Leukocyte-mimicking stem cell delivery via in situ coating of cells with a bioactive hyperbranched polyglycerol.

Since stem cells emerged as a new generation of medicine, there are increasing efforts to deliver stem cells to a target tissue via intravascular injection. However, the therapeutic stem cells lack the capacity to detect and adhere to the target tissue. Therefore, this study presents synthesis of a bioactive hyperbranched polyglycerol (HPG) that can noninvasively associate with stem cells and further guide them to target sites, such as inflamed endothelium.

Tailoring the dependency between rigidity and water uptake of a microfabricated hydrogel with the conformational rigidity of a polymer cross-linker.

Many diverse applications utilize hydrogels as carriers, sensors, and actuators, and these applications rely on the refined control of physical properties of the hydrogel, such as elastic modulus and degree of swelling. Often, hydrogel properties are interdependent; for example, when elastic modulus is increased, degree of swelling is decreased. Controlling these inverse dependencies remains a major barrier for broader hydrogel applications.

The interplay between cell adhesion cues and curvature of cell adherent alginate microgels in multipotent stem cell culture.

Cell-adherent microcarriers are increasingly used to expand multipotent stem cells on a large scale for therapeutic applications. However, the role of the microcarrier properties and geometry on the phenotypic activities of multipotent cells has not been well studied. This study presents a significant interplay of the number of cell adhesion sites and the curvature of the microcarrier in regulating cell growth and differentiation by culturing mesenchymal stem cells on alginate microgels chemically linked with oligopeptides containing the Arg-Gly-Asp (RGD) sequence.

Hydrogels used for cell-based drug delivery.

Stem cells, progenitor cells, and lineage-committed cells are being considered as a new generation of drug depots for the sustained release of therapeutic biomolecules. Hydrogels are often used in conjunction with the therapeutic secreting cells to provide a physical barrier to protect the cells from hostile extrinsic factors. Although the hydrogels significantly improve the therapeutic efficacy of transplanted cells, there have been no successful products commercialized based on these technologies.

Three-dimensional synthetic niche components to control germ cell proliferation.

Spermatogonial stem cells (SSCs) are increasingly studied for potential use in tissue regeneration due to their ability to dedifferentiate into embryonic stem cell-like cells. For their successful therapeutic use, these cells must first be expanded in vitro using an appropriate culture system. We hypothesized that a hydrogel with proper biochemical and biomechanical properties may mimic the composition and structure of the native basement membrane onto which SSCs reside, thus allowing us to control SSC proliferation.