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Notes: Systemic ingestion of vanadate, a nonspecific inhibitor of tyrosine phosphatases, doubles wound breaking strength, enhances the packing of collagen fibers, and prevents the appearance of myofibroblasts in granulation tissue. Will the local application of vanadate mimic the systemic effects? Pairs of polyvinyl alcohol sponges, each with a central reservoir and attached injection port, were subcutaneously implanted in rats. Daily, one implant received 0.2 ml of saline and the other received 0.2 ml of 0.03 mM vanadate in saline. On day 7, harvested sponges had equivalent wet weights. The vanadate-treated sponges had fibroblasts separated by connective tissue, with a more intense birefringence of the collagen fibers. Transmission electron microscopy showed collagen more uniformly packed in the vanadate treated sponges where collagen fibers were equally spaced and had equal diameters. By immunohistology, myofibroblasts, defined by the expression of α-smooth muscle actin within stress fibers, were absent in vanadate-treated granulation tissue. The expression of α-smooth muscle actin was restricted to smooth muscle cells of blood vessels. Controls had densely packed α-smooth muscle actin staining myofibroblasts, weak birefringence, and randomly spaced collagen fibers with irregular diameters. We conclude that the local application of vanadate prevents the appearance of myofibroblasts and optimizes the organization of collagen fibers in developing granulation tissue. (WOUND REP REG 2003;11:204–212)

Notes: Excessive contraction of hypertrophic scar and subsequent contracture formation are a formidable problem after thermal injury. A comparison between fibroblasts from hypertrophic scar and normal skin was made with the use of fibroblast-populated collagen lattices as a measure of cellular generated contractile forces. Hypertrophic scar and normal skin fibroblasts were mixed with soluble tendon collagen and Dulbecco's modified Eagle medium supplemented with 10% serum, and contraction was measured by serial area measurements. Parallel experiments in the presence of transforming growth factor-β or anti-transforming growth factor-β antibody examined the role of this cytokine on lattice contraction. Transforming growth factor-β activity was measured in an additional set of 10 biopsy specimens. Hypertrophic scar fibroblasts contract lattices at a significantly faster rate than do normal skin fibroblasts. Exogenous transforming growth factor-β increased lattice contraction by normal skin fibroblasts but had little effect on hypertrophic scar cell-populated lattices. The addition of anti-transforming growth factor-β antibody decreased lattice contraction by both cell types. Transforming growth factor-β activity was significantly increased in the hypertrophic scar biopsy specimens. Excessive scar contraction and post-burn scar contracture result from increased contraction forces generated by hypertrophic scar cells. This increased contractility appears to be mediated by increased endogenous presence of transforming growth factor-β.

Notes: Fetal rabbit wounds that are sutured show excellent repair without obvious scarring. In contrast, an unsutured wound in a rabbit fetus does not close, and it appears that the process of wound contraction does not occur. Experiments were carried out to illustrate the mechanisms responsible for the noncontraction of open fetal rabbit wounds. Results showed that the lack of wound contraction was not an artifact caused by rapid fetal growth. With regard to the ability of cultured fetal fibroblasts to show cytoplasmic muscle-induced cell contraction, we found that, in cultured fetal fibroblasts, cell contraction was induced by adenosine triphosphate. Contractile abilities of fetal-derived fibroblasts were equivalent to those of adult-derived fibroblasts. The fetal fibroblasts also demonstrated the generation of superior contractile activity when examined in a fibroblast-populated collagen lattice model. Finally, the ability of amniotic fluid to alter wound contraction was addressed by means of the fibroblast-populated collagen lattice in vitro model. Increasing concentrations of amniotic fluid inhibited fetal fibroblast lattice contraction. Therefore, rabbit amniotic fluid contains an inhibitor that may be partially responsible for the noncontraction of fetal rabbit wounds in utero.

Notes: In previous wound healing experiments with the use of midgestation murine fetal forelimb explants, wounds were made before or immediately after amputation from the fetus. This experimental technique allows one to ask the question: Do circulatory elements initiate or sustain the repair process in vitro? The hypotheses tested in the current study were that repair occurs in organ culture in the absence of systemic influences and that the in vivo transition from fetal-like to adult-type repair persists in an unperfused in vitro system. Gestational day-14 mouse forelimbs were harvested and placed in serum-free culture medium. Before amputation, control forelimbs received linear full-incision microscalpel wounds that were closed primarily. The animals in the other group were not immediately wounded but cultured for 4 days and then wounded with primary wound closure. All limbs were cultured for 7 days after wounding and then processed for histologic analysis. In the immediately wounded limbs, scarless healing occurred with collagen fibers deposited in a reticular form. In contrast, the delay-wounded limbs had collagen organized in parallel arrays (disordered), constituting repair by scarring. Wound repair proceeded as a local phenomenon in the absence of systemic mediators. We conclude that day-14 gestation forelimbs undergo maturation in culture, causing a transition from scarless to adult scar repair.

Notes: The release of mast cell granules is commonly associated with inflammation and fibrosis. However, does direct communication between mast cells and fibroblasts through gap junction intercellular communication (GJIC) occur? Fibroblast populated collagen lattice (FPCL) cast with mast cells show enhanced lattice contraction. Do released granules or GJIC between mast cells and fibroblasts promote enhanced lattice contraction? Mast cells preloaded with a fluorescent dye that readily passes through gap junctions were cast in FPCL. Dye passed from mast cells into fibroblasts within these cocultured mast cell-FPCLs. Fatty acid amide hydrolase inhibitor blocks the breakdown of oleamide, which is a potent endogenous inhibitor of GJIC. GJIC was blocked for 3 days when mast cells were pulsed for 3 hours with fatty acid amide hydrolase inhibitor. Mast cells pretreated with fatty acid amide hydrolase inhibitor cast in cocultured mast cell-FPCLs failed to enhance cocultured lattice contraction. Mast cell-FPCLs made with mouse fibroblasts unable to generate GJIC failed to show enhanced lattice contraction. Degranulated mast cells were equal to intact mast cells at enhancing cocultured mast cell-FPCL contraction. The supernatant from degranulated mast cells had no effect upon FPCL contraction. Therefore, enhanced mast cell-FPCL contraction appears to be independent of mast cell granules, but dependent upon GJIC between fibroblasts and mast cells. We speculate that mast cell–fibroblast GJIC may play a role in fibrosis.

Notes: The participation of fibroblasts in wound repair is a coordinated effort requiring sequential cellular modulations to behavior including migration (entering), proliferation (increasing cell numbers), synthesis (depositing a collagen matrix), remodeling (organizing collagen), transformation into myofibroblasts, apoptosis, and elimination. Disruptions in that orderly sequence of behaviors will alter repair. Insights into controlling wound repair have focused on soluble factors such as cytokines and growth factors. Here we examine the direct communications between coupled cells through gap junctional intercellular communications. Molecules of less than 1000 MW pass directly between cells through gated gap junction channels. Sugars, amino acids, and oxygen, as well as second messengers such as cAMP, inositol phosphates, and calcium can pass directly between coupled cells. Does gap junctional intercellular communication affect fibroblast phenotype progression in granulation tissue maturation? In rats gap junctional intercellular communication uncouplers heptanol and endosulfan were injected daily into polyvinyl alcohol sponge implants. At 7 days, uncoupler-treated implants had capsules with increased fibroblast density, reduced cell penetration into the sponge, and diminished numbers of myofibroblasts. By polarized light, the uncouplers reduced the deposition and organization of collagen and thereby disrupted the coordinated phenotypic changes seen in fibroblasts during the repair process. It is proposed that gap junctional intercellular communication is critical for fibroblast progression from migratory cell to apoptosis as granulation tissue matures into scar. (WOUND REP REG 2003;11:481–489)

Notes: The role for the metabolism of hyaluronic acid in the repair process is uncertain. Fetal dermal wounds do not heal by scarring and have sustained high levels of hyaluronic acid. In contrast, adult dermis is repaired by scarring and has less hyaluronic acid. Initially after injury, hyaluronic acid is elevated in both adult and fetal wounds, and although it remains elevated in fetal repair, it is rapidly degraded in adult wounds. The chronic addition of hyaluronic acid or hyaluronidase to polyvinyl alcohol sponge implants in adult mice was investigated in this study. Polyvinyl alcohol sponge implants containing a central reservoir were placed subcutaneously in the dorsum of adult male CD-1 mice. Mice were divided into three groups: a phosphate-buffered saline control, a 20 µg hyaluronic acid treatment group, and a 10 U hyaluronidase treatment group. The central reservoir of each sponge implant received appropriate compound every 3 days for 2 weeks via transdermal injection and were then evaluated histologically. At 2 weeks, the cellular density and the quantity of granulation tissue deposition were the greatest in the hyaluronidase group and were lowest in the hyaluronic acid group. In addition, the organization of collagen fiber bundles was the most dense in the hyaluronidase group and least in the hyaluronic acid group. In a second experiment, polyvinyl alcohol sponge implants in mice received either phosphate-buffered saline solution or 20 µg hyaluronic acid every 3 days for 1 week. On day 5, an aliquot of fluorescently tagged native collagen was injected into the sponges. Sponges were harvested at day 7, cryosections made, and the presence of autofluorescent collagen fibers assessed. The autofluorescent collagen fiber bundles in the phosphate-buffered saline solution group were organized in thick parallel bundles, whereas the collagen bundles from hyaluronic acid-treated implants were organized in fine lacelike structures. Chronic addition of hyaluronic acid appears to mimic the fetal dermal connective tissue matrix in which repair proceeds with diminished collagen deposition, organized in finer collagen fiber bundles in granulation tissue. On the other hand, the removal of hyaluronic acid by the chronic administration of hyaluronidase increases the amount of granulation tissue. Elevated levels of hyaluronic acid in granulation tissue appear to modulate the ability of resident fibroblasts to organize collagen fiber bundles.

Notes: There are numerous causes for slow or delayed wound healing. Because slowly healing wounds are often inflamed, we quantitated the inflammatory chemokine, interleukin-8, produced by slowly healing human burn wounds and compared this to interleukin-8 from healed wounds and normal intact skin. Interleukin-8 levels were increased significantly in unhealed wounds (19.7 ng/ml) compared to healed wounds (7.7 ng/ml) or normal skin (5.7 ng/ml). Interleukin-8 in these ranges was added to adult human keratinocytes and fibroblasts. Interleukin-8 significantly decreased keratinocyte replication but had no effect on fibroblast replication. The rate or final degree of fibroblast populated collagen lattice contraction was inhibited at interleukin-8 concentrations between 10 and 30 ng/ml, but not altered at concentrations below 10 ng/ml and above 100 ng/ml. The concurrent application of indomethacin at 10 μg/ml reversed this interleukin-8 induced inhibition. Interleukin-8 inhibited myosin ATPase activity, apparently by reducing the phosphorylation of nonmuscle myosin light chain. We conclude that elevated levels of interleukin-8 may be found during delayed healing, and these elevated interleukin-8 levels may directly contribute to retarded wound closure.

Notes: Chronic abdominal sepsis is associated with impaired tissue repair. Treatment of burn patients with growth hormone results in improved healing of skin graft donor sites. The goal of this study was to determine whether administration of growth hormone could attenuate the inhibitory effects of sepsis on cutaneous wound healing. Four groups of male Sprague Dawley rats were studied: control, control + growth hormone, sepsis, and sepsis + growth hormone. Sepsis was caused by implantation of a bacterial focus in the peritoneal cavity. Control animals underwent sham laparotomy, and polyvinyl alcohol sponge implants were placed in subdermal pockets in all animals. Saline or growth hormone (400 μg) was injected subcutaneously every 12 hours. On day 5, the incisional wounds and polyvinyl alcohol sponge implants were harvested. The breaking strength of abdominal incisions was measured. Granulation tissue penetration and quality were determined by scoring polyvinyl alcohol sponge implant histology from 1 to 4 in a blinded fashion. Collagen deposition in polyvinyl alcohol sponge implants was quantitated by hydroxyproline assay. Septic mortality was not altered by growth hormone administration. Septic animals showed a reduction in food consumption for 2 days after surgery (p 〈 0.05 vs. controls), which was not affected by growth hormone administration. The breaking strength of incisional wounds and hydroxyproline content of polyvinyl alcohol sponge implants was reduced in septic rats (p 〈 0.001 vs. controls) but administration of growth hormone for 5 days did not improve breaking strength or collagen deposition in either group. We conclude that the administration of growth hormone for 5 days did not improve collagen deposition or breaking strength in cutaneous wounds from control or septic animals. The results suggest that growth hormone treatment is unlikely to improve tissue repair in sepsis-induced catabolic illness.