The Development of an Advanced Model for Multilayer Human Skin Reconstruction In Vivo.

Human skin reconstruction on immune-deficient mice has become indispensable for in vivo studies performed in basic research and translational laboratories. Further advancements in making sustainable, prolonged skin equivalents to study new therapeutic interventions rely on reproducible models utilizing patient-derived cells and natural three-dimensional culture conditions mimicking the structure of living skin. Here, we present a novel step-by-step protocol for grafting human skin cells onto immunocompromised mice that requires low starting cell numbers, which is essential when primary patient cells are limited for modeling skin conditions. The core elements of our method are the sequential transplantation of fibroblasts followed by keratinocytes seeded into a fibrin-based hydrogel in a silicone chamber. We optimized the fibrin gel formulation, timing for gel polymerization in vivo, cell culture conditions, and seeding density to make a robust and efficient grafting protocol. Using this approach, we can successfully engraft as few as 1.0 × 106 fresh and 2.0 × 106 frozen-then-thawed keratinocytes per 1.4 cm2 of the wound area. Additionally, it was concluded that a successful layer-by-layer engraftment of skin cells in vivo could be obtained without labor-intensive and costly methodologies such as bioprinting or engineering complex skin equivalents. Key features • Expands upon the conventional skin chamber assay method (Wang et al., 2000) to generate high-quality skin grafts using a minimal number of cultured skin cells. • The proposed approach allows the use of frozen-then-thawed keratinocytes and fibroblasts in surgical procedures. • This system holds promise for evaluating the functionality of skin cells derived from induced pluripotent stem cells and replicating various skin phenotypes. • The entire process, from thawing skin cells to establishing the graft, requires 54 days. Graphical overview.

A High-Efficiency Method for the Production of Endothelial Cells from Human Induced Pluripotent Stem Cells.

Endothelial cells (ECs) are important components of the circulatory system. These cells can be used for in vitro modeling of cardiovascular diseases and in regenerative medicine to promote vascularization of engineered tissue constructs. However, low proliferative capacity and patient-to-patient variability limit the use of primary ECs in the clinic and disease modeling. ECs differentiated from human induced pluripotent stem cells (iPSCs) can serve as a viable alternative to primary ECs for these applications. This is because human iPSCs can proliferate indefinitely and have the potential to differentiate into a variety of somatic cell lines, providing a renewable source of patient-specific cells. Here, we present an optimized, highly reproducible method for the differentiation of human iPSCs toward vascular ECs. The protocol relies on the activation of the WNT signaling pathway and the use of growth factors and small molecules. The resulting iPSC-derived ECs can be cultured for multiple passages without losing their functionality and are suitable for both in vitro and in vivo studies.

High-efficiency RNA-based reprogramming of human primary fibroblasts.

Induced pluripotent stem cells (iPSCs) hold great promise for regenerative medicine; however, their potential clinical application is hampered by the low efficiency of somatic cell reprogramming. Here, we show that the synergistic activity of synthetic modified mRNAs encoding reprogramming factors and miRNA-367/302s delivered as mature miRNA mimics greatly enhances the reprogramming of human primary fibroblasts into iPSCs. This synergistic activity is dependent upon an optimal RNA transfection regimen and culturing conditions tailored specifically to human primary fibroblasts. As a result, we can now generate up to 4,019 iPSC colonies from only 500 starting human primary neonatal fibroblasts and reprogram up to 90.7% of individually plated cells, producing multiple sister colonies. This methodology consistently generates clinically relevant, integration-free iPSCs from a variety of human patient's fibroblasts under feeder-free conditions and can be applicable for the clinical translation of iPSCs and studying the biology of reprogramming.