DBF-Net: a semi-supervised dual-task balanced fusion network for segmenting infected regions from lung CT images.

IF 2.7 4区计算机科学 Q3 COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE

Evolving Systems Pub Date : 2023-01-01 Epub Date: 2022-09-19 DOI:10.1007/s12530-022-09466-w

Xiaoyan Lu, Yang Xu, Wenhao Yuan

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Abstract

Accurate segmentation of infected regions in lung computed tomography (CT) images is essential to improve the timeliness and effectiveness of treatment for coronavirus disease 2019 (COVID-19). However, the main difficulties in developing of lung lesion segmentation in COVID-19 are still the fuzzy boundary of the lung-infected region, the low contrast between the infected region and the normal trend region, and the difficulty in obtaining labeled data. To this end, we propose a novel dual-task consistent network framework that uses multiple inputs to continuously learn and extract lung infection region features, which is used to generate reliable label images (pseudo-labels) and expand the dataset. Specifically, we periodically feed multiple sets of raw and data-enhanced images into two trunk branches of the network; the characteristics of the lung infection region are extracted by a lightweight double convolution (LDC) module and fusiform equilibrium fusion pyramid (FEFP) convolution in the backbone. According to the learned features, the infected regions are segmented, and pseudo-labels are made based on the semi-supervised learning strategy, which effectively alleviates the semi-supervised problem of unlabeled data. Our proposed semi-supervised dual-task balanced fusion network (DBF-Net) creates pseudo-labels on the COVID-SemiSeg dataset and the COVID-19 CT segmentation dataset. Furthermore, we perform lung infection segmentation on the DBF-Net model, with a segmentation sensitivity of 70.6% and specificity of 92.8%. The results of the investigation indicate that the proposed network greatly enhances the segmentation ability of COVID-19 infection.

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DBF-Net：一种用于从肺部CT图像中分割感染区域的半监督双任务平衡融合网络。

肺部计算机断层扫描（CT）图像中感染区域的准确分割对于提高2019冠状病毒病（新冠肺炎）治疗的及时性和有效性至关重要。然而，新冠肺炎肺部病变分割发展的主要困难仍然是肺部感染区域的模糊边界、感染区域与正常趋势区域之间的低对比度以及难以获得标记数据。为此，我们提出了一种新的双任务一致性网络框架，该框架使用多个输入来连续学习和提取肺部感染区域特征，用于生成可靠的标签图像（伪标签）并扩展数据集。具体来说，我们周期性地将多组原始图像和数据增强图像馈送到网络的两个主干分支中；肺部感染区域的特征通过骨干中的轻量级双卷积（LDC）模块和纺锤形平衡融合金字塔（FEFP）卷积来提取。根据学习到的特征，对感染区域进行分割，并基于半监督学习策略制作伪标签，有效缓解了未标记数据的半监督问题。我们提出的半监督双任务平衡融合网络（DBF-Net）在COVID-SemiSeg数据集和新冠肺炎CT分割数据集上创建伪拉贝尔。此外，我们在DBF-Net模型上进行了肺部感染的分割，分割灵敏度为70.6%，特异性为92.8%。研究结果表明，所提出的网络大大提高了新冠肺炎感染的分割能力。

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来源期刊

Evolving Systems COMPUTER SCIENCE, ARTIFICIAL INTELLIGENCE-

CiteScore

7.80

自引率

6.20%

发文量

期刊介绍： Evolving Systems covers surveys, methodological, and application-oriented papers in the area of dynamically evolving systems. ‘Evolving systems’ are inspired by the idea of system model evolution in a dynamically changing and evolving environment. In contrast to the standard approach in machine learning, mathematical modelling and related disciplines where the model structure is assumed and fixed a priori and the problem is focused on parametric optimisation, evolving systems allow the model structure to gradually change/evolve. The aim of such continuous or life-long learning and domain adaptation is self-organization. It can adapt to new data patterns, is more suitable for streaming data, transfer learning and can recognise and learn from unknown and unpredictable data patterns. Such properties are critically important for autonomous, robotic systems that continue to learn and adapt after they are being designed (at run time). Evolving Systems solicits publications that address the problems of all aspects of system modelling, clustering, classification, prediction and control in non-stationary, unpredictable environments and describe new methods and approaches for their design. The journal is devoted to the topic of self-developing, self-organised, and evolving systems in its entirety — from systematic methods to case studies and real industrial applications. It covers all aspects of the methodology such as Evolving Systems methodology Evolving Neural Networks and Neuro-fuzzy Systems Evolving Classifiers and Clustering Evolving Controllers and Predictive models Evolving Explainable AI systems Evolving Systems applications but also looking at new paradigms and applications, including medicine, robotics, business, industrial automation, control systems, transportation, communications, environmental monitoring, biomedical systems, security, and electronic services, finance and economics. The common features for all submitted methods and systems are the evolving nature of the systems and the environments. The journal is encompassing contributions related to: 1) Methods of machine learning, AI, computational intelligence and mathematical modelling 2) Inspiration from Nature and Biology, including Neuroscience, Bioinformatics and Molecular biology, Quantum physics 3) Applications in engineering, business, social sciences.