG-PET in depicting hypometabolism associated with TLE. This approach could improve non-invasive SOZ localization, offering a promising tool for epilepsy presurgical assessment. It potentially broadens the applicability of ASL in clinical practice and could reduce reliance on FDG-PET for epilepsy and other neurological disorders.
背景和意义:使用氟脱氧葡萄糖的正电子发射断层扫描(PET)(FDG-PET)是检测颞叶癫痫(TLE)发作起始区(SOZ)相关代谢低下区域的标准成像模式。然而,FDG-PET 费用昂贵,而且需要使用放射性示踪剂。动脉自旋标记(ASL)提供了一种基于核磁共振成像的脑血流(CBF)量化方法,也能帮助定位 SOZ,但相对于 FDG-PET 而言,ASL 的性能有限。在本研究中,我们试图通过开发一种深度学习框架,从 ASL 和结构 MRI 输入中合成类似 FDG-PET 的图像,从而提高 ASL 的诊断性能。研究方法我们纳入了 68 名癫痫患者,其中 36 人患有侧位性良好的 TLE。我们比较了不同脑区的 FDG-PET 和 ASL CBF 值之间的耦合,以及这些值在整个大脑中的不对称性。此外,我们还评估了每种模式在不同脑区侧化 SOZ 的能力。利用成对的 PET-ASL 数据,我们开发了一种生成对抗神经网络 (GAN)--FlowGAN,它能根据 ASL 和 T1 加权 MRI 输入合成类似 PET 的图像。我们将合成的 PET 图像与受试者的实际 PET 图像进行了对比测试,以评估其再现临床上有意义的 TLE 低代谢和不对称性的能力。结果:我们发现 PET 和 ASL CBF 值在不同脑区的耦合度各不相同。PET 和 ASL 在新皮层颞叶和额叶脑区的耦合度较高(Spearman's r > 0.30, p <0.05),但在中颞叶结构的耦合度较低(Spearman's r < 0.30, p >0.05)。全脑 PET 和 ASL CBF 不对称值都能很好地区分左右 TLE 受试者,但 PET(AUC = 0.96,95% CI:[0.88, 1.00])优于 ASL(AUC = 0.81;95% CI:[0.65, 0.96])。FlowGAN 生成的图像与实际 PET 图像具有很高的结构相似性(SSIM = 0.85)。总体而言,合成 PET 与原始 PET 之间的不对称值相关性要好于 ASL CBF 与原始 PET 之间的不对称值相关性,平均相关性增加了 0.15(95% CI:[0.07, 0.24],p<0.001,Cohen's d = 0.91)。此外,ASL-PET 相关性较差的区域(如颞中叶结构)在使用合成 PET 图像后改善最大。结论:FlowGANFlowGAN提高了ASL的诊断性能,生成的合成PET图像与实际的FDG-PET图像非常相似,能够描述与TLE相关的代谢低下。这种方法可以改善非侵入性 SOZ 定位,为癫痫术前评估提供了一种前景广阔的工具。它有可能拓宽 ASL 在临床实践中的应用范围,减少癫痫和其他神经系统疾病对 FDG-PET 的依赖。