Use of human mesenchymal cells to improve vascularization in a mouse model for scaffold-based dermal regeneration

All engineered bioartificial structures developed for tissue regeneration require oxygen and nutrients to establish proper physiological functions. Aiming to improve vascularization during dermal regeneration, we combined the use of a bioartificial collagen scaffold and a defined human mesenchymal cell (MC) line. This cell line, termed V54/2, exhibits typical morphologic and immunohistochemical characteristics of MC. V54/2 cells seeded in the scaffold were able to survive, proliferate, and secrete significant amounts of vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) during 2 weeks in vitro. To induce dermal regeneration, scaffolds with or without cells were transplanted in a nude mice full skin defect model. After 2 weeks of transplantation, scaffolds seeded with V54/2 cells showed more vascularization during the dermal regeneration process than controls, and the presence of human cells in the regenerating tissue was detected by immunohistochemistry. To confirm if local presence of angiogenic growth factors is sufficient to induce neovascularization, scaffolds were loaded with VEGF and bFGF and used to induce dermal regeneration in vivo. Results showed that scaffolds supplemented with growth factors were significantly more vascularized than control scaffolds (scaffolds without growth factors). The present work suggests that combined use of MC and bioartificial scaffolds induces therapeutic angiogenesis during the scaffold-based dermal regeneration process.     

Fibrin-based scaffold incorporating VEGF- and bFGF-loaded nanoparticles stimulates wound healing in diabetic mice

Diabetic skin ulcers are difficult to heal spontaneously due to the reduced levels and activity of endogenous growth factors. Recombinant human vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) are known to stimulate cell proliferation and accelerate wound healing. Direct delivery of VEGF and bFGF at the wound site in a sustained and controllable way without loss of bioactivity would enhance their biological effects. The aim of this study was to develop a poly(ether)urethane–polydimethylsiloxane/fibrin-based scaffold containing poly(lactic-co-glycolic acid) (PLGA) nanoparticles loaded with VEGF and bFGF (scaffold/GF-loaded NPs) and to evaluate its wound healing properties in genetically diabetic mice (db/db). The scaffold application on full-thickness dorsal skin wounds significantly accelerated wound closure at day 15 compared to scaffolds without growth factors (control scaffold) or containing unloaded PLGA nanoparticles (scaffold/unloaded NPs). However, the closure rate was similar to that observed in mice treated with scaffolds containing free VEGF and bFGF (scaffold/GFs). Both scaffolds containing growth factors induced complete re-epithelialization, with enhanced granulation tissue formation/maturity and collagen deposition compared to the other groups, as revealed by histological analysis. The ability of the scaffold/GF-loaded NPs to promote wound healing in a diabetic mouse model suggests its potential use as a dressing in patients with diabetic foot ulcers.     

In Vitro Release of Dexamethasone or bFGF from Chitosan/Hydroxyapatite Scaffolds

Chitosan scaffolds containing dexamethasone (Dex) or basic fibroblast growth factor (bFGF) were developed to create alternative drug-delivery systems for possible tissue-engineering applications such as periodontal bone regeneration. Chitosan solutions (2% and 3% (w/v) in acetic acid) were prepared from chitosan flakes with high deacetylation degree (>85%), then these solutions were freeze-dried at –80°C to obtain scaffolds with interconnected pore structures. Dex and bFGF were incorporated into scaffolds by embedding method (solvent sorption method). The initial loading amounts were varied as 300, 600 and 900 ng Dex per dry scaffold (average dry weight is 3 mg) and 50 or 100 ng bFGF per dry scaffold to a range of deliverable doses. Release studies which were conducted in Dulbecco's phosphate-buffered saline (DPBS) showed that 900 ng Dex loaded chitosan scaffolds in both compositions released total Dex during a 5-day period at a nearly constant rate after the initial burst. However, bFGF release from all scaffolds with both loading amounts (50 ng or 100 ng) was completed in 10 or 20 h. In order to prolong the release period of bFGF, composite scaffolds were fabricated in the presence of hydroxyapatite (HA) beads with average particle size of 40 μm. Sustained release of bFGF up to 7 days was achieved due to the electrostatic interactions between HA and bFGF molecules. These results suggested that chitosan scaffolds can be suitable for Dex release; however, the presence of HA in the chitosan scaffold is necessary to achieve the desired release period for bFGF.     

Therapeutic efficacy of antibiotic-loaded gelatin microsphere/silk fibroin scaffolds in infected full-thickness burns

Despite advances in burn treatment, burn infection remains a major cause of morbidity and mortality. In this study, an antibacterial silk fibroin (SF) scaffold for burn treatment was designed; gelatin microspheres (GMs) were impregnated with the antibiotic gentamycin sulfate (GS), and the GS-impregnated GMs were then embedded in a SF matrix to fabricate GS/GM/SF scaffolds. The developed GS/GM/SF scaffolds could serve as a dermal regeneration template in full-thickness burns. The average pore size and porosity of the GS/GM/SF scaffolds were 40–80 μm and 85%, respectively. Furthermore, the drug release rate of the scaffolds was significantly slower than that of either GS/GM or GS/SF scaffolds. And the composite scaffold exhibited stronger antimicrobial activities against Escherichia coli, Staphylococcus aureus and Pseudomonas aeruginosa. Hence, we evaluated the wound-healing effects and antibacterial properties of the GS/GM/SF scaffolds in a rat full-thickness burn infection model. Over 21 days, the GS/GM/SF scaffolds not only significantly reduced burn infection by P. aeruginosa but also accelerated the regeneration of the dermis and exhibited higher epithelialization rates than did GS/SF and SF scaffolds. Thus, GS/GM/SF scaffolds are potentially effective for treatment of full-thickness infected burns, and GS/GM/SF scaffolds are a promising therapeutic tool for severely burned patients.     

Tailored design of electrospun composite nanofibers with staged release of multiple angiogenic growth factors for chronic wound healing

The objective of this research study is to develop a collagen (Col) and hyaluronic acid (HA) inter-stacking nanofibrous skin equivalent substitute with the programmable release of multiple angiogenic growth factors (vascular endothelial growth factor (VEGF), platelet-derived growth factor (PDGF), basic fibroblast growth factor (bFGF) and endothelial growth factor (EGF)) either directly embedded in the nanofibers or encapsulated in the gelatin nanoparticles (GNs) by electrospinning technology. The delivery of EGF and bFGF in the early stage is expected to accelerate epithelialization and vasculature sprouting, while the release of PDGF and VEGF in the late stage is with the aim of inducing blood vessels maturation. The physiochemical characterizations indicate that the Col–HA–GN nanofibrous membrane possesses mechanical properties similar to human native skin. The design of a particle-in-fiber structure allows growth factors for slow controlled release up to 1 month. Cultured on biodegradable Col–HA membrane with four kinds of growth factors (Col–HA w/4GF), endothelial cells not only increase in growth rate but also form a better network with a thread-like tubular structure. The therapeutic effect of Col–HA w/4GF membrane on streptozotocin (STZ)-induced diabetic rats reveals an accelerated wound closure rate, together with elevated collagen deposition and enhanced maturation of vessels, as revealed by Masson’s trichrome stain and immunohistochemical analysis, respectively. From the above, the electrospun Col–HA–GN composite nanofibrous skin substitute with a stage-wise release pattern of multiple angiogenic factors could be a promising bioengineered construct for chronic wound healing in skin tissue regeneration.     

Effect of EGF and bFGF on Fibroblast Proliferation and Angiogenic Cytokine Production from Cultured Dermal Substitutes

Abstract

Growth factors accelerate wound healing but the underlying mechanisms remain poorly understood. The aim of this study was to investigate the effect of epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) on fibroblast proliferation and production of angiogenic factors from cultured dermal substitutes (CDS). In the first experiment, fibroblasts were seeded into a flask at a density of 1 × 10⁴ cells/cm².Cell proliferation was assessed after culturing in media containing EGF or bFGF at concentrations ranging from 2 to 50 μg. The number of fibroblasts increased significantly in the presence of EGF or bFGF, but fibroblasts detached from the flasks in the presence of 50 μg bFGF. In the second experiment, CDS were prepared by incorporating fibroblasts into collagen gels. To make a wound surface model, the CDS was elevated to the air–liquid interface, on which a spongy sheet of hyaluronic acid (HA) containing EGF or bFGF was placed. The amount of vascular endothelial growth factor (VEGF) and hepatocyte growth factor (HGF) released from the CDS after 1 week of cultivation was measured by ELISA. When the CDS was covered with a HA sponge containing EGF (Group 1), fibroblasts released 3.5-times more VEGF compared with a HA-alone sponge (control group). When covered with a HA sponge containing bFGF (Group 2), 8.7-times more VEGF was released compared with the control group. Fibroblasts in Groups 1 and 2 released 9.6- and 9.3-times more HGF, respectively, compared with the control group. Thus, EGF stimulates fibroblasts to produce VEGF and HGF, in addition to its ability to enhance epidermal cell proliferation.     

Human basic fibroblast growth factor fused with Kringle4 peptide binds to a fibrin scaffold and enhances angiogenesis

Appropriate three-dimensional (3D) scaffolds and signal molecules could accelerate tissue regeneration and wound repair. In this work, we targeted human basic fibroblast growth factor (bFGF), a potent angiogenic factor, to a fibrin scaffold to improve therapeutic angiogenesis. We fused bFGF to the Kringle4 domain (K4), a fibrin-binding peptide from human plasminogen, to endow bFGF with specific fibrin-binding ability. The recombinant K4bFGF bound specifically to the fibrin scaffold so that K4bFGF was delivered in a site-specific manner, and the fibrin scaffold provided 3D support for cell migration and proliferation. Subcutaneous implantation of the fibrin scaffolds bound with K4bFGF but not with bFGF induced neovascularization. Immunohistochemical analysis showed significantly more proliferation cells in the fibrin scaffolds incorporated with K4bFGF than in those with bFGF. Moreover, the regenerative tissues were integrated well with the fibrin scaffolds, suggesting its good biocompatibility. In summary, targeted delivery of K4bFGF could potentially improve therapeutic angiogenesis.     

Preparation and characterization of bionic bone structure chitosan/hydroxyapatite scaffold for bone tissue engineering

Three-dimensional oriented chitosan (CS)/hydroxyapatite (HA) scaffolds were prepared via in situ precipitation method in this research. Scanning electron microscopy (SEM) images indicated that the scaffolds with acicular nano-HA had the spoke-like, multilayer and porous structure. The SEM of osteoblasts which were polygonal or spindle-shaped on the composite scaffolds after seven-day cell culture showed that the cells grew, adhered, and spread well. The results of X-ray powder diffractometer and Fourier transform infrared spectrometer showed that the mineral particles deposited in the scaffold had phase structure similar to natural bone and confirmed that particles were exactly HA. In vitro biocompatibility evaluation indicated the composite scaffolds showed a higher degree of proliferation of MC3T3-E1 cell compared with the pure CS scaffolds and the CS/HA10 scaffold was the highest one. The CS/HA scaffold also had a higher ratio of adhesion and alkaline phosphate activity value of osteoblasts compared with the pure CS scaffold, and the ratio increased with the increase of HA content. The ALP activity value of composite scaffolds was at least six times of the pure CS scaffolds. The results suggested that the composite scaffolds possessed good biocompatibility. The compressive strength of CS/HA15 increased by 33.07% compared with the pure CS scaffold. This novel porous scaffold with three-dimensional oriented structure might have a potential application in bone tissue engineering.     

Optimization and evaluation of silk fibroin-chitosan freeze-dried porous scaffolds for cartilage tissue engineering application

Silk fibroin/chitosan blend has been reported to be an attractive biomaterial that provides a 3D porous structure with controllable pore size and mechanical property suitable for tissue engineering applications. However, there is no systematic study for optimizing the ratio of silk fibroin (SF) and chitosan (CS) which seems to influence the scaffold property to a great extent. The present research, therefore, investigates the effect of blend ratio of SF and CS on scaffold property and establishes the optimum value of blend ratio. Among the various blends, the scaffolds with blend ratio of SF/CS (80:20) were found to be superior. The scaffold possesses pore size in the range 71–210 μm and porosity of 82.2 ± 1.3%. The compressive strength of the scaffold was measured as 190 ± 0.2 kPa. The cell supportive property of the scaffold in terms of cell attachment, cell viability, and proliferation was confirmed by cell culture study using mesenchymal stem cells derived from umbilical cord blood. Furthermore, the assessment of glycosaminoglycan secretion on the scaffolds indicates its potentiality toward cartilage tissue regeneration.     

Bioactivation of dermal scaffolds with a non-viral copolymer-protected gene vector

The use of scaffolds in skin tissue engineering is accompanied with low regeneration rates and high risk of infection. In this study, we activated an FDA-approved collagen scaffold for dermal regeneration by incorporation of copolymer-protected gene vectors (COPROGs) to induce a temporary release of VEGF. In vitro results show that the presence of COPROGs did not affect the distribution, attachment, proliferation and viability of cells in the scaffold. A transient release of VEGF was observed for up to 3 weeks. Moreover a high amount of VEGF was also found in the cells and associated with the scaffold. In a full skin defect model in nude mice, VEGF levels were significantly increased compared to controls in VEGF gene activated scaffolds 14 d after implantation, but not in skin from the wound edge. Results showed an increased amount of non-adherent cells, especially erythrocytes, and von Willebrandt factor (vWF) and a yellow red appearance of gene activated scaffolds in relation to controls. This suggests the presence of leaky vessels. In this work we show that the bioactivation of collagen scaffolds with COPROGs presents a new technology that allows a local release of therapeutic proteins thus enhancing the regenerative potential in vivo.     

多孔HA/PU复合支架材料生物相容性的评估

进行了三维多孔立体结构的纳米羟基磷灰石/聚氨酯(HA/PU)复合支架材料体外细胞培养和体内肌肉埋植实验研究,评估材料的生物相容性。实验选用SD大鼠的骨髓基质干细胞(BMSCs)和健康的SD雌性大鼠,进行细胞相容性、形态学观察和组织学切片分析。HA/PU支架材料的多孔性为细胞的生长提供了良好的微环境,细胞在内部贴壁爬行、增殖并分化,细胞毒性为零级,材料与周围组织有良好的结合,降解的空间有结缔组织纤维长入。实验表明,HA/PU复合支架材料具有良好的细胞亲和性和组织学相容性,可作为一类新型组织工程支架材料。     

Sustained release of vascular endothelial growth factor from mineralized poly(lactide-co-glycolide) scaffolds for tissue engineering

Strategies to engineer bone tissue have focused on either: (1) the use of scaffolds for osteogenic cell transplantation or as conductive substrates for guided bone regeneration; or (2) release of inductive bioactive factors from these scaffold materials. This study describes an approach to add an inductive component to an osteoconductive scaffold for bone tissue engineering. We report the release of bioactive vascular endothelial growth factor (VEGF) from a mineralized, porous, degradable polymer scaffold. Three dimensional, porous scaffolds of the copolymer 85 : 15 poly(lactide-co-glycolide) were fabricated by including the growth factor into a gas foaming/particulate leaching process. The scaffold was then mineralized via incubation in a simulated body fluid. Growth of a bone-like mineral film on the inner pore surfaces of the porous scaffold is confirmed by mass increase measurements and quantification of phosphate content within scaffolds. Release of ¹²⁵I-labeled VEGF was tracked over a 15 day period to determine release kinetics from the mineralized scaffolds. Sustained release from the mineralized scaffolds was achieved, and growth of the mineral film had only a minor effect on the release kinetics from the scaffolds. The VEGF released from the mineralized and non-mineralized scaffolds was over 70% active for up to 12 days following mineralization treatment, and the growth of mineral had little effect on total scaffold porosity.     

The effect of collagen-targeting platelet-derived growth factor on cellularization and vascularization of collagen scaffolds

Platelet-derived growth factor BB (PDGF-BB) was an important inductive factor during wound healing, but the lack of efficient delivery system limited its clinical application. Here, a peptide of seven amino acids was firstly utilized to engineer PDGF-BB to construct a collagen-targeting system. This peptide functioned as collagen-binding domain (CBD) to specially target the PDGF-BB to the collagen and restrict its diffusion. In our study, in vitro activity assay showed that the CBD-fused PDGF (CBD-PDGF) and native PDGF (NAT-PDGF) possessed similar activity to stimulate the human fibroblast proliferation. As expected, this peptide promoted the binding of PDGF to collagen scaffolds, and CBD-PDGF caused more cells to proliferate on the collagen gel than NAT-PDGF when the same amounts of PDGF were added. In the in vivo experiment, CBD-PDGF-loaded collagen scaffolds were uniformly cellularized and vascularized compared to that of NAT-PDGF-loaded scaffolds. Our study demonstrated that the CBD targeted PDGF to the collagen scaffold to exert its functions, and it suggested this could be an effective system for targeting tissue regeneration and wound repair.     

Preparation and characterization of nano-hydroxyapatite/silk fibroin porous scaffolds

Novel tissue engineering scaffold materials of nano-hydroxyapatite (nHA)/silk fibroin (SF) biocomposite were prepared by freeze-drying. The needle-like nHA crystals of about 10 nm in diameter by 50–80 nm in length, which were uniformly distributed in the porous nHA/SF scaffolds, were prepared by a co-precipitation method with a size. The as-prepared nHA/SF scaffolds showed good homogeneity, interconnected pores and high porosity. XRD and FT-IR analysis suggested that the silk fibroin was in β-sheet structure, which usually provides outstanding mechanical properties for silk materials. In this work, composite scaffolds containing as high as 70% (w/w) nHA were prepared, which had excellent compressive modulus and strength, higher than the scaffolds at low nHA content level and other porous biodegradable polymeric scaffolds often considered in bone-related tissue engineering reported previously. The cell compatibility of composite scaffolds was evaluated through cell viability by MTT assay. All these results indicated that these nHA/SF scaffold materials may be a promising biomaterial for bone tissue engineering.     

Immunohistochemical expression of growth factors in subacute thyroiditis and their effects on thyroid folliculogenesis and angiogenesis in collagen gel matrix culture

The inflammatory-mechanistic basis of subacute thyroiditis remains unclear. To elucidate the roles of vascular endothelial cell growth factor (VEGF), basic fibroblast growth factor (bFGF), platelet-derived growth factor-BB (PDGF), transforming growth factor-β1 (TGF-β1) and epidermal growth factor (EGF) in the inflammatory process, their immunoexpression was examined in biopsy specimens of ten cases. At the granulomatous stage, all cases expressed VEGF, bFGF, PDGF, and TGF-β1 in monocytes/macrophages infiltrating into follicle lumina, and in both epithelioid histiocytes and multinucleated giant cells of the granulomas. In fibroblasts and endothelial cells around the granulomas, all cases displayed VEGF, bFGF, and PDGF, but TGF-β1 was detected only in fibroblasts in two cases. No cases expressed EGF in any of the above cell types. At the regenerative stage, all cases expressed VEGF, bFGF, and EGF in regenerating thyrocytes, whereas three and no cases displayed PDGF and TGF-β1, respectively. Ten, seven and six cases expressed PDGF in fibroblasts, endothelial cells, and monocytes, respectively. In these cell types, all cases expressed VEGF and bFGF, whereas no cases displayed TGF-β1 and EGF. To estimate the roles of these growth factors in thyroid tissue regeneration, their effects on thyroid folliculogenesis and angiogenesis were examined using collagen gel culture of thyrocytes and endothelial cells, respectively. Cell proliferation was also studied by bromodeoxyuridine (BrdU) uptake. EGF decreased follicle formation and TGF-β1 drastically inhibited it, but the others had no effect. VEGF showed the greatest effect on vessel formation, although all of the others promoted it. EGF and VEGF or bFGF caused the highest BrdU uptake in thyrocytes and endothelial cells, respectively. The data suggest firstly, that at the granulomatous stage of subacute thyroiditis, growth factor-rich monocytes/macrophages infiltrating into follicle lumina trigger the granulomatous reaction, and VEGF, bFGF, PDGF, and TGF-β1 produced by the stromal cell types tested mediate the reaction; secondly, that at the regenerative stage, EGF serves follicle regeneration through its mitogenic effect on thyrocytes, although some cofactors with EGF are involved in folliculogenesis and the decreased expression of TGF-β1, a fibrogenic factor, contributes to thyroid tissue repair; and thirdly, that VEGF and bFGF are more responsible for the angiogenesis at both stages than the other factors studied. Copyright © 1999 John Wiley & Sons, Ltd.     

Preparation and characterisation of vancomycin-impregnated gelatin microspheres/silk fibroin scaffold

A type of antibacterial silk fibroin (SF) scaffold was developed and characterised as a potential functional wound dressing for acute trauma treatment. To achieve this, SF solution was mixed with previously fabricated vancomycin (Vm)-loaded gelatin (G) microspheres, followed by a freeze-drying step. Some physical and antimicrobial properties of the prepared Vm/G/SF scaffolds were investigated and the results demonstrated that the average pore size and porosity of the composite scaffold were 60–80?μm and 75%, respectively. The compressive stress and compressive modulus of Vm/G/SF scaffold were 140 and 468?KPa, respectively. Compared with Vm/G microspheres and Vm/SF scaffold, the Vm/G/SF scaffold has slower release rate of Vm. In addition, the Vm release rate of Vm/G/SF scaffold matched well with the degradation rate of SF scaffold. With respect to the antimicrobial effect, the results showed that the Vm/G/SF scaffold had good antimicrobial activity against Staphylococcus aureus (gram-positive), which is a gram-positive bacteria commonly found in infected wounds.     

In vitro cultivation of canine multipotent mesenchymal stromal cells on collagen membranes treated with hyaluronic acid for cell therapy and tissue regeneration

Support structures for dermal regeneration are composed of biodegradable and bioresorbable polymers, animal skin or tendons, or are bacteria products. The use of such materials is controversial due to their low efficiency. An important area within tissue engineering is the application of multipotent mesenchymal stromal cells (MSCs) to reparative surgery. The combined use of biodegradable membranes with stem cell therapy may lead to promising results for patients undergoing unsuccessful conventional treatments. Thus, the aim of this study was to test the efficacy of using membranes composed of anionic collagen with or without the addition of hyaluronic acid (HA) as a substrate for adhesion and in vitro differentiation of bone marrow-derived canine MSCs. The benefit of basic fibroblast growth factor (bFGF) on the differentiation of cells in culture was also tested. MSCs were collected from dog bone marrow, isolated and grown on collagen scaffolds with or without HA. Cell viability, proliferation rate, and cellular toxicity were analyzed after 7 days. The cultured cells showed uniform growth and morphological characteristics of undifferentiated MSCs, which demonstrated that MSCs successfully adapted to the culture conditions established by collagen scaffolds with or without HA. This demonstrates that such scaffolds are promising for applications to tissue regeneration. bFGF significantly increased the proliferative rate of MSCs by 63% when compared to groups without the addition of the growth factor. However, the addition of bFGF becomes limiting, since it has an inhibitory effect at high concentrations in culture medium.     

Gradient nanofibrous chitosan/poly ɛ-caprolactone scaffolds as extracellular microenvironments for vascular tissue engineering

One of the major challenges of tissue-engineered small-diameter blood vessels is restenosis caused by thrombopoiesis. The goal of this study was to develop a 3D gradient heparinized nanofibrous scaffold, aiding endothelial cells lined on the lumen of blood vessel to prevent thrombosis. The vertical graded chitosan/poly ?-caprolactone (CS/PCL) nanofibrous vessel scaffolds were fabricated with chitosan and PCL by sequential quantity grading co-electrospinning. To mimic the natural blood vessel microenvironment, we used heparinization and immobilization of vascular endothelial growth factor (VEGF) in the gradient CS/PCL. The quantity of heparinized chitosan nanofibers increased gradually from the tunica adventitia to the lumen surfaces in the gradient CS/PCL wall of tissue engineered vessel. More heparin reacted to chitosan nanofiber in gradient CS/PCL than in uniform CS/PCL nanofibrous scaffolds. Antithrombogenic properties of the scaffolds were enhanced by the heparinization of these scaffolds, as shown by activated partial thromboplastin time and platelet adhesion assay. Compared to the uniform CS/PCL scaffold, the release of VEGF from the gradient CS/PCL was more stable and sustained, and the burst release of VEGF was reduced approximately 42.5% within the initial 12 h. The adhesion and proliferation of human umbilical vein endothelial cells (HUVEC) were enhanced on the gradient CS/PCL scaffold. Furthermore, HUVEC grew and formed an entire monolayer on the top side of the gradient CS/PCL scaffold. Therefore, use of vertical gradient heparinized CS/PCL nanofibrous scaffolds could provide an approach to create small-diameter blood vessel grafts with innate properties of mammalian vessels of anticoagulation and rapid induction of re-endothelialization.     

Biological characterization of EDC-crosslinked collagen-hyaluronic acid matrix in dermal tissue restoration

Porous collagen matrices crosslinked with various amounts of hyaluronic acid (HA) by 1-ethyl-3-(3-dimethyl aminopropyl)carbodiimide (EDC) were developed as scaffolds for dermal tissue regeneration. The effect of HA on cells in accordance with HA concentrations in the collagenous matrices was investigated using cultures of fetal human dermal fibroblasts, and the effect of EDC-crosslinked collagen-HA matrix on wound size reduction was also evaluated in vivo. Scanning electron microscopic views of the matrices demonstrated that all of the collagen-HA matrices had interconnected pores with mean diameters of 150-250 microm. An HA matrix retention test showed that the concentration of HA decreased slowly after an initial rapid decrease over 24h. Fetal human dermal fibroblasts adhered well to all of the collagen-based matrices as compared with the Porous polyurethane matrix used as a control. An 3-(4,5-dimethylthiazolyl)-2,5-diphenyltetrazolium bromide based proliferation test and the hematoxylin and eosin staining of a 2 week cultured matrix showed that the proliferation of fibroblasts was enhanced on a 9.6% HA contained collagen matrix. No significant difference was in terms of fibroblast migration into the various types of scaffolds as HA content was increased. In vivo testing showed that dermis treated with collagen or collagen-HA matrix was thicker than the control, and epithelial regeneration was accelerated, and collagen synthesis increased. However, no significant effect of HA on wound size reduction was found.     

基于丝素/胶原/羟基磷灰石仿生骨材料的多维结构及其性能

目的 体外构建丝素蛋白（silk fibroin,SF）、I型胶原(type I collagen,Col-I)和羟基磷灰石(hydroxyapatite, HA)共混体系制备二维复合膜和三维仿生支架,研究其理化性质和生物相容性,探讨其在组织工程支架材料中应用的可行性。方法 通过在细胞培养小室底部共混SF/Col-I/HA以及低温3D打印结合真空冷冻干燥法制备二维复合膜及三维支架。通过机械性能测试、电子显微镜和Micro-CT检测材料的理化性质,检测细胞的增殖评估其生物相容性。结果 通过共混和低温3D打印获得稳定的二维复合膜及三维多孔结构支架;力学性能具有较好的一致性,孔径、吸水率、孔隙率和弹性模量均符合构建组织工程骨的要求;支架为网格状的白色立方体,内部孔隙连通性较好; HA均匀分布在复合膜中,细胞黏附在复合膜上,呈扁平状;细胞分布在支架孔壁周围,呈梭形状,生长及增殖良好。结论 利用SF/Col-I/HA共混体系成功制备复合膜及三维支架,具有较好的孔连通性与孔结构,有利于细胞和组织的生长以及营养输送,其理化性能以及生物相容性符合骨组织工程生物材料的要求。