involucrin and Burns

The healing of wounds, including those from burns, currently exerts a burden on healthcare systems worldwide. Hydrogels are widely used as wound dressings and in the field of tissue engineering. The popularity of bacterial cellulose-based hydrogels has increased owing to their biocompatibility. Previous study demonstrated that bacterial cellulose/acrylic acid (BC/AA) hydrogel increased the healing rate of burn wound. This in vivo study using athymic mice has extended the use of BC/AA hydrogel by the addition of human epidermal keratinocytes and human dermal fibroblasts. The results showed that hydrogel loaded with cells produces the greatest acceleration on burn wound healing, followed by treatment with hydrogel alone, compared with the untreated group. The percentage wound reduction on day 13 in the mice treated with hydrogel loaded with cells (77.34 ± 6.21%) was significantly higher than that in the control-treated mice (64.79 ± 6.84%). Histological analysis, the expression of collagen type I via immunohistochemistry, and transmission electron microscopy indicated a greater deposition of collagen in the mice treated with hydrogel loaded with cells than in the mice administered other treatments. Therefore, the BC/AA hydrogel has promising application as a wound dressing and a cell carrier.

Topics: Acetobacteraceae; Acrylates; Animals; Bandages; Burns; Cells, Cultured; Cellulose; Coculture Techniques; Collagen Type I; Fibroblasts; Humans; Hydrogels; Keratin-14; Keratinocytes; Male; Mice, Nude; Protein Precursors; Skin; Wound Healing

Skin-derived precursors (SKPs) are remnants of the embryonic neural crest stem cells that reside in the dermis until adulthood. Although they possess a wide range of differentiation potentials, their differentiation into keratinocyte-like cells and their roles in skin wound healing are obscure. The present study aimed to investigate the differentiation of SKPs into keratinocyte-like cells and evaluate their role in healing of third degree burn wounds. To this aim, SKPs were differentiated into keratinocyte-like cells on tissue culture plate and collagen-chitosan scaffold prepared by freeze-drying. Their differentiation capability was detected by real-time RT-PCR and immunofluorescence. Thereafter, they were cultured on scaffold and implanted in a rat model of burn wound. Histopathological and immunohistochemical analyses were employed to examine the reconstituted skin. The research findings revealed that SKPs were able to differentiate along the epidermal lineage and this ability can be enhanced on a suitable scaffold. Additionally, the results indicated that SKPs apparently promoted wound healing process and accelerate its transition from proliferating stage to maturational phase, especially if they were differentiated into keratinocyte-like cells. Regarding the results, it is concluded that SKPs are able to differentiate into keratinocyte-like cells, particularly when they are cultured on collagen-chitosan scaffold. Moreover, they can regenerate epidermal and dermal layers including thick collagen bundles, possibly through differentiation into keratinocyte-like cells.

Topics: Animals; Burns; Cell Differentiation; Cell Lineage; Cells, Cultured; Epidermal Cells; Fibronectins; Filaggrin Proteins; Intermediate Filament Proteins; Keratin-14; Keratinocytes; Protein Precursors; Rats; Rats, Wistar; Regenerative Medicine; Skin; Stem Cells; Tissue Scaffolds; Vimentin; Wound Healing

A cell-based wound coverage with keratinocytes and fibroblasts on the basis of a commercially available dermal substitute (Matriderm ((R)), Kollagen/Elastin matrix) was generated, in order to treat wide burn wounds. First the expansion of keratinocytes was optimised and the culturing time was minimised. Raw material was 1-2 cm (2) split skin. Dermis and epidermis were separated by enzymatic treatment with thermolysin. After treatment of both compartments with trypsin and collagenase I, keratinocytes and fibroblasts were isolated and expanded in collagen I coated dishes. After 10 days fibroblasts were seeded on Matriderm ((R)). After cultivation of the fibroblasts-containing matrix for one week keratinocytes were seeded on top. After an additional week of submersed cultivation the matrix was lifted up to the air-liquid interface to initiate epidermal cell differentiation. After 16 days in the air-liquid interphase the matrix was fixed and underwent immunohistochemical and electron microscopic analysis. Histological analysis showed a regularly stratification of the epidermal part. We observed collagen IV, a marker for the basement membrane, between epidermis and dermis. Desmoglein and the differentiation markers involucrine and cytokeratin 10 were found in the suprabasal layers of the epidermis. Electron microscopic analysis showed the basement membrane in the epidermal junction zone as well as cell-cell connections in the form of desmosomes. Late differentiation characteristics, like granular structures and the cornified layer, were found in the stratum granulosum and stratum corneum. Our results demonstrate that a skin equivalent can be generated by using a collagen/elastin matrix, with an expansion rate of 50-100-fold. This skin equivalent may be useful for covering deep wounds.

Topics: Basement Membrane; Burns; Collagen; Collagen Type IV; Desmogleins; Elastin; Epidermis; Fibroblasts; Humans; Keratinocytes; Microscopy, Electron; Microscopy, Fluorescence; Protein Precursors; Skin; Skin, Artificial; Tissue Engineering

RHPS, composed of confluent allogeneic keratinocytes cultured on cell-free pig dermis, stimulates wound healing when applied with the keratinocyte layer facing the wound. So far it has not been clarified whether the confluent keratinocytes implanted 'upside-down' can 'take' or only stimulate healing by producing growth factors. Confluent male keratinocytes were grafted onto donor sites of three female patients. Biopsies were taken on days 4, 6 and 9 after grafting. The fate of donor cells was followed in paraffin sections by FISH for the Y chromosome and by persisting expression of vimentin taken as a marker of cultured keratinocytes. Histological evaluation was complemented by detection of keratin 10 and involucrin. All three donor sites healed within one week. On day 4 the early neoepidermis was multilayered but disordered after transplantation. A large proportion of cells were apparently of donor origin as indicated by the presence of Y chromosomes, irregular morphology, expression of vimentin in the bottom and upper layers of the neoepidermis, and by irregular expression of involucrin and keratin 10 only in the central layer of the neoepidermis. From day 6 onwards, the new epidermis acquired an ordered stratification. Involucrin and keratin 10 renewed normal distribution in suprabasal layers. Concomitantly, vimentin expression was decreasing. The Y chromosome was still found on day 6 but not on day 9. We concluded that confluent allogeneic keratinocytes temporarily 'take' to the wound and contribute to rapid wound closure, being replaced by the patient's epidermal cells after about one week.

Topics: Adult; Animals; Biomarkers; Burns; Cell Survival; Cells, Cultured; Coculture Techniques; Dermis; Female; Graft Survival; Humans; In Situ Hybridization, Fluorescence; Keratin-10; Keratinocytes; Keratins; Male; Protein Precursors; Swine; Tissue Engineering; Transplantation, Homologous; Transplants; Vimentin; Wound Healing; Y Chromosome

The Epicel ASAProgram service generates autologous keratinocyte grafts used for the closure of full-thickness wounds in moderately and severely burned patients. The manufacturing process used to generate Epicel service autografts (ESA) is based upon the keratinocyte co-culture technique described by Rheinwald and Green which employs murine Swiss 3T3/J2 fibroblasts as feeder cells. Recently, a technique has been described that employs a polyurethane wound dressing, HydroDerm (HD, Innovative Technologies, Ltd), as a delivery vehicle for cultured keratinocytes intended for autologous grafting. We have examined the practical feasibility of this technique and report on testing the ability of HD to support keratinocyte growth and epithelium formation in vitro, at the air-liquid interface (ALI), and in vivo, after grafting to full-thickness wounds created on the backs of athymic (Swiss Nu/Nu) mice. The results demonstrate that keratinocytes grow on the HD dressing in Gibco SFM at a rate that is approximately 15 per cent of that observed when cells are cultivated on tissue culture (TC) plastic using standard techniques, yet the cells retain their proliferative capacity and form an epithelium in vitro when cultivated at the ALI on a dermal substrate. Keratinocyte-seeded HD membranes were also transferred to full-thickness wounds in athymic mice. Animals grafted with cells seeded to HD developed human epithelium, as revealed by species-specific detection of involucrin and evolved a normal attachment to the wound substratum, as demonstrated through the expression of dermally opposed laminin and alpha 6 beta 4 integrin. The ability of keratinocytes to maintain proliferative potential after seeding onto HD and their ability to form a properly oriented epithelium in vitro and in vivo suggests that this wound dressing may be useful as a vehicle for autologous keratinocyte grafting and help to provide earlier epithelial coverage to the burned patient. However, because of the slow proliferation rate of keratinocytes on HydroDerm, timely graft delivery would be best achieved by combining cell expansion via the Rheinwald and Green culture system, followed by the seeding of cells onto HydroDerm in a reduced calcium medium for subsequent autologous grafting.

Topics: 3T3 Cells; Animals; Antigens, Surface; Bandages; Burns; Calcium; Cell Adhesion; Cell Count; Cell Division; Cells, Cultured; Culture Media; Culture Techniques; Epithelium; Epitopes; Feasibility Studies; Humans; Integrin alpha6beta4; Integrins; Keratinocytes; Laminin; Membranes, Artificial; Mice; Mice, Nude; Pharmaceutical Vehicles; Polyurethanes; Protein Precursors; Skin; Species Specificity; Transplantation, Autologous