从潜在的心脏时空信息中进行深度学习:从超声心动图中识别高级生物成像标记。

IF 2.9 Q2 BIOPHYSICS
Biophysics reviews Pub Date : 2024-03-27 eCollection Date: 2024-03-01 DOI:10.1063/5.0176850
Amanda Chang, Xiaodong Wu, Kan Liu
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引用次数: 0

摘要

超声心动图的主要优势在于能实时整合全面的时空心脏成像数据,帮助一线或床边病人进行风险分层和管理。然而,众所周知,超声心动图的采集、处理和判读都依赖于人工和主观的人为描记,因此存在一定的差异性,这对工作流程和协议的标准化以及最终判读的准确性提出了挑战。在计算能力发达的时代,利用机器学习算法进行超声心动图大数据分析有望降低成本、认知错误以及观察者内部和观察者之间的差异性。新颖的时空深度学习(DL)模型可以整合基于无标记像素超声心动图数据的时间臂信息,用于自适应语义时空校准的卷积,以构建个性化的四维心脏网格,评估整体和区域心脏功能,检测早期瓣膜病变,并区分不常见的心血管疾病。同时,时空 DL 预测模型的数据可视化有助于提取潜在的时空成像特征,以开发早期疾病阶段的先进成像生物标记物,并促进我们对病理生理学的了解,从而支持个性化预防或治疗策略的开发。由于便携式超声心动图已越来越多地被用作辅助农村医疗服务的护理点成像工具,这些新的时空 DL 技术的应用显示了简化超声心动图采集、处理和数据分析的潜力,从而提高工作流程的标准化和效率,并实时提供风险分层和决策支持工具,以促进建立新的成像诊断网络,提高农村医疗服务的参与度。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Deep learning from latent spatiotemporal information of the heart: Identifying advanced bioimaging markers from echocardiograms.

A key strength of echocardiography lies in its integration of comprehensive spatiotemporal cardiac imaging data in real-time, to aid frontline or bedside patient risk stratification and management. Nonetheless, its acquisition, processing, and interpretation are known to all be subject to heterogeneity from its reliance on manual and subjective human tracings, which challenges workflow and protocol standardization and final interpretation accuracy. In the era of advanced computational power, utilization of machine learning algorithms for big data analytics in echocardiography promises reduction in cost, cognitive errors, and intra- and inter-observer variability. Novel spatiotemporal deep learning (DL) models allow the integration of temporal arm information based on unlabeled pixel echocardiographic data for convolution of an adaptive semantic spatiotemporal calibration to construct personalized 4D heart meshes, assess global and regional cardiac function, detect early valve pathology, and differentiate uncommon cardiovascular disorders. Meanwhile, data visualization on spatiotemporal DL prediction models helps extract latent temporal imaging features to develop advanced imaging biomarkers in early disease stages and advance our understanding of pathophysiology to support the development of personalized prevention or treatment strategies. Since portable echocardiograms have been increasingly used as point-of-care imaging tools to aid rural care delivery, the application of these new spatiotemporal DL techniques show the potentials in streamlining echocardiographic acquisition, processing, and data analysis to improve workflow standardization and efficiencies, and provide risk stratification and decision supporting tools in real-time, to prompt the building of new imaging diagnostic networks to enhance rural healthcare engagement.

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