Altered phenotypic gene expression of 10T1/2 mesenchymal cells in nonuniformly stretched PEGDA hydrogels

Wj, Richardson; Wilson, Emily; Moore, Jr Je

doi:10.1152/ajpcell.00340.2012

Cited by 6 publications

(2 citation statements)

References 53 publications

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“…Like other synthetic polymers, PEG hydrogels are inert to matrix proteases, lack a fibrillar structure, and also have sub-micron pores. Consequently, encapsulated cells are confined by the surrounding polymer, which does not allow cell alignment or elongation in response to strain (Richardson et al 2013). We encapsulated U2OS osteosarcoma cells within collagen microspheres suspended within PEGDA hydrogel and investigated the morphological changes to the cells when the composite scaffold was subjected to cyclic uniaxial strain ( Figure 2).…”

Section: Engineered Tissuesmentioning

confidence: 99%

The many ways adherent cells respond to applied stretch

Sears

Kaunas

2016

Journal of Biomechanics

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Cells in various tissues are subjected to mechanical stress and strain that have profound effects on cell architecture and function. The specific response of the cell to applied strain depends on multiple factors, including cell contractility, spatial and temporal strain pattern, and substrate dimensionality and rigidity. Recent work has demonstrated that the cell response to applied strain depends on a complex combination of these factors, but the way these factors interact to elicit a specific response is not intuitive. We submit that an understanding of the integrated response of a cell to these factors will provide new insight into mechanobiology and contribute to the effective design of deformable engineered scaffolds meant to provide appropriate mechanical cues to the resident cells.

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Section: Engineered Tissuesmentioning

confidence: 99%

The many ways adherent cells respond to applied stretch

Sears

Kaunas

2016

Journal of Biomechanics

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“…Third, while we simulated the effect of strain-dependent deposition, we assumed this cell response was a function of global strain and did not depend on each cell’s local orientation. Fourth, cell culture experiments have shown that mechanical loading can also modify cell proliferation (Sawaguchi et al 2010; Richardson et al 2013; Sun et al 2016). We did not include strain-induced proliferation in our model as past measurements in the supraspinatus tendon showed subtle decreases in cell density with increased levels of loading (Thomopoulos et al 2003; Galatz et al 2009).…”

Section: Discussionmentioning

confidence: 99%

Potential strain-dependent mechanisms defining matrix alignment in healing tendons

Richardson

Kegerreis

Thomopoulos

et al. 2018

Biomech Model Mechanobiol

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Tendon mechanical function after injury and healing is largely determined by its underlying collagen structure, which in turn is dependent on the degree of mechanical loading experienced during healing. Experimental studies have shown seemingly conflicting outcomes: although collagen content steadily increases with increasing loads, collagen alignment peaks at an intermediate load. Herein, we explored potential collagen remodeling mechanisms that could give rise to this structural divergence in response to strain. We adapted an established agent-based model of collagen remodeling in order to simulate various strain-dependent cell and collagen interactions that govern long-term collagen content and fiber alignment. Our simulation results show two collagen remodeling mechanisms that give rise to divergent collagen content and alignment in healing tendons: (1) strain-induced collagen fiber damage in concert with increased rates of deposition at higher strains, or (2) strain-dependent rates of enzymatic degradation. These model predictions identify critical future experiments needed to isolate each mechanism's specific contribution to the structure of healing tendons.

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