基于高效不变特征中心生长分析的多模态对比域共享生成对抗网络改进了脑肿瘤分类。

IF 1.6 4区生物学 Q3 BIOLOGY Electromagnetic Biology and Medicine Pub Date : 2024-07-30 DOI:10.1080/15368378.2024.2375266

Amarendra Reddy Panyala, Baskar Manickam

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引用次数: 0

摘要

对脑肿瘤类别进行高效、准确的分类仍然是医学成像领域的一项重大挑战。虽然现有技术已经取得了长足进步，但它们对通用特征的依赖往往会导致次优结果。为了克服这些问题，本文提出了基于高效不变特征中心增长分析的多模态对比域共享生成对抗网络（MCDS-GNN-IBTC-CGA）来改进脑肿瘤分类。然后使用范围-多普勒匹配滤波器（RDMF）对输入图像进行预处理，以提高图像质量。然后采用三元模式和离散小波变换（TPDWT）进行特征提取，重点关注白色、灰度、边缘相关性和深度特征。该方法利用多模态对比域共享生成对抗网络（MCDS-GNN）将脑肿瘤图像分为胶质瘤、脑膜瘤和垂体瘤。最后，Coati 优化算法（COA）对 MCDS-GNN 的权重参数进行了优化。建议的 MCDS-GNN-IBTC-CGA 利用准确度、特异性、灵敏度、精确度、F1 分数和均方误差（MSE）进行了经验评估。MCDS-GNN-IBTC-CGA 的准确率分别为 12.75%、11.39%、13.35%、11.42% 和 12.98%。在这里，MCDS-GNN-IBTC-CGA 的准确率分别为 12.75%、11.39%、13.35%、11.42% 和 12.98%，优于现有的先进技术，如利用并行深度卷积神经网络（PDCNN-BTC）进行脑肿瘤分类、注意力引导卷积神经网络进行脑肿瘤分类（AGCNN-BTC）、智能驱动深度残差学习脑肿瘤分类法（DCRN-BTC）、全卷积神经网络脑肿瘤分类法（FCNN-BTC）、基于卷积神经网络和多层感知器的脑肿瘤分类法（CNN-MLP-BTC）。

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Generative adversarial network for Multimodal Contrastive Domain Sharing based on efficient invariant feature-centric growth analysis improved brain tumor classification.

Efficient and accurate classification of brain tumor categories remains a critical challenge in medical imaging. While existing techniques have made strides, their reliance on generic features often leads to suboptimal results. To overcome these issues, Multimodal Contrastive Domain Sharing Generative Adversarial Network for Improved Brain Tumor Classification Based on Efficient Invariant Feature Centric Growth Analysis (MCDS-GNN-IBTC-CGA) is proposed in this manuscript.Here, the input imagesare amassed from brain tumor dataset. Then the input images are preprocesssed using Range - Doppler Matched Filter (RDMF) for improving the quality of the image. Then Ternary Pattern and Discrete Wavelet Transforms (TPDWT) is employed for feature extraction and focusing on white, gray mass, edge correlation, and depth features. The proposed method leverages Multimodal Contrastive Domain Sharing Generative Adversarial Network (MCDS-GNN) to categorize brain tumor images into Glioma, Meningioma, and Pituitary tumors. Finally, Coati Optimization Algorithm (COA) optimizes MCDS-GNN's weight parameters. The proposed MCDS-GNN-IBTC-CGA is empirically evaluated utilizing accuracy, specificity, sensitivity, Precision, F1-score,Mean Square Error (MSE). Here, MCDS-GNN-IBTC-CGA attains 12.75%, 11.39%, 13.35%, 11.42% and 12.98% greater accuracy comparing to the existingstate-of-the-arts techniques, likeMRI brain tumor categorization utilizing parallel deep convolutional neural networks (PDCNN-BTC), attention-guided convolutional neural network for the categorization of braintumor (AGCNN-BTC), intelligent driven deep residual learning method for the categorization of braintumor (DCRN-BTC),fully convolutional neural networks method for the classification of braintumor (FCNN-BTC), Convolutional Neural Network and Multi-Layer Perceptron based brain tumor classification (CNN-MLP-BTC) respectively.

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来源期刊

Electromagnetic Biology and Medicine 生物-生物物理

CiteScore

3.60

自引率

11.80%

发文量

审稿时长

>12 weeks

期刊介绍： Aims & Scope: Electromagnetic Biology and Medicine, publishes peer-reviewed research articles on the biological effects and medical applications of non-ionizing electromagnetic fields (from extremely-low frequency to radiofrequency). Topic examples include in vitro and in vivo studies, epidemiological investigation, mechanism and mode of interaction between non-ionizing electromagnetic fields and biological systems. In addition to publishing original articles, the journal also publishes meeting summaries and reports, and reviews on selected topics.