Artificial Intelligence Automation of Echocardiographic Measurements.

IF 22.3 1区医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS

Journal of the American College of Cardiology Pub Date : 2025-09-30 Epub Date: 2025-09-07 DOI:10.1016/j.jacc.2025.07.053

Yuki Sahashi, Hirotaka Ieki, Victoria Yuan, Matthew Christensen, Milos Vukadinovic, Christina Binder-Rodriguez, Justin Rhee, James Y Zou, Bryan He, Paul Cheng, David Ouyang

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引用次数: 0

Abstract

Background: Accurate measurement of echocardiographic parameters is crucial for the diagnosis of cardiovascular disease and tracking of change over time; however, manual assessment requires time-consuming effort and can be imprecise. Artificial intelligence has the potential to reduce clinician burden by automating the time-intensive task of comprehensive measurement of echocardiographic parameters.

Objectives: The purpose of this study was to develop and validate open-sourced deep learning semantic segmentation models for the automated measurement of 18 anatomic and Doppler measurements in echocardiography.

Methods: We trained models for the automated measurement of echocardiography parameters using data sets between 2011 and 2023 from Cedars-Sinai Medical Center (CSMC). The outputs of segmentation models were compared with sonographer measurements from temporal split data from CSMC and an external data set from Stanford Healthcare (SHC) to access accuracy and precision.

Results: We used 877,983 echocardiographic measurements from 155,215 studies from CSMC to develop EchoNet-Measurements, an open-source deep learning model for echocardiographic annotation. The models demonstrated high accuracy when compared with sonographer measurements from held-out data from CSMC and an independent external validation data set from SHC. Measurements across all 9 B-mode and 9 Doppler measurements had high accuracy (mean coverage probability of 0.796 and 0.839 and mean relative difference of 0.120 and 0.096 on held-out test set from CSMC and external data set from SHC, respectively). When evaluated end-to-end on 2,103 temporally distinct studies at CSMC, EchoNet-Measurements had similar reasonable performance (mean coverage probability 0.803 and mean relative difference of 0.108). Performance was consistent across patient characteristics including age, sex, and atrial fibrillation, obesity status, and machine vendors.

Conclusions: EchoNet-Measurements achieves high accuracy in automated echocardiographic quantification and potential for assisting the clinicians in the echocardiography workflow. This open-source model provides the foundation for future developments in artificial intelligence applied to echocardiography.

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超声心动图测量的人工智能自动化。

背景：准确测量超声心动图参数对心血管疾病的诊断和随时间变化的跟踪至关重要；然而，手工评估需要耗费时间，而且可能不精确。人工智能有可能通过自动化超声心动图参数综合测量的耗时任务来减轻临床医生的负担。目的：本研究的目的是开发和验证开源深度学习语义分割模型，用于超声心动图中18个解剖和多普勒测量的自动测量。方法：我们使用雪松-西奈医学中心（CSMC） 2011年至2023年的数据集训练超声心动图参数自动测量模型。将分割模型的输出与超声仪测量的来自CSMC的时间分裂数据和来自斯坦福医疗（SHC）的外部数据集进行比较，以获得准确性和精度。结果：我们从CSMC的155,215项研究中使用了877,983项超声心动图测量数据来开发EchoNet-Measurements，这是一个用于超声心动图注释的开源深度学习模型。与来自CSMC的保留数据和来自SHC的独立外部验证数据集的超声仪测量结果相比，模型显示出较高的准确性。所有9个b模式和9个多普勒测量值均具有较高的精度（CSMC的支撑测试集和SHC的外部数据集的平均覆盖概率分别为0.796和0.839，平均相对差分别为0.120和0.096）。当对CSMC的2103项时间上不同的研究进行端到端评估时，EchoNet-Measurements具有相似的合理性能（平均覆盖概率0.803，平均相对差0.108）。不同的患者特征包括年龄、性别、心房颤动、肥胖状况和机器供应商的表现是一致的。结论：EchoNet-Measurements在超声心动图自动量化中具有较高的准确性，具有辅助临床医生超声心动图工作流程的潜力。这个开源模型为人工智能应用于超声心动图的未来发展提供了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of the American College of Cardiology 医学-心血管系统

CiteScore

42.70

自引率

3.30%

发文量

5097

审稿时长

2-4 weeks

期刊介绍： The Journal of the American College of Cardiology (JACC) publishes peer-reviewed articles highlighting all aspects of cardiovascular disease, including original clinical studies, experimental investigations with clear clinical relevance, state-of-the-art papers and viewpoints. Content Profile: -Original Investigations -JACC State-of-the-Art Reviews -JACC Review Topics of the Week -Guidelines & Clinical Documents -JACC Guideline Comparisons -JACC Scientific Expert Panels -Cardiovascular Medicine & Society -Editorial Comments (accompanying every Original Investigation) -Research Letters -Fellows-in-Training/Early Career Professional Pages -Editor’s Pages from the Editor-in-Chief or other invited thought leaders