Derivation and external validation of a deep learning model to predict changes in coronary plaque burden.

IF 9.5 1区医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS

Eurointervention Pub Date : 2026-05-04 DOI:10.4244/EIJ-D-25-01352

Hector M García-García, Carlos A Bulant, Gustavo A Boroni, Alejandro Clausse, Thomas Engstrøm, Pedro A Lemos, Nathan A Lecaros Yap, Murat Cap, Juan F Iglesias, Robert van Geuns, Irene M Lang, David Spirk, Jonas D Häner, Konstantinos C Koskinas, Ryota Kakizaki, Yasushi Ueki, George C M Siontis, Cristos V Bourantas, Pablo J Blanco, Lorenz Räber

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引用次数: 0

Abstract

Background: Predicting the progression/regression of coronary plaque burden is challenging.

Aims: We aimed to develop a deep learning model to forecast changes in percent atheroma volume (ΔPAV) using intravascular ultrasound (IVUS).

Methods: We analysed data from IBIS-4 and PACMAN-AMI. Core lab measurements of plaque burden were available from IVUS pullbacks. Each model consists of a bidirectional Long Short-Term Memory (biLSTM) layer followed by two fully connected layers with one neuron each, resulting in both a classification for input progression/regression and an estimation of the ΔPAV.

Results: For the derivation and validation, a total of 1,960 regions of interest (ROIs) from the IBIS-4 dataset were used. The mean±standard deviation of the model accuracy was 0.85±0.02, the Matthews correlation coefficient was 0.70±0.04, and the F1 score was 0.85±0.02 for both progression and regression classes. In the testing (external validation) process with the PACMAN-AMI dataset, 5,283 ROIs were utilised. The mean ΔPAV was -0.31±5.63, for which 2,665 featured regression with a mean ΔPAV of -4.57±3.73, and 2,618 presented progression with a mean ΔPAV of 4.02±3.55, representing 49.6% of plaque progression prevalence. The predictive performance across the 100 trained models in the testing dataset showed an accuracy of 0.84, a Matthews correlation coefficient of 0.68, and an F1 score for the progression and regression classes of 0.84.

Conclusions: This is the first deep learning model capable of detecting changes in plaque progression by analysing the rate of plaque burden change between adjacent frames.

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一个预测冠状动脉斑块负荷变化的深度学习模型的推导和外部验证。

背景：预测冠状动脉斑块负荷的进展/消退具有挑战性。目的：我们旨在利用血管内超声（IVUS）开发一个深度学习模型来预测动脉粥样硬化体积百分比的变化（ΔPAV）。方法：对IBIS-4和PACMAN-AMI数据进行分析。通过IVUS回拉可获得斑块负荷的核心实验室测量。每个模型由一个双向长短期记忆（biLSTM）层组成，然后是两个完全连接的层，每个层有一个神经元，从而产生对输入进度/回归的分类和对ΔPAV的估计。结果：为了进行推导和验证，使用了IBIS-4数据集中的1,960个感兴趣区域（roi）。模型精度的平均值±标准差为0.85±0.02，Matthews相关系数为0.70±0.04，进阶类和回归类的F1评分均为0.85±0.02。在PACMAN-AMI数据集的测试（外部验证）过程中，使用了5,283个roi。平均ΔPAV为-0.31±5.63，其中2,665例出现回归，平均ΔPAV为-4.57±3.73,2,618例出现进展，平均ΔPAV为4.02±3.55，占斑块进展患病率的49.6%。测试数据集中100个训练模型的预测性能显示，准确率为0.84，马修斯相关系数为0.68，级数和回归类的F1得分为0.84。结论：这是第一个深度学习模型，能够通过分析相邻框架之间菌斑负担的变化率来检测菌斑进展的变化。

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

Eurointervention CARDIAC & CARDIOVASCULAR SYSTEMS-

CiteScore

10.30

自引率

4.80%

发文量

380

审稿时长

3-8 weeks

期刊介绍： EuroIntervention Journal is an international, English language, peer-reviewed journal whose aim is to create a community of high quality research and education in the field of percutaneous and surgical cardiovascular interventions.