Effect of supplemental ornithine on wound healing

BACKGROUND: Supplemental arginine has been shown to enhance wound healing, in particular collagen synthesis. Ornithine is the main metabolite of arginine in the urea cycle and shares many of the biopharmacologic effects of arginine. The present study examines the effect of ornithine supplementation on wound healing and attempts to describe its possible mechanism. METHODS: Wild type (WT) and iNOS knockout (KO) mice were randomized to receive either normal chow and tap water or chow and water each supplemented with 0.5% ornithine (w/w). All animals underwent a midline dorsal skin incision with implantation of polyvinyl alcohol sponges into subcutaneous pockets. On postoperative day 14 the animals were sacrificed. The dorsal wound was harvested for breaking strength determination while the wound sponges were assayed for hydroxyproline content, total wound fluid amino acid, and nitrite/nitrate (NOx) concentration. RESULTS: Dietary ornithine supplementation enhanced wound breaking strength and collagen deposition in both WT and KO mice. This was accompanied by increased wound fluid proline and ornithine levels but not arginine, citrulline, or NOx levels. CONCLUSIONS: The results from this study demonstrate that ornithine supplementation enhances wound healing in both WT and KO mice. This suggests that ornithine's effect on wound healing is independent of the iNOS pathway.     

Characterization of incisional wound healing in inducible nitric oxide synthase knockout mice

BACKGROUND: Excisional wound healing in inducible nitric oxide synthase knockout (iNOS-KO) mice has been previously shown to be impaired compared with their background strain controls. Incisional wounds were created in this experiment in both types of animals and paradoxically were found to heal with the same rapidity and breaking strength in both groups. METHODS: Dorsal 2.5 cm incisional wounds were created in iNOS-KO mice, as well as their parental strain controls (C57BL/6J). Standardized polyvinyl alcohol sponges were implanted in the wounds to allow for measurement of collagen deposition. Animals were harvested on postoperative days (PODs) 3, 5, 7, 10, 14, and 28, and their wounds subjected to tensiometric breaking strength analysis. Nonisotopic in situ hybridization quantitative analysis for iNOS, endothelial NOS (eNOS), basic fibroblast growth factor (bFGF), transforming growth factor-beta1 (TGF-beta1), vascular endothelial growth factor (VEGF), and interleukin-4 (IL-4) expression in the wounds was performed. Hydroxyproline levels were quantitated in the harvested polyvinyl alcohol sponges. Data were analyzed with the Students t test. RESULTS: No significant differences were found in breaking strengths or levels of hydroxyproline (and thus collagen) in iNOS-KO versus wild-type wounds at all tested time points. Flawed iNOS expression levels in iNOS-KO animals were similar to (functional) iNOS expression in wild-types. eNOS and bFGF expression nearly doubled on POD 7 in iNOS-KO incisions (P =.002, and.002), respectively and remained 200% to 300% elevated thereafter. TGF-beta1 expression was increased approximately 50% to 100% in iNOS-KO wounds on PODs 5 and 7 (P =.006 and.01, respectively). VEGF and IL-4 expression was elevated by 25% to 100% in wild-type compared with iNOS-KO animals at all time points (P <.01). CONCLUSIONS: The overexpression of TGF-beta1 and eNOS may represent mechanisms in iNOS-KO mice to compensate for their loss of functional iNOS, resulting in incisional wound healing equivalent to controls. Their impaired expression of VEGF and IL-4, on the other hand, may partially explain the delayed excisional wound healing noted in these animals.     

Supplemental L-arginine enhances wound healing in diabetic rats

L-arginine has been shown to enhance wound strength and collagen deposition in rodents and humans. Diabetes mellitus, which impairs wound healing, is accompanied by a reduction in nitric oxide at the wound site. The amino acid L-arginine is the only substrate for nitric oxide synthesis. We sought to determine whether supplemental L-arginine can restore the impaired wound healing of diabetic rats. Fifty-six male Lewis rats were used in this study, of which twenty-nine rats were rendered diabetic 7 days prior to surgery with intraperitoneal streptozotocin. Twenty-seven untreated rats served as controls. Animals underwent a dorsal skin incision with implantation of polyvinyl-alcohol sponges. Sixteen diabetic and 14 normal rats received 1 g/kg/day of L-arginine by injection, while the remainder received saline injections only. Animals were euthanized 10 days postwounding, and their wounds were analyzed for breaking strength. The wound sponges were assayed for total hydroxyproline and nitrite/nitrate content. Plasma and wound fluid concentrations of L-arginine, ornithine, and citrulline were determined. Wound sponge RNA was extracted and subjected to Northern blot analysis for procollagen I and III. Diabetic wounds had greatly decreased breaking strengths compared with controls. L-arginine significantly enhanced wound breaking strengths in both control (+23%) and diabetic animals (+44%), and also increased wound hydroxyproline levels in both diabetic (+40%) and control animals (+24%) as compared to their saline-treated counterparts. mRNA for procollagen I and III were elevated by L-arginine treatment in both diabetic rats and controls. Treatment with L-arginine significantly increased wound fluid nitrite/nitrate levels in diabetic animals. The data show that the impaired healing of diabetic wounds can be partially corrected by L-arginine supplementation, and that this effect is accompanied by enhanced wound nitric oxide synthesis.     

精氨酸促进糖尿病伤口愈合的机制

目的 观察精氨酸促进糖尿病伤口愈合的机制。方法 成年雄性Lewis大鼠，以链脲佐菌素复制糖尿病模型，7d后在大鼠背部制作伤口，置入PVA海绵，每天腹腔注射L-精氨酸1g／kg体重，10d后动物安乐死取样，观察伤口液精氨酸、鸟氨酸、瓜氨酸、NOx、尿素氮及蛋白含量的变化。结果与对照组大鼠比较，糖尿病大鼠伤口液总蛋白、NOx水平显著升高，精氨酸、鸟瓜氨酸、瓜氨酸及尿素氮水平无明显变化。结论 精氨酸促进糖尿病伤口愈合的机制可能与iNOS途径有关，与精氨酸酶途径无关。     

Inhibition of nitric oxide synthesis in wounds: pharmacology and effect on accumulation of collagen in wounds in mice.

OBJECTIVE: To investigate the effect of systemic inhibition of nitric oxide (NO) synthesis in wounds on collagen accumulation. DESIGN: Randomised experimental study. SETTING: Teaching hospital, USA. MATERIAL: 240 Balb/C mice divided into groups of 10 animals each. INTERVENTIONS: Polyvinyl alcohol sponges were inserted subcutaneously through a dorsal skin incision. Beginning on the day of wounding, N omega-nitro-L-arginine-methylester (L-NAME), NG-L-monomethyl-arginine (L-NMMA), aminoguanidine hemisulphate (AGU), and S-methyl isothiouronium (MITU) were given orally or intraperitoneally. The mice were killed 10 days later. MAIN OUTCOME MEASURES: Nitrite and nitrate concentrations, both stable end products of NO, were measured in wound fluid. Sponge hydroxyproline content was assayed as an index of reparative collagen deposition. RESULTS: NOS inhibitors given orally in the drinking water or by daily intraperitoneal injection had no effect on wound nitrite/nitrate concentrations or deposition of collagen in wounds. When given continuously through intraperitoneally-placed osmotic pumps, AGU (500 mg/kg/day) (p < 0.001) and MITU (p < 0.01) significantly reduced wound fluid nitrite/nitrate concentrations in a dose dependent manner. Inhibition of wound nitric oxide synthase by 500 mg AGU/kg/day and 100 mg MITU/kg/day was paralleled by lowered accumulation of collagen in wounds (p < 0.01). CONCLUSION: NO is beneficial in wound healing.     

The role of iNOS in wound healing

BACKGROUND: We have previously shown that the blockade of nitric oxide (NO) synthesis impairs wound healing, in particular collagen synthesis. Conversely, impaired wound healing is accompanied by decreased wound NO synthesis. Fibroblast collagen synthesis, proliferation, and fibroblast-mediated matrix contraction are critical to wound healing. We examined the wound healing-related phenotypic changes that are induced by the loss of inducible nitric oxide synthase (iNOS) gene function in fibroblasts. METHODS: Dermal fibroblasts were obtained from 8- to 12-week-old iNOS--knock out (KO; C57BL/Ai-[KO] Nos2 N5) and wild type mice by an explant technique and used after 1 to 3 passages. Proliferation ([(3)H]-thymidine incorporation) and collagen synthesis ([(3)H]-proline incorporation into collagenase-sensitive protein) were studied after stimulation with 10% fetal bovine serum. Matrix remodeling was assessed by the measurement of the contraction of fibroblast-populated collagen lattices. RESULTS: iNOS-KO fibroblasts proliferated more slowly, synthesized less collagen, and contracted fibroblast-populated collagen lattices more slowly than wild-type fibroblast. Collagen synthesis was restored to normal in KO fibroblasts in response to NO donors (s-nitroso-N-acetylpenicillamine). CONCLUSIONS: iNOS deficiency causes significant impairment in wound healing-related properties of fibroblasts, which suggests that NO plays an important role in wound healing.     

Regulation of nitric oxide synthesis in wounds by IFN-gamma depends on TNF-alpha.

Macrophage-derived nitric oxide is a critical mediator in wound healing. Its regulation in vivo, however, remains unclear. We hypothesized that interferon (IFN)-gamma plays an important role in the regulation of nitric oxide in wounds. Groups of 12 male IFN-gamma -knockout mice and wild-type controls underwent dorsal skin incision and polyvinyl alcohol sponges were inserted subcutaneously. Mice were sacrificed 10 days later to determine wound breaking strength and reparative collagen deposition. Synthesis of nitric oxide (NO), tumor necrosis factor (TNF)-alpha, and IFN-gamma was measured in the wound. Wound-derived macrophages were tested for NO synthesis in the presence or absence of IFN-gamma, TNF-alpha, and anti-TNF-alpha antibody. In a separate experiment, IFN-gamma -knockout mice and wild-type controls were treated with molsidomine, a nitric oxide donor. It was found that wound collagen deposition and wound breaking strength were impaired in IFN-gamma-knockout mice (p < .05). Impaired healing was reflected in diminished synthesis of TNF-alpha and NO in wounds (p < .05). In vivo treatment with molsidomine reversed impaired healing in IFN-gamma-deficient mice. Ex vivo, addition of IFN-gamma stimulated the synthesis of TNF-alpha and NO in wound-derived macrophages. IFN-gamma -induced NO synthesis by wound-derived macrophages was abolished by anti-TNF-alpha-antibody-treatment, which could be fully reversed by exogenous TNF-alpha. Thus we conclude that IFN-gamma-deficiency impairs wound healing and diminishes NO synthesis in wound-derived macrophages. The stimulatory effect of IFN-gamma on macrophage NO production depends on endogenous TNF-alpha synthesis.     

Regulation of Nitric Oxide Synthesis in Wounds by IFN-γ Depends on TNF-α

Macrophage-derived nitric oxide is a critical mediator in wound healing. Its regulation in vivo, however, remains unclear. We hypothesized that interferon (IFN)-γ plays an important role in the regulation of nitric oxide in wounds. Groups of 12 male IFN-γ -knockout mice and wild-type controls underwent dorsal skin incision and polyvinyl alcohol sponges were inserted subcutaneously. Mice were sacrificed 10 days later to determine wound breaking strength and reparative collagen deposition. Synthesis of nitric oxide (NO), tumor necrosis factor (TNF)-α, and IFN-γ was measured in the wound. Wound-derived macrophages were tested for NO synthesis in the presence or absence of IFN-γ, TNF-α, and anti-TNF-α antibody. In a separate experiment, IFN-γ -knockout mice and wild-type controls were treated with molsidomine, a nitric oxide donor. It was found that wound collagen deposition and wound breaking strength were impaired in IFN-γ-knockout mice (p <. 05). Impaired healing was reflected in diminished synthesis of TNF-α and NO in wounds (p <. 05). In vivo treatment with molsidomine reversed impaired healing in IFN-γ-deficient mice. Ex vivo, addition of IFN-γ stimulated the synthesis of TNF-α and NO in wound-derived macrophages. IFN-γ -induced NO synthesis by wound-derived macrophages was abolished by anti-TNF-α-antibody-treatment, which could be fully reversed by exogenous TNF-α. Thus we conclude that IFN-γ-deficiency impairs wound healing and diminishes NO synthesis in wound-derived macrophages. The stimulatory effect of IFN-γ on macrophage NO production depends on endogenous TNF-α synthesis.     

Differential expression of inflammatory mediators in radiation-impaired wound healing

BACKGROUND: Radiation impairs healing, although the underlying mechanisms are not clearly defined. Normal healing requires a fine balance of promoting and inhibiting factors. We hypothesize that there may be a down-regulation of promoting factors (nitric oxide) and, in turn, an up-regulation of healing inhibiting factors (TNF-alpha and IFN-gamma) in the wound after radiation. MATERIAL AND METHODS: Groups of 10 rats were irradiated using single dose 12 or 24 Gy electron radiation at the dorsal skin. Control rats were sham-irradiated. On Day 5 a skin incision in the irradiated area was performed and polyvinyl alcohol sponges were inserted subcutaneously. Rats were sacrificed 10 days later to determine the wound-breaking strength and reparative collagen deposition. Nitrite and nitrate (index of NO synthesis), TNF-alpha, and IFN-gamma were measured within the wound fluid. Expression of the inducible NO-synthase (iNOS) was investigated by immunohistochemistry. Wound-derived fibroblasts were tested in vitro for NO and collagen synthesis. RESULTS: Irradiation significantly reduced wound collagen deposition and wound-breaking strength (P < 0.05). Impaired healing was reflected in diminished wound NO synthesis and iNOS expression (P < 0.01). TNF-alpha and IFN-gamma were increased in irradiated wounds (P < 0.05). Ex vivo, NO synthesis and collagen deposition by fibroblasts from irradiated rats were decreased (P < 0.01). In vitro irradiation of fibroblasts from nonirradiated rats decreased both NO and collagen production (P < 0.01). CONCLUSION: Radiation-impaired healing is reflected in an imbalance of promoting and inhibiting factors, leading to increased levels of TNF-alpha and IFN-gamma and decreased NO expression in the wound.     

Local arginine supplementation results in sustained wound nitric oxide production and reductions in vascular endothelial growth factor expression and granulation tissue formation

OBJECTIVE: The goal of this work was to test the functional role of L-arginine in promotion of nitric oxide (NO) production and the vigorous granulation tissue formation characteristic of this wound model. BACKGROUND: Therapeutic use of supplemental arginine has been proposed as a safe and efficacious method to produce NO from nitric oxide synthase (NOS) and to produce proline and polyamines from arginase to improve wound healing. Although NO appears to be necessary to promote wound healing, the preferential metabolism of arginine to NO via NOS 2 may be detrimental if maintained beyond the initial days of healing. METHODS: A ventral hernia, surgically created in the abdominal wall of 12 swine, was repaired with silicone sheeting and skin closure. Osmotic infusion pumps, inserted in remote subcutaneous pockets, continuously delivered saline (n = 6) or L-arginine (n = 6) into the wound environment. Granulation tissue thickness was determined by ultrasonography. Fluid was aspirated serially from the wound compartment for measurements of nitrite/nitrate (NOx), vascular endothelial growth factor (VEGF), transforming growth factor-beta1 (TGF-beta1), and amino acid concentrations. On day 14, the animals were sacrificed and the abdominal wall was harvested for immunohistochemical and molecular analysis. RESULTS: In animals receiving saline, a nearly linear four-fold increase in granulation tissue thickness was measured during the 14-day interval. In contrast, quantitative ultrasound analysis detected significant reductions in L-arginine infused granulation tissue thickness compared with controls between days 4 and 14 (P < 0.05). Wound vessel count and luminal vascular surface area estimates derived from image analysis of histological sections were two- to three-fold lower in the L-arginine animals compared with controls (P < 0.05). Significant and sustained increases in wound fluid NOx levels were noted in L-arginine animals compared to saline controls (230 microM versus 75 microM at day 14, P < 0.05). Conversely, late VEGF levels (days 11 to 14) were reduced in the L-arginine animals compared to controls (7500 pg/ml versus 10,000 pg/ml at day 11, P < 0.05; 7250 pg/ml versus 11,101 pg/ml at day 14, P < 0.05). Arginine concentrations remained two- to four-fold greater in L-arginine treated animals compared with controls over the entire time course (P < 0.05). There were no significant differences in concentrations of ornithine, citrulline, or proline noted between groups over the 14-day period. Finally, TGF-beta1 levels were unaffected by L-arginine treatment. CONCLUSION: Although NO appears to be necessary for granulation tissue formation, early supplemental arginine may disturb the reciprocal regulation of NOS 2 and arginase, leading to the preferential metabolism of arginine to excess NO rather than ornithine, with consequent reductions in angiogenesis and granulation tissue formation.     

MHC-class-II-deficiency impairs wound healing

BACKGROUND: MHC-class-II-deficient mice lack T helper cell dependent immune reactions. T cell related immune functions are critical for normal wound healing. We hypothesized that MHC-II-deficiency compromises wound repair by affecting the normal wound immune response. MATERIAL AND METHODS: Groups of 10 male MHC-class II-knockout mice and wild-type controls underwent dorsal skin incision. Polyvinyl alcohol sponges were then inserted subcutaneously. The mice were sacrificed 10 days later to determine wound breaking strength and reparative collagen deposition. Activity of T cells and macrophages isolated from the spleens and from the healing wounds was investigated. Fibroblasts derived from the wounds were tested ex vivo for proliferative activity and collagen synthesis. RESULTS: Wound collagen deposition and wound breaking strength were impaired in MHC-class-II-knockout mice (P < 0.05). Impaired healing was reflected in diminished mitogen-reactivity of splenic T-cells (P < 0.01), and decreased CD4 expression in wounds. In addition, basal and LPS + IFN-gamma-induced synthesis of TNF-alpha and nitric oxide by wound-derived macrophages was impaired. Exvivo, fibroblast proliferation and fibroblast collagen production from MHC-II-deficient mice was decreased. CONCLUSION: MHC-II-deficiency compromises wound healing. This may be a reflection of impaired wound immune cell function and decreased activity of wound fibroblasts.     

Nitric oxide enhances experimental wound healing in diabetes

BACKGROUND: Diabetes is characterized by a nitric oxide deficiency at the wound site. This study investigated whether exogenous nitric oxide supplementation with the nitric oxide donor molsidomine (N-ethoxycarbomyl-3-morpholinyl-sidnonimine) could reverse the impaired healing in diabetes. METHODS: Wound healing was studied by creating a dorsal skin incision with subcutaneous polyvinyl alcohol sponge implantation in diabetic and non-diabetic rats. Half of each group was treated with molsidomine. Collagen metabolism was assessed by wound breaking strength, hydroxyproline (OHP) content, RNA expression for collagen type I and III, and matrix metalloproteinase (MMP) 2 activity in wound sponges. Wound fluid, plasma and urinary nitric oxide metabolite levels, and the number of inflammatory cells were assessed. RESULTS: OHP content and wound breaking strength were significantly increased by molsidomine. MMP-2 activity in wound fluid was decreased in diabetes and upregulated by nitric oxide donors. The impaired inflammatory reaction in diabetes was unaffected by nitric oxide donor treatment and ex vivo nitric oxide synthesis was no different between wound macrophages from control and diabetic animals, suggesting that the nitric oxide deficiency in the wound is due to a smaller inflammatory reaction in diabetes. CONCLUSION: The nitric oxide donor molsidomine can at least partially reverse impaired healing associated with diabetes.     

Role of nitric oxide in wound repair

After injury, wound healing is essential for recovery of the integrity of the body. It is a complex, sequential cascade of events. Nitric oxide (NO) is a small radical, formed from the amino acid L-arginine by three distinct isoforms of nitric oxide synthase. The inducible isoform (iNOS) is synthesized in the early phase of wound healing by inflammatory cells, mainly macrophages. However many cells participate in NO synthesis during the proliferative phase after wounding. NO released through iNOS regulates collagen formation, cell proliferation and wound contraction in distinct ways in animal models of wound healing. Although iNOS gene deletion delays, and arginine and NO administration improve healing, the exact mechanisms of action of NO on wound healing parameters are still unknown. The current review summarizes what is known about the role of NO in wound healing and points out path for further research.     

Wound healing in nude mice: a study on the regulatory role of lymphocytes in fibroplasia

In order to understand the role of T cells in postinjury fibroplasia, we have studied wound healing in congenitally athymic nude mice that lack a normally developed T cell system. Healing of incisional wounds, as assessed by wound breaking strength, was significantly stronger in nude mice compared with normal thymus-bearing animals. This was accompanied by a marked increase in the amount of reparative collagen synthesized at the wound site, as assessed by the hydroxyproline content of subcutaneously implanted sponges. Because nude mice have some extrathymic T cell maturation, we used an anti-Thy-1.2 (30H12) monoclonal antibody to selectively deplete T cells in vivo. Although such treatments impaired wound healing in normal mice, they had no effect on any wound healing parameter in nude mice. In a separate experiment, T cell reconstitution of nude mice, sufficient to significantly enhance in vivo delayed hypersensitivity responses, led to a decrease in both wound breaking strength and hydroxyproline deposition in subcutaneously implanted polyvinyl sponges. The data suggest that T cells play a dual role in wound healing: an early stimulatory role on macrophages, endothelial cells, and fibroblasts, and a late counterregulatory role, which may be responsible for the orderly completion of wound repair.     

Supplemental vitamin A prevents the tumor-induced defect in wound healing.

To test our hypothesis that supplemental vitamin A would mitigate the impaired healing that occurs in tumor-bearing animals, six groups of C3H mice, eight per group, eating a standard commercial mouse chow ad libitum that supports normal growth, reproduction, and longevity were innoculated with 200,000 C3HBA cells. When tumors measured approximately 6 mm in diameter, the mice were anesthesized and wounded (dorsal skin incisions and subcutaneous polyvinyl alcohol sponges). Twenty-four hours later, two groups (one continued on the chow and the other started on the chow supplemented with 150,000 IU vitamin A/kg chow) underwent local tumor irradiation; two groups, one ingesting the chow, the other the vitamin A supplemented chow, were started on cyclophosphamide therapy; two groups, one ingesting the chow, the other the vitamin A supplemented chow, received neither local tumor irradiation nor cyclophosphamide therapy. An additional two groups ingesting the chow, one group neither innoculated with tumor nor wounded, the other wounded by not innoculated, served as controls. Wound breaking strength and sponge reparative collagen accumulation (assessed by hydroxyproline proline measurement) were used as indicators of wound healing. The mice were killed 12 days after wounding. Tumor presence decreased wound breaking strength and sponge hydroxyproline content; these effects were largely negated by supplemental vitamin A. Local tumor irradiation diminished the adverse effect of tumor on sponge reparative collagen content but to a lesser extent than the supplemental vitamin A. Supplemental vitamin A added to the irradiation effect on healing but irradiation did not add to the vitamin A effect. Cyclophosphamide, a systemic radiomimetic anti-tumor agent, did not alter the impaired wound healing of the tumor-bearing mice. Supplemental vitamin A mitigated the impaired wound healing in the cyclophosphamide-treated tumor-bearing mice. Supplemental vitamin A also moderated the effects of wounding, tumor, and tumor therapies (local irradiation and cyclophosphamide) on the increase in adrenal size, leukopenia, thrombocytopenia, and thymic involution (except the last was not moderated in the cyclophosphamide-treated tumor-bearing rats). The splenic enlargement in the untreated tumor-bearing wounded rats and in those treated with cyclophosphamide was lessened by supplemental vitamin A. We hypothesize that these anti-stress effects of vitamin A underlie, in part, its action in mitigating the impaired wound healing of tumor-bearing mice, including those treated by local irradiation or cyclophosphamide. These findings have implications for the care of patients with malignant tumors.     

Significance of T-lymphocytes in wound healing

To determine the importance of T-lymphocytes in wound healing, we examined the effect of T-lymphocyte depletion on the healing of surgical wounds. Thirty Balb/c mice were injected intraperitoneally with 1 mg of rat anti-mouse (IgG2b) cytotoxic monoclonal antibody (30H12) against the Thy1.2 (all T) determinant. Twenty-four hours later animals showed a greater than 95% depletion of Thy1.2 cells in peripheral blood and spleen. Thirty control mice received nonspecific rat immunoglobulin (1 mg). Twenty-four hours after treatment mice underwent a 2.5 cm dorsal skin incision with subcutaneous placement of polyvinyl alcohol sponges. Injections were repeated at weekly intervals. Wound healing was assessed at 2, 3, and 4 weeks by the breaking strength of wound strips and by the hydroxyproline content of sponge granulomas (an index of wound reparative collagen deposition). Thy1.2 depletion at death was 95% to 57% in peripheral blood and 86% to 68% in the spleen. Both groups gained weight equally. We found that T cell depletion significantly impairs wound breaking strength and wound collagen deposition at all times studied. The data strongly suggest that T-lymphocytes modulate fibroblast activity during normal wound healing.     

Inhibition of wound repair by thymic hormones

To further define the role of the thymus in wound healing, we studied the effects of two thymic hormones on fibroplasia in normal euthymic and in nude athymic mice. Groups of 10 mice underwent a 2.5 cm dorsal skin incision with subcutaneous placement of polyvinyl alcohol sponges. Starting on the day of wounding, the following daily injections were given: (1) thymopentin (TP5), an active synthetic pentapeptide of thymopoietin, a naturally occurring thymic hormone (1 microgram/day/IM); (2) thymulin or facteur thymique serique (FTS), a naturally occurring circulating thymic hormone (0.2 microgram/day/IM); (3) control saline solution (0.1 ml/day/IM). All mice were killed 4 weeks after wounding, and wound breaking strength and hydroxyproline content of the sponge granulomas were measured. The results show that both thymic hormones impaired wound breaking strength and reparative collagen synthesis in normal and athymic mice. The magnitude of the wound healing impairment induced by the two hormones was equal in the thymus-bearing and in the nude mice. The data support previous findings, which suggested that the thymus has an inhibitory effect on wound healing.     

Biological fate and clinical implications of arginine metabolism in tissue healing

Since its discovery in 1987, many biological roles (including wound healing) have been identified for nitric oxide (NO). The gas is produced by NO synthase using the dibasic amino acid l ‐arginine as a substrate. It has been established that a lack of dietary l ‐arginine delays experimental wound healing. Arginine can also be metabolized to urea and ornithine by arginase‐1, a pathway that generates l‐ proline, a substrate for collagen synthesis, and polyamines, which stimulate cellular proliferation. Herein, we review subjects of interest in arginine metabolism, with emphasis on the biochemistry of wound NO production, relative NO synthase isoform activity in healing wounds, cellular contributions to NO production, and NO effects and mechanisms of action in wound healing.     

Wound healing in Mac‐1 deficient mice

Mac‐1 (CD11b/CD18) is a macrophage receptor that plays several critical roles in macrophage recruitment and activation. Because macrophages are essential for proper wound healing, the impact of Mac‐1 deficiency on wound healing is of significant interest. Prior studies have shown that Mac‐1^?/? mice exhibit deficits in healing, including delayed wound closure in scalp and ear wounds. This study examined whether Mac‐1 deficiency influences wound healing in small excisional and incisional skin wounds. Three millimeter diameter full thickness excisional wounds and incisional wounds were prepared on the dorsal skin of Mac‐1 deficient (Mac‐1^?/?) and wild type (WT) mice, and wound healing outcomes were examined. Mac‐1 deficient mice exhibited a normal rate of wound closure, generally normal levels of total collagen, and nearly normal synthesis and distribution of collagens I and III. In incisional wounds, wound breaking strength was similar for Mac‐1^?/? and WT mice. Wounds of Mac‐1 deficient mice displayed normal total macrophage content, although macrophage phenotype markers were skewed as compared to WT. Interestingly, amounts of TGF‐β1 and its downstream signaling molecules, SMAD2 and SMAD3, were significantly decreased in the wounds of Mac‐1 deficient mice compared to WT. The results suggest that Mac‐1 deficiency has little impact on the healing of small excisional and incisional wounds. Moreover, the findings demonstrate that the effect of single genetic deficiencies on wound healing may markedly differ among wound models. These conclusions have implications for the interpretation of the many prior studies that utilize a single model system to examine wound healing outcomes in genetically deficient mice.