模拟不同器官特异性肿瘤组织内癌细胞和基质细胞所经历的物理力

IF 3.7 3区 医学 Q2 ENGINEERING, BIOMEDICAL IEEE Journal of Translational Engineering in Health and Medicine-Jtehm Pub Date : 2024-04-15 DOI:10.1109/JTEHM.2024.3388561
Morgan Connaughton;Mahsa Dabagh
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引用次数: 0

摘要

据报道,微环境对癌细胞施加的机械力会改变细胞的运动、增殖和凋亡,从而促使细胞形成侵袭性表型。这些机械力包括压缩力、拉伸力、静水压和剪切力。这些力的重要性被推测为改变癌细胞及其微环境的生物物理特性,是肿瘤恶性程度的指标。我们的目标是研究和量化肿瘤的恶性程度与癌细胞和微环境成分所受作用力之间的相关性。在这项研究中,我们建立了一个多成分三维肿瘤组织模型,该模型由被成纤维细胞和细胞外基质(ECM)包围的癌细胞组成。我们对包括乳腺、肾脏和胰腺在内的三种不同器官的研究结果表明A) 肿瘤组织内的应力受器官特定 ECM 生物物理特性的影响;B) 侵袭性更强的癌细胞会承受更高的应力;C) 与乳腺和肾脏相比,胰腺的 ECM 更软(杨氏模量为 1.0 kPa),癌细胞更硬(杨氏模量分别为 2.4 kPa 和 1.7 kPa)。D) 与被成纤维细胞包围的细胞相比,与 ECM 接触的癌细胞承受更高的应力,但当癌细胞被成纤维细胞包围时,承受高应力的肿瘤基质区域的最大长度为 40 ~\mu \text{m}$,而当癌细胞位于 ECM 附近时,最大长度为 12 ~\mu \text{m}$。这项研究为了解癌细胞、成纤维细胞和 ECM 所承受的应力如何与不同器官中癌细胞的恶性状态相关联迈出了重要的第一步。量化不同器官特异性 ECM 在不同恶性阶段对癌细胞施加的作用力将有助于:第一,开发治疗策略;第二,准确预测哪些肿瘤将高度恶性;第三,建立控制癌细胞恶性进展的准确标准。此外,我们的肿瘤组织硅学模型还能提供关键的有用信息,用于指导体外或体内实验,缩小需要研究的变量范围,了解哪些因素可能会影响癌症治疗,甚至是需要寻找的生物标志物。
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Modeling Physical Forces Experienced by Cancer and Stromal Cells Within Different Organ-Specific Tumor Tissue
Mechanical force exerted on cancer cells by their microenvironment have been reported to drive cells toward invasive phenotypes by altering cells’ motility, proliferation, and apoptosis. These mechanical forces include compressive, tensile, hydrostatic, and shear forces. The importance of forces is then hypothesized to be an alteration of cancer cells’ and their microenvironment’s biophysical properties as the indicator of a tumor’s malignancy state. Our objective is to investigate and quantify the correlation between a tumor’s malignancy state and forces experienced by the cancer cells and components of the microenvironment. In this study, we have developed a multicomponent, three-dimensional model of tumor tissue consisting of a cancer cell surrounded by fibroblasts and extracellular matrix (ECM). Our results on three different organs including breast, kidney, and pancreas show that: A) the stresses within tumor tissue are impacted by the organ specific ECM’s biophysical properties, B) more invasive cancer cells experience higher stresses, C) in pancreas which has a softer ECM (Young modulus of 1.0 kPa) and stiffer cancer cells (Young modulus of 2.4 kPa and 1.7 kPa) than breast and kidney, cancer cells experienced significantly higher stresses, D) cancer cells in contact with ECM experienced higher stresses compared to cells surrounded by fibroblasts but the area of tumor stroma experiencing high stresses has a maximum length of $40 ~\mu \text{m}$ when the cancer cell is surrounded by fibroblasts and $12 ~\mu \text{m}$ for when the cancer cell is in vicinity of ECM. This study serves as an important first step in understanding of how the stresses experienced by cancer cells, fibroblasts, and ECM are associated with malignancy states of cancer cells in different organs. The quantification of forces exerted on cancer cells by different organ-specific ECM and at different stages of malignancy will help, first to develop theranostic strategies, second to predict accurately which tumors will become highly malignant, and third to establish accurate criteria controlling the progression of cancer cells malignancy. Furthermore, our in silico model of tumor tissue can yield critical, useful information for guiding ex vivo or in vitro experiments, narrowing down variables to be investigated, understanding what factors could be impacting cancer treatments or even biomarkers to be looking for.
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来源期刊
CiteScore
7.40
自引率
2.90%
发文量
65
审稿时长
27 weeks
期刊介绍: The IEEE Journal of Translational Engineering in Health and Medicine is an open access product that bridges the engineering and clinical worlds, focusing on detailed descriptions of advanced technical solutions to a clinical need along with clinical results and healthcare relevance. The journal provides a platform for state-of-the-art technology directions in the interdisciplinary field of biomedical engineering, embracing engineering, life sciences and medicine. A unique aspect of the journal is its ability to foster a collaboration between physicians and engineers for presenting broad and compelling real world technological and engineering solutions that can be implemented in the interest of improving quality of patient care and treatment outcomes, thereby reducing costs and improving efficiency. The journal provides an active forum for clinical research and relevant state-of the-art technology for members of all the IEEE societies that have an interest in biomedical engineering as well as reaching out directly to physicians and the medical community through the American Medical Association (AMA) and other clinical societies. The scope of the journal includes, but is not limited, to topics on: Medical devices, healthcare delivery systems, global healthcare initiatives, and ICT based services; Technological relevance to healthcare cost reduction; Technology affecting healthcare management, decision-making, and policy; Advanced technical work that is applied to solving specific clinical needs.
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