Revolutionizing Colon Histopathology Glandular Segmentation Using an Ensemble Network With Watershed Algorithm

IF 3 4区计算机科学 Q2 ENGINEERING, ELECTRICAL & ELECTRONIC

International Journal of Imaging Systems and Technology Pub Date : 2024-09-24 DOI:10.1002/ima.23179

Bijoyeta Roy, Mousumi Gupta, Bidyut Krishna Goswami

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引用次数: 0

Abstract

Colorectal adenocarcinoma, the most prevalent form of colon cancer, originates in the glandular structures of the intestines, presenting histopathological abnormalities in affected tissues. Accurate gland segmentation is crucial for identifying these potentially fatal abnormalities. While recent methodologies have shown success in segmenting glands in benign tissues, their efficacy diminishes when applied to malignant tissue segmentation. This study aims to develop a robust learning algorithm using a convolutional neural network (CNN) to segment glandular structures in colon histology images. The methodology employs a CNN based on the U-Net architecture, augmented by a weighted ensemble network that integrates DenseNet 169, Inception V3, and Efficientnet B3 as backbone models. Additionally, the segmented gland boundaries are refined using the watershed algorithm. Evaluation on the Warwick-QU dataset demonstrates promising results for the ensemble model, by achieving an F1 score of 0.928 and 0.913, object dice coefficient of 0.923 and 0.911, and Hausdorff distances of 38.97 and 33.76 on test sets A and B, respectively. These results are compared with outcomes from the GlaS challenge (MICCAI 2015) and existing research findings. Furthermore, our model is validated with a publicly available dataset named LC25000, and visual inspection reveals promising results, further validating the efficacy of our approach. The proposed ensemble methodology underscores the advantages of amalgamating diverse models, highlighting the potential of ensemble techniques to enhance segmentation tasks beyond individual model capabilities.

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利用带分水岭算法的集合网络革新结肠组织病理学腺体分割技术

大肠腺癌是最常见的结肠癌，起源于肠道的腺体结构，受影响的组织会出现组织病理学异常。准确的腺体分割对于识别这些潜在的致命异常至关重要。虽然最近的方法在良性组织的腺体分割方面取得了成功，但在应用于恶性组织分割时，其效果却大打折扣。本研究旨在利用卷积神经网络（CNN）开发一种稳健的学习算法，以分割结肠组织学图像中的腺体结构。该方法采用了基于 U-Net 架构的 CNN，并以 DenseNet 169、Inception V3 和 Efficientnet B3 为骨干模型的加权集合网络作为增强。此外，还使用分水岭算法对分割的腺体边界进行了细化。在 Warwick-QU 数据集上的评估结果表明，该集合模型取得了良好的效果，在测试集 A 和 B 上的 F1 分数分别为 0.928 和 0.913，对象骰子系数分别为 0.923 和 0.911，豪斯多夫距离分别为 38.97 和 33.76。这些结果与 GlaS 挑战赛（MICCAI 2015）的结果和现有研究成果进行了比较。此外，我们的模型还通过名为 LC25000 的公开数据集进行了验证，目测结果令人满意，进一步验证了我们方法的有效性。所提出的集合方法强调了合并不同模型的优势，突出了集合技术在增强分割任务方面的潜力，超越了单个模型的能力。

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

International Journal of Imaging Systems and Technology 工程技术-成像科学与照相技术

CiteScore

6.90

自引率

6.10%

发文量

138

审稿时长

3 months

期刊介绍： The International Journal of Imaging Systems and Technology (IMA) is a forum for the exchange of ideas and results relevant to imaging systems, including imaging physics and informatics. The journal covers all imaging modalities in humans and animals. IMA accepts technically sound and scientifically rigorous research in the interdisciplinary field of imaging, including relevant algorithmic research and hardware and software development, and their applications relevant to medical research. The journal provides a platform to publish original research in structural and functional imaging. The journal is also open to imaging studies of the human body and on animals that describe novel diagnostic imaging and analyses methods. Technical, theoretical, and clinical research in both normal and clinical populations is encouraged. Submissions describing methods, software, databases, replication studies as well as negative results are also considered. The scope of the journal includes, but is not limited to, the following in the context of biomedical research: Imaging and neuro-imaging modalities: structural MRI, functional MRI, PET, SPECT, CT, ultrasound, EEG, MEG, NIRS etc.; Neuromodulation and brain stimulation techniques such as TMS and tDCS; Software and hardware for imaging, especially related to human and animal health; Image segmentation in normal and clinical populations; Pattern analysis and classification using machine learning techniques; Computational modeling and analysis; Brain connectivity and connectomics; Systems-level characterization of brain function; Neural networks and neurorobotics; Computer vision, based on human/animal physiology; Brain-computer interface (BCI) technology; Big data, databasing and data mining.