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深度学习分割模型在左心室分割中的对比研究。

Comparative studies of deep learning segmentation models for left ventricle segmentation.

机构信息

Department of Electrical Engineering, Faculty of Engineering, Universiti Malaya, Kuala Lumpur, Malaysia.

Faculty of Information and Communication Technology, BUITEMS, Quetta, Pakistan.

出版信息

Front Public Health. 2022 Aug 25;10:981019. doi: 10.3389/fpubh.2022.981019. eCollection 2022.

DOI:10.3389/fpubh.2022.981019
PMID:36091529
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC9453312/
Abstract

One of the primary factors contributing to death across all age groups is cardiovascular disease. In the analysis of heart function, analyzing the left ventricle (LV) from 2D echocardiographic images is a common medical procedure for heart patients. Consistent and accurate segmentation of the LV exerts significant impact on the understanding of the normal anatomy of the heart, as well as the ability to distinguish the aberrant or diseased structure of the heart. Therefore, LV segmentation is an important and critical task in medical practice, and automated LV segmentation is a pressing need. The deep learning models have been utilized in research for automatic LV segmentation. In this work, three cutting-edge convolutional neural network architectures (SegNet, Fully Convolutional Network, and Mask R-CNN) are designed and implemented to segment the LV. In addition, an echocardiography image dataset is generated, and the amount of training data is gradually increased to measure segmentation performance using evaluation metrics. The pixel's accuracy, precision, recall, specificity, Jaccard index, and dice similarity coefficients are applied to evaluate the three models. The Mask R-CNN model outperformed the other two models in these evaluation metrics. As a result, the Mask R-CNN model is used in this study to examine the effect of training data. For 4,000 images, the network achieved 92.21% DSC value, 85.55% Jaccard index, 98.76% mean accuracy, 96.81% recall, 93.15% precision, and 96.58% specificity value. Relatively, the Mask R-CNN outperformed other architectures, and the performance achieves stability when the model is trained using more than 4,000 training images.

摘要

在所有年龄段中,导致死亡的主要因素之一是心血管疾病。在心脏功能分析中,从 2D 超声心动图图像分析左心室 (LV) 是心脏患者的常见医疗程序。LV 的一致和准确分割对理解心脏的正常解剖结构以及区分心脏的异常或患病结构具有重要影响。因此,LV 分割是医疗实践中的一项重要且关键的任务,自动 LV 分割是当务之急。深度学习模型已被用于自动 LV 分割的研究。在这项工作中,设计并实现了三种最先进的卷积神经网络架构 (SegNet、全卷积网络和 Mask R-CNN) 来分割 LV。此外,还生成了一个超声心动图图像数据集,并逐渐增加训练数据量,使用评估指标来衡量分割性能。应用像素精度、精确率、召回率、特异性、Jaccard 指数和骰子相似性系数来评估这三个模型。Mask R-CNN 模型在这些评估指标中优于其他两个模型。因此,在这项研究中使用 Mask R-CNN 模型来检查训练数据的效果。对于 4000 张图像,该网络实现了 92.21%的 DSC 值、85.55%的 Jaccard 指数、98.76%的平均准确率、96.81%的召回率、93.15%的精确率和 96.58%的特异性值。相对而言,Mask R-CNN 优于其他架构,并且当使用超过 4000 张训练图像训练模型时,性能达到稳定。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/35ff/9453312/66aba5893ab9/fpubh-10-981019-g0008.jpg
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