PDGF-BB、IL-13和TGF-β1诱导真皮成纤维细分泌Ⅰ型胶原蛋白的比较

目的用不同浓度的白介素13(IL-13)、转化生长因子β1(TGF-β1)和血小板源性生长因子BB(PDGF-BB)在体外诱导真皮成纤维细胞,以甄选促进诱导Ⅰ型胶原蛋白高分泌的细胞因子。方法选用出生2d的SD大鼠背部皮肤进行真皮成纤维细胞原代培养,采用免疫荧光技术对其进行纯度鉴定。实验分为4组:PDGF-BB(30ng/mL)组、IL-13(100ng/m)组、TGF-β1(10ng/mL)组和不加任何处理因素的阴性对照组,用MTT法、ELISA检测在24h、48h、72h时的真皮成纤维细胞的增殖情况及培养液中Ⅰ型胶原蛋白的浓度。结果原代培养真皮成纤维细胞的纯度达90%以上。PDGF-BB、IL-13、TGF-β1均能促进真皮成纤维细胞增殖和Ⅰ型胶原蛋白分泌,在48h、72h时PDGF-BB组的培养液中Ⅰ型胶原蛋白浓度明显高于IL-13组、TGF-β1组及阴性对照组(P<0.05)。结论浓度为30ng/mL的PDGF-BB促进真皮成纤维细胞增殖和分泌Ⅰ型胶原蛋白的作用更为显著。     

Expansion and delivery of human fibroblasts on micronized acellular dermal matrix for skin regeneration

In order to obtain an abundant supply of autologous dermal fibroblasts for the manufacture of engineered autologous dermal substitutes, we fabricated the micronized acellular dermal matrix (MADM) microcarriers and expanded human fibroblasts on them. This novel approach eliminated the need for the repeated trypsinizations that may disrupt cell–extracellular matrix interactions and impair cell viability. This cell expansion protocol simultaneously formed an engineered particulate dermal substitute (EPDS) avoiding cell reseeded on the scaffolds process. We further tested its feasibility and effectiveness in athymic murine subcutaneous injection and full-thickness cutaneous wound model. Our results showed that MADM microcarriers retained the ultrastructure of the acellular dermal matrix, had good biocompatibility, and supported human fibroblast expansion either as a direct culture substrate or through culturing cells in conditioned medium prepared from them. In the animal study, EPDS formed a thick layer of tissue below the subcutaneous muscle tissue at 3 weeks following EPDS injection into subcutaneous tissue. In full-thickness cutaneous wound, the degree of wound healing with EPDS implantation was better than that without EPDS although healing rates were not significantly different between wounds implanted with or without EPDS. This demonstrates the potential utility of MADM not only as a cell culture substrate to expand fibroblasts but also as a cell transplantation vehicle for skin regeneration, with several advantages over current expansion–transplantation protocols for skin regeneration. In addition, EPDS may be used for cosmetic or reconstructive soft tissue augmentation in a minimally invasive fashion.     

Biocompatible nanofiber matrices for the engineering of a dermal substitute for skin regeneration

Natural and synthetic biodegradable nanofibers are extensively used for biomedical applications and tissue engineering. Biocompatibility and a well-established safety profile for polycaprolactone (PCL) and collagen represent a favorable matrix for preparing a dermal substitute for engineering skin. Collagen synthesized by fibroblasts is a good surface active agent and demonstrates its ability to penetrate a lipid-free interface. During granulation tissue formation, fibronectin provides a temporary substratum for migration and proliferation of cells and provides a template for collagen deposition, which increases stiffness and tensile strength of this healing tissues. The objective of this study was to fabricate nanofiber matrices from novel biodegradable PCL and collagen to mimic natural extracellular matrix (ECM) and to examine the cell behavior, cell attachment, and interaction between cells and nanofiber matrices. Collagen nanofiber matrices show a significant (p < 0.001) level of fibroblast proliferation and increase up to 54% compared with control tissue culture plate (TCP) after 72 h. The present investigation shows that PCL-coated collagen matrices are suitable for fibroblast growth, proliferation, and migration inside the matrices. This novel biodegradable PCL and collagen nanofiber matrices support the attachment and proliferation of human dermal fibroblasts and might have potential in tissue engineering as a dermal substitute for skin regeneration.     

Repair of tendon defect with dermal fibroblast engineered tendon in a porcine model

Harvesting autologous tenocytes for tendon engineering may cause secondary tendon defect at the donor site. Dermal fibroblasts are an easily accessible cell source and do not cause major donor site defect. This study aims to explore the possibility of tendon engineering using dermal fibroblasts. A total of 45 hybrid pigs were randomly divided into three groups: experimental group (n = 15)--repair of tendon defect with a dermal fibroblast engineered tendon; control group 1 (n = 15)--repair of defect with a tenocyte engineered tendon; and control group 2 (n = 15)-repair of defect with a scaffold alone. Both autologous dermal fibroblasts and tenocytes were seeded on polyglycolic acid (PGA) unwoven fibers to form a cell-scaffold construct and cultured in vitro for 7 days before in vivo implantation to repair a defect of flexor digital superficial tendon. Specimens were harvested at weeks 6, 14, and 26 for gross, histological, and mechanical analyses. Microscopy revealed good attachment of both dermal fibroblasts and tenocytes on PGA fibers and matrix production. In vivo results showed that fibroblast and tenocyte engineered tendons were similar to each other in their gross view, histology, and tensile strength. At 6 weeks, parallel collagen alignment was observed at both ends, but not in the middle in histology, with more cellular components than natural tendons. At weeks 14 and 26, both engineered tendons exhibited histology similar to that of natural tendon. Collagens became parallel throughout the tendon structure, and PGA fibers were completely degraded. Interestingly, dermal fibroblast and tenocyte engineered tendons did not express type III collagen at 26 weeks, which remained observable in normal pig skin and control group 2 tissue using polarized microscopy, suggesting a possible phenotype change of implanted dermal fibroblasts. Furthermore, both fibroblast and tenocyte engineered tendons shared similar tensile strength, about 75% of natural tendon strength. At 6 weeks in control group 2, neo-tissue was formed only at the peripheral area by host cells. A cord-like tissue was formed at weeks 14 and 26. However, the formed tissue was histologically disorganized and mechanically weaker than both cell-engineered tendons (p < 0.05). These results suggest that dermal fibroblasts may have the potential as seed cells for tendon engineering.     

17beta-estradiol regulates the secretion of TGF-beta by cultured human dermal fibroblasts

Estrogen plays an important role in skin homeostasis, as demonstrated by the changes seen in the skin of post-menopausal women, changes reversed by HRT. Estrogen also has a role in wound healing, since estrogen deficiency as occurs post-menopausally and in ovariectomised animals, is associated with a reduced rate of wound healing. Estrogen appears to modulate all phases of wound healing with effects on inflammatory cells, epithelialization, angiogenesis, extracellular matrix deposition and tissue remodelling. This study was designed to investigate the effects of 17beta-estradiol on cultured human dermal fibroblasts using an in vitro wound-healing assay. The end points investigated were cell migration, proliferation, total collagen secretion and active TGF-beta1 secretion. 17beta-estradiol significantly increased the migration and proliferation of cultured dermal fibroblasts following mechanical wounding, although the secretion of total soluble collagen was not altered. An increase in TGF-beta1 was demonstrated by unwounded confluent dermal fibroblast monolayers in response to 17beta-estradiol, but paradoxically, a decrease in the secretion of TGF-beta1 was demonstrated in the mechanically wounded dermal fibroblasts. These results identify human dermal fibroblasts as estrogen target cells and provide further evidence for a role by which estrogen regulates this particular cell type as part of the wound-healing process. However, the paradoxical nature of the effect of estrogen on TGF-beta1 secretion following mechanical wounding suggests that the cellular mechanism of action is complex. A greater understanding of the cell-specific action of estrogen may help to develop therapies that will improve cutaneous wound healing in the future.     

Platelet-rich plasma stimulates human dermal fibroblast proliferation via a Ras-dependent extracellular signal-regulated kinase 1/2 pathway

Platelet-rich plasma (PRP) contains a high concentration of several growth factors and contributes to soft-tissue engineering and wound healing. However, the effect of PRP on human dermal fibroblast proliferation and responses is unknown. This was investigated in the present study using PRP prepared from the whole human blood using the double-spin method. Human dermal fibroblast cultures were established from skin samples collected during plastic surgery. Platelet concentration and growth factor levels in PRP were estimated, and a cell proliferation assay was carried out after PRP treatment. The role of Ras-dependent extracellular signal-regulated kinase (ERK)1/2 in the effects of PRP was investigated in human dermal fibroblasts by suppressing ERK1/2 expression with an inhibitor or by short interfering (si)RNA-mediated knockdown, and assessing ERK1/2 phosphorylation by western blotting as well as proliferation in PRP-treated cells. We found that PRP stimulated human dermal fibroblast proliferation, which was suppressed by ERK1/2 inhibitor treatment (P < 0.01). ERK1/2 phosphorylation was increased in the presence of PRP, while siRNA-mediated knockdown of ERK1/2 blocked cell proliferation normally induced by PRP treatment (P < 0.01). These results demonstrate that PRP induces human dermal fibroblast proliferation via activation of ERK1/2 signaling. Our findings provide a basis for the development of agents that can promote wound healing and can be applied to soft-tissue engineering.     

In vitro characterization of an artificial dermal scaffold

The treatment of extensive burn injuries has been enhanced by the development of artificial skin substitutes. Integra Artificial Skin, an acellular collagen-glycosaminoglycan (C-GAG) dermal equivalent requires a two-stage grafting procedure. However, preseeding the C-GAG dermal equivalent with cultured fibroblasts and keratinocytes, with the aim of performing a single-stage grafting procedure, may be beneficial in terms of replacing the requirement for traditional split-skin grafts. In this comparative in vitro study, the interactions of cultured human dermal fibroblasts and epidermal keratinocytes in Integra Artificial Skin in comparison to cadaver deepidermalized dermis (DED) was investigated. An increase in cell proliferation and migration in the C-GAG dermal equivalent was observed over time. Cocultures of fibroblasts and keratinocytes on both dermal equivalents showed positive expression of proliferation, differentiation, and extracellular matrix (ECM) protein markers. Organization of keratinocytes in the epidermal layers of DED composites were better compared to the C-GAG composites. Deposition of ECM proteins was enhanced in the presence of keratinocytes in both dermal equivalents. Results demonstrate that in vitro the C-GAG dermal equivalent is biocompatible for cell attachment, migration, proliferation, and differentiation. Preseeding Integra Artificial Skin with cultured autologous fibroblasts and keratinocytes for in vivo application, as a single-stage grafting procedure, warrants testing. A better clinical outcome may be achieved as shown by our in vitro results of the coculture composites.     

Effects of leukocyte and fibroblast interferon on events in the fibroblast cell cycle.

Serum-depleted human foetal skin fibroblasts were stimulated by addition of 10% foetal calf serum to proliferate synchronously for at least one cell cycle. This proliferation was suppressed by leukocyte or fibroblast interferon (IF), which prolonged the G1 phase and diminished the rate of DNA synthesis during the S phase in a dose-dependent manner. When used in identical concentration, as judged in terms of units of antiviral activity, fibroblast IF had more pronounced effects on cell cycle events than leukocyte IF. Interferon exerted its effect in early G1, before the cells were irreversibly committed to DNA synthesis.     

Diversity of fibroblasts--a review on implications for skin tissue engineering

Enormous advances in the development of skin substitutes have occurred in the past 3 decades. Major obstacles yet to be overcome in the quest for an optimal skin substitute include controlling scar formation, contraction and the loss of adnexal structures. Mesenchyme-derived signals are essential for epithelial proliferation, skin morphogenesis, homeostasis and differentiation. Having previously shown that fibroblasts differentiate along a lineage from highly proliferative progenitor fibroblasts with characteristic spindle-shaped appearance to differentiated postmitotic polygonal fibrocytes, we have now established that the different subsets of fibroblasts exert significantly different patterns of cytokine release and that the highest levels of keratinocyte growth factor and transforming growth factor-beta1 expression result from differentiated fibroblasts. Coculture studies with keratinocytes reveal that postmitotic fibroblasts stimulate keratinocyte proliferation to a greater extent than progenitor fibroblasts. Acellular and fibroblast-seeded dermal substitutes have been shown to improve scarring and contraction in animal studies, the latter substitutes yielding the most favorable results. Fibroblasts from different body sites display different functional properties which may affect their suitability for dermal substitutes. Future in vivo human studies in tissue-engineered dermal substitutes will likely focus on fibroblast-seeded lattices and the impact of fibroblast subpopulations and bone marrow-derived mesenchymal stem cells on dermal regeneration.     

Engineering of a dermal equivalent: seeding and culturing fibroblasts in PEGT/PBT copolymer scaffolds

The engineering of dermal skin substitutes, using autologous fibroblasts, requires high seeding efficiencies, a homogeneous cell distribution in the scaffolds, and optimal culture conditions. Dynamic seeding in spinner flasks was used to seed and subsequently culture fibroblasts in three-dimensional scaffolds. Several seeding and culture variables were investigated. Simulation of medium movement with microspheres showed that three different regions existed in medium (outer, middle, and inner), where overall particle movement was different. In the middle region the flow was turbulent and scaffolds were best placed in this region. After fibroblast seeding, methylene blue staining and scanning electron microscopy analysis of the scaffolds showed that at a low stirring speed (20 rpm) fibroblasts attached mainly onto the upper part of the scaffold, and at 40 and 60 rpm fibroblasts attached and spread throughout the scaffolds. Measurements of total DNA content per scaffold showed that lower stirring speeds (20 and 40 rpm) resulted in significantly higher cell-seeding efficiencies (20 rpm, 99.8 +/- 11.3%; 40 rpm, 93.8 +/- 10.5%) compared with 60 rpm (85.9 +/- 5.3%). Seeding kinetics were comparable for all three speeds investigated. In subsequent studies, 40 rpm was chosen for seeding. Using initial cell numbers ranging from 0.3 x 10(6) to 1.5 x 10(6) fibroblasts per scaffold, seeding efficiencies higher than 85% were consistently found (n = 4). The culture of fibroblast-seeded scaffolds at different stirring speeds (10-80 rpm) showed that stirring speeds higher than 10 rpm significantly stimulated fibroblast proliferation and glycosaminoglycan and collagen deposition as compared with 10 rpm. After 21 days, scaffolds cultured at 80 rpm showed significantly more collagen deposition as compared with those maintained at lower speeds. In conclusion, to achieve high seeding efficiencies, uniform fibroblast distribution and tissue formation in a three-dimensional scaffold, fibroblasts can be dynamically seeded at 40 rpm and subsequently cultured at a stirring speed of 60-80 rpm in spinner flasks. This flexible system shows that it is feasible to tissue engineer autologous dermal substitutes in a clinically acceptable time frame.     

Evaluation of ultra-thin poly(epsilon-caprolactone) films for tissue-engineered skin

Various natural and synthetic polymeric materials have been used as scaffold matrices for tissue-engineered skin. However, the commercially available skin replacement products pose problems of poor mechanical properties and immunological rejection. We have thus developed a film of 5 microm thickness, via biaxial stretching of poly(epsilon-caprolactone) (PCL), as a potential matrix for living skin replacements. The aim of this study was to evaluate the feasibility of using biaxially stretched PCL films as matrices for culturing human dermal fibroblasts. For this purpose, we cultured human dermal fibroblasts for 7 days on the films. Glass cover slips and polyurethane (PU) sheets were used as controls. The data from phase contrast light, confocal laser, and scanning electron microscopy suggested that biaxially stretched PCL films support the attachment and proliferation of human dermal fibroblasts. Thymidine-labeling results showed quantitatively that cell proliferation on the PCL films was superior to that on the PU samples. These results indicated that biaxially stretched PCL films supported the growth of human dermal fibroblasts and might have potential to be applied in tissue engineering a dermal equivalent or skin graft.     

Higher numbers of autologous fibroblasts in an artificial dermal substitute improve tissue regeneration and modulate scar tissue formation

Cultured skin substitutes are increasingly important for the treatment of burns and chronic wounds. The role of fibroblast numbers present in a living-skin equivalent is at present unknown. The quality of dermal tissue regeneration was therefore investigated in relation to the number of autologous fibroblasts seeded in dermal substitutes, transplanted instantaneously or precultured for 10 days in the substitute. A full-thickness porcine wound model was used to compare acellular dermal substitutes (ADS) with dermal substitutes seeded with fibroblasts at two densities, 1x10(5) (0-DS10) and 5x10(5) cells/cm(2) (0-DS50), and with dermal substitutes seeded 10 days before operation at the same densities (10-DS10 and 10-DS50) (n=7 for each group, five pigs). After transplantation of the dermal substitutes, split-skin mesh grafts were applied on top. Wound healing was evaluated blind for 6 weeks. Cosmetic appearance was evaluated and wound contraction was measured by planimetry. The wound biopsies taken after 3 weeks were stained for myofibroblasts (alpha-smooth muscle actin), and after 6 weeks for scar tissue formation (collagen bundles organized in parallel and the absence of elastin staining). Collagen maturation was investigated with polarized light. For wound cosmetic parameters, the 10-DS50 and 0-DS50 treatments scored significantly better than the ADS treatment, as did the 10-DS50 treatment for wound contraction (p<0.05, paired t-test). Three weeks after wounding, the area with myofibroblasts in the granulation tissue, determined by image analysis, was significantly smaller for 0-DS50, 10-DS10, and 10-DS50 than for the ADS treatment (p<0.04, paired t-test). After 6 weeks, the wounds treated with 0-DS50, 0-DS10, and 10-DS50 had significantly less scar tissue and significantly more mature collagen bundles in the regenerated dermis. This improvement of wound healing was correlated with the higher numbers of fibroblasts present in the dermal substitute at the moment of transplantation. In conclusion, dermal regeneration of experimental full-skin defects was significantly improved by treatment with dermal substitutes containing high numbers of (precultured) autologous fibroblasts.     

Changes in the migratory ability of human lung and skin fibroblasts during in vitro aging and in vivo cellular senescence.

The migration of human lung and skin fibroblasts was determined during in vitro aging and in vivo cellular senescence by measuring their migration from the edge of a denuded area of a monolayer. The migration of human fetal lung fibroblasts (TIG-1 and TIG-3) decreased only very slightly with increasing passage, whereas the migration of human fetal skin fibroblasts (TIG-3S) declined gradually: the difference in cell migratory ability between early and late passages was significant (P less than 0.05). The migratory patterns of skin fibroblasts from adult and elderly donors were also similar to that of fetal skin fibroblasts. Next, the migratory abilities of fibroblast lines from adult and elderly donor groups were compared, using relatively early passaged cells. The migratory ability of the elderly-donor skin fibroblast lines was significantly lower (P less than 0.05) than that of the adult-donor skin fibroblast lines. Addition of suramin and monensin suppressed the migration of fibroblasts from fetal, adult and elderly donors, which implies that fibroblast migration is regulated by growth factors and matrix substances. The relationships between the age-dependent decline of migratory ability, growth factors and the extracellular matrix are discussed.     

Human mast cells stimulate fibroblast proliferation, collagen synthesis and lattice contraction: a direct role for mast cells in skin fibrosis

BACKGROUND: Mast cells, the key cells of immediate hypersensitivity type reactions, have also been postulated to have a central role in influencing tissue remodelling and fibrosis occurring in the skin. OBJECTIVE: Our aim was to investigate the direct role of human mast cells (HMC) in skin fibrotic processes, by assessing the effects of the addition of the human mast cell line HMC-1 to human skin fibroblasts, and to identify the responsible mediators. METHODS: HMC-1 sonicates were added to human skin fibroblasts and the following parameters were evaluated: proliferation ([3H]-thymidine), collagen synthesis ([3H] proline), activity of matrix metalloproteinases (MMPs) (zymography) and tissue inhibitors of metalloproteinases (TIMPs) (reverse zymography), and collagen gel contraction. RESULTS: HMC-1 sonicate increased significantly both proliferation and collagen production in the human skin fibroblasts and these properties were not affected by heating of the sonicate (56 degrees C, 30 min, or 100 degrees C, 3 min). Two main mast cell mediators, histamine and tryptase, were found to be responsible for the increase in fibroblast proliferation and collagen production. HMC-1 sonicate did not display any pre-formed gelatinase activity, and its addition to the fibroblasts did not change their pro-MMP-2 and MMP-2 activity. On the other hand, HMC-1 were found to possess TIMP-1 and TIMP-2. Addition of HMC-1 had no effect on fibroblasts TIMP-1 but induced a dose-dependent increase of TIMP-2 activity. In addition, HMC-1 sonicate seeded together with the fibroblasts in tri-dimensional collagen gel significantly enhanced their contraction. CONCLUSION: We have shown that human mast cells, by granule-stored and therefore quickly releasable mediators, increase human skin fibroblast proliferation, collagen synthesis, TIMP-2 and collagen gel contraction. Therefore, mast cells have a direct and potentiating role in skin remodelling and fibrosis.     

Evaluation of electrospun PCL/gelatin nanofibrous scaffold for wound healing and layered dermal reconstitution

The current design requirement for a tissue engineering skin substitute is that of a biodegradable scaffold through which fibroblasts can migrate and populate. This artificial "dermal layer" needs to adhere to and integrate with the wound, which is not always successful for the current artificial dermal analogues available. The high cost of these artificial dermal analogues also makes their application prohibitive both to surgeons and patients. We propose a cost-effective composite consisting of a nanofibrous scaffold directly electrospun onto a polyurethane dressing (Tegaderm, 3M Medical) - which we call the Tegaderm-nanofiber (TG-NF) construct - for dermal wound healing. Cell culture is performed on both sides of the nanofibrous scaffold and tested for fibroblast adhesion and proliferation. It is hoped that these studies will result in a fibroblast-populated three-dimensional dermal analogue that is feasible for layered applications to build up thickness of dermis prior to re-epithelialization. Results obtained in this study suggest that both the TG-NF construct and dual-sided fibroblast-populated nanofiber construct achieved significant cell adhesion, growth and proliferation. This is a successful first step for the nanofiber construct in establishing itself as a suitable three-dimensional scaffold for autogenous fibroblast populations, and providing great potential in the treatment of dermal wounds through layered application.     

Fibroblasts accelerate culturing of mucosal substitutes

Reconstruction of large mucosal defects of the floor of the mouth is typically performed with keratinizing skin. Drawbacks include donor site defects and hair bearing of the flaps. Cultured mucosal substitutes (CMSs) have been developed for clinical use to replace keratinizing skin. Acellular dermis is often used as a dermal carrier for autologous cells, because it reduces wound contraction and is easier for the surgeon to handle than, for example, collagen gels. A major problem of CMSs using acellular dermis is variation in epidermal quality. To improve the quality of the CMSs, human fibroblasts were incorporated into the acellular dermis and seeded with human keratinocytes. To study the role of the fibroblasts in epidermal morphology and basement membrane formation, CMSs were stained for differentiation markers beta1 integrin, cytokeratin 10, and involucrin after 1 and 2 weeks in culture. Basement membrane formation was analyzed using laminin 5 and collagen IV and VII staining; proliferation was analyzed using Ki-67 staining. The epidermises of fibroblast-containing CMSs matured faster into a well-organized epithelium than did those that did not contain CMSs. A 52.7% increase in basal cells, a 53.5% increase in mitosis index, and a 78.0% increase in keratinocyte cell layers were observed. Addition of fibroblasts reduced culturing time and enhanced proliferation, maturation, and quality of the epidermis.     

Electrospun synthetic human elastin:collagen composite scaffolds for dermal tissue engineering

We present an electrospun synthetic human elastin:collagen composite scaffold aimed at dermal tissue engineering. The panel of electrospun human tropoelastin and ovine type I collagen blends comprised 80% tropoelastin+20% collagen, 60% tropoelastin+40% collagen and 50% tropoelastin+50% collagen. Electrospinning efficiency decreased with increasing collagen content under the conditions used. Physical and mechanical characterization encompassed fiber morphology, porosity, pore size and modulus, which were prioritized to identify the optimal candidate for dermal tissue regeneration. Scaffolds containing 80% tropoelastin and 20% collagen (80T20C) were selected on this basis for further cell interaction and animal implantation studies. 80T20C enhanced proliferation and migration rates of dermal fibroblasts in vitro and were well tolerated in a mouse subcutaneous implantation study where they persisted over 6weeks. The 80T20C scaffolds supported fibroblast infiltration, de novo collagen deposition and new capillary formation.     

The effect of chitin and chitosan on the proliferation of human skin fibroblasts and keratinocytes in vitro

The effects of chitin [(1 --> 4)-2-acetamido-2-deoxy-beta-D-glucan] and its partially deacetylated derivatives, chitosans, on the proliferation of human dermal fibroblasts and keratinocytes were examined in vitro. Chitosans with relatively high degrees of deacetylation strongly stimulated fibroblast proliferation while samples with lower levels of deacetylation showed less activity. Fraction, CL313A, a shorter chain length, 89% deacetylated chitosan chloride was further evaluated using cultures of fibroblasts derived from a range of human donors. Some fibroblast cultures produced a positive mitogenic response to CL313A treatment with proliferation rates being increased by approximately 50% over the control level at an initial concentration of 50 microg/ml, whilst others showed no stimulation of proliferation or even a slight inhibition (< 10%). The stimulatory effect on fibroblast proliferation required the presence of serum in the culture medium suggesting that the chitosan may be interacting with growth factors present in the serum and potentiating their effect. In contrast to the stimulatory effects on fibroblasts, fraction CL313A inhibited human keratinocyte mitogenesis with up to 40% inhibition of proliferation being observed at 50 microg/ml. In general highly deacetylated chitosans were more active than those with a lower degree of deacetylation. These data demonstrate that highly deacetylated chitosans can modulate human skin cell mitogenesis in vitro. Analysis of their effects on cells in culture may be useful as a screen for their potential activity in vivo as wound healing agents, although in the case of fibroblasts it is important to select appropriate strains of cells for use in the screen.     

Mononuclear cell-fibroblast interactions in scleroderma

We studied cell proliferation and collagen biosynthesis in cocultures of dermal fibroblasts with peripheral blood mononuclear cells (MNC) from scleroderma patients and from age-matched normal controls. Autologous one-way mixed MNC-fibroblast cultures revealed that fibroblasts do not stimulate MNC proliferation. Conversely, MNC stimulate autologous fibroblasts from scleroderma patients as well as from normal controls. This effect is increased in cells from scleroderma patients in which it seems to be mediated both by cell-to-cell interaction and through the production of soluble factors by MNC. In normal control cell systems we found no proliferative effect of supernatants of unstimulated cells or from those stimulated in autologous mixed-lymphocyte reactions. Coculture of fibroblasts with autologous MNC resulted in increased [14C]proline incorporation into both collagenic and noncollagenic proteins. This effect was mediated mostly by soluble factors that are released into the culture medium. Protein synthesis by MNC-fibroblast cocultures from scleroderma patients was significantly greater than protein synthesis by those from normal controls. Culture supernatants from unstimulated MNC or from autologous mixed-lymphocyte cultures caused a slight decrease in collagenic protein synthesis by cultured fibroblasts from scleroderma patients but not by those from normal controls. This effect of culture supernatants could be reproduced, and magnified, with purified IL-1 on cells from either patients or controls. Our findings indicate abnormal MNC-fibroblast interactions in scleroderma that could play an important role in the pathogenesis of fibrosis, the hallmark of this condition.     

Modulation of growth and function of human gingival fibroblasts by fibroblast-activating factor derived from Porphyromonas gingivalis W50.

The effect of a 24-kDa fibroblast-activating factor (FAF) isolated from outer membrane vesicles of Porphyromonas gingivalis W50 on the modulation of [3H]thymidine uptake and cell proliferation was examined in selected fibroblast and transformed cell lines. FAF enhanced the proliferation of human gingival fibroblasts, human skin fibroblasts, and human umbilical vein endothelial cells in subconfluent and confluent cells, suggesting that FAF might be functioning as a competence factor. The transformed cell lines, U-937 and HEp-2, were not responsive. FAF and several human-derived growth factors showed a synergistic effect on proliferation. [3H]proline and [3H]leucine were rapidly incorporated into fibroblasts in the presence of FAF; however, there was no selective induction of collagen synthesis. FAF was not active in the induction of interleukin-1 and interleukin-6. It is hypothesized that FAF from P. gingivalis functions as a growth factor for human fibroblasts but is without activity for transformed cells.