Addison Walker scite author profile

The performance of implantable biomaterials derived from decellularized tissue, including encouraging results with skeletal muscle, suggests that the extracellular matrix (ECM) derived from native tissue has promising regenerative potential. Yet, the supply of biomaterials derived from donated tissue will always be limited, which is why the in-vitro fabrication of ECM biomaterials that mimic the properties of tissue is an attractive alternative. Towards this end, our group has utilized a novel method to collect the ECM that skeletal muscle myoblasts secrete and form it into implantable scaffolds. The cell derived ECM contained several matrix constituents, including collagen and fibronectin that were also identified within skeletal muscle samples. The ECM was organized into a porous network that could be formed with the elongated and aligned architecture observed within muscle samples. The ECM material supported the attachment and in-vitro proliferation of cells, suggesting effectiveness for cell transplantation, and was well tolerated by the host when examined in-vivo. The results suggest that the ECM collection approach can be used to produce biomaterials with compositions and structures that are similar to muscle samples, and while the physical properties may not yet match muscle values, the in-vitro and in-vivo results indicate it may be a suitable first generation alternative to tissue derived biomaterials.

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Valve interstitial cell shape modulates cell contractility independent of cell phenotype

Tandon

Razavi

Ravishankar

et al. 2016

Journal of Biomechanics

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Valve interstitial cells are dispersed throughout the heart valve and play an important role in maintaining its integrity, function, and phenotype. While prior studies have detailed the role of external mechanical and biological factors in the function of the interstitial cell, the role of cell shape in regulating contractile function, in the context of normal and diseased phenotypes, is not well understood. Thus, the aim of this study was to elucidate the link between cell shape, phenotype, and acute functional contractile output. Valve interstitial cell monolayers with defined cellular shapes were engineered via constraining cells to micropatterned protein lines (10, 20, 40, 60 or 80µm wide). Samples were cultured in either normal or osteogenic medium. Cellular shape and architecture were quantified via fluorescent imaging techniques. Cellular contractility was quantified using a valve thin film assay and phenotype analyzed via western blotting, zymography, and qRT-PCR. In all pattern widths, cells were highly aligned, with maximum cell and nuclear elongation occurring for the 10μm pattern width. Cellular contractility was highest for the most elongated cells, but was also increased in cells on the widest pattern (80μm) that also had increased CX43 expression, suggesting a role for both elongated shape and increased cell-cell contact in regulating contractility. Cells cultured in osteogenic medium had greater expression of smooth muscle markers and correspondingly increased contractile stress responses. Cell phenotype did not significantly correlate with altered cell shape, suggesting that cellular shape plays a significant role in the regulation of valve contractile function independent of phenotype.

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Cell derived extracellular matrix fibers synthesized using sacrificial hollow fiber membranes

et al. 2017

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The therapeutic potential of biological scaffolds as adjuncts to synthetic polymers motivates the engineering of fibers formed using the extracellular matrix (ECM) secreted by cells. To capture the ECM secreted by cells during in vitro culture, a solvent degradable hollow fiber membrane (HFM) was created and utilized as a cell culture platform. NIH/3T3 fibroblasts were injected into the narrow (0.986 ± 0.042 mm) lumina of mesoporous polysulfone HFMs and maintained in culture for up to 3 weeks. Following cell culture, HFMs were dissolved using N-methyl-2-pyrrolidone and the accumulated ECM was collected. The ECM retained the filamentous dimensions of the HFM lumen. The process yielded up to 0.89 ± 0.20 mg of ECM for every mm of HFM dissolved. Immunofluorescence, second-harmonic generation microscopy, and tandem mass spectrometry indicated the presence of an array of ECM constituents, including collagen, fibronectin, and proteoglycans, while FTIR spectra suggested thorough HFM material dissolution. Isolated ECM fibers, although fragile, were amenable to handling and exhibited an average elastic modulus of 34.6 ± 15.3 kPa, ultimate tensile strength of 5.2 ± 2.2 kPa, and elongation-at-break of 29% ± 18%. ECM fibers consisted of an interconnected yet porous (32.7% ± 5.8% open space) network which supported the attachment and in vitro proliferation of mammalian cells. ECM fibers were similarly synthesized using muscle and astrocyte cells, suggesting process robustness across different cell types. Ultimately, these ECM fibers could be utilized as an alternative to synthetics for the manufacture of woven meshes targeting wound healing or regenerative medicine applications.

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Repeated In Vitro Impact Conditioning of Astrocytes Decreases the Expression and Accumulation of Extracellular Matrix

et al. 2019

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Addison Walker

Development of a biological scaffold engineered using the extracellular matrix secreted by skeletal muscle cells

Valve interstitial cell shape modulates cell contractility independent of cell phenotype

Cell derived extracellular matrix fibers synthesized using sacrificial hollow fiber membranes

Repeated In Vitro Impact Conditioning of Astrocytes Decreases the Expression and Accumulation of Extracellular Matrix

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