Pluripotent stem cells (PSCs), including embryonic stem cells (ESCs) and induced pluripotent stem cells (iPSCs) have promise in regenerative medicine for a variety of applications. Their potential in the treatment of cardiovascular disease is of particular interest due to its severity and prevalence. In order to be successful for cell therapy, PSCs must be pre-differentiated into cardiomyocytes to prevent teratoma formation in vivo. Current methods focus on the supplementation of soluble factors to culture medium to drive differentiation into mesodermal lineages; however, these methods are costly with varying cardiomyocyte yields. Since cardiomyocytes are exposed to dynamic environments in vivo, there is potential in using mechanical stimulation to further drive differentiation in vitro. In this review, we will describe the most recent developments in how mechanical stimulation, including fluid shear, cyclic strain, and magnetically mediated strain, can guide cardiomyogenesis in PSCs.
Successful cellular cardiomyoplasty is dependent on biocompatible materials that can retain the cells in the myocardium in order to promote host tissue repair following myocardial infarction. A variety of methods have been explored for incorporating a cell-seeded matrix into the heart, the most popular options being direct application of an injectable system or surgical implantation of a patch. Fibrin-based gels are suitable for either of these approaches, as they are biocompatible and have mechanical properties that can be tailored by adjusting the initial fibrinogen concentration. We have previously demonstrated that conjugating amine-reactive homo-bifunctional polyethylene glycol (PEG) to the fibrinogen prior to crosslinking with thrombin can increase stability both in vivo and in vitro. Similarly, when mesenchymal stem cells are combined with PEGylated fibrin and injected into the myocardium, cell retention can be significantly increased and scar tissue reduced following myocardial infarction. We hypothesized that this gel system could similarly promote cardiomyocyte viability and function in vitro, and that optimizing the mechanical properties of the hydrogel would enhance contractility. In this study, we cultured HL-1 cardiomyocytes either on top of plated PEGylated fibrin (2D) or embedded in 3D gels and evaluated cardiomyocyte function by assessing the expression of cardiomyocyte specific markers, sarcomeric α-actin, and connexin 43, as well as contractile activity. We observed that the culture method can drastically affect the functional phenotype of HL-1 cardiomyocytes, and we present data suggesting the potential use of PEGylated fibrin gel layers to prepare a sheet-like construct for myocardial regeneration.
Morphological analysis is an essential step in verifying the success of a tissue engineering strategy where the presence of a desired cellular phenotype must be determined. While morphometry has transitioned from observational grading to computational quantification, established quantitative methods eliminate information by relying on two-dimensional (2D) analysis to describe three-dimensional (3D) niches. In this study, we demonstrate the validity and utility of 3D morphological quantification using two common angiogenesis assays in our fibrin-based in vitro model: (1) the microcarrier bead assay with human mesenchymal stem cells and (2) the rat aortic ring outgrowth assay. The quantification method is based on collecting and segmenting fluorescent confocal z-stacks into 3D models with 3D Slicer, an open-source magnetic resonance imaging/computed tomography analysis program. Data from 3D models are then processed into biologically relevant metrics in MATLAB for statistical analysis. Metrics include descriptive parameters such as vascular network length, volume, number of network segments, and degree of network branching. Our results indicate that 2D measures are significantly different than their 3D counterparts unless the vascular network exhibits anisotropic growth along the plane of imaging. Additionally, the statistical outcomes of 3D morphological quantification agreed with our initial qualitative observations among different test groups. This novel quantification approach generates more spatially accurate and objective measures, representing an important step toward improving the reliability of morphological comparisons.
To evaluate the appropriate time frame for applying mechanical stimuli to induce mesenchymal stromal cell (MSC) differentiation for ligament tissue engineering, developmental cell phenotypes were monitored during a period of in vitro culture. MSCs were seeded onto surface-modified silk fibroin fiber matrices and cultured in Petri dishes for 15 days. Cell metabolic activity, morphology, and gene expression of extracellular matrix (ECM) proteins (collagen type I and III and fibronectin), ECM receptors (integrins alpha-2, alpha-5, and beta-1), and heat-shock protein 70 (HSP-70) were monitored during the culture of MSC. MSCs showed fluctuations in cell metabolic activity, ECM, integrin, and HSP-70 transcription potentially correlating to innate developmental processes. Cellular response to mechanical stimulation was dependent on the stage of cell development. At day 9, when levels of cell metabolic activity, ECM, integrin, and HSP-70 transcription peaked, mechanical stimulation increased MSC metabolic activity, alignment, and collagen production. Mechanical stimulation applied at day 1 and 3 showed detrimental effects on MSCs seeded on silk matrices. The results presented in this study identify a unique correlation between innate MSC development processes on a surface-modified silk matrix and dynamic environmental signaling.
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