Michelle Verkerk scite author profile

Patients with large burn wounds have a limited amount of healthy donor skin. An alternative for the autologous skin graft is transplantation with autologous keratinocytes. Conventionally, the keratinocytes are cultured with mouse feeder layer cells in medium containing fetal calf serum (FCS) to obtain sufficient numbers of cells. These xenobiotic materials can be a potential risk for the patient. The aim of the present study was to investigate if keratinocytes could be expanded in culture without the need of a feeder layer and FCS. Keratinocytes were cultured on tissue culture plastic with or without collagen type IV coating in medium containing Ultroser G (serum substitute) and keratinocyte growth factor (KGF). An in vitro skin equivalent model was used to examine the capacity of these cells to form an epidermis. Keratinocytes in different passages (P2, P4, and P6) and freshly isolated cells were studied. Keratinocytes grown on collagen type IV were able to form an epidermis at higher passage numbers than cells grown in the absence of collagen type IV (P4 and P2, respectively). In both cases the reconstructed epidermis showed an increased expression of Ki-67, SKALP, involucrin, and keratin 17 compared to normal skin. Only 50,000 keratinocytes grown on collagen type IV in P4 were needed to form 1 cm2 epidermis, whereas 150,000 of freshly isolated keratinocytes were necessary. Using this culture technique sufficient numbers of keratinocytes, isolated from 1 cm2 skin, were obtained to cover 400 cm2 of wound surface in 2 weeks. The results show that keratinocytes can be cultured without the need of a fibroblast feeder layer and FCS and that these cells are still able to create a fully differentiated epidermis. This culture technique can be a valuable tool for the treatment of burn wounds and further development of tissue engineered skin.

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Collagen cross‐linking by adipose‐derived mesenchymal stromal cells and scar‐derived mesenchymal cells: Are mesenchymal stromal cells involved in scar formation?

Bogaerdt

Veen

Zuijlen

et al. 2009

Wound Repair Regeneration

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In this work, different fibroblast-like (mesenchymal) cell populations that might be involved in wound healing were characterized and their involvement in scar formation was studied by determining collagen synthesis and processing. Depending on the physical and mechanical properties of the tissues, specific collagen cross-linking routes are followed. In skin the cross-linking of the pyridinium type is normally very low; however, in different forms of fibrosis increased levels of this type of cross-linking have been found. The enzyme lysyl hydroxylase-2b (LH-2b) plays a crucial role in this type of cross-linking. The gene expression levels of LH-2b, alpha-smooth muscle actin, and collagen types I and III were determined in dermis, subcutaneous fat, and (hypertrophic) scar tissue as well as in isolated cultured mesenchymal cells derived from these tissues, by real-time RT-polymerase chain reaction. Cultured mesenchymal cells from fat and scar tissue as well as the tissues itself showed significantly higher expression of LH-2b, alpha-SMA, and collagen type I than dermal mesenchymal cells. LH-2b-dependent pyridinium cross-linking was significantly enhanced in fat and scar tissue compared with dermis. FACS analysis was performed to characterize the fibroblast-like cells from the dermis, fat, and scar tissue. All cell populations express the distinct pattern of CD markers also expressed by mesenchymal stromal cells. Furthermore, parts of these cell populations were able to differentiate into adipocytes, chondrocytes, and osteoblasts. We conclude, therefore, that mesenchymal (stem) cells from the subcutaneous fat might be responsible for the accumulation of collagen in these scars.

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Expression profile of proteins involved in scar formation in the healing process of full‐thickness excisional wounds in the porcine model

Ulrich

Verkerk

Reijnen

et al. 2007

Wound Repair Regeneration

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Scar formation in deep dermal wounds is associated with excessive collagen deposition and contraction. Increased collagen synthesis and decreased collagen degradation are the mechanisms through which this form of fibrosis can occur. Another factor might be a different kind of collagen cross-linking seen in fibrotic skin diseases. This type of cross-linking is dependent on the enzyme lysyl hydroxylase-2b. In this study, we examined the expression profile of the potential key players in scar formation in time in healing of acute wounds. Collagen types I and III, lysyl hydroxylase-2b, alpha-smooth muscle actin, transforming growth factor betas, and the matrix metalloproteinases and their inhibitor mRNA levels were determined. All genes examined show distinct expression patterns over time. The expression of lysyl hydroxylase-2b peaks at day 7, and precedes collagen types I and III expression. Eight weeks after wounding, the scars showed an increased level of lysyl hydroxylase-2b-mediated collagen cross-linking. This study shows that the fibrosis-specific type of cross-linking of collagen seen in human hypertrophic scarring also plays a role in this animal model of wound healing. Moreover, the expression of the putative gene responsible for this type of cross-linking, the lysyl hydroxylase-2b, is elevated during wound healing.

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Differential expression of CRABP-II in fibroblasts derived from dermis and subcutaneous fat

Bogaerdt¹,

Ghalbzouri²,

Hensbergen³

et al. 2004

Biochemical and Biophysical Research Communications

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