The nonhematopoietic component of bone marrow includes multipotent mesenchymal stem cells (MSC) capable of differentiating into fat, bone, muscle, cartilage, and endothelium. In this report, we describe the cell culture and characterization, delivery system, and successful use of topically applied autologous MSC to accelerate the healing of human and experimental murine wounds. A single bone marrow aspirate of 35-50 mL was obtained from patients with acute wounds (n = 5) from skin cancer surgery and from patients with chronic, long-standing, nonhealing lower extremity wounds (n = 8). Cells were grown in vitro under conditions favoring the propagation of MSC, and flow cytometry and immunostaining showed a profile (CD29+, CD44+, CD105+, CD166+, CD34-, CD45-) highly consistent with published reports of human MSC. Functional induction studies confirmed that the MSC could differentiate into bone, cartilage, and adipose tissue. The cultured autologous MSC were applied up to four times to the wounds using a fibrin polymer spray system with a double-barreled syringe. Both fibrinogen (containing the MSC) and thrombin were diluted to optimally deliver a polymerized gel that immediately adhered to the wound, without run-off, and yet allowing the MSC to remain viable and migrate from the gel. Sequential adjacent sections from biopsy specimens of the wound bed after MSC application showed elongated spindle cells, similar to their in vitro counterparts, which immunostained for MSC markers. Generation of new elastic fibers was evident by both special stains and antibodies to human elastin. The application of cultured cells was safe, without treatment-related adverse events. A strong direct correlation was found between the number of cells applied (greater than 1 x 10(6) cells per cm2 of wound area) and the subsequent decrease in chronic wound size (p = 0.0058). Topical application of autologous MSC also stimulated closure of full-thickness wounds in diabetic mice (db/db). Tracking of green fluorescent protein (GFP)+ MSC in mouse wounds showed GFP+ blood vessels, suggesting that the applied cells may persist as well as act to stimulate the wound repair process. These findings indicate that autologous bone marrow-derived MSC can be safely and effectively delivered to wounds using a fibrin spray system.
A great deal of interest has been focused recently on the potential use of synthetic polypeptide growth factors to stimulate healing of chronic wounds. In this pilot double-blind randomized study conducted at a single center, we used human recombinant epidermal growth factor (h-EGF) to treat 44 patients with venous ulceration of the lower extremities. An aqueous solution (10 micrograms/mL) of h-EGF was applied topically to the ulcers twice a day until healing occurred or for a maximum of 10 weeks. Patients were evaluated weekly for measurements of ulcer size and for the formation of granulation tissue suitable for grafting. Nine patients were excluded from efficacy evaluation because of protocol violations. Therefore, 35 patients (17 h-EGF, 18 placebo) were evaluable for efficacy, and 44 patients (22 h-EGF, 22 placebo) were available for safety. The median baseline ulcer size for all patients was 18.5 cm2, and was not significantly different between h-EGF and placebo group (12.9 cm2 versus 19.2 cm2, respectively, P = .27). By study end, six (35%) of h-EGF treated patients and two (11%) in the placebo group had healed completely (P = .10). Another 6 patients (2 of 17 h-EGF, 4 of 18 placebo; P = .50) developed healthy granulation tissue that was suitable for grafting. The median ulcer size reduction was 7% for h-EGF versus 3% for placebo per week (P = .29), and 73% versus 33% at study end (P = .32). No untoward side effects were related to the application of h-EGF. We conclude that topical application of h-EGF, in the dose and manner used in this study, was safe but failed to significantly enhance re-epithelialization of venous ulcers. However, a greater reduction in ulcer size and a larger number of healed ulcers with the use of h-EGF are encouraging results.
Background: A bilayered skin substitute composed of allogeneic keratinocytes and fibroblasts in a collagen gel has been approved by the US Food and Drug Administration for the treatment of venous and diabetic ulcers. Its mechanism of action has not been fully determined. Objective: To determine the longevity of allogeneic fibroblasts and keratinocytes in a bilayered skin substitute in patients with venous leg ulcers. Methods: Ten patients with venous leg ulcers were treated with a bilayered skin substitute on day 0, days 3 to 5, and weeks 1 through 3. Biopsy specimens of the grafted wound were taken. We used polymerase chain reaction analysis to determine whether allogeneic DNA was present in the biopsy specimens. Results: We detected allogeneic DNA in 2 of 8 specimens at 1 month after initial grafting. Neither of the 2 patients showed persistence of allogeneic DNA at 2 months after initial grafting. Conclusions: Allogeneic cells from a bilayered skin substitute do not appear to survive permanently after grafting for treatment of venous leg ulcers. Other mechanisms of action might include cytokine release, structural support, or provision of a moist wound environment.
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