Epidermal lipid metabolism of cultured skin substitutes during healing of full-thickness wounds in athymic mice

Cultured epidermal keratinocytes provide an abundant supply of biologic material for wound treatment. Because restoration of barrier function is a definitive criterion for efficacy of wound closure and depends on the lipids present in the epidermis, we analyzed lipid composition of the epidermis in cultured skin substitutes in vitro and after grafting to athymic mice. The cultured skin substitutes were prepared from human keratinocytes and fibroblasts attached to collagen-glycosaminoglycan substrates. After 14 days of incubation, cultured skin substitutes were grafted orthotopically onto full-thickness wounds in athymic mice. Samples for lipid analysis were collected after 14 and 34 days of in vitro incubation, and 3 weeks and 4 months after grafting. Both in vitro samples show disproportions in epidermal lipid profile as compared with the native human epidermis, i.e., a low amount of phospholipids (indicating imbalance in proliferation and differentiation); a large excess of triglycerides (storage lipids); and low levels of free fatty acids, gluco-sphingolipids, cholesterol sulfate, and ceramides-suggesting abnormal composition of stratum corneum barrier lipids. Fatty acid analysis of cultured skin substitutes in vitro revealed insufficient uptake of linoleic acid, which resulted in increased synthesis of and substitution with monounsaturated fatty acids, mainly oleic acid. These abnormalities were partially corrected by 3 weeks after grafting; and 4 months after grafting, all epidermal lipids, with some minor exceptions, were synthesized in proportions very similar to human epidermis. Results of this study show that grafting of cultured skin substitutes to a physiologic host permits the recovery of lipid in proportion to that required for barrier formation in normal human epidermis.     

Skin wound closure in athymic mice with cultured human cells, biopolymers, and growth factors

Skin wound closure remains a major problem in acute and reconstructive skin grafting after large burns because of limited availability of donor skin. This report evaluates six protocols for preparation in vitro of skin substitutes composed of cultured human cells, biopolymers, and growth factors for wound closure. Full-thickness wounds in athymic mice treated in a single procedure with cultured skin substitutes were compared directly to treatments with murine skin autograft, human skin xenograft, or no graft. Rectilinear planimetry of healed wounds 6 weeks after surgery showed that skin substitutes cultured in serum-free medium, and for 24 hours before surgery in defined medium with basic fibroblast growth factor (100 ng/ml), were not statistically different (p less than 0.05) in size from treatment with human skin xenograft. Acceptance and persistence of skin substitutes cultured in serum-free media were 70% at 6 weeks after surgery, as determined by staining of healed skin with a fluorescein-labeled monoclonal antibody against human HLA-ABC antigens. Ultrastructural examination of wounds with cultured human skin 6 weeks after treatment showed complete basement membrane, including anchoring fibrils, presence of melanocytes and pigment transfer to keratinocytes, and innervation of healed skin adjacent to basement membrane. These findings demonstrate effectiveness of cultured skin substitutes for closure of skin wounds and illustrate important capabilities to modulate the natural processes of wound repair, to increase supply of materials used for wound repair, and to enhance quality of wound healing.     

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.     

Keratin expression in cultured skin substitutes suggests that the hyperproliferative phenotype observed in vitro is normalized after grafting

Cultured skin substitutes, consisting of fibroblasts and keratinocytes in a biopolymer matrix, are an adjunctive treatment for full thickness burn wounds. Previous studies revealed that cultured skin substitutes in vitro exhibit a gene expression profile similar to hyperproliferative skin or wounded normal skin. In the present study, we sought to determine whether this hyperproliferative phenotype is maintained after healing of grafted cultured skin in vivo. Immunohistochemistry was used to localize multiple keratin proteins in native human skin, and in cultured skin substitutes in vitro and after grafting to athymic mice. Keratin 6, keratin 16, and keratin 17, which are known to be upregulated during keratinocyte activation and in hyperproliferative epidermis, were highly expressed in cultured skin substitutes in vitro. These proteins were low or undetectable in native human skin, and were reduced in cultured skin after grafting. Conversely, keratin 15, which is downregulated in activated keratinocytes, was not detected in cultured skin substitutes in vitro but was upregulated after grafting to mice. The results confirm previous observations suggesting a hyperproliferative or activated phenotype in cultured skin substitutes in vitro, similar to wounded native skin. After grafting to athymic mice, the expression patterns suggest a normalization of cultured skin substitutes to a phenotype more closely resembling uninjured human skin.     

Combined use of a collagen-based dermal substitute and a fibrin-based cultured epithelium: a step toward a total skin replacement for acute wounds

Integra, a dermal replacement, is used as an immediate and temporary coverage for acute wounds, after which, autograft is used to reconstitute permanently the epidermal coverage. The fibrin sheet-cultured epithelium autograft (FS-CEA) could provide an effective alternative to the surgical procedure. To evaluate this hypothesis, we compared the association of Integra/FS-CE to Integra/control-cultured epithelium (control-CE). Their respective abilities: (1) to produce dermal-epidermal construct in vitro; (2) to generate skin replacement when grafted onto athymic mice were studied. We have shown that: (1) 83% of the FS-CE attached to the artificial dermis in vitro compared to only 33% for control-CE; (2) retraction of the grafted area was significantly lower 2 weeks after grafted with FS-CE than with the control-CE (P < 0.05); (3) 83% of the mice grafted with FS-CE showed the presence of a differentiated human epidermis 21 days after grafting, while such an epidermis was absent in all the animals of the control-CE group. We found that the use of FS-CE greatly improved adhesion, development of the epithelium and graft take onto the artificial dermis. We believe this technology should significantly improve the performance of dermal-epidermal skin replacement for acute wounds.     

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.     

用毛囊隆突细胞构建复合皮的实验观察

目的 以人毛囊隆突细胞为种子细胞体外构建组织工程复合皮，在体观察其功能性修复全层皮肤缺损的可行性。方法 胶原酶消化法体外分离培养人毛囊隆突细胞和毛乳头细胞，实验分为A、B两组。A组将毛囊隆突细胞与毛乳头细胞按1：2混合，接种于胶原包被的聚羟基乙酸纤维支架中；B组单纯接种相同数量的毛乳头细胞。而后覆盖角质形成细胞膜片，构成组织工程复合皮，移植于裸鼠全层皮肤缺损创面。观察创面愈合情况，分别于术后2、4、6周在光学显微镜下观察移植物组织学变化。结果 组织工程复合皮能够有效修复A、B两组裸鼠全层皮肤缺损。术后2周，A、B组创面均可见完整的表皮及真皮结构。术后4-6周，A组复合皮表皮层明显增厚并形成基膜的钉突，可见毛囊样结构；B组仅表皮层有所增厚但基膜平整，未见钉突和毛囊结构形成。结论 以聚羟基乙酸真皮基质为支架，用角质形成细胞、毛囊隆突细胞和毛乳头细胞共同构建的组织工程复合皮，可以有效修复裸鼠全层皮肤缺损。其中毛囊隆突细胞参与了创面解剖修复，同时可能引导组织结构和功能的修复。     

Transient hyperproliferation of a transgenic human epidermis expressing hepatocyte growth factor

Hepatocyte growth factor (HGF) is a fibroblast-derived protein that affects the growth, motility, and differentiation of epithelial cells including epidermal keratinocytes. To investigate the role of HGF in cutaneous biology and to explore the possibility of using it in a tissue engineering approach, we used retroviral-mediated gene transfer to introduce the gene encoding human HGF into diploid human keratinocytes. Modified cells synthesized and secreted significant levels of HGF in vitro and the proliferation of keratinocytes expressing HGF was enhanced compared with control unmodified cells. To investigate the effects of HGF in vivo, we grafted modified keratinocytes expressing HGF onto athymic mice using acellular dermis as a substrate. When compared with controls, HGF-expressing keratinocytes formed a hyperproliferative epidermis. The epidermis was thicker, had more cells per length of basement membrane, and had increased numbers of Ki-67-positive proliferating cells, many of which were suprabasal in location. Hyperproliferation subsided and the epidermis was equivalent to controls by 2 weeks, a time frame that coincides with healing of the graft. Transient hyperproliferation may be linked to the loss of factors present in the wound that activate HGF. These data suggest that genetically modified skin substitutes secreting HGF may have applications in wound closure and the promotion of wound healing.     

The role of fibroblasts in dermal vascularization and remodeling of reconstructed human skin after transplantation onto the nude mouse.

The vascularization and the dermal remodeling of two different types of human skin reconstructed "in vitro" and grafted onto the nude mouse were studied. They were composed of human keratinocytes grown either on a human acellular deepidermized dermis (DED), or on a lattice composed of human fibroblasts embedded in bovine type I collagen, a living dermal equivalent (LDE). At different stages after grafting, the transplants were harvested and processed for an immunohistological study with species-specific and non-species-specific antibodies. At one month after grafting, the two types of grafted dermis contained blood vessels whose vascular basement membranes were labeled with a mouse-specific anti-type IV collagen antibody. With an antibody specific for human type IV collagen, a constant labeling of the vascular basement membrane was only observed in the LDE containing fibroblasts. In the DED, a constant association of the mouse endothelial cells with human type IV collagen was observed at early stages after grafting. At later stages, the human type IV collagen progressively disappeared. On the other hand, the dermal-epidermal junction underneath the human epidermis contained human type IV collagen in the two types of reconstructed skin. Labeling with the species-specific antibodies directed against human or murine type I collagen showed that the ratio murine type I collagen versus human type I collagen increased with time, suggesting that the DED is progressively invaded by mouse fibroblasts that produce the mouse collagen. On the other hand, in the LDE, the preexisting bovine type I collagen became progressively undetectable while both human type I collagen and elastic fibers were deposited by numerous human fibroblasts. Mouse type I collagen was not detected. Altogether, these observations made by grafting human skin reconstructed "in vitro" onto the nude mouse should be interesting for evaluating the usefulness of grafting a dermal substrate together with the epidermal sheet in the treatment of burns.     

Assessment of replication rates of human keratinocytes in engineered skin substitutes grafted to athymic mice

Stable closure of skin wounds with engineered skin substitutes (ESS) requires indefinite mitotic capacity to generate the epidermis. To evaluate whether keratinocytes in ESS exhibit the stem cell phenotype of label retention, ESS (n = 6–9/group) were pulsed with 5‐bromo‐2'‐deoxyuridine (BrdU) in vitro, and after grafting to athymic mice (n = 3–6/group). Pulse and immediate chase in vitro labeled virtually all basal keratinocytes at day 8, with label uptake decreasing until day 22. Label retention in serial chase decreased more rapidly from day 8 to day 22, with a reorganization of BrdU‐positive cells into clusters. Similarly, serial chase of labeled basal keratinocytes in vivo decreased sharply from day 20 to day 48 after grafting. Label uptake was assessed by immediate chases of basal keratinocytes, and decreased gradually to day 126, while total labeled cells remained relatively unchanged. These results demonstrate differential rates of label uptake and retention in basal keratinocytes of ESS in vitro and in vivo, and a proliferative phenotype with potential for long‐term replication in the absence of hair follicles. Regulation of a proliferative phenotype in keratinocytes of ESS may improve the biological homology of tissue‐engineered skin to natural skin, and contribute to more rapid and stable wound healing.     

Incubation of cultured skin substitutes in reduced humidity promotes cornification in vitro and stable engraftment in athymic mice

Cultured skin substitutes have been used successfully for adjunctive treatment of excised burns and chronic skin wounds. However, limitations inherent to all models of cultured skin include deficient barrier function in vitro, and delayed keratinization after grafting in comparison to native skin autografts. Experimental conditions for incubation of skin substitutes were tested to stimulate barrier development before grafting, and measure responses in function and stability after grafting. Cultured skin substitutes consisted of human keratinocytes and fibroblasts attached to collagen-glycosaminoglycan biopolymer substrates. Parallel cultured skin substitutes were incubated at the air-liquid interface in ambient (48-61%) or saturated (79-91%) relative humidity, and grafted to athymic mice on culture day 14. Additional cultured skin substitutes were incubated in the experimental conditions for a total of 28 days. Cadaveric human skin and acellular biopolymer substrates served as controls. Epidermal barrier was evaluated as the change in surface hydration by surface electrical capacitance with the NOVA Dermal Phase Meter. Cultured skin substitutes and cadaveric skin incubated in ambient humidity had lower baseline surface electrical capacitance and less change in surface electrical capacitance than parallel samples incubated in saturated humidity at all time points in vitro. Data from healing cultured skin substitutes at 2, 4, 8 and 12 weeks after grafting showed an earlier return to hydration levels comparable to native human skin, and more stable engraftment for skin substitutes from ambient humidity. The data indicate that cultured skin substitutes in ambient humidity have lower surface electrical capacitance and greater stability in vitro, and that they reform epidermal barrier more rapidly after grafting than cultured skin substitutes in saturated humidity. These results suggest that restoration of functional epidermis by cultured skin substitutes is stimulated by incubation in reduced humidity in vitro.     

Role of wound healing myofibroblasts on re-epithelialization of human skin

In human skin, large burned surfaces heal using two concomitant phenomena: re-epithelialization and dermal neoformation. Numerous studies report the role of interactions between keratinocytes and fibroblasts, but the relationship between wound healing myofibroblasts and keratinocytes is not clear, even though these two cell types coexist during healing. We investigated the influence of myofibroblasts on keratinocyte growth and differentiation using an in vitro skin model. A histological study was performed to determine the speed and quality of epithelialization. When the dermis was populated with fibroblasts, a continuous epidermis was formed in 7-10 days. In contrast, with wound healing myofibroblasts or without cell in dermis, the complete reepithelialization never occurred over the 10-day period studied. After 7 further days of epidermal differentiation, histology showed an epidermis more disorganized and expression of basement membrane constituents was reduced when wound healing myofibroblasts or no cells were added in the dermis instead of fibroblasts. These results suggest that wound healing myofibroblasts are not efficient to stimulate keratinocyte growth and differentiation. Treatment of fibroblasts with TGFbeta1 induced an increase of epidermal cell differentiation as seen when myofibroblasts were present. However, this cytokine did not change re-epithelialization rate and induced an increase of basement membrane matrix deposition in opposition to myofibroblasts. Thus, TGFbeta1 action is not sufficient to explain all the different keratinocyte reactions towards fibroblasts and wound healing myofibroblasts. Our conclusion is that myofibroblasts seem to have a limited role in the re-epithelialization process and might be more associated with the increased extracellular matrix secretion.     

Rejection, after a slightly prolonged survival time, of Langerhans cell-free allogeneic cultured epidermis used for wound coverage in humans

Autologous cultured epidermis (CE) grown from small skin biopsies in vitro has been successfully applied for wound grafting in humans. Since it has been reported recently that allogeneic CE might be tolerated as permanent wound cover, we investigated the properties of CE and its use as autologous and allogeneic grafts. Except for some differences, such as the absence of Langerhans cells and the lack of a stratum corneum, CE resembled its natural analogue. Autologous CE applied for grafting of leg ulcers and various surgical skin defects adhered firmly and permanently to the wound bed within 2 weeks, became regularly stratified, and formed a stratum corneum. Langerhans cells gradually entered the grafts; the dermis contained no inflammatory infiltrate. Allogeneic CE unmatched for MHC and blood group antigens used to partially cover tangentially excised third-degree burns, donor sites of split-thickness skin, and a defect after tumor excision initially survived well like the autografts. However, they were completely rejected after 10-22 (mean, 14.5) days, which is 4-5 days later than reported for split-thickness skin allografts. Clinically, rejection presented as "melting" of the graft. (Immuno)histologically, we found a dense mononuclear dermal infiltrate consisting predominantly of activated T cells, vacuolization, and single-cell necrosis of keratinocytes, as well as HLA-DR expression on keratinocytes, and finally separation and lysis of the epidermis. Limiting dilution analysis in 2 out of 4 allograft recipients revealed a considerable increase of circulating donor-specific cytotoxic T cell precursors during graft rejection. We conclude that grafting of allogeneic CE does not lead to permanent but to slightly prolonged graft survival.     

Grafting of large pieces of human reconstructed skin in a porcine model.

Present techniques can save about 25% of patients burnt over more than 90% of their body surface. However, problems of functional and aesthetic repair arise, which are often resolved only by major therapeutic procedures. Current advances in skin substitutes permit the cultivation, from a skin biopsy, of large surfaces of in vitro human reconstructed skin (HRS). Our model, obtained by the co-culture of fibroblasts and keratinocytes on a dermal substrate composed of collagen-glycosaminoglycan-chitosan, reproduces, in vitro, a tissue close to human skin, which could play a role in reconstructive surgery. The objectives of this experiment were to assess whether it is possible to perform large HRS grafts and to evaluate the preliminary cosmetic results. We used four immunosuppressed female pigs. Full-thickness skin resections of 50-100 cm(2)were performed on the dorsa of the animals. The defects were grafted with between one and six pieces of HRS under tied-over dressings. At day 14, we found a soft and smooth surface of good transparent healthy pink skin, which was very easy to distinguish from the surrounding tissues. The junctions between different pieces of living skin were not visible. Immunohistological studies with specific anti-human keratin 14 antibodies confirmed the graft take: 7 days after grafting the human epidermis was attached to the living dermis and showed good organisation with a basal cell layer and suprabasal cells; 28 days after grafting the human epidermis seemed to be replaced by pig epidermis. This study highlights the possibility of grafting large surfaces with HRS using a routine operating technique.     

组织工程化表皮膜片构建及其在供皮区的应用研究

目的构建组织工程化表皮细胞膜片并应用于供皮区创面治疗。方法利用患者少量自体或同种异体正常皮肤分离、培养、扩增的表皮细胞,接种于壳聚糖明胶膜构建成表皮细胞膜片;将膜片移植于治疗组供皮区创面、适度加压,同时设立对照组:空白材料对照以及传统油纱布对照覆盖创面。于术后5～10d、30d、90d行大体观察、组织学检查、广谱角蛋白、外皮蛋白、层粘连蛋白、免疫组织化学检测以及Ⅰ、Ⅲ型胶原比值测定(偏光显微镜、RTPCR)。结果利用自体及异体表皮细胞和壳聚糖明胶膜能够构建出人表皮细胞膜片,应用于临床供皮区创面治疗15例,经过3个月随访,疗效肯定。移植膜片创面愈合时间(8.1±1.3)d,空白材料对照区为(16.2±3.8)d,空白油纱布对照区为(23.0±5.8)d。移植膜片存活良好,结构较完整、术后30d及90d观察:12例无明显增生,3例有轻度增生(20.0%),而空白油纱布对照区11例遗留增生性瘢痕(74.4%,χ2=8.127,P<0.01)。结论表皮细胞-壳聚糖明胶膜片能促进供皮区创面早期愈合并减少后期瘢痕增生,具有良好治疗效果。     

Impaired cutaneous wound healing in mice lacking tetranectin

Tetranectin was originally purified from human serum on the basis of plasminogen kringle 4-binding properties. Tetranectin enhances plasminogen activation by a tissue-type plasminogen activator so that it has been suggested to play a role in tissue remodeling. We have generated mice with a targeted disruption of the tetranectin gene to elucidate the biological function of tetranectin. In this study, we showed that wound healing was markedly delayed in tetranectin-null mice compared with wild-type mice. A single full-thickness incision was made in the dorsal skin. By 14 days after the incision, the wounds fully healed in all wild-type mice based on the macroscopic closure; in contrast, the progress of wound healing in the tetranectin null mice appeared to be impaired. In histological analysis, wounds of wild-type mice showed complete reepithelialization and healed by 14 days after the incision. However, those of tetranectin-null mice never showed complete reepithelialization at 14 days. At 21 days after the injury, the wound healed and was covered with an epidermis. These results supported the fact that tetranectin may play a role in the wound healing process.     

Demonstration of epidermal transfer from a polymer membrane using genetically marked porcine keratinocytes

The culture of keratinocytes on flexible membranes has been proposed as a means to simplify, accelerate and improve the efficiency with which proliferating cells are delivered to full thickness or non-healing skin defects. However, there have been no studies that monitor the transfer of cells from such membranes to the wound bed. We have used a porcine model of lacZ gene marked cultured autologous keratinocyte grafting to demonstrate unambiguously the transfer of cultured cells to cutaneous wounds from the EpiGen polymer membrane developed by Smith & Nephew Group plc. Full thickness wounds enclosed within rigid chambers were first grafted with autologous de-epidermalised dermis (DED). Keratinocytes were cultured on EpiGen membranes and applied to the wound beds 7 days after the DED grafts. Epidermal remnants persist within the DED and the resultant epidermis is therefore, a mixture of wound regeneration and delivered cultured cells. Unequivocal evidence for keratinocyte transfer from the membrane was obtained through the observed macroscopic surface staining for lacZ transduced cells and lacZ positive cells detected in sections through deeper layers of epidermal tissue. This method offers a general approach for evaluating the efficiency of keratinocyte delivery using upside-down flexible membrane transfer.     

Preparation of laser micropore porcine acellular dermal matrix for skin graft: an experimental study

In our previous study, we used composite grafts consisting of meshed porcine acellular dermal matrix (PADM) and thin split-thickness autologous epidermis to cover full thickness burn wounds in clinical practice. However, a certain degree of contraction might occur because the distribution of dermal matrix was not uniform in burn wound. In this study, we prepare a composite skin graft consisting of PADM with the aid of laser to improve the quality of healing of burn wound. METHODS: PADM was prepared by the trypsin/Triton X-100 method. Micropores were produced on the PADM with a laser punch. The distance between micropores varied from 0.8, 1.0, 1.2 to 1.5mm. Full thickness defect wounds were created on the back of 144 SD rats. The rats were randomly divided into six groups: micropore groups I-IV in which the wound were grafted with PADM with micropores, in four different distances, respectively and split-thickness autograft; mesh group rats received meshed PADM graft and split-thickness autograft; control group received simple split-thickness autografting. The status of wound healing was histologically observed at regular time points after surgery. The wound healing rate and contraction rate were calculated. RESULTS: The wound healing rate in micropore groups I and II was not statistically different from that in control group, but was significantly higher than that in mesh group 6 weeks after grafting. The wound healing rate in micropore groups III and IV was lower than that in mesh and control groups 4 and 6 weeks after grafting. The wound contraction rate in micropore groups I and II was remarkably lower than that in control group 4 and 6 weeks after surgery and it was significantly much lower than that in mesh group 6 weeks after surgery. Histological examination revealed good epithelization, regularly arranged collagenous fibers and integral structure of basement membrane. CONCLUSION: Laser micropore PADM (0.8 or 1.0mm in distance) grafting in combination with split-thickness autografting can improve wound healing. The PADM with laser micropores in 1.0mm distance is the better choice.     

异种脱细胞真皮基质与自体皮复合移植后基底膜重塑的实验观察

目的　观察异种 (猪 )脱细胞真皮基质与薄自体皮复合移植模型中基底膜重塑的变化规律。　方法　将异种 (猪 )脱细胞真皮基质与薄自体皮复合移植于大鼠创面 ,分别于移植后 1、2、3、4、8、12、16周留取标本 ,采用免疫组化、透射电镜等方法 ,观察基底膜中层粘连蛋白的变化规律及 12周时基底膜的超微结构 ,同时以单纯薄自体皮移植进行对照。　结果　异种脱细胞真皮基质与薄自体皮复合移植后 ,层粘连蛋白的表达高于单纯薄自体皮移植。 12周时复合移植组基底膜清晰连续 ,半桥粒较多且分布均匀 ;薄自体皮组基底膜致密板模糊、不连续 ,半桥粒减少且分布不均。　结论　异种脱细胞真皮基质与薄自体皮复合移植后 ,基底膜中层粘连蛋白表达增高 ,可能有利于复合皮移植后基底膜的重塑 ,增强表皮和真皮之间的连接 ,进而改善创面愈合质量     

大张表皮片覆盖预防断层皮片供区瘢痕

目的介绍一种用自体大张表皮片即时覆盖断层皮片供区以预防其瘢痕生长的方法。方法用鼓式或电动取皮机切取断层皮片，厚度在0．3～0.5mm之间，用电动取皮机切取大张表皮片，厚度0．07～0．12mm（0．0028in～0．0048in），供皮区一般首选在背部、腰部、臀部或头皮，其次是胸腹和四肢；将表皮片覆盖在断层皮片供区，边缘用纳米银纱布条压紧，外加缝合或钉皮钉固定。表皮片供区和移植区内层均用油纱布，外层纳米银纱布覆盖，以缝线包压法包扎。结果从1999年11月至2003年11月共用于118例的133个整形部位。断层皮片供区移植表皮片后，无瘢痕生长，平坦，光滑，外观接近正常皮肤，但无毛囊和汗腺。表皮片供区短时间内潮红，无瘢痕增生，3个月以后逐渐接近正常皮肤。结论大张表皮片移植覆盖断层皮片供区是一种预防断层皮片供区瘢痕生长的好方法，值得推广和应用。