分形测量作为乳腺癌乳房x光片组织病理复杂性的预测因子。

IF 1.6 4区生物学 Q4 BIOCHEMISTRY & MOLECULAR BIOLOGY

Physical biology Pub Date : 2025-10-03 DOI:10.1088/1478-3975/ae0f6e

Abhijeet Das, Ramray Bhat, Mohit Kumar Jolly

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引用次数: 0

摘要

本研究探讨了基于分形的全局纹理特征在区分恶性和正常乳房x线照片和评估其分子亚型分化潜力方面的功效。使用标准化的预处理技术对数字乳房x线照片进行分析，并计算分形度量以捕获乳房组织结构的复杂性和连通性。我们引入了液滴蓄水池作为衡量组织潜在连通性的新参数。分形维数、多重分形强度和分形储层与腔隙维数和rsamnyi维数相比，可以有效地表征乳房x线影像纹理的特定特征；然而，将它们整合到机器学习模型中，在类别之间产生了适度的歧视性表现。此外，虽然胞浆性储层具有区分Luminal B与其他分子亚型的概念潜力，但其总体判别能力仍然有限。这项概念验证研究强调了分形纹理分析作为乳腺癌诊断中一种非侵入性生物标志物的探索潜力。

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Fractal Measures as Predictors of Histopathological Complexity in Breast Carcinoma Mammograms.

This study investigates the efficacy of fractal-based global texture features for distinguishing between malignant and normal mammograms and assessing their potential for molecular subtype differentiation. Digital mammograms were analyzed using standardized preprocessing techniques, and fractal measures were computed to capture complexity and connectivity properties within breast tissue structures. We introduced the succolarity reservoir as a novel parameter accounting for tissues' latent connectivity. Fractal dimension, multifractality strength, and succolarity reservoir were found to effectively characterize specific features of mammographic texture in contrast to lacunarity and Rényi dimensions; however, their incorporation into machine learning models yielded moderate discriminatory performance between categories. In addition, while succolarity reservoir exhibits conceptual potential for differentiating Luminal B from other molecular subtypes, its overall discriminative power remains limited. This proof-of-concept study underscores the exploratory potential of fractal-based texture analysis as a non-invasive biomarker in breast carcinoma diagnosis.

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来源期刊

Physical biology 生物-生物物理

CiteScore

4.20

自引率

0.00%

发文量

审稿时长

3 months

期刊介绍： Physical Biology publishes articles in the broad interdisciplinary field bridging biology with the physical sciences and engineering. This journal focuses on research in which quantitative approaches – experimental, theoretical and modeling – lead to new insights into biological systems at all scales of space and time, and all levels of organizational complexity. Physical Biology accepts contributions from a wide range of biological sub-fields, including topics such as: molecular biophysics, including single molecule studies, protein-protein and protein-DNA interactions subcellular structures, organelle dynamics, membranes, protein assemblies, chromosome structure intracellular processes, e.g. cytoskeleton dynamics, cellular transport, cell division systems biology, e.g. signaling, gene regulation and metabolic networks cells and their microenvironment, e.g. cell mechanics and motility, chemotaxis, extracellular matrix, biofilms cell-material interactions, e.g. biointerfaces, electrical stimulation and sensing, endocytosis cell-cell interactions, cell aggregates, organoids, tissues and organs developmental dynamics, including pattern formation and morphogenesis physical and evolutionary aspects of disease, e.g. cancer progression, amyloid formation neuronal systems, including information processing by networks, memory and learning population dynamics, ecology, and evolution collective action and emergence of collective phenomena.