Bioengineered Substrata to Probe Cellular Behavior

用于探测细胞行为的生物工程基质

• 批准号: 7124176
• 负责人: JOYCE Y WONG
• 金额: $ 36.27万
• 依托单位: BOSTON UNIVERSITY (CHARLES RIVER CAMPUS)
• 依托单位国家: 美国
• 财政年份: 2003
• 资助国家: 美国
• 起止时间: 2003-09-22 至 2008-06-30
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7124176
• 关键词: biomechanics; biotechnology; cell adhesion; cell components; cell growth regulation; cell morphology; cell motility; cell proliferation; cytoskeletal proteins; extracellular matrix; immunocytochemistry; integrins; phenotype; phosphorylation; restenosis; tissue engineering; vascular smooth muscle; video microscopy

DESCRIPTION (provided by applicant): Restenosis due to intimal hyperplasia and vasoconstriction remains a major problem in treatments of arterial occlusive disease. Smooth muscle cells play a major role in vascular remodeling, and local control of their cellular phenotype would greatly enhance efforts to reduce the occurrence of restenosis. A common result of vascular injury is excessive remodeling of the extracellular matrix, which becomes rich in collagens and proteoglycans. While this leads to changes in biochemical properties, it also significantly alters biomechanical properties. Based on recent work that cells respond to substrata with varying mechanical properties, our central hypothesis is that the biomechanical properties of the substratum will modulate vascular smooth muscle cell cellular phenotype that is relevant for restenosis. Current therapies for restenosis largely involve soluble factors, but little attention has been focused on understanding the effects of substratum biomechanical properties on cellular phenotype. The objective of the proposed research is to create model systems that will recapitulate the biomechanical environment during vascular remodeling and to identify key relationships between substrate compliance and cellular phenotype associated with restenosis. This objective will be achieved by investigating the effect of substrate compliance on the cellular phenotype of smooth muscle cells on model bioengineered substrata that are designed to exhibit a systematic variation in their compliance ranging from the microscopic to macroscopic length scales. The outcome of this research will be a novel in vitro model system that will more closely mimic the biomechanical environment of the remodeled matrix in which one can test the effects of agents on vascular smooth muscle cell phenotype. This model system can also be applied to other pathophysiologic systems. Synthetic hydrogels will be used as model substrata in order to control the local mechanical compliance. Aim 1 is to develop bioengineered substrata with well-defined mechanical compliance at the macro- and microscales. Results from studies in Aims 2 and 3 will be used in the refinement of Aim 1. Aim 2 will establish and quantify relationships between substrate compliance and vascular smooth muscle cell phenotypes associated with restenosis. Aim 3 will test the effects of substrate compliance on the expression, localization, and activity of putative mechanosensing cellular components (integrins, cytoskeleton, FAK, paxillin, Rho GTPases). These studies will advance new insights on the physical factors that control phenotypic modulation of vascular smooth muscle cells with the aim of developing therapies to block restenosis.

描述（由申请人提供）： 由于内膜增生和血管收缩引起的再狭窄仍然是动脉闭塞性疾病治疗中的一个主要问题。平滑肌细胞在血管重塑中起主要作用，局部控制其细胞表型将大大增强减少再狭窄发生的努力。血管损伤的一个常见结果是细胞外基质的过度重塑，其变得富含胶原和蛋白聚糖。虽然这会导致生物化学特性的变化，但它也会显着改变生物力学特性。基于最近的工作，细胞响应于基质不同的机械性能，我们的中心假设是，生物力学性能的基质将调节血管平滑肌细胞的细胞表型，是相关的再狭窄。目前再狭窄的治疗主要涉及可溶性因子，但很少关注基质生物力学特性对细胞表型的影响。拟议研究的目的是创建模型系统，将概括血管重塑过程中的生物力学环境，并确定与再狭窄相关的基质顺应性和细胞表型之间的关键关系。这一目标将通过研究基质顺应性对模型生物工程基质上平滑肌细胞的细胞表型的影响来实现，所述模型生物工程基质被设计为在其顺应性中表现出从微观到宏观长度尺度的系统变化。这项研究的结果将是一种新的体外模型系统，它将更接近地模拟重塑基质的生物力学环境，其中可以测试药物对血管平滑肌细胞表型的影响。该模型系统也可应用于其他病理生理系统。合成水凝胶将用作模型基质，以控制局部机械顺应性。目的1是开发生物工程基质，在宏观和微观尺度上具有明确的机械顺应性。目标2和3的研究结果将用于目标1的完善。目的2将建立和量化基质顺应性和血管平滑肌细胞表型与再狭窄之间的关系。目的3将测试底物顺应性对推定的机械敏感细胞组分（整合素、细胞骨架、FAK、桩蛋白、Rho GTP酶）的表达、定位和活性的影响。这些研究将推进对控制血管平滑肌细胞表型调节的物理因素的新见解，目的是开发阻断再狭窄的疗法。