MDU-Net: multi-scale densely connected U-Net for biomedical image segmentation.

IF 4.7 3区医学 Q1 MEDICAL INFORMATICS

Health Information Science and Systems Pub Date : 2023-03-13 eCollection Date: 2023-12-01 DOI:10.1007/s13755-022-00204-9

Jiawei Zhang, Yanchun Zhang, Yuzhen Jin, Jilan Xu, Xiaowei Xu

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引用次数: 0

Abstract

Biomedical image segmentation plays a central role in quantitative analysis, clinical diagnosis, and medical intervention. In the light of the fully convolutional networks (FCN) and U-Net, deep convolutional networks (DNNs) have made significant contributions to biomedical image segmentation applications. In this paper, we propose three different multi-scale dense connections (MDC) for the encoder, the decoder of U-shaped architectures, and across them. Based on three dense connections, we propose a multi-scale densely connected U-Net (MDU-Net) for biomedical image segmentation. MDU-Net directly fuses the neighboring feature maps with different scales from both higher layers and lower layers to strengthen feature propagation in the current layer. Multi-scale dense connections, which contain shorter connections between layers close to the input and output, also make a much deeper U-Net possible. Besides, we introduce quantization to alleviate the potential overfitting in dense connections, and further improve the segmentation performance. We evaluate our proposed model on the MICCAI 2015 Gland Segmentation (GlaS) dataset. The three MDC improve U-Net performance by up to 1.8% on test A and 3.5% on test B in the MICCAI Gland dataset. Meanwhile, the MDU-Net with quantization obviously improves the segmentation performance of original U-Net.

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MDU-Net:用于生物医学图像分割的多尺度密集连接U-Net。

生物医学图像分割在定量分析、临床诊断和医疗干预中发挥着核心作用。鉴于全卷积网络（FCN）和U-Net，深度卷积网络（DNN）对生物医学图像分割应用做出了重大贡献。在本文中，我们为U型架构的编码器、解码器以及它们之间提出了三种不同的多尺度密集连接（MDC）。基于三个密集连接，我们提出了一种用于生物医学图像分割的多尺度密集连接U-Net（MDU-Net）。MDU-Net直接融合来自上层和下层的具有不同尺度的相邻特征图，以加强当前层中的特征传播。多尺度密集连接，在靠近输入和输出的层之间包含较短的连接，也使更深的U-Net成为可能。此外，我们引入量化来缓解密集连接中潜在的过拟合，并进一步提高分割性能。我们在MICCAI 2015腺体分割（GlaS）数据集上评估了我们提出的模型。在MICCAI Gland数据集中，三种MDC在测试A和测试B中分别将U-Net性能提高了1.8%和3.5%。同时，量化后的MDU-Net明显提高了原始U-Net的分割性能。

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

Health Information Science and Systems MEDICAL INFORMATICS-

CiteScore

11.30

自引率

5.00%

发文量

期刊介绍： Health Information Science and Systems is a multidisciplinary journal that integrates artificial intelligence/computer science/information technology with health science and services, embracing information science research coupled with topics related to the modeling, design, development, integration and management of health information systems, smart health, artificial intelligence in medicine, and computer aided diagnosis, medical expert systems. The scope includes: i.) smart health, artificial Intelligence in medicine, computer aided diagnosis, medical image processing, medical expert systems ii.) medical big data, medical/health/biomedicine information resources such as patient medical records, devices and equipments, software and tools to capture, store, retrieve, process, analyze, optimize the use of information in the health domain, iii.) data management, data mining, and knowledge discovery, all of which play a key role in decision making, management of public health, examination of standards, privacy and security issues, iv.) development of new architectures and applications for health information systems.