Vascularized 3D Human Skin Models in the Forefront of Dermatological Research.

In vitro engineered skin models are emerging as an alternative platform to reduce and replace animal testing in dermatological research. Despite the progress made in recent years, considerable challenges still exist for the inclusion of diverse cell types within skin models. Blood vessels, in particular, are essential in maintaining tissue homeostasis and are one of many primary contributors to skin disease inception and progression. Substantial efforts in the past have allowed the successful fabrication of vascularized skin models that are currently utilized for disease modeling and drugs/cosmetics testing. This review first discusses the need for vascularization within tissue-engineered skin models, highlighting their role in skin grafting and disease pathophysiology. Second, the review spotlights the milestones and recent progress in the fabrication and utilization of vascularized skin models. Additionally, advances including the use of bioreactors, organ-on-a-chip devices, and organoid systems are briefly explored. Finally, the challenges and future outlook for vascularized skin models are addressed.

Purification and differentiation of human adipose-derived stem cells by membrane filtration and membrane migration methods.

Human adipose-derived stem cells (hADSCs) are easily isolated from fat tissue without ethical concerns, but differ in purity, pluripotency, differentiation ability, and stem cell marker expression, depending on the isolation method. We isolated hADSCs from a primary fat tissue solution using: (1) conventional culture, (2) a membrane filtration method, (3) a membrane migration method where the primary cell solution was permeated through membranes, adhered hADSCs were cultured, and hADSCs migrated out from the membranes. Expression of mesenchymal stem cell markers and pluripotency genes, and osteogenic differentiation were compared for hADSCs isolated by different methods using nylon mesh filter membranes with pore sizes ranging from 11 to 80 µm. hADSCs isolated by the membrane migration method had the highest MSC surface marker expression and efficient differentiation into osteoblasts. Osteogenic differentiation ability of hADSCs and MSC surface marker expression were correlated, but osteogenic differentiation ability and pluripotent gene expression were not.

Proliferation and osteogenic differentiation of amniotic fluid-derived stem cells.

Human amniotic fluid-derived stem cells (hAFCs) are pluripotent fetal cells capable of differentiating into multiple lineages, including cell types of each of the three embryonic germ layers. Proper differentiation and maintenance of pluripotency, the defining characteristics of stem cells, are regulated not only by the cells themselves but also by their microenvironment. Furthermore, the physical characteristics of the cell culture materials, such as material elasticity, influence the results of stem cell differentiation. We investigated the osteogenic differentiation efficiency of hAFCs cultured on cell culture materials with different elasticities that were grafted with extracellular matrix-derived oligopeptides. Polyvinyl alcohol-co-itaconic acid (PV) hydrogels with different elasticities were prepared by controlling the crosslinking intensity, and the resulting PV hydrogels were grafted with and without extracellular matrix (ECM)-derived oligopeptides. Specific ECM-derived oligopeptides were used to maintain the pluripotency of AFCs and were determined by evaluation of pluripotent gene expression (Sox2 and Oct4). The osteogenic differentiation efficiency of the hAFCs, cultured on PV hydrogels grafted with and without ECM-derived oligopeptides, was analyzed by alkaline phosphatase activity, Alizarin Red S staining, and von Kossa staining. Unmodified PV hydrogels induced osteoblast differentiation of hAFCs with high efficiency. We conclude that the hAFCs interacting with ECM-derived oligopeptides tended to maintain an undifferentiated state.

Data of continuous harvest of stem cells via partial detachment from thermoresponsive nanobrush surfaces.

This data article contains two figures and one table supporting the research article entitled: "Continuous harvest of stem cells via partial detachment from thermoresponsive nanobrush surface" [1]. The table shows coating conditions of three copolymers, poly(styrene-co-acrylic acid) grafted with oligovitronectin, poly(styrene-co-N-isopropylacrylamide) and poly(styrene-co-polyethylene glycol methacrylate) to prepare thermoresponsive surface. XPS spectra show the nitrogen peak of the polystyrene surface coated with poly(styrene-co-acrylic acid) grafted with oligovitronectin. The surface coating density analyzed from sorption of poly(styrene-co-acrylic acid) grafted with oligovitronectin by UV-vis spectroscopy is also presented.

Continuous harvest of stem cells via partial detachment from thermoresponsive nanobrush surfaces.

Stem cell culture is typically based on batch-type culture, which is laborious and expensive. Here, we propose a continuous harvest method for stem cells cultured on thermoresponsive nanobrush surfaces. In this method, stem cells are partially detached from the nanobrush surface by reducing the temperature of the culture medium below the critical solution temperature needed for thermoresponse. The detached stem cells are harvested by exchange into fresh culture medium. Following this, the remaining cells are continuously cultured by expansion in fresh culture medium at 37 °C. Thermoresponsive nanobrush surfaces were prepared by coating block copolymers containing polystyrene (for hydrophobic anchoring onto culture dishes) with three types of polymers: (a) polyacrylic acid with cell-binding oligopeptides, (b) thermoresponsive poly-N-isopropylacrylamide, and (c) hydrophilic poly(ethyleneglycol)methacrylate. The optimal coating durations and compositions for these copolymers to facilitate adequate attachment and detachment of human adipose-derived stem cells (hADSCs) and embryonic stem cells (hESCs) were determined. hADSCs and hESCs were continuously harvested for 5 and 3 cycles, respectively, via the partial detachment of cells from thermoresponsive nanobrush surfaces.