The basal keratinocyte progenitor cells in cultured epithelial autografts (CEAs) regenerate human epidermis after transplantation, a curative therapy for severe burns and, recently, diseases with epidermal loss, such as junctional epidermolysis bullosa (EB). Although a culturing technique for skin keratinocytes was developed four decades ago, the xenogeneic nature of that conventional CEA culture system restricts its use to the treatment of critical and life-threatening cases, such as severe burns on >30% of total body surface area and EB. In the present protocol, we describe how to implement a defined, xeno-free culture system that supports long-term ex vivo expansion of functional human epidermal keratinocytes.
View Article and Find Full Text PDFBasement membrane laminins (LNs) have been shown to modulate cellular phenotypes and differentiation both in vitro and during organogenesis in vivo. At least 16 laminin isoforms are present in mammals, and most are available as recombinant proteins. Ubiquitous LN511 and LN521 promote the clonal derivation and expansion of pluripotent embryonic stem cells (ESCs), and, together with other highly cell type-specific laminins, they can support the differentiation of stem cells into, for example, cardiac muscle fibers, retinal pigmented epithelial (RPE) cells and photoreceptors, dopamine (DA) neurons, and skin keratinocytes.
View Article and Find Full Text PDFThe current expansion of autologous human keratinocytes to resurface severe wound defects still relies on murine feeder layer and calf serum in the cell culture system. Through our characterization efforts of the human skin basement membrane and murine feeder layer 3T3-J2, we identified two biologically relevant recombinant laminins-LN-511 and LN-421- as potential candidates to replace the murine feeder. Herein, we report a completely xeno-free and defined culture system utilizing these laminins which enables robust expansion of adult human skin keratinocytes.
View Article and Find Full Text PDFACS Appl Mater Interfaces
October 2017
Bioengineered extracellular matrix (ECM) mimetic materials have tunable properties and can be engineered to elicit desirable cellular responses for wound repair and tissue regeneration. By incorporating relevant cell-instructive domains, bioengineered ECM mimics can be designed to provide well-defined ECM-specific cues to influence cell motility and differentiation. More importantly, bioengineered ECM surfaces are ideal platforms for studying cell-material interactions without the need to genetically alter the cells.
View Article and Find Full Text PDFRecombinant technology is a versatile platform to create novel artificial proteins with tunable properties. For the last decade, many artificial proteins that have incorporated functional domains derived from nature (or created de novo) have been reported. In particular, artificial extracellular matrix (aECM) proteins have been developed; these aECM proteins consist of biological domains taken from fibronectin, laminins and collagens and are combined with structural domains including elastin-like repeats, silk and collagen repeats.
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