Autologous Cultured Bone Marrow-Derived Mesenchymal Stem Cells in a Fibrin Spray to Treat Venous Ulcers: A Randomized Controlled Double-Blind Pilot Study.

We treated a small cohort of venous ulcers that were very unresponsive to standard and advanced therapies with autologous cultured bone marrow-derived mesenchymal stem cells (MSCs). This pilot clinical trial was randomized, controlled, and double-blinded. Subjects were treated with either normal saline (Group A), fibrin spray alone (Group B), or MSCs in fibrin (1 million cells/cm2 of wound bed surface) (Group C). The control and test materials were applied to the wound using a double-barreled syringe with thrombin and fibrinogen (with or without MSCs) in each barrel, or saline alone in both barrels. The MSCs were separated, cultured in vitro, and expanded in a dedicated Good Manufacturing Practice (GMP) facility from 30-50 ml of bone marrow aspirate obtained from the iliac crest in Group C subjects. To ensure that the study remained controlled and blinded, subjects who were randomized to one of the two control arms (saline or fibrin) underwent sham bone marrow aspiration performed by a hematologist who anesthetized the iliac crest area down to and pushing against the periosteum, but without penetrating the bone marrow. Therefore, both the clinician who evaluated wound progress and the study subjects had no knowledge of whether bone aspiration was actually performed and what treatment had been applied to the wound. The study was performed after full FDA investigational new drug (IND) approval. The primary endpoint was the rate of healing (wound closure as linear healing from the wound margins in cm/week), as measured by the Gilman equation. One-way ANOVA was used to calculate the statistical significance of differences between the mean healing rates of each of the 3 treatment groups every 4 weeks and over the 24 weeks of treatment. Overall, treatment with MSCs accelerated the healing rate by about 10-fold compared to those in the saline and fibrin control groups. Although the total number of patients in this pilot study was small (n=11), the statistical significance was surprisingly promising: p<0.01 and f-ratio of 15.9358. No serious adverse events were noted. This small but carefully performed prospective, controlled, randomized, and double-blinded pilot study in a rare population of totally unresponsive patients adds to previous reports showing the promise of MSCs in the treatment of chronic wounds and provides proof of principle for how to approach this type of very demanding clinical and translational research.

Dermal Fibroblasts from Chronic Wounds Exhibit Paradoxically Enhanced Proliferative and Migratory Activities that May be Related to the Non-Canonical Wnt Signaling Pathway.

It is generally thought that dermal fibroblasts from chronic wounds are in a state of senescence, which contributes to the failure to heal. This assumption, based on limited experimental evidence, has led to the widespread use of therapeutic approaches focused on delivering new fibroblasts and/or increasing resident fibroblast activity to promote healing. In this study, we decided to re-visit the evidence for the relative inactivity of resident chronic wound fibroblasts. We therefore evaluated the proliferative and migratory activities of matching, patient-derived dermal fibroblasts from a chronic wound (wound dermal fibroblasts, or WDF), ipsilateral thigh newly created acute wound dermal fibroblasts (ADF, Day-3 after wounding the normal thigh skin), and ipsilateral thigh normal dermal skin fibroblasts (NDF). This approach was used in each of 10 consecutive non-selected individual patients with a venous leg ulcer, and allowed us to determine whether WDF are intrinsically less active than NDF and AWD. Cell migration and proliferation were quantified by a live-cell analysis system and MTT assay, respectively, in low (0.5%) or high (10%) levels of fetal bovine serum (FBS). In addition, the ability of patient-derived fibroblasts to modulate wound re-epithelialization in vivo was analyzed by transplantation in a mouse tail full-thickness wound model. Wnt5a mRNA, its ROR1 co-receptors, and ROR2 mRNA levels were determined by qRT-PCR. We report that WDF had increased -SMA and increased levels of Wnt5a. Moreover, using live-cell imaging in a scratch assay monolayer model, WDF showed baseline migratory activity similar to those of NDF and ADF, and such activity was not stimulated by FBS. WDF showed the same capacity to increase wound re-epithelialization as NDF and ADF. Together, these results suggest that WDF are not actually less "active" than NDF and ADF. This enhanced activity of chronic wound fibroblasts may lead to high energy requirements that contribute to a failure to heal. The findings may represent a new paradigm for wound chronicity, impaired healing, and high recurrence rates.

Low-grade elastic compression regimen for venous leg ulcers--an effective compromise for patients requiring daily dressing changes.

Venous leg ulcers (VLUs) affect millions of patients worldwide and are a tremendous financial burden on our health care system. The hallmark of venous disease of the lower extremities is venous hypertension, and compression is the current mainstay of treatment. However, many patients are non-compliant, partly because of the complexity of the dressings and the difficulties with application and removal. The aim of our study was to test an effective compression dressing regimen for patients with VLUs who require changing the ulcer primary dressing twice daily. We used two layers of a latex-free tubular elastic bandage for compression. The primary endpoint of our study was increased wound-healing rate and our secondary endpoint was complete wound closure. All active study subjects had positive healing rates at week 4 and week 8. Two subjects achieved complete wound closure by week 8. We conclude that compression with a latex-free tubular elastic bandage can be safely used in patients with VLUs requiring frequent dressing changes. This type of compression allows for daily inspection of wounds, dressing changes at home, flexibility in the context of clinical trials, and is a compromise for patients who are intolerant to compression dressings.

Wound edge biopsy sites in chronic wounds heal rapidly and do not result in delayed overall healing of the wounds.

Wound biopsies are an essential diagnostic component in the management of chronic wounds. First, the possibility of malignancy or infection in the wound often requires sampling of the wound edge and its bed. Secondly, several practice guidelines recommend biopsying wounds that have not responded to treatment after 2-6 weeks. However, there has always been a concern that the biopsy may worsen the wound and delay overall healing. In this report, we investigated the safety and effects of wound biopsies on overall chronic wound healing rates (advance of the wound edge per week toward the center) before and after the biopsy was performed. In a cohort of 14 consecutive patients with chronic wounds of the lower extremity, we found that postbiopsy chronic wound healing rates (0.99+/-1.18 mm/week; mean+/-SD) were not decreased and were actually higher than prebiopsy chronic wound healing rates (0.49+/-0.85 mm/week; mean+/-SD, p<0.05). In addition, we documented that healing of the biopsy sites up to the original wound edge occurred within 6 weeks in 11 of the 14 subjects. Therefore, we conclude that chronic wounds do not worsen after being biopsied and that wound biopsies are a safe procedure that does not delay overall healing of the chronic wound.

Fibroblasts from non-healing human chronic wounds show decreased expression of beta ig-h3, a TGF-beta inducible protein.

BACKGROUND: Increasing evidence shows persistent phenotypic alterations in fibroblasts from non-healing human chronic wounds, which may result in faulty extracellular matrix deposition and keratinocyte migration. We have previously shown that these cells are characterized by morphological changes, low proliferative potential and unresponsiveness to TGF-beta1, and down regulated phosphorylation of Smad 2/3 and p42/44 MAPK from decreased expression of the TGF-beta type II receptor. OBJECTIVE: To identify genes and proteins that may be differentially expressed in chronic wounds and their cultured fibroblasts. METHODS: Differential display analysis with 120 random primer sets was used in fibroblasts from human venous ulcers and acute wounds created on the ipsilateral thighs of the same patients. Positive differential results were confirmed by RT-PCR. Immunohistochemistry of cultured fibroblasts and tissues was used to determine the expression of differentially expressed proteins. RESULTS: A total of 16 differentially expressed genes were identified and cloned. The only candidate gene that was differentially expressed in all patients and confirmed by repeated differential display testing and RT-PCR was beta ig-h3, a TGF-beta-induced gene involved in cell adhesion, migration, and proliferation. Decreased expression of beta ig-h3 in chronic wounds and their fibroblasts was further confirmed by Western blot and immunostaining. CONCLUSION: These findings point to beta ig-h3 as an important gene characterizing the abnormal phenotype of chronic wound fibroblasts. Corrective measures to increase the expression of this protein might have therapeutic potential.

Migration of the epidermal over the dermal component (epiboly) in a bilayered bioengineered skin construct.

A bilayered bioengineered living skin construct (LSC) consisting of viable human neonatal keratinocytes over a collagenous dermis seeded with dermal fibroblasts has been used extensively in difficult-to heal human wounds. Its biological properties include production of several mediators, cytokines, and growth factors and the ability to heal itself upon injury. In this study, we investigated the process of keratinocyte migration in LSC. At baseline, 6-mm punch biopsies of the construct were placed in serum-free medium (AIM-V) or Dulbecco's modified Eagle medium. At varying time points, the LSC samples were processed and analyzed using histology and immunohistochemistry. By 72 h, in a time-dependent manner, the overlying epidermis had migrated over and enveloped the entire underlying dermis, a process known as epiboly. Increasing concentrations of neutralizing antibodies to epidermal growth factor or interleukin-1 alpha down-regulated the extent of epiboly, as measured using computerized planimetry, but antibodies to transforming growth factor-beta 1 did not affect it. The consistent expression of laminin V, alpha3beta1 integrin, and vitronectin (epibolin) and its integrin receptor (alphavbeta5) characterized the tongue of migrating epidermis. Increasing concentrations of antibodies to vitronectin blocked the process of epiboly, as did antibodies to the alphavbeta5 integrin receptor, which mediates vitronectin-driven keratinocyte locomotion. This process of epiboly provides novel mechanisms of action for bioengineered skin constructs.

Autologous bone marrow-derived cultured mesenchymal stem cells delivered in a fibrin spray accelerate healing in murine and human cutaneous wounds.

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.

An in vitro priming step increases the expression of numerous epidermal growth and migration mediators in a tissue-engineering construct.

An FDA-approved, prototypic, living, bilayered skin construct (BSC) has been used for non-healing wounds. Using this particular construct as proof of principle, we hypothesized that an in vitro 'priming' step may enhance its repertoire of expression of key mediators and genes. The priming step used here was incubation in Dulbecco's modified Eagle's medium (DMEM) for 24 h at 37°C and 5% CO2 , with or without construct meshing. Microarray and ingenuity pathway analysis (IPA) showed that >1000 genes were overexpressed by the priming step, including interleukin 6 (IL-6), which plays important roles in wound healing. Genes highly overexpressed by priming were those involved in epidermal proliferation and migration. Quantitative real-time PCR (qRT-PCR), immunostaining and western blots verified the results. An epiboly assay (epidermal migration over dermis) showed that BSC epiboly was inhibited by IL-6 neutralizing antibody. Back wounds of nude mice were treated with primed or control BSCs for 3 days prior to harvesting; primed BSCs showed a significantly (p = 0.006) greater level of epidermal migration vs unprimed. Our study demonstrates that an in vitro priming step induces wound healing-related genes in the BSC, leading to a construct that could prove more effective in stimulating wound healing. Copyright © 2014 John Wiley & Sons, Ltd.

Serratia marcescens Bullous Cellulitis in a Splenectomized Patient: A Case Report and Review of the Literature.

Serratia marcescens is a Gram-negative bacillus belonging to the Enterobacteriaceae family. Cutaneous infection with Serratia is rare, and usually occurs in immunocompromised individuals. Primary cutaneous infections are uncommon, but they are typically severe and are associated with significant morbidity and mortality. The pathogenetic factors leading to S. marcescens infection are not fully understood, but contributing virulence factors include proteases, secreted exotoxins, and the formation of biofilm. We report a case of cellulitis occurring in a splenectomized patient, which led to multiple wound debridements and a transmetatarsal amputation. This dramatic case led us to review the published literature on soft tissue infections caused by S. marcescens.

Safety and efficacy of a bilayered skin construct in full-thickness surgical wounds.

This was a prospective, randomized, controlled clinical trial assessing the safety and efficacy of a living bilayered skin construct (BSC; Organogenesis, Canton, MA) in treating full-thickness surgical excision wounds. We enrolled 31 patients needing excision of a non-melanoma skin cancer. The patients consisted of 18 females and 13 males, with an average age of 67 years (range: 44 to 84 years). Patients were randomized to either receive a single application of BSC or to heal by secondary intention. Endpoints to assess efficacy included time to complete wound closure, intensity and duration of post-operative pain, cosmetic appearance, patient satisfaction, and quality of the healed wound. Endpoints to assess safety included infection at the wound site and rejection of the BSC. Findings indicate that BSC is safe in the post-operative treatment of acute surgical wounds for removal of non-melanoma skin cancer. The data also suggest that BSC may facilitate management by decreasing post-operative pain. It is unclear whether or not BSC decreases healing time of acute wounds or results in a better cosmetic outcome.

Liver enzymes and lipid levels in patients with lipodermatosclerosis and venous ulcers treated with a prototypic anabolic steroid (stanozolol): a prospective, randomized, double-blinded, placebo-controlled trial.

Anabolic steroids have been used to treat lower extremity ulcerations, including venous and cryofibrinogenemic ulcers and lipodermatosclerosis (LDS). Yet there have been no studies to determine the severity and reversibility of side effects of anabolic steroids on liver enzymes and lipid profiles in elderly patients. We therefore evaluated, in a prospective, randomized, double-blinded, placebo-controlled trial, the extent and reversibility of abnormal liver enzymes and lipid profiles in patients with LDS and venous leg ulcers treated with stanozolol at 2 mg twice daily for up to 6 months. Follow-up laboratory testing was done for 2 months after cessation of treatment. A total of 44 patients with LDS and venous ulcers were enrolled and treated with either leg compression alone (placebo) or leg compression plus oral stanozolol 2 mg twice daily (active). Baseline and follow-up laboratory testing of liver enzymes and lipid profiles were obtained. A total of 21 active and 23 placebo patients were treated and evaluated. We measured liver enzymes (aspartate aminotransferase [AST/SGOT], alanine aminotransferase [ALT/SGPT], γ-glutamyl transferase [GGT]) and lipid profile components (high-density lipoprotein [HDL], low-density lipoprotein [LDL], total cholesterol) before, during, and after the treatment period. We found that AST/SGOT and ALT/SGPT became significantly elevated in 29% (P = .0415 at 2 months) and 33% (P = .0182 at 1 month) of patients treated with stanozolol or placebo, respectively, with return to baseline in the posttreatment period. Unexpectedly, 91% of patients on stanozolol developed a significant (P < .0001) decrease in HDL levels, by as much as 37 U/L. All patients remained asymptomatic and levels returned to baseline after discontinuation of the drug. We conclude that low-dose stanozolol, 2 mg twice daily, produces asymptomatic and temporary elevation of liver transaminases and depression of the HDL level in a significant proportion of patients.

The longevity of a bilayered skin substitute after application to venous ulcers.

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.

Topical delivery of cultured stem cells to human non-healing wounds: GMP facility development in an academic setting and FDA requirements for an IND and human testing.

With increasing emphasis on translational research, the need for appropriate regulatory oversight and approval has become essential. The requirements of the Food and Drug Administration (FDA) for Investigational New Drug (IND) exemption in studies that are investigator-initiated have become increasingly stringent. Moreover, academic institutions have not had substantial experience in establishing Good Manufacturing Practice (GMP) facilities required for manipulating human cells in vitro and for chemical or biochemical manufacturing. GMP regulations are established by the FDA under the authority of the Federal Food, Drug and Cosmetic Act. In this report, the authors outline the general strategy and some critical steps that an investigator and the institution may find helpful in developing a GMP facility, especially in an academic center. Also, more specifically and as proof of principle, we describe our approach to culturing autologous bone marrow-derived human mesenchymal stem cells (MSCs) and delivering them to non healing wounds. The lessons learned in this often lengthy and challenging process may be helpful to other academic institutions and investigators embarking on manipulating and delivering viable cells for human experimentation.

Bone marrow cell mobilization by the systemic use of granulocyte colony-stimulating factor (GCSF) improves wound bed preparation.

Innovative approaches are needed to accelerate the healing of human chronic wounds not responding to conventional therapies. An evolving and promising treatment is the use of stem cells. Our group has previously described the use of expanded (in vitro) autologous stem cells aspirated from human bone marrow and applied topically in a fibrin spray to human acute and chronic wounds. More recently, we have sought ways to mobilize stem cells directly from the bone marrow, without in vitro expansion. In this report, we show that systemic injections of granulocyte colony-stimulating factor (GCSF) can mobilize stem cells from bone marrow into the peripheral blood and then to the wound site. Our objectives were to optimize parameters for this method by using mouse models and proof of principle in a human chronic wound situation. Mice were injected for 5 days with 2 different formulations of GCSF and compared to control saline. To monitor stem cell mobilization, flow cytometric measurements of Sca-1 and c-Kit and colony-forming cell assays were performed. Full-thickness tail wounds in mice were created and monitored for healing, and polyvinyl alcohol sponges were implanted dorsally to assess collagen accumulation. To determine bone marrow stem cell homing to the wound site, chimeric mice transplanted with Green Fluorescent Protein bone marrow cells were scanned by live imaging. Additionally, as proof of principle, we tested the systemic GCSF approach in a patient with a nonhealing venous ulcer. Our findings lay the ground work and indicate that the systemic administration of GCSF is effective in mobilizing bone marrow stem cells into the peripheral blood and to the wound site. These findings are associated with an increased accumulation of collagen and promising results in terms of wound bed preparation and healing.

Differential keratin expression during epiboly in a wound model of bioengineered skin and in human chronic wounds.

Epiboly represents the process by which keratinocytes migrate to envelop a surface. The authors have been investigating a living bilayered skin construct (BSC) that is used in the treatment of lower extremity wounds due to venous insufficiency and diabetes. The construct demonstrates epiboly after injury and incubation in vitro, and this model may be useful for studying epidermal migration and the process of skin maturation. Punch biopsies of the construct in vitro were cultured and immunostained for specific keratins at baseline and at 24 to 72 hours. For comparison, skin biopsy specimens from human chronic venous ulcers and acute healing wounds were similarly processed. The authors found that K1 and K10 were fully expressed in the epidermis of the fully epibolized surface on BSC. K1 was also present in the migrating edge of specimens, whereas K10 was not detectable. K16 and K6 were evident in normal skin and the epibolized area of the construct; K6 expression was very prominent in the migrating edge. Importantly, K17 was distinctly limited to the epibolized surface and the migrating edge, and its expression was very similar to that observed in healing human wounds. In conclusion, differential expression of keratins in this epiboly model closely reflects in vivo studies and supports keratin specificity in the processes of migration and differentiation of new epidermis. Therefore, these findings provide further and important validity for the study of epithelialization and the hope of developing prognostic markers for venous ulcer healing.

Clinical research in dermatology: 10 steps to getting started.

Clinical research plays a very important role in the development of drugs and devices, including those for wound healing. The process of initiating a clinical trial can be rather daunting, particularly with the ever-increasing regulatory hurdles. Many clinicians are generally either not trained or have limited knowledge of these matters. In this short review, the present authors discuss the 10 most important steps required in initiating a clinical trial. This information is applicable not only to wound healing studies, but also to other investigational trials.

Human chronic wounds treated with bioengineered skin: histologic evidence of host-graft interactions.

Bioengineered skin is being used to successfully treat a variety of wounds. Randomized controlled clinical trials have shown that a living bilayered skin construct (BSC), consisting of human neonatal keratinocytes and fibroblasts in a collagen matrix, was able to accelerate complete closure of both venous and diabetic ulcers. BSC was particularly effective in difficult-to-heal wounds of long duration. In patients treated with BSC, no obvious signs of gross clinical rejection were observed. Testing of these treated patients showed no BSC-specific immune response and no immune response to bovine collagen or alloantigens expressed on keratinocytes and fibroblasts. However, very little is known about the histologic changes that occur after BSC has been placed on human wounds. We report our preliminary histologic observations in this uncontrolled study of a cohort of 11 patients with 14 wounds treated with BSC in whom biopsy specimens of the grafted sites were obtained at least 2 weeks after application of the construct. The etiology of these ulcers varied from arterial or venous disease to an extensively and poorly healing burn wound. Histologically, thickening of the grafted bioengineered skin was seen in all samples where residual BSC could be identified. Mucin deposition was noted in the dermal layer of the wounds and BSC in 13 of the 14 specimens examined. Unexpectedly, and in spite of good clinical outcome, 4 of the 14 specimens exhibited a foreign body-like granulomatous response. There was no history of prior exposure to BSC in the 4 patients who had a granulomatous response. These early histologic observations suggest that stimulatory interactions develop between BSC and the wound. The consistently found deposition of mucin may point to a fetal pattern of wound repair associated with the neonatal cells in BSC.

Human beta-defensin-2 expression is increased in chronic wounds.

First identified in psoriatic epidermis and subsequently in other inflammatory cutaneous lesions, human beta-defensin-2 (hbetaD-2) is one of two endogenous antimicrobial peptides related to defensins in plants and animals. Our objective was to determine the expression of hbetaD-2 after injury and in chronic wounds. Biopsies of normal ipsilateral thigh skin and wound edges were taken from nine consecutive patients with venous leg ulcers (day 1) and from the same biopsy sites 2 days later (day 3). Sequential samples were also obtained from intact or meshed bilayered bioengineered skin consisting of neonatal human keratinocytes and dermal fibroblasts in a collagen matrix. Specimens were processed and immunostained for hbetaD-2 using a polyclonal rabbit antibody. In both human tissues and bioengineered skin, staining for hbetaD-2 was confined to the upper epidermal layers, sparing the basal cells. Analysis of 26 tissue samples from patients showed that normal skin had no hbetaD-2 expression but that marked up-regulation occurred after wounding by day 3. Conversely, chronic ulcers showed moderate-to-strong immunostaining for hbetaD-2 at baseline on day 1, with little or no change in intensity after wounding by day 3. In vitro, bioengineered skin showed increased distribution of cytoplasmic hbetaD-2 immunostaining after meshing. We conclude that the expression of hbetaD-2 is up-regulated after injury. Chronic wounds uniformly show a constitutively high baseline expression of hbetaD-2, possibly due to ongoing tissue injury and bacterial colonization.

Full-thickness wounding of the mouse tail as a model for delayed wound healing: accelerated wound closure in Smad3 knock-out mice.

Experimentally induced wounds in animal models are useful in gaining a better understanding of the cellular and molecular processes of wound healing, and in the initial evaluation of the safety and effectiveness of potential therapeutic agents. However, studying delayed healing has proved difficult in animals, whose wounds heal within a few days. In this report, we describe a novel method for establishing mouse wounds that require up to 3 weeks or more for complete closure, and we show the validity of this model in Smad3 null mice, which are known to display accelerated healing. Full-thickness wounds, measuring 0.3 by 1.0 cm, were made down to fascia on the dorsal aspect of the mouse tail in Smad3 knock-out mice and control littermates, approximately 1 cm distal to the body of the animal. The wounds were left to heal by secondary intention and were assessed histologically by computerized planimetry for wound closure at various times after wounding. The wounds in wild-type mice displayed delayed healing, with full closure occurring between 14 and 25 days after wounding. Complete closure of similar wounds in Smad3 null mice healed 30 percent faster (p < 0.01). By immunostaining for ki67, a marker for proliferation, Smad3 null animals also showed increased proliferation of dermal wound cells by day 4 after wounding. Cultured dermal fibroblasts from Smad3 null mice had increased baseline DNA synthesis and, interestingly, an enhanced response to transforming growth factor-beta1. By Western blot analysis, Smad3 null mice fibroblasts showed a compensatory increase in mitogen-activated protein kinase phosphorylation in response to transforming growth factor-beta1, suggesting that mitogen-activated protein kinase overcompensation together with loss of Smad3 may be involved in the modulation of faster healing. We conclude that this novel tail-wounding model may be useful for studying delayed wound closure.

Preliminary study of fine changes in the duration of dynamic cooling during 755-nm laser hair removal on pain and epidermal damage in patients with skin types III-V.

BACKGROUND AND OBJECTIVES: The use of the long-pulsed 755-nm alexandrite laser has been an effective tool in hair removal. A dynamic cooling device (DCD) is commonly used with this laser in order to minimize epidermal damage. No studies have examined how fine changes in DCD duration may affect comfort and epidermal damage during laser hair removal. This study was designed to determine what effect, changes in the duration of dynamic cooling would have on pain and epidermal damage with laser hair removal (755 nm alexandrite) in patients with darker skin types. STUDY DESIGN/MATERIALS AND METHODS: Ten volunteers with Fitzpatrick skin types III-V were enrolled. A 755-nm alexandrite laser with a pulse duration of 3 milliseconds and equipped with a DCD was used with the 12 mm spot size on matched treatment sites. We compared cryogen spurt durations of 0, 20, 40, 60, 80, and 100 milliseconds on pain and epidermal changes. The spray delay was set at 1 millisecond. Pain rating scales and epidermal changes (skin sloughing, hyperpigmentation, hypopigmentation and scarring) were assessed. RESULTS: Overall a decrease in pain was seen with increases in spurt duration. A spurt duration of 20 milliseconds was beneficial for pain reduction in all patients. Longer spurt durations were associated with additional pain relief especially when geographic spacing of pulses was maximized to prevent thermal build-up. In regards to epidermal protection, most patients benefited with shorter cryogen durations of 20-60 milliseconds. There was little advantage with longer spurt durations. Some patients treated at higher fluences without cooling had no detectable side effects. CONCLUSIONS: Increasing DCD spurt duration in laser hair removal provides its strongest benefit in the area of pain reduction, particularly in type V patients. Increasing cryogen spurt durations above a protective threshold shows no significant benefit in terms of epidermal protection. Changing the spurt duration may not be as important in some patients with darker skin types.