Weldon School of Biomedical Engineering, Purdue University, 206 South Martin Jischke Drive, West Lafayette, IN 47907, United States.
School of Materials Engineering, Purdue University, Neil Armstrong Hall of Engineering, 701 West Stadium Avenue, West Lafayette, IN 47907, United States.
Acta Biomater. 2021 Oct 15;134:466-476. doi: 10.1016/j.actbio.2021.07.035. Epub 2021 Jul 21.
The mechanical properties of tissues are critical design parameters for biomaterials and regenerative therapies seeking to restore functionality after disease or injury. Characterizing the mechanical properties of native tissues and extracellular matrix throughout embryonic development helps us understand the microenvironments that promote growth and remodeling, activities critical for biomaterials to support. The mechanical characterization of small, soft materials like the embryonic tissues of the mouse, an established mammalian model for development, is challenging due to difficulties in handling minute geometries and resolving forces of low magnitude. While uniaxial tensile testing is the physiologically relevant modality to characterize tissues that are loaded in tension in vivo, there are no commercially available instruments that can simultaneously measure sufficiently low tensile force magnitudes, directly measure sample deformation, keep samples hydrated throughout testing, and effectively grip minute geometries to test small tissues. To address this gap, we developed a micromanipulator and spring system that can mechanically characterize small, soft materials under tension. We demonstrate the capability of this system to measure the force contribution of soft materials, silicone, fibronectin sheets, and fibrin gels with a 5 nN - 50 µN force resolution and perform a variety of mechanical tests. Additionally, we investigated murine embryonic tendon mechanics, demonstrating the instrument can measure differences in mechanics of small, soft tissues as a function of developmental stage. This system can be further utilized to mechanically characterize soft biomaterials and small tissues and provide physiologically relevant parameters for designing scaffolds that seek to emulate native tissue mechanics. STATEMENT OF SIGNIFICANCE: The mechanical properties of cellular microenvironments are critical parameters that contribute to the modulation of tissue growth and remodeling. The field of tissue engineering endeavors to recapitulate these microenvironments in order to construct tissues de novo. Therefore, it is crucial to uncover the mechanical properties of the cellular microenvironment during tissue formation. Here, we present a system capable of acquiring microscale forces and optically measuring sample deformation to calculate the stress-strain response of soft, embryonic tissues under tension, and easily adaptable to accommodate biomaterials of various sizes and stiffnesses. Altogether, this modular system enables researchers to probe the unknown mechanical properties of soft tissues throughout development to inform the engineering of physiologically relevant microenvironments.
组织的力学性能是生物材料和再生疗法的关键设计参数,它们旨在在疾病或损伤后恢复功能。在胚胎发育过程中,对天然组织和细胞外基质的力学性能进行表征有助于我们了解促进生长和重塑的微环境,这些活动对于生物材料的支持至关重要。由于难以处理微小的几何形状和解决低幅度的力,像小鼠这样的胚胎组织等小型软材料的力学特性的表征具有挑战性,小鼠是发育的成熟哺乳动物模型。虽然单轴拉伸测试是一种生理相关的方式,可以对体内受到张力的组织进行特性描述,但没有商业上可用的仪器可以同时测量足够低的拉伸力幅度,直接测量样品变形,在整个测试过程中保持样品湿润,并有效地夹持微小的几何形状来测试小组织。为了解决这个差距,我们开发了一种微操纵器和弹簧系统,可以在张力下对小型软材料进行力学特性描述。我们展示了该系统测量软材料、硅酮、纤维连接蛋白片和纤维蛋白凝胶的力贡献的能力,其力分辨率为 5 nN-50 µN,并进行了各种力学测试。此外,我们研究了小鼠胚胎腱力学,证明该仪器可以测量作为发育阶段函数的小而软组织的力学差异。该系统可以进一步用于对软生物材料和小组织进行力学特性描述,并为设计旨在模拟天然组织力学的支架提供生理相关的参数。
细胞微环境的力学特性是促进组织生长和重塑的关键参数。组织工程领域努力在体内重新构建这些微环境,以构建新的组织。因此,揭示组织形成过程中细胞微环境的力学特性至关重要。在这里,我们提出了一种能够获取微尺度力并通过光学测量样品变形来计算拉伸下软质胚胎组织的应力-应变响应的系统,并且易于适应各种尺寸和刚度的生物材料。总之,这个模块化系统使研究人员能够探测整个发育过程中软组织的未知力学特性,为生理相关微环境的工程设计提供信息。
