用于黑色素瘤病灶分割的生命特征细胞神经网络(VCeNN):受生物学启发的深度学习方法

IF 2.9 2区 工程技术 Q2 RADIOLOGY, NUCLEAR MEDICINE & MEDICAL IMAGING
Tongxin Yang, Qilin Huang, Fenglin Cai, Jie Li, Li Jiang, Yulong Xia
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引用次数: 0

摘要

皮肤黑色素瘤是一种致死率极高的癌症。开发一种能够准确划分黑色素瘤病变、具有高鲁棒性和泛化能力的医学影像分割模型是一项艰巨的挑战。本研究从细胞功能特征和自然选择中汲取灵感,提出了一种名为 "生命特征细胞神经网络 "的新型医学图像分割模型。该模型结合了在多细胞生物体中观察到的重要特征,包括记忆、适应、凋亡和分裂。记忆模块可使网络在训练的早期阶段迅速适应输入数据,从而加速模型的收敛。适应模块允许神经元根据不同的环境条件选择适当的激活函数。凋亡模块通过修剪激活值较低的神经元来降低过度拟合的风险。分裂模块通过复制激活值高的神经元来增强网络的学习能力。实验评估证明了该模型在提高医学图像分割神经网络性能方面的功效。所提出的方法在众多公开数据集上都取得了优异的成绩,这表明它有望为医学图像分析领域做出重大贡献,并促进医学图像的准确、高效分割。所提出的方法在众多公开数据集上取得了优异的成绩,F1 得分为 0.901,Intersection over Union 为 0.841,Dice coefficient 为 0.913,这表明该方法有望在医学图像分析领域做出重大贡献,促进医学图像的准确、高效分割。
本文章由计算机程序翻译,如有差异,请以英文原文为准。

Vital Characteristics Cellular Neural Network (VCeNN) for Melanoma Lesion Segmentation: A Biologically Inspired Deep Learning Approach

Vital Characteristics Cellular Neural Network (VCeNN) for Melanoma Lesion Segmentation: A Biologically Inspired Deep Learning Approach

Cutaneous melanoma is a highly lethal form of cancer. Developing a medical image segmentation model capable of accurately delineating melanoma lesions with high robustness and generalization presents a formidable challenge. This study draws inspiration from cellular functional characteristics and natural selection, proposing a novel medical segmentation model named the vital characteristics cellular neural network. This model incorporates vital characteristics observed in multicellular organisms, including memory, adaptation, apoptosis, and division. Memory module enables the network to rapidly adapt to input data during the early stages of training, accelerating model convergence. Adaptation module allows neurons to select the appropriate activation function based on varying environmental conditions. Apoptosis module reduces the risk of overfitting by pruning neurons with low activation values. Division module enhances the network’s learning capacity by duplicating neurons with high activation values. Experimental evaluations demonstrate the efficacy of this model in enhancing the performance of neural networks for medical image segmentation. The proposed method achieves outstanding results across numerous publicly available datasets, indicating its potential to contribute significantly to the field of medical image analysis and facilitating accurate and efficient segmentation of medical imagery. The proposed method achieves outstanding results across numerous publicly available datasets, with an F1 score of 0.901, Intersection over Union of 0.841, and Dice coefficient of 0.913, indicating its potential to contribute significantly to the field of medical image analysis and facilitating accurate and efficient segmentation of medical imagery.

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来源期刊
Journal of Digital Imaging
Journal of Digital Imaging 医学-核医学
CiteScore
7.50
自引率
6.80%
发文量
192
审稿时长
6-12 weeks
期刊介绍: The Journal of Digital Imaging (JDI) is the official peer-reviewed journal of the Society for Imaging Informatics in Medicine (SIIM). JDI’s goal is to enhance the exchange of knowledge encompassed by the general topic of Imaging Informatics in Medicine such as research and practice in clinical, engineering, and information technologies and techniques in all medical imaging environments. JDI topics are of interest to researchers, developers, educators, physicians, and imaging informatics professionals. Suggested Topics PACS and component systems; imaging informatics for the enterprise; image-enabled electronic medical records; RIS and HIS; digital image acquisition; image processing; image data compression; 3D, visualization, and multimedia; speech recognition; computer-aided diagnosis; facilities design; imaging vocabularies and ontologies; Transforming the Radiological Interpretation Process (TRIP™); DICOM and other standards; workflow and process modeling and simulation; quality assurance; archive integrity and security; teleradiology; digital mammography; and radiological informatics education.
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