COVLIAS 3.0：基于云量化混合 UNet3+ 深度学习的肺部计算机断层扫描 COVID-19 病灶检测。

IF 3 Q2 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Frontiers in Artificial Intelligence Pub Date : 2024-06-28 eCollection Date: 2024-01-01 DOI:10.3389/frai.2024.1304483

Sushant Agarwal, Sanjay Saxena, Alessandro Carriero, Gian Luca Chabert, Gobinath Ravindran, Sudip Paul, John R Laird, Deepak Garg, Mostafa Fatemi, Lopamudra Mohanty, Arun K Dubey, Rajesh Singh, Mostafa M Fouda, Narpinder Singh, Subbaram Naidu, Klaudija Viskovic, Melita Kukuljan, Manudeep K Kalra, Luca Saba, Jasjit S Suri

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引用次数: 0

摘要

背景与新颖性：当 RT-PCR 对早期诊断和了解 COVID-19 的严重程度无效时，就需要通过计算机断层扫描（CT）来诊断 COVID，尤其是对有高磨玻璃不透光、合并症和疯狂铺层的患者。放射科医生发现，在 CT 中手动检测病灶的方法非常具有挑战性且乏味。以前曾尝试过单人深度学习（SDL），但其性能处于中下水平。本研究提出了两个新的基于云的量化深度学习 UNet3+ 混合（HDL）模型，其中包含了全面的跳转连接，以增强和改善检测：方法：利用放射科专家的注释来训练一个 SDL（UNet3+）和两个 HDL 模型，即 VGG-UNet3+ 和 ResNet-UNet3+。为了保证准确性，云框架采用了 5 倍交叉验证协议，在 3,500 张 CT 扫描图像上进行训练，并在未见过的 500 张 CT 扫描图像上进行测试。使用了两种损失函数：骰子相似度（Dice Similarity，DS）和二元交叉熵（binary crossentropy，BCE）。使用（i）面积误差、（ii）DS、（iii）Jaccard 指数、（iii）Bland-Altman 和（iv）相关图评估性能：在两种 HDL 模型中，ResNet-UNet3+ 在 Dice 和 BCE 损失方面分别比 UNet3+ 高出 17% 和 10%。使用量化技术对模型进行进一步压缩后显示，UNet3+、VGG-UNet3+ 和 ResNet-UNet3+ 模型的大小分别减少了 66.76%、36.64% 和 46.23%。Mann-Whitney 检验、配对 t 检验、Wilcoxon 检验和 Friedman 检验等统计检验证明了其稳定性和可靠性，所有检验结果均为 p 结论：在 HDL 框架下，UNet3+ 与 VGG 和 ResNet 的全面跳接证明了这一假设，显示出提高 COVID-19 检测准确性的强大效果。

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COVLIAS 3.0: cloud-based quantized hybrid UNet3+ deep learning for COVID-19 lesion detection in lung computed tomography.

Background and novelty: When RT-PCR is ineffective in early diagnosis and understanding of COVID-19 severity, Computed Tomography (CT) scans are needed for COVID diagnosis, especially in patients having high ground-glass opacities, consolidations, and crazy paving. Radiologists find the manual method for lesion detection in CT very challenging and tedious. Previously solo deep learning (SDL) was tried but they had low to moderate-level performance. This study presents two new cloud-based quantized deep learning UNet3+ hybrid (HDL) models, which incorporated full-scale skip connections to enhance and improve the detections.

Methodology: Annotations from expert radiologists were used to train one SDL (UNet3+), and two HDL models, namely, VGG-UNet3+ and ResNet-UNet3+. For accuracy, 5-fold cross-validation protocols, training on 3,500 CT scans, and testing on unseen 500 CT scans were adopted in the cloud framework. Two kinds of loss functions were used: Dice Similarity (DS) and binary cross-entropy (BCE). Performance was evaluated using (i) Area error, (ii) DS, (iii) Jaccard Index, (iii) Bland-Altman, and (iv) Correlation plots.

Results: Among the two HDL models, ResNet-UNet3+ was superior to UNet3+ by 17 and 10% for Dice and BCE loss. The models were further compressed using quantization showing a percentage size reduction of 66.76, 36.64, and 46.23%, respectively, for UNet3+, VGG-UNet3+, and ResNet-UNet3+. Its stability and reliability were proved by statistical tests such as the Mann-Whitney, Paired t-Test, Wilcoxon test, and Friedman test all of which had a p < 0.001.

Conclusion: Full-scale skip connections of UNet3+ with VGG and ResNet in HDL framework proved the hypothesis showing powerful results improving the detection accuracy of COVID-19.

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来源期刊

Frontiers in Artificial Intelligence Multiple-

CiteScore

6.10

自引率

2.50%

发文量

272

审稿时长

13 weeks