用于病理肺癌图像多层次分割的自适应增强人类记忆算法。

IF 7 2区 医学 Q1 BIOLOGY Computers in biology and medicine Pub Date : 2024-12-01 Epub Date: 2024-10-16 DOI:10.1016/j.compbiomed.2024.109272
Mahmoud Abdel-Salam, Essam H Houssein, Marwa M Emam, Nagwan Abdel Samee, Mona M Jamjoom, Gang Hu
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引用次数: 0

摘要

肺癌是一个严重的健康问题,需要迅速准确的诊断才能有效治疗。在医学成像中,分割是识别和隔离感兴趣区域的关键,这对精确诊断和治疗计划至关重要。传统的基于元启发式的分割方法往往存在收敛速度慢、优化阈值效果差、探索与利用不平衡等问题,导致其在肺癌图像的多阈值分割中表现不佳。本研究提出了 ASG-HMO,它是人类记忆优化算法(HMO)的增强变体,因其简单、通用和参数最小而被选中。虽然 HMO 从未应用于多阈值图像分割,但其特性使其成为改进病理肺癌图像分割的理想选择。ASG-HMO 融合了四种创新策略,可解决分割过程中的关键难题。首先,提出了增强型自适应相互性阶段,以平衡探索和利用,准确划分肿瘤边界,而不会陷入次优解。其次,利用螺旋运动策略,通过同时关注整体肺部结构和错综复杂的肿瘤细节,自适应地完善分割解决方案。第三,高斯突变策略在搜索过程中引入了多样性,从而能够探索更广泛的分割阈值,提高分割区域的准确性。最后,提出了自适应 t 分布干扰策略,以帮助算法避免局部最优,并在后期细化分割。通过在 IEEE CEC'17 和 CEC'20 基准套件上的严格测试,ASG-HMO 的有效性得到了验证,随后将其应用于九张组织病理学肺癌图像的多级阈值分割。在这些实验中,测试了六种不同的分割阈值,并将该算法与几种经典、最新和先进的分割算法进行了比较。此外,所提出的 ASG-HMO 利用二维仁义熵和二维直方图来提高分割过程的精确度。病理肺癌分割的定量结果分析表明,ASG-HMO 的峰值信噪比(PSNR)为 31.924,结构相似性指数(SSIM)为 0.919,特征相似性指数(FSIM)为 0.990,概率兰德指数(PRI)为 0.924。这些结果表明,ASG-HMO 在收敛速度和分割准确性方面都明显优于现有算法。这证明了 ASG-HMO 作为病理肺癌图像精确分割框架的稳健性,为改善临床诊断过程提供了巨大潜力。
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An adaptive enhanced human memory algorithm for multi-level image segmentation for pathological lung cancer images.

Lung cancer is a critical health issue that demands swift and accurate diagnosis for effective treatment. In medical imaging, segmentation is crucial for identifying and isolating regions of interest, which is essential for precise diagnosis and treatment planning. Traditional metaheuristic-based segmentation methods often struggle with slow convergence speed, poor optimized thresholds results, balancing exploration and exploitation, leading to suboptimal performance in the multi-thresholding segmenting of lung cancer images. This study presents ASG-HMO, an enhanced variant of the Human Memory Optimization (HMO) algorithm, selected for its simplicity, versatility, and minimal parameters. Although HMO has never been applied to multi-thresholding image segmentation, its characteristics make it ideal to improve pathology lung cancer image segmentation. The ASG-HMO incorporating four innovative strategies that address key challenges in the segmentation process. Firstly, the enhanced adaptive mutualism phase is proposed to balance exploration and exploitation to accurately delineate tumor boundaries without getting trapped in suboptimal solutions. Second, the spiral motion strategy is utilized to adaptively refines segmentation solutions by focusing on both the overall lung structure and the intricate tumor details. Third, the gaussian mutation strategy introduces diversity in the search process, enabling the exploration of a broader range of segmentation thresholds to enhance the accuracy of segmented regions. Finally, the adaptive t-distribution disturbance strategy is proposed to help the algorithm avoid local optima and refine segmentation in later stages. The effectiveness of ASG-HMO is validated through rigorous testing on the IEEE CEC'17 and CEC'20 benchmark suites, followed by its application to multilevel thresholding segmentation in nine histopathology lung cancer images. In these experiments, six different segmentation thresholds were tested, and the algorithm was compared to several classical, recent, and advanced segmentation algorithms. In addition, the proposed ASG-HMO leverages 2D Renyi entropy and 2D histograms to enhance the precision of the segmentation process. Quantitative result analysis in pathological lung cancer segmentation showed that ASG-HMO achieved superior maximum Peak Signal-to-Noise Ratio (PSNR) of 31.924, Structural Similarity Index Measure (SSIM) of 0.919, Feature Similarity Index Measure (FSIM) of 0.990, and Probability Rand Index (PRI) of 0.924. These results indicate that ASG-HMO significantly outperforms existing algorithms in both convergence speed and segmentation accuracy. This demonstrates the robustness of ASG-HMO as a framework for precise segmentation of pathological lung cancer images, offering substantial potential for improving clinical diagnostic processes.

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来源期刊
Computers in biology and medicine
Computers in biology and medicine 工程技术-工程:生物医学
CiteScore
11.70
自引率
10.40%
发文量
1086
审稿时长
74 days
期刊介绍: Computers in Biology and Medicine is an international forum for sharing groundbreaking advancements in the use of computers in bioscience and medicine. This journal serves as a medium for communicating essential research, instruction, ideas, and information regarding the rapidly evolving field of computer applications in these domains. By encouraging the exchange of knowledge, we aim to facilitate progress and innovation in the utilization of computers in biology and medicine.
期刊最新文献
An adaptive enhanced human memory algorithm for multi-level image segmentation for pathological lung cancer images. Integrating multimodal learning for improved vital health parameter estimation. Riemannian manifold-based geometric clustering of continuous glucose monitoring to improve personalized diabetes management. Transformative artificial intelligence in gastric cancer: Advancements in diagnostic techniques. Artificial intelligence and deep learning algorithms for epigenetic sequence analysis: A review for epigeneticists and AI experts.
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