Long-term regeneration of human epidermis on third degree burns transplanted with autologous cultured epithelium grown on a fibrin matrix

BACKGROUND: Extensive third degree burn wounds can be permanently covered by the transplantation of autologous cultured keratinocytes. Many modifications to Green and colleagues' original technique have been suggested, including the use of a fibrin matrix. However, the properties of the cultured cells must be assessed using suitable criteria before a modified method of culture for therapeutic purposes is transferred to clinical use, because changes in culture conditions may reduce keratinocyte lifespan and result in the loss of the transplanted epithelium. METHODS: To evaluate the performances of human keratinocytes grown on a fibrin matrix, we assay for their colony-forming ability, their growth potential and their ability to generate an epidermis when grafted onto athymic mice. The results of these experiments allowed us to compare side by side the performance for third degree burn treatment of autologous cultured epithelium grafts grown according to Rheinwald and Green on fibrin matrices with that of grafts grown directly on plastic surfaces. RESULTS: We found that human keratinocytes cultured on a fibrin matrix had the same growth capacity and transplantability as those cultured on plastic surfaces and that the presence of a fibrin matrix greatly facilitated the preparation, handling, and surgical transplantation of the grafts, which did not need to be detached enzymatically. The rate of take of grafts grown on fibrin matrices was high, and was similar to that of conventionally cultured grafts. The grafted autologous cells are capable of generating a normal epidermis for many years and favor the regeneration of a superficial dermis. CONCLUSION: We have demonstrated that: 1) fibrin matrices have considerable advantages over plastic for the culture of skin cells for grafting and that it is now possible to generate and transplant enough cultured epithelium from a small skin biopsy to restore completely the epidermis of an adult human in 16 days; and 2) the generated epidermis self-renews itself for years. The use of fibrin matrices thus significantly improves the transplantation of cultured epithelium grafts for extensive burns as recently demonstrated in a follow-up work.     

Upward migration of cultured autologous keratinocytes in Integra artificial skin: a preliminary report.

The combination of cultured autologous keratinocytes with the dermal regeneration template Integra could offer increased possibilities for reconstructive surgery and wound healing. A single-step application of cells, centrifuged deep into an Integra-like matrix at the silicone-matrix junction, has been described but might prove technically complex for clinical use. We have investigated the possibility of simplifying this procedure by applying cultured cells directly to the underside of the Integra or directly to the wound bed immediately prior to grafting. The objective was to see whether cells would migrate through the matrix in an upward direction. We tested the principle of this concept using a pig wound healing model. Integra was seeded directly with cultured cells and grafted onto fresh full-thickness wounds, or unseeded Integra was applied to freshly excised wound beds that had just been seeded with the same number of cells. Biopsies were taken at 3, 7, 11, and 14 days. Histological sections showed that the cells moved through the Integra to give a confluent surface epithelium. Direct seeding onto the Integra was the most efficient method. Transduction of cultured autologous keratinocytes in vitro with a MFGlacZnls retrovirus confirmed that the epidermis was derived from the cultured autologous keratinocytes.     

Transplantation of acellular dermis and keratinocytes cultured on porous biodegradable microcarriers into full-thickness skin injuries on athymic rats

In search of an optimal transplantation regime for sufficient dermal and epidermal regeneration after a full-thickness skin injury, wounds on athymic rats were grafted with split-thickness skin grafts or acellular human dermis followed by transplantation with human keratinocytes either in single-cell suspension or cultured on porous biodegradable microcarriers. After 2 weeks, all wounds grafted with acellular human dermis showed a well organised and vascularised dermal component and reepithelialisation on the grafted dermal matrix was complete 21 days after transplantation with human keratinocytes. Wounds grafted with human keratinocytes seeded on biodegradable microcarriers or split-thickness skin grafts displayed over time (i.e. 16-21 days post-transplantation) a significantly thicker epithelial cell layer in comparison to wounds grafted with keratinocytes in single-cell suspensions or microcarriers not seeded with cells. Furthermore, measurements of dermal thickness in the closed wounds 21 days after grafting showed a significantly thicker and well organised neodermal component in wounds transplanted with keratinocytes seeded on microcarriers or split-thickness skin grafts compared to all other wounds. Positive immunostaining towards von Willebrand factor revealed the plausible proangiogenic effects of transplantation with keratinocytes seeded on microcarriers. Analysis of representative tissue sections after fluorescence in situ hybridisation visualised that grafted human keratinocytes were present in the epidermal layers covering the wounds 16 and 21 days after transplantation, strongly indicating preservation of cell viability. These results shows that the use of biodegradable microcarriers in the culture of autologous keratinocytes for treatment of full-thickness wounds not only facilitate the cultivation, transportation and transplantation processes but also enhances the dermal regeneration induced by a dermal scaffold which results in a clinical result that is significantly superior to the one obtained when keratinocytes are transplanted in a single-cell suspension.     

Upside-down transfer of porcine keratinocytes from a porous, synthetic dressing to experimental full-thickness wounds.

Currently, the use of cultured epithelial autografts as an alternative to split-thickness skin autografts for coverage of full-thickness wounds is limited due to fragility of the sheet and variability in the outcome of healing. This could be circumvented by the transfer of proliferating keratinocytes, instead of differentiated sheets, to the wound bed and the "in vivo" regeneration of epidermis. The aim of this study was to achieve re-epithelialization on experimental full-thickness wounds in the pig using a porous, synthetic carrier seeded with proliferating keratinocytes. Porcine keratinocytes were isolated by enzymatic digestion and cultured in Optimem basal medium with mitogens. In a full-thickness wound model, carriers with different seeding densities were transplanted upside down onto the wound bed. Keratinocytes were labeled using a fluorescent red membrane marker, PKH-26 GL. Transfer of keratinocytes and re-epithelialization were recorded macroscopically and histologically. On day 4 after transplantation, transfer of fluorescently labeled keratinocytes was shown by their presence in the granulation tissue. An immature epidermis, as well as epithelial cords and islands, formed as early as day 8. At day 12 a stratified epidermis and wound closure were established and epithelial cysts were formed by differentiation of epithelial islands. Wounds treated with seeding densities as low as 50,000 cells/cm(2) showed wound closure within 12 days, whereas wounds treated with 10,000 cells/cm(2) or the nonseeded (acellular) carriers did not show complete re-epithelialization before day 17 after treatment. This study showed that porcine keratinocytes, transplanted "upside down" in experimental full-thickness wounds using a synthetic carrier, continued to proliferate and started to differentiate, enabling the formation of a new epidermis in a time frame of 12 days.     

Regeneration of neomucosa using cell-seeded collagen-GAG matrices in athymic mice

Tissue engineering of oral mucosa could allow improved reconstructive options for intraoral tissue defects. Porous collagen-glycosaminoglycan (CG) matrices coated with a silicone elastomer were seeded by centrifugation with cultured human oral mucosal epithelial cells (strain OKG4 gingival keratinocytes) at a density of 250,000 cells per square centimeter. Full-thickness dorsal wounds (1.5 x 1.5 cm) were created surgically on each athymic mouse and were treated with either a seeded matrix or an unseeded matrix, or they were left open as a control. The CG matrices reduced the degree of wound contraction at day 14 compared with open wounds. The epithelial thickness of seeded matrices at day 14 was significantly greater (p = 0.0001) than that of unseeded matrices. Seeded matrices had more rapid degradation at 14 days compared with unseeded matrices. Human oral mucosal cells seeded into CG matrices contribute to form a stratified and differentiated epithelial layer during revascularization, cellular infiltration, and degradation of the CG matrix.     

The co-application of sprayed cultured autologous keratinocytes and autologous fibrin sealant in a porcine wound model.

We have explored the potential for cultured autologous keratinocytes to form an epidermis when delivered as a spray intermixed with autologous fibrin sealant. Twelve full-thickness wounds in Large White pigs (six wounds in each of two pigs) were isolated from the surrounding skin by 4 cm diameter polytetrafluoroethylene chambers, and grafted with Integra artificial skin (Ethicon). Autologous fibrin sealant was produced 10 days later, using an automated processor unit (Vivostat System, ConvaTec, Bristol Myers Squibb), from 120 ml of autologous citrated blood taken 30 min before keratinocyte application. Nine wounds were sprayed, using a Vivostat System automated applicator unit, with a mixture of the sealant preparation and freshly trypsinised cultured autologous keratinocytes in growth medium, at a density of 1-3 x 10(5) cm(-2). Three control wounds were sprayed with the same mixture without cells. The sealant-cell mixture polymerised and adhered to the wound surface immediately. Histological analysis of biopsies taken following sealant-cell application showed that isolated spherical keratinocytes were distributed throughout the sealant at between 3.1 x 10(4) cm(-2) and 7.6 x 10(4) cm(-2). After 4 days discreet colonies of keratinocytes were observed on the wound bed. At 14 days a multi-layered undulating epidermis was formed, punctuated by sporadic epidermal cysts; the mean area of epithelium was 50.1% (s.d. = 19.7%, n = 9). There was no epithelium in the controls (s.d. = 0, n = 3). The difference was statistically significant (P=0.016). This study suggests that co-sprayed cultured keratinocytes and autologous fibrin sealant may be an effective means of delivering epithelial cells to assist wound healing.     

Fibroblasts improve performance of cultured composite skin substitutes on athymic mice

BACKGROUND: This study investigated the impact of adding human fibroblasts to a cultured composite skin substitute model of cultured human keratinocytes and acellular human dermis. METHODS: Skin substitutes were prepared by seeding human keratinocytes on the papillary side of acellular dermis with or without seeding fibroblasts on the reticular side. Performance of the grafts was compared both in vitro by histology and in vivo on surgically created full-thickness wounds on athymic mice. Graft size and contraction were measured and immunohistochemical stains were done to reveal vascularization. RESULTS: Skin substitutes with fibroblasts formed thicker epidermis than skin substitutes without fibroblasts. When transplanted onto athymic mice, skin substitutes with fibroblasts maintained their original size with only 2% contraction. In contrast, skin substitutes without fibroblasts showed 29% contraction. Vascular basement membrane specific mouse CD31staining and endothelial cell specific mouse collagen type IV staining revealed vascularization as early as 1 week posttransplant in grafts with fibroblasts, and was significantly higher than grafts without fibroblasts at 2 weeks. CONCLUSIONS: Addition of fibroblasts to keratinocyte based composite skin substitutes improves epidermis formation, enhances vascularization and reduces contraction.     

Employing human keratinocytes cultured on macroporous gelatin spheres to treat full thickness-wounds: an in vivo study on athymic rats

Providing cutaneous wounds with sufficient epidermis to prevent infections and fluid loss is one of the most challenging tasks associated with surgical treatment of burns. Recently, application of cultured keratinocytes in this context has allowed this challenge to be met without several of the limitations connected with the use of split-thickness skin grafts. The continuous development of this novel approach has now revealed that transplantation of cultured autologous keratinocytes as single-cell suspensions exhibits several advantages over the use of cultured epidermal grafts. However, a number of methodological problems remain to be solved, primarily with regards to the complexity of culturing these cells; loss of viability and other negative effects during their preparation and transportation; the relatively long period of time required following transplantation to obtain a sufficiently protective epidermis. In the present investigation we attempted to eliminate these limitations by culturing the keratinocytes on macroporous gelatin spheres. Accordingly, the efficacies of normal human keratinocytes in single-cell suspension or growing on macroporous gelatin spheres, as well as of split-thickness skin grafts in healing wounds on athymic rats were compared. Human keratinocytes were found to adhere and proliferate efficiently both on the surface and within the pores of such spheres. Transplantation of such cells adherent to the spheres resulted in significantly more rapid formation of a stratified epidermis than did transplantation of single-cell suspensions or spheres alone. Twenty-three days after transplantation, the epidermis formed from the cells bound to the spheres was not as thick as the epidermis on wounds covered with split-thickness skin grafts, but significantly thicker than on wounds to which single-cell suspensions, spheres alone or no transplant at all was applied. Furthermore, fluorescence in situ hybridisation revealed that the transplanted keratinocytes, both those adherent to gelatin spheres and those in single-cell suspension, were components of the newly formed epidermis. These findings indicate that application of biodegradable macroporous spheres may prove to be of considerable value in designing cell-based therapies for the treatment of acute and persistent wounds.     

Composite skin graft: frozen dermal allografts support the engraftment and expansion of autologous epidermis

Rapid closure of burn wounds significantly reduces the complications associated with thermal injury. Successful wound coverage, however, is often limited by the lack of suitable autografts. To circumvent this limitation a composite graft was developed which combines the utility and availability of allogeneic skin with the permanence of an autograft. Composite grafts were first employed in a rat wound model and subsequently to treat six patients with thermal injuries. In experiments with rats, full-thickness excised (1") wounds were prepared on thoracic walls, covered with previously frozen allograft skin, dressed, and secured. Five days later, the dead epidermis was removed and trypsin-disaggregated syngeneic epidermal cells applied to the exposed dermal surface. Successful engraftment with complete epidermal coverage could be observed within 7 to 10 days. In eight patients, split-thickness skin bank allografts were placed on full-thickness burn wounds. Four days later the dead epidermis was removed and vacuum blister-prepared sheets of autologous epidermis grafted to the exposed dermal surface. In all eight patients successful engraftment ensued. Increased pigmentation at the site of each original epidermal graft confirmed the stability of underlying allograft dermis. Epidermal expansion ranged from 1:20 to 1:100. All patients were followed from 10 to 12 months with no demonstrated graft loss or significant wound contracture. Composite skin grafts which combine allogeneic dermis and an expanded autologous epidermis can effect rapid wound closure and will remain stable without evidence of rejection or graft breakdown for at least 12 months.     

Development and evaluation of a new composite Laserskin graft

BACKGROUND: Tremendous effort has been made to improve the graft take rate of cultured epidermal autograph. The purpose of this study is to develop and evaluate a new composite Laserskin graft (CLSG) as a human skin substitute for wound resurfacing. METHODS: The seeding efficacy of cultured keratinocytes on plain Laserskin was compared with the 3T3 cell-seeded Laserskin and allogenic fibroblast-populated Laserskin. Three different types of CLSG, 2 cm in diameter each, were prepared and tested in rats. Type A CLSG consisted of proliferative allogenic rat fibroblasts on both sides of the Laserskin with autologous keratinocytes also on the upper side. Fibroblasts and keratinocytes were seeded only on the upper side of the Laserskin in type B CLSG. Keratinocytes alone were seeded on plain Laserskin in type C CLSG. Type B CLSG consisting of autologous keratinocytes and autologous dermal fibroblasts was tested on five selected wounds (5x5 cm each) of a patient with full-thickness burn. In another burn patient, type B CLSG consisting of autologous keratinocytes and allogenic dermal fibroblasts was grafted onto three wounds (5x5 cm each). RESULTS: The seeding efficacy of human keratinocytes on plain Laserskin increased from 75% to 95% when proliferative allogenic fibroblasts were grown as a feeder layer on the Laserskin. The seeding efficacy of rat keratinocytes increased from 36% to 88% in the presence of a proliferative allogenic fibroblast feeder layer, whereas human/rat keratinocytes had respective seeding efficacy of 98%/91% on Laserskin preseeded with mitomycin C-treated 3T3 cells. Skin biopsies of grafted type A CLSG on day 14 after grafting showed complete epithelialization without severe inflammation in 16 of 20 (80%) grafted surgical wounds in rats. There were eight (40%) and seven (35%) "takes" of the CLSG in types B and C, respectively. The infection rate in type B CLSG was two (10%). There was one (5%) infection in types A and C. The respective take rates on the two patients grafted with type B CLSG were 60% and 100%. CONCLUSION: The animal experiment and the preliminary clinical data showed that the CSLGs consisting of autologous keratinocytes and of autologous/allogenic fibroblasts are good human skin substitutes in terms of durability, biocompatibility, high seeding efficacy for keratinocytes, high graft take rate, and low infection rate.     

New grafts for old? A review of alternatives to autologous skin.

Immediate resurfacing of skin defects is a challenging prospect, especially in patients with extensive full-thickness burns. Currently, split-thickness autografts offer the best form of wound coverage, but limited donor sites and their associated morbidity have prompted the search for alternatives. The application of allogeneic skin is restricted by availability and the risk of transmission of infection, whilst synthetic skin substitutes are simply expensive dressings. The problems of limited expansion may be overcome by culturing keratinocytes in vitro. Unlike autologous cells, allogeneic keratinocytes are available immediately, although they survive for less than a week when applied to full-thickness skin defects. Moreover, the absence of a dermal component in these grafts predisposes to instability and contracture. A cross-linked collagen and glycosaminoglycan dermal substitute, covered with thin split-skin grafts or cultured autologous keratinocytes, shows promise in burns patients. An alternative is a collagen matrix populated by allogeneic fibroblasts and overlaid with cultured autologous or allogeneic keratinocytes. The clinical application of cultured grafts remains imperfect but offers the prospect of immediate coverage and massive expansion.     

Culture of keratinocytes for transplantation without the need of feeder layer cells

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.     

Cultured human keratinocytes as a single cell suspension in fibrin glue combined with preserved dermal grafts enhance skin reconstitution in athymic mice full-thickness wounds

Cultured human keratinocytes as a single cell suspension in fibrin glue combined with preserved dermal grafts enhance skin reconstitution in athymic mice full-thickness wounds. The technique of transplanting cultured human keratinocytes suspended as single cells in a fibrin-glue matrix (KFGS) has been recently developed to overcome common disadvantages of standard cultured epidermal sheet grafts. The combination of this method with glycerolized (nonvital) xenograft overlays in standardized nude mice full-thickness wounds, as compared to KFGS alone or controls with no grafts, showed enhancement of epithelial regeneration in terms of epithelial thickness and diminished wound contraction during the 6-week follow-up. Total scar thickness was increased after the combined KFGS/xenograft technique. The time taken to complete wound reepithelialization was similar in the two groups. Reconstitution of the dermo-epidermal junction zone as shown by electron microscopy and immunohistochemistry was enhanced by the KFGS+xenograft technique, showing structures resembling rete ridges 6 weeks postoperatively. The combined KFGS/xenograft technique is able to transfer proliferative single keratinocytes. The method simplifies the application when compared to conventional epithelial sheet grafting and reduces wound contraction when compared to pure keratinocyte grafting. Received: 15 October 1998 / / Accepted: 10 March 1999     

Autologous keratinocytes cultured on benzylester hyaluronic acid membranes in the treatment of chronic full-thickness ulcers

Keratinocytes were obtained from three patients with chronic full-thickness ulcers of different aetiologies. The cells were isolated, cultured and then seeded on to a membrane composed of benzylester hyaluronic acid. Once the keratinocytes had become subconfluent, the keratinocyte-containing matrix sheets were then applied as autologous grafts to the patients' ulcers. Results indicate that autologous grafting of keratinocytes cultured on benzylester hyaluronic acid membranes provides improved graft handling, reduces total time required for tissue cultivation and enhances cellular vitality because of the possibility of grafting at a subconfluent non-differentiated stage.     

Cultured keratinocytes in fibrin with decellularised dermis close porcine full-thickness wounds in a single step

The purpose of this study was to assess the feasibility of combined keratinocyte and dermal scaffold transplantation performed in a single step for treatment of full-thickness wounds. Cultured autologous keratinocytes were suspended in fibrin and grafted together with decellularised human dermis (Alloderm) in a porcine animal model, involving 10 animals over 4 weeks. Wound healing was evaluated by planimetry. Histology included morphological analysis as well as immunohistochemistry at regular intervals (1, 2 and 4 weeks). The results showed both successful histo-integration of the in vivo composite grafts and reduced wound contraction, compared with the control group (plain epithelial grafts). Histologically a neo-epithelium originated from the grafted cells on top of the decellularised dermis, as well as a reconstituted basement membrane. After 4 weeks cellular ingrowth into the dermal matrix could be observed. The successful combination of a keratinocyte-fibrin suspension and acellular dermis applied in a single step onto full-thickness wounds resulted in closure.     

Dermal fibroblasts do not enhance the graft take rate of autologous, cultured keratinocyte suspension on full-thickness wounds in rats

Dermal fibroblasts are known to play an important role in wound healing. In this study, cultured autologous keratinocyte suspension was applied with fibrin glue to the full-thickness wounds in rats (N = 20). Histological analysis on day 14 showed regenerated epithelium in 10 wounds (50%). Keratinocytes were also premixed with allogeneic dermal fibroblasts in a ratio of 3:1 and 5:1 before application to other full-thickness wounds (N = 20) with fibrin glue. Regeneration of epithelium was observed in 10 (50%) and 9 (45%) wounds respectively. Acute inflammatory reaction and mild to moderate proliferation of fibroblasts in the subepithelial layer of the allogeneic fibroblasts were noted. The addition of dermal fibroblasts to keratinocytes/fibrin glue does not enhance the take rate of the cultured keratinocyte suspension.     

Evaluation of a biodegradable matrix containing cultured human fibroblasts as a dermal replacement beneath meshed skin grafts on athymic mice.

Meshed, expanded split-thickness skin grafts (MSTSG) frequently achieve poor results when used to cover full-thickness wounds. Poor cosmetic and functional results occur in part because the epithelium that grows across the skin graft interstices lacks a dermis. We used a living dermal replacement composed of either polyglycolic acid (PGA) or polyglactin-910 (PGL) mesh containing confluent, cultured human fibroblasts. These grafts were applied to full-thickness wounds on athymic mice; widely expanded, 3:1 ratio human MSTSG was then placed over the dermal graft. Histologic examination of wounds during a 99-day period after graft placement showed that PGA/PGL-fibroblast grafts vascularized to the wound, and the MSTSG simultaneously vascularized to the PGA/PGL-fibroblast graft. Epithelialization from the MSTSG bridges proceeded rapidly across the surface of the PGA/PGL-fibroblast grafts, resulting in an epithelialized layer that covered a densely cellular substratum that resembled dermis. Basement membrane formation at the dermal-epidermal junction of the epithelialized interstices was confirmed by immunohistochemical microscopy. Minimal inflammatory reaction to the PGA/PGL-fibroblast grafts was seen. Grafts composed of PGA or PGL biodegradable meshes combined with cultured fibroblasts vascularize in full-thickness wounds, resulting in formation of organized tissue beneath the epithelialized surface that resembles dermis.     

Genetic modification of cultured skin substitutes by transduction of human keratinocytes and fibroblasts with platelet-derived growth factor-A

Gene therapy promises the potential for improved treatment of cutaneous wounds. This study evaluated whether genetically modified cultured skin substitutes can act as vehicles for gene therapy in an athymic mouse model of wound healing. Human keratinocytes and fibroblasts were genetically engineered by retroviral transduction to overexpress human platelet-derived growth factor-A chain. Three types of skin substitutes were prepared from collagen-glycosaminoglycan substrates populated with fibroblasts and keratinocytes: HF-/HK-, containing both unmodified fibroblasts and keratinocytes; HF-/HK+, containing unmodified fibroblasts and modified keratinocytes; and HF+/HK-, containing modified fibroblasts and unmodified keratinocytes. Skin substitutes were cultured for two weeks before grafting to full-thickness wounds on athymic mice. The modified skin substitutes secreted significantly elevated levels of platelet-derived growth factor throughout the culture period. Expression of retroviral platelet-derived growth factor-A mRNA was maintained after grafting to mice, and was detected in all HF-/HK+ grafts and one HF+/HK- graft at two weeks after surgery. Although no differences were seen between control and modified grafts, the results suggest that genetically modified cultured skin substitutes can be a feasible mechanism for cutaneous gene therapy. The cultured skin model used for these studies has advantages over other skin analogs containing only epidermal cells; because it contains both fibroblasts and keratinocytes, it therefore offers greater opportunities for genetic modification and potential modulation of wound healing.     

Microvascular endothelial cell seeding of small-diameter Dacron vascular grafts

One obstacle to the clinical implementation of endothelial cell seeding of vascular prostheses is the difficulty in derivation of large numbers of autologous endothelial cells from blood vessels of patients requiring vascular grafting. Capillary endothelial cells obtained from fat have been suggested as an abundant alternative to large-vessel endothelium for graft seeding. The object of this study was to evaluate the performance of 4-mm internal diameter (ID) Dacron Microvel grafts seeded with omentally derived microvascular endothelial cells. Six-cm lengths of the test grafts were implanted bilaterally into canine carotid arteries. One of each pair of grafts was seeded with endothelial cells (means = 8.4 x 10(6)) derived from collagenase digestion of autologous omental fat samples. The contralateral graft of each pair was nonseeded. At 5 weeks postoperatively, the grafts were harvested and evaluated. The mean patencies of both the seeded and nonseeded grafts were 89 percent. The mean thrombus-free surface area for seeded grafts was 95 +/- 11 percent. This value was significantly different statistically from the mean thrombus-free surface area of nonseeded grafts, which was 43 +/- 19 percent (P less than .05). Histologically, midgraft regions of seeded grafts were cellular, stained positive for collagen, and were characterized by inner capsules ranging in thickness between 35-94 microns. Luminal cells were identified as endothelial by peroxidase antiperoxidase staining techniques. Midgraft regions of nonseeded grafts demonstrated thrombus accumulation, limited cellularity, and inner capsules between 59-194 microns thick. Scanning electron microscopy of seeded grafts revealed smooth luminal surfaces with tight junctions between adjacent cells; surface cells were not present on midgraft regions of nonseeded grafts. In conclusion, endothelial cells derived from omental fat successfully surfaced on Dacron grafts and imparted characteristics to the graft that would predict long-term graft success.     

Use of a composite skin graft composed of cultured human keratinocytes and fibroblasts and a collagen-GAG matrix to cover full-thickness wounds on athymic mice

In patients with extensive full-thickness burns, wound coverage may be accelerated if skin can be expanded to produce a skin replacement that reproducibly supplies blood to the wound and has good structural qualities. In addition, development of skin replacements may benefit patients who require reconstruction or replacement of large areas of abnormal skin. We have developed a composite skin replacement composed of cultured human keratinocytes (HK) and fibroblasts. Cultured human fibroblasts are seeded into the interstices, and cultured HKs are applied to the surface of a matrix composed of type I collagen crosslinked with a glycosaminoglycan, which has a defined physical structure. After HKs reach confluence on the matrix surface, the composite grafts are placed on full-thickness wounds on the dorsum of athymic mice. Graft acceptance, confirmed by positive staining with antibodies specific for human HLA-ABC antigens on HKs, is approximately 90%. A defined skin structure is present histologically by day 10 after grafting, with a differentiated epithelium and a subepidermal layer densely populated by fibroblasts and capillaries without evidence of inflammation. Fluorescent light microscopy to identify laminin and type IV collagen and electron microscopy confirm the presence of basement membrane components by 10 days after grafting. Attachment of the graft to the wound is similar with and without the addition of human basic fibroblast growth factor, a potent angiogenic agent, to the skin replacement before graft placement on wounds.