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Sensitive detection of cell-derived force and collagen matrix tension in microtissues undergoing large-scale densification

Xiang Wang, Qiang Gao, Xiaoning Han, Bing Bu, Longfei Wang, Aoqi Li, Linhong Deng

2021Proceedings of the National Academy of Sciences16 citationsDOIOpen Access PDF

Abstract

Mechanical forces generated by cells and the tension of the extracellular matrix (ECM) play a decisive role in establishment, homeostasis maintenance, and repair of tissue morphology. However, the dynamic change of cell-derived force during large-scale remodeling of soft tissue is still unknown, mainly because the current techniques of force detection usually produce a nonnegligible and interfering feedback force on the cells during measurement. Here, we developed a method to fabricate highly stretchable polymer-based microstrings on which a microtissue of fibroblasts in collagen was cultured and allowed to contract to mimic the densification of soft tissue. Taking advantage of the low-spring constant and large deflection range of the microstrings, we detected a strain-induced contraction force as low as 5.2 µN without disturbing the irreversible densification. Meanwhile, the microtissues displayed extreme sensitivity to the mechanical boundary within a narrow range of tensile stress. More importantly, results indicated that the cell-derived force did not solely increase with increased ECM stiffness as previous studies suggested. Indeed, the cell-derived force and collagen tension exchanged dramatically in dominating the microtissue strain during the densification, and the proportion of cell-derived force decreased linearly as the microtissue densified, with stiffness increasing to ∼500 Pa. Thus, this study provides insights into the biomechanical cross-talk between the cells and ECM of extremely soft tissue during large-extent densification, which may be important to guide the construction of life-like tissue by applying appropriate mechanical boundary conditions.

Topics & Concepts

Extracellular matrixStiffnessMaterials scienceSoft tissueTension (geology)MechanobiologyMatrix (chemical analysis)Ultimate tensile strengthTissue engineeringBiomedical engineeringBiophysicsNanotechnologyComposite materialCell biologyAnatomyPathologyMedicineBiologyCellular Mechanics and Interactions3D Printing in Biomedical ResearchTendon Structure and Treatment
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