In vivo evaluation of wound bed reaction and graft performance after cold skin graft storage: new targets for skin tissue engineering.

Surplus harvested skin grafts are routinely stored at 4 to 6°C in saline for several days in plastic surgery. The purpose of this study was to evaluate the influence of storage on human skin graft performance in an in vivo intravital microscopic setting after transplantation. Freshly harvested human full-thickness skin grafts and split-thickness skin grafts (STSGs) after storage of 0, 3, or 7 days in moist saline at 4 to 6°C were transplanted into the modified dorsal skinfold chamber, and intravital microscopy was performed to evaluate vessel morphology and angiogenic change of the wound bed. The chamber tissue was harvested 10 days after transplantation for evaluation of tissue integrity and inflammation (hematoxylin and eosin) as well as for immunohistochemistry (human CD31, murine CD31, Ki67, Tdt-mediated dUTP-biotin nick-end labelling). Intravital microscopy results showed no differences in the host angiogenic response between fresh and preserved grafts. However, STSGs and full-thickness skin grafts exhibited a trend toward different timing and strength in capillary widening and capillary bud formation. Preservation had no influence on graft quality before transplantation, but fresh STSGs showed better quality 10 days after transplantation than 7-day preserved grafts. Proliferation and apoptosis as well as host capillary in-growth and graft capillary degeneration were equal in all groups. These results indicate that cells may activate protective mechanisms under cold conditions, allowing them to maintain function and morphology. However, rewarming may disclose underlying tissue damage. These findings could be translated to a new approach for the design of full-thickness skin substitutes.

Practice of split-thickness skin graft storage and histological assessment of tissue quality.

Storage of split-thickness skin grafts (STSGs) represents a standard procedure in burn surgery. The purpose of this study was to evaluate clinical routine of STSG preservation. Further, we aimed at investigating the effect of storage on tissue integrity and cell viability, proliferation, apoptosis and vascularization. A survey was performed among plastic surgery centres in Europe. STSGs were harvested from healthy patients and analysed by histology (HE, Verhoeff's, Masson's Trichrome, Sirius Red) and immunohistochemistry (Ki67, TUNEL, CD31). Cell viability was determined by MTT assay. The survey revealed that storage of STSGs up to 10 days is common practice. STSGs mostly were stored at 4 °C in saline-moisturized gauze. Histology showed no disintegration of the tissue or a decrease of collagen and elastic fibres. Proliferation increased to 22.5% of total cells after 3 days. On day 7 of STSG storage apoptotic cells amounted for 25% of total cells. Cell viability decreased by 50% after day 3 of storage. Even though reportedly superior methods for skin grafts storage exist, most study participants applied the simplest method of storage. Our data underscore this practice. However, a reduced cell viability after 3 days of storage may have an influence on graft healing.

Metalloproteinases facilitate connection of wound bed vessels to pre-existing skin graft vasculature.

BACKGROUND: Despite advances in tissue engineering of human skin, the exact revascularization processes remain unclear. Therefore it was the aim of this study to investigate the vascular transformations during engraftment and to identify associated proteolytic factors. METHODS: The modified dorsal skinfold chamber with autologous skin grafting was prepared in C57BL/6J mice, and intravital microscopy was performed. The expression of proteases and vascular factors was quantified by immunohistochemistry. RESULTS: Reperfusion of the skin graft after 72hours was followed by a temporary angiogenic response of the graft vessels. Wound bed bud formation appeared after 24 to 48hours representing starting points for capillary sprouting. In the reperfused skin graft larger buds developed over several days without transformation into angiogenic sprouts; instead pruning took place. MT1-MMP was detected at sprout tips of in-growing vessels. MMP-2 expression was located at the wound bed/graft connection sites. Pericytes were found to withdraw from the angiogenic vessel in order to facilitate sprouting. CONCLUSIONS: Skin graft vasculature responded with temporary angiogenesis to reperfusion, which was pruned after several days and exhibited a different morphology than regular sprouting angiogenesis present within the wound bed. Furthermore we identified MT1-MMP as sprout-tip located protease indicating its potential role as sprout growth facilitator as well as potentially in lysing the existing graft capillaries in order to connect to them. The differences between the wound bed and skin graft angiogenesis may represent a relevant insight into the processes of vascular pruning and may help in the engineering of skin substitutes.

In vivo visualization of the origination of skin graft vasculature in a wild-type/GFP crossover model.

INTRODUCTION: Skin substitutes are increasingly produced in tissue engineering, but still the understanding of the physiological skin revascularization process is lacking. To study in vivo conditions we recently introduced a mouse model, in which we already characterized the angiogenic changes within the wound bed and the skin graft. The aim of this study was to identify the origination of the vasculature during skin graft revascularization in vivo and to track vessel development over time. METHODS: We created a crossover wild-type/GFP skin transplantation model, in which each animal carried the graft from the other strain. The preparation of the modified dorsal skin fold chamber including cross-over skin grafting was performed in male C57BL/6J wild-type mice (n=5) and C57BL/6-Tg(ACTB-EGFP)1O sb/J mice (n=5). Intravital microscopy in 12 areas of wild-type and GFP skin grafts was performed daily over a time period of 10 days. RESULTS: Graft reperfusion started after 48-72 h. After reperfusion GFP-positive structures from the wound bed were visible in the graft capillaries with the highest density in the center of the graft. Overall, we observed a replacement of existing graft capillaries with vessels from the wound bed in 68% of the vessels. Of note, vessel replacement occurred in almost 100% of graft vessels in the periphery. Additionally, vessels within the graft showed a temporary angiogenic response between days 3-8, which originated predominantly from the autochthonous graft vasculature, but also contained already grown-in vessels from the wound bed. CONCLUSIONS: These in vivo data indicate an early in-growth of angiogenic bed vessels into the existing vascular channels of the graft and subsequent centripetal replacement. Additionally we observed a temporary angiogenic response of the autochthonous capillaries of the skin graft with contribution from bed vessels. These findings further support the theory that sprouting angiogenesis from the wound bed in combination with the replacement of existing graft vessels are the key factors in skin graft taking. Thus, manufacturing of skin substitutes should be aimed at providing pre-formed vascular channels within the construct to improve vascularization.