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一种利用磁共振成像衍生的心脏生物力学的非缺血性心肌病创新人工智能分类模型。

An Innovative Artificial Intelligence Classification Model for Non-Ischemic Cardiomyopathy Utilizing Cardiac Biomechanics Derived from Magnetic Resonance Imaging.

作者信息

Fu Liqiang, Zhang Peifang, Cheng Liuquan, Zhi Peng, Xu Jiayu, Liu Xiaolei, Zhang Yang, Xu Ziwen, He Kunlun

机构信息

Chinese PLA Medical School, Beijing 100853, China.

Medical Innovation Research Department, Chinese PLA General Hospital, Beijing 100853, China.

出版信息

Bioengineering (Basel). 2025 Jun 19;12(6):670. doi: 10.3390/bioengineering12060670.

DOI:10.3390/bioengineering12060670
PMID:40564486
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC12189867/
Abstract

Significant challenges persist in diagnosing non-ischemic cardiomyopathies (NICMs) owing to early morphological overlap and subtle functional changes. While cardiac magnetic resonance (CMR) offers gold-standard structural assessment, current morphology-based AI models frequently overlook key biomechanical dysfunctions like diastolic/systolic abnormalities. To address this, we propose a dual-path hybrid deep learning framework based on CNN-LSTM and MLP, integrating anatomical features from cine CMR with biomechanical markers derived from intraventricular pressure gradients (IVPGs), significantly enhancing NICM subtype classification by capturing subtle biomechanical dysfunctions overlooked by traditional morphological models. Our dual-path architecture combines a CNN-LSTM encoder for cine CMR analysis and an MLP encoder for IVPG time-series data, followed by feature fusion and dense classification layers. Trained on a multicenter dataset of 1196 patients and externally validated on 137 patients from a distinct institution, the model achieved a superior performance (internal AUC: 0.974; external AUC: 0.962), outperforming ResNet50, VGG16, and radiomics-based SVM. Ablation studies confirmed IVPGs' significant contribution, while gradient saliency and gradient-weighted class activation mapping (Grad-CAM) visualizations proved the model pays attention to physiologically relevant cardiac regions and phases. The framework maintained robust generalizability across imaging protocols and institutions with minimal performance degradation. By synergizing biomechanical insights with deep learning, our approach offers an interpretable, data-efficient solution for early NICM detection and subtype differentiation, holding strong translational potential for clinical practice.

摘要

由于早期形态学重叠和细微的功能变化,非缺血性心肌病(NICM)的诊断仍存在重大挑战。虽然心脏磁共振成像(CMR)提供了金标准的结构评估,但目前基于形态学的人工智能模型经常忽略舒张/收缩异常等关键生物力学功能障碍。为了解决这个问题,我们提出了一种基于卷积神经网络(CNN)-长短期记忆网络(LSTM)和多层感知器(MLP)的双路径混合深度学习框架,将电影CMR的解剖特征与从心室内压力梯度(IVPG)得出的生物力学标记相结合,通过捕捉传统形态学模型忽略的细微生物力学功能障碍,显著提高了NICM亚型分类的准确性。我们的双路径架构结合了用于电影CMR分析的CNN-LSTM编码器和用于IVPG时间序列数据的MLP编码器,随后是特征融合和密集分类层。该模型在1196例患者的多中心数据集上进行训练,并在来自不同机构的137例患者上进行外部验证,取得了卓越的性能(内部曲线下面积:0.974;外部曲线下面积:0.962),优于ResNet50、VGG16和基于影像组学的支持向量机(SVM)。消融研究证实了IVPG的重要贡献,而梯度显著性和梯度加权类激活映射(Grad-CAM)可视化证明该模型关注生理相关的心脏区域和阶段。该框架在不同成像协议和机构中保持了强大的通用性,性能下降最小。通过将生物力学见解与深度学习相结合,我们的方法为早期NICM检测和亚型分化提供了一种可解释、数据高效的解决方案,在临床实践中具有很强的转化潜力。

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