Selection of Force Sensors for In Situ Measurement of Neotissue Microenvironments.

IF 3.5 3区 医学 Q3 CELL & TISSUE ENGINEERING Tissue Engineering Part A Pub Date : 2024-10-25 DOI:10.1089/ten.tea.2024.0192
Marta Rodriguez Navas, Eric M Darling
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Abstract

Mechanical forces are a critical stimulus in both native and engineered tissues. Direct measurement of these microenvironmental forces has been challenging, particularly for cell-dense models. To address this, we previously developed hydrogel-based force sensors that are approximately the size of a cell and can be imaged over time to computationally assess the forces exerted by surrounding cells and matrix. The goal of this project was to identify how the physical characteristics of force sensors impact measurements. Sensors were varied in size, elastic modulus, and surface coating before being included in stem cell suspensions that then spontaneously self-assembled into spheroidal neotissues. Using this model of early mesenchymal condensation, we hypothesized that larger, softer sensors would provide greater sensitivity and precision, whereas protein coatings would influence the directionality of applied forces (tensile vs. compressive). These experiments were conducted using a high-content imaging system that allowed analysis of over a thousand sensors to evaluate the various conditions. Results indicated that measurement fidelity was highest for force sensors that had a diameter >20 µm and modulus ∼0.2 kPa. Extremely soft sensors deformed too much, whereas stiffer sensors deformed too little. Collagen and N-cadherin coatings, which replicated cell-matrix or cell-cell binding, respectively, allowed for tensile forces to be exerted on the sensors, with greater forces being observed for N-cadherin sensors in these highly cellular neotissue constructs. Uncoated sensors were universally compressed due to the lack of cell-sensor adhesion. Disruption of the actin cytoskeleton lessened microenvironmental forces, whereas disruption of microtubules had no measurable effect. Potential future applications of the technology include studies of in situ forces in developing tissues as well as a real-time sensor for monitoring the growth of engineered constructs.

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选择用于现场测量新组织微环境的力传感器
机械力是原生组织和工程组织的关键刺激因素。直接测量这些微环境力具有挑战性,特别是对于细胞密集的模型。为了解决这个问题,我们之前开发了基于水凝胶的力传感器,这种传感器与细胞大小相近,可以随着时间的推移进行成像,从而对周围细胞和基质施加的力进行计算评估。该项目的目标是确定力传感器的物理特性如何影响测量结果。传感器的大小、弹性模量和表面涂层各不相同,然后将其放入干细胞悬浮液中,干细胞悬浮液会自发地自我组装成球形新组织。利用这一早期间充质凝聚模型,我们假设较大、较软的传感器将提供更高的灵敏度和精度,而蛋白质涂层将影响外力的方向性(拉伸与压缩)。这些实验是使用高内容成像系统进行的,该系统可对一千多个传感器进行分析,以评估各种条件。结果表明,直径大于 20 µm、模量 ∼0.2 kPa 的力传感器的测量保真度最高。极软的传感器变形太大,而较硬的传感器变形太小。胶原蛋白和 N-粘连蛋白涂层分别复制了细胞-基质或细胞-细胞结合,可对传感器施加拉力,在这些高度细胞化的新组织构建物中,N-粘连蛋白传感器的拉力更大。由于缺乏细胞-传感器粘附,无涂层传感器普遍受到压缩。破坏肌动蛋白细胞骨架可减轻微环境力,而破坏微管则没有明显影响。该技术未来的潜在应用包括研究发育中组织的原位力,以及用于监测工程构建体生长的实时传感器。
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来源期刊
Tissue Engineering Part A
Tissue Engineering Part A Chemical Engineering-Bioengineering
CiteScore
9.20
自引率
2.40%
发文量
163
审稿时长
3 months
期刊介绍: Tissue Engineering is the preeminent, biomedical journal advancing the field with cutting-edge research and applications that repair or regenerate portions or whole tissues. This multidisciplinary journal brings together the principles of engineering and life sciences in the creation of artificial tissues and regenerative medicine. Tissue Engineering is divided into three parts, providing a central forum for groundbreaking scientific research and developments of clinical applications from leading experts in the field that will enable the functional replacement of tissues.
期刊最新文献
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