Hyalite Sol-Gel Amoeba: A Physiology-Based Biophysical Model for Segmentation and Biotransformation of Medical Images To 3D Solid-State Characterizing Native Tissue Properties for Patient-Specific and Patient-Appropriate Analysis for Surgical Applications

INTERNATIONAL JOURNAL OF COMPUTERS & TECHNOLOGY Pub Date : 2022-05-27 DOI:10.24297/ijct.v22i.9228

H. S. Gandhi

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Abstract

Introduction: The endeavour to improve medical image segmentation techniques for higher analysis in surgical planning and medical therapeutics is far from becoming a standard of care in clinical practice. Hyalite Sol-Gel Amoeba model based on biophysical sciences apart from performing image segmentation is designed to extract real-world tissue densities for patient-specific and patient-appropriate analysis. Objectives: Amoeba Proteus is a unicellular independent entity, with a nucleus and sol-gel protoplasm enclosed in a membrane. The study presents versatile restructuring anatomy and physiology of the Amoeba Proteus for segmentation of 2D, and 3D medical images based on well-established principles of energy minimization and active contour. It demonstrates how the animalcule glides and advances by throwing pseudopodia driven by phenomenal actin-myosin activity that can segment a region-of-interest, and finally, at the time of apoptosis, its protoplasm and organelles acquire distribution of original image intensities to characterize tissue densities. Methods: This seminal study following a brief review of computer vision science discusses the relationship between optical density and tissue density, and the theory of sol-gel fluid mechanics. The framework of the HSG-Amoeba is described with the segmentation of various skeletal components of the thoracic cage. Results: This being a foundational study to describe the concept of the HSG-Amoeba model it requires the development of a mathematical algorithm to demonstrate its worthiness as a tool for surgical applications. Conclusion: The focus of the study is to present the design and framework of the newly conceived HSG-Amoeba model to segment a medical image and extract tissue densities without altering the original image intensities.

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Hyalite溶胶-凝胶变形虫:一种基于生理的生物物理模型，用于医学图像的分割和生物转化，以3D固态表征原生组织特性，用于外科应用的患者特异性和患者适当分析

简介:努力改进医学图像分割技术，以便在手术计划和医学治疗中进行更高的分析，远未成为临床实践中的护理标准。基于生物物理科学的Hyalite溶胶-凝胶阿米巴模型除了进行图像分割外，还设计用于提取真实世界的组织密度，以进行患者特异性和适合患者的分析。目的:变形虫是一种单细胞独立生物，其细胞核和溶胶-凝胶原生质被膜包裹。该研究提出了变形变形虫的多功能重组解剖和生理分割二维和三维医学图像基于完善的能量最小化和活动轮廓的原则。它展示了小动物如何通过投掷假足来滑行和前进，这是由现象级的肌动蛋白-肌球蛋白活性驱动的，可以分割感兴趣的区域，最后，在细胞凋亡时，其原生质和细胞器获得原始图像强度的分布，以表征组织密度。方法:本开创性研究在简要回顾计算机视觉科学的基础上，讨论了光密度与组织密度之间的关系，以及溶胶-凝胶流体力学理论。hsg -阿米巴的框架是用胸廓的各种骨骼成分的分割来描述的。结果:这是一项描述hsg -阿米巴模型概念的基础研究，需要开发一种数学算法来证明其作为外科应用工具的价值。结论:本研究的重点是在不改变原始图像强度的情况下，提出新构想的hsg -阿米巴模型的设计和框架，以分割医学图像并提取组织密度。

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INTERNATIONAL JOURNAL OF COMPUTERS & TECHNOLOGY

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