Comparison of the properties of collagen–chitosan scaffolds after γ-ray irradiation and carbodiimide cross-linking

The property of collagen–chitosan porous scaffold varies according to cross-linking density and scaffold composition. This study was designed to compare the properties of collagen–chitosan porous scaffolds cross-linked with γ-irradiation and carbodiimide (CAR) for the first time. Eleven sets of collagen–chitosan scaffolds containing different concentrations of chitosan at a 5% increasing gradient were fabricated. Fourier transform infrared spectroscopy was performed to confirm the success of cross-linking in the scaffolds. The scaffold morphology was evaluated under scanning electron microscope (SEM). SEM revealed that chitosan was an indispensable material for the fabrication of γ-ray irradiation scaffold. The microstructure of γ-ray irradiation scaffold was less stable than those of alternative scaffolds. Based upon swelling ratio, porosity factor, and collagenase degradation, γ-ray irradiation scaffold was less stable than CAR and 25% proportion of chitosan scaffolds. Mechanical property determines the orientation in γ-irradiation and CAR scaffold. In vitro degradation test indicated that γ-irradiation and CAR cross-linking can elevate the scaffold biocompatibility. Compared with γ-ray irradiation, CAR cross-linked scaffold containing 25% chitosan can more significantly enhance the bio-stability and biocompatibility of collagen–chitosan scaffolds. CAR cross-linked scaffold may be the best choice for future tissue engineering.     

Heparin-modified dendrimer cross-linked collagen matrices for the delivery of basic fibroblast growth factor (FGF-2)

Tissue integration between a tissue-engineered corneal equivalent and the host eye is of critical importance in ensuring long-term implant success. A novel dendrimer cross-linked collagen scaffold has previously shown good corneal epithelial cell compatibility in vitro particularly when the highly functional dendrimer cross-linkers were functionalized to introduce additional biological groups. Herein we investigated heparinization of these materials and their potential to facilitate the delivery of basic fibroblast growth factor (FGF-2) in an active form, ultimately for use as a corneal tissue scaffold. Collagen gels cross-linked with 1-ethyl-3-(3-dimethyl aminopropyl) carbodiimide hydrochloride (EDC) and N-hydroxysuccinimide (NHS) chemistry, and varying amounts of polypropyleneimine octaamine generation 2 (G2) dendimer and heparin were synthesized. Swelling studies and differential scanning calorimetry characterization indicated higher gel stability with the introduction of dendrimer cross-linking, which was not compromised by heparin integration. Dendrimer cross-linked gels with or without heparin gave multiple denaturation peaks, as did the heparinized EDC gels. This is thought to be the result of the heterogeneous cross-linking possible between collagen, the dendrimer and heparin. Release of FGF-2 from collagen gels showed typical first-order kinetics, with an initial burst followed by a prolonged gradual release. Heparinized dendrimer cross-linked gels released approx. 40% of the growth factor over a 2-week period, with significance maintenance of growth factor activity. Incorporation of heparin resulted in somewhat prolonged release from these systems.     

Heparin-modified dendrimer cross-linked collagen matrices for the delivery of basic fibroblast growth factor (FGF-2)

Tissue integration between a tissue-engineered corneal equivalent and the host eye is of critical importance in ensuring long-term implant success. A novel dendrimer cross-linked collagen scaffold has previously shown good corneal epithelial cell compatibility in vitro particularly when the highly functional dendrimer cross-linkers were functionalized to introduce additional biological groups. Herein we investigated heparinization of these materials and their potential to facilitate the delivery of basic fibroblast growth factor (FGF-2) in an active form, ultimately for use as a corneal tissue scaffold. Collagen gels cross-linked with 1-ethyl-3-(3-dimethyl aminopropyl) carbodiimide hydrochloride (EDC) and N-hydroxysuccinimide (NHS) chemistry, and varying amounts of polypropyleneimine octaamine generation 2 (G2) dendimer and heparin were synthesized. Swelling studies and differential scanning calorimetry characterization indicated higher gel stability with the introduction of dendrimer cross-linking, which was not compromised by heparin integration. Dendrimer cross-linked gels with or without heparin gave multiple denaturation peaks, as did the heparinized EDC gels. This is thought to be the result of the heterogeneous cross-linking possible between collagen, the dendrimer and heparin. Release of FGF-2 from collagen gels showed typical first-order kinetics, with an initial burst followed by a prolonged gradual release. Heparinized dendrimer cross-linked gels released approx. 40% of the growth factor over a 2-week period, with significance maintenance of growth factor activity. Incorporation of heparin resulted in somewhat prolonged release from these systems.     

京尼平交联3D打印胶原/壳聚糖支架的表征北大核心

背景:胶原/壳聚糖支架需交联才能达到相应力学性能,有研究表示调节交联剂浓度可以在一定范围内调控支架的理化性能。目的:探究京尼平浓度对胶原/壳聚糖支架理化性能的影响,制备理化性能可调节的组织工程支架。方法:将胶原和壳聚糖粉末分别溶于弱酸后混合均匀,作为打印墨水,利用生物3D打印机低温打印胶原支架与胶原/壳聚糖支架,经冻干、中和处理后分别以1,3,5 mmol/L的京尼平进行交联。检测各组支架的表观结构稳定性、抗拉能力、溶胀性能、降解性能与生物相容性。结果与结论:①将支架在PBS中浸泡3 d后,对比未交联的冻干支架,交联后胶原支架表面维持规则的孔结构,但是支架出现明显变形;交联后胶原/壳聚糖支架表面结构规则,仅1 mmol/L京尼平交联的胶原/壳聚糖支架存在轻微变形。②随着京尼平浓度的增加,各组支架的力学性能增加,并且对应交联浓度下的胶原/壳聚糖支架力学性能好于胶原支架。③随着京尼平浓度的增加,胶原支架的溶胀率下降,胶原/壳聚糖支架的溶胀率无明显变化。④浸泡于胶原酶溶液中后,不同浓度京尼平交联的胶原支架在1 h内被完全降解,胶原/壳聚糖支架的降解速率随京尼平浓度的增加而降低,均呈现先快速后平缓的趋势。⑤将骨髓间充质干细胞接种于各组交联支架3 d后,1,3 mmol/L京尼平交联的胶原/壳聚糖支架(或胶原支架)上的细胞数量明显多于5 mmol/L京尼平交联的胶原/壳聚糖支架(P<0.05)。⑥结果表明,京尼平可在一定范围调节胶原/壳聚糖支架理化性能,其中3 mmol/L京尼平交联的胶原/壳聚糖支架具有较好的力学性能、抗酶解能力与生物相容性。     

Orthogonal scaffold of magnetically aligned collagen lamellae for corneal stroma reconstruction

The creation of 3D scaffolds that mimic the structure of physiological tissue required for normal cell function is a major bioengineering challenge. For corneal stroma reconstruction this necessitates the creation of a stroma-like scaffold consisting of a stack of orthogonally disposed sheets of aligned collagen fibrils. This study demonstrates that such a scaffold can be built up using magnetic alignment. By allowing neutralized acid-soluble type I collagen to gel in a horizontal magnetic field (7 T) and by combining a series of gelation-rotation-gelation cycles, a scaffold of orthogonal lamellae composed of aligned collagen fibrils has been formed. Although initially dilute, the gels can be concentrated without noticeable loss in orientation. The gels are translucent but their transparency can be greatly improved by the addition of proteoglycans to the gel-forming solution. Keratocytes align by contact guidance along the direction of collagen fibrils and respect the orthogonal design of the collagen template as they penetrate into the bulk of the 3D matrix. The scaffold is a significant step towards the creation of a corneal substitute with properties resembling those of native corneal stroma.     

Dendrimer crosslinked collagen as a corneal tissue engineering scaffold: mechanical properties and corneal epithelial cell interactions

Generation 2 polypropyleneimine octaamine dendrimers were used to generate highly crosslinked collagen with mechanical properties that would make it appropriate for use as a corneal tissue-engineering scaffold. Crosslinking of a highly concentrated collagen solution (2-4%) was effected using the water-soluble carbodiimide 1-ethyl-3-(3-dimethyl aminopropyl) carbodiimide hydrochloride (EDC). The multifunctional dendrimers were introduced as novel multifunctional crosslinkers after the activation of the carboxylic acid groups of glutamic and aspartic acid residues in collagen. Glutaraldehyde, a common collagen crosslinker, was used as comparison, as was EDC, itself an alternative crosslinker, which forms "zero-length or self-crosslinking". The mechanical properties resultant gels were determined. Young's modulus of the dendrimer crosslinked gels was significantly higher than that observed with the other crosslinkers, increasing to 5 MPa compared with 0.1 MPa for the EDC crosslinked gels. Transmission electron microscopy (TEM) analysis of the gels demonstrated the presence of fibrils in the thermally gelled collagen controls; no fibrils were observed in the dendrimer crosslinked gels. As a result, the optical transparency of the dendrimer crosslinked collagen was significantly better than that of the collagen thermal gels. The EDC and glutaraldehyde crosslinked gels were generally less transparent than those crosslinked with the dendrimers. Glucose permeation results demonstrated that the dendrimer crosslinked collagen had higher glucose permeability than natural human cornea. Dendrimer crosslinked collagen gels supported human corneal epithelial cell growth and adhesion, with no cell toxicity. In comparison, some potentially cytotoxic effects were observed with glutaraldehyde crosslinked collagen. Overall, the dendrimer crosslinked collagen gels showed promising properties that suggest that these might be suitable scaffolds for corneal tissue engineering and potentially other tissue engineering applications.     

Compressed collagen gel as the scaffold for skin engineering

Collagen gel scaffolds can potentially be utilized as cell seeded systems for skin tissue engineering. However, its dramatic contraction after being mixed with cells and its mechanical weakness are the drawbacks for its application to skin engineering. In this study, a compressed collagen gel scaffold was fabricated through the rapid expulsion of liquid from reconstituted gels by the application of ‘plastic compression’(PC) technique. Both compressed and uncompressed gels were characterized with their gel contraction rate, morphology, the viability of seeded cells, their mechanical properties and the feasibility as a scaffold for constructing tissue-engineered skin. The results showed that the compression could significantly reduce the contraction of the collagen gel and improve its mechanical property. In addition, seeded dermal fibroblasts survived well in the compressed gel and seeded epidermal cells gradually developed into a stratified epidermal layer, and thus formed tissue engineered skin. This study reveals the potential of using compressed collagen gel as a scaffold for skin engineering.     

The modification of scaffold material in building artificial dermis

Type X collagen is principal extracellular matrix (ECM) in natural dermis. To prepare artificial dermis, collagen is traditional, and most superior biomaterial. But beside collagen, the dermis also contains many other ECM. Among them, glycosaminoglycan (GAG) is another important substance. To imitate the natural dermis, and modificate the scaffold materials, two types of scaffolds were prepared: one is traditional type X collagen spongy scaffold, the other is collagen-chondroitin sulfate (CS) spongy scaffold. Collagen was blended with CS, one kind of GAG, and cross-linked by 1-ethyl-3-(3-dimethyl aminopropyl) carbodiimide (EDC). Dermis fibroblast was isolated from neonate prepuce, and dermis fibroblasts were cultured on the scaffolds. The physical and chemical properties of the scaffolds were tested, including SEM, DSC, H&E staining, immunohistochemical staining and CS content analysis and so on. The results indicated that EDC is an effective and non-cytotoxic cross-link reagent, and attaching CS into collagen scaffold could improve the stability and histocompatibility of scaffold.     

Collagen/chitosan porous scaffolds with improved biostability for skin tissue engineering

Porous scaffolds for skin tissue engineering were fabricated by freeze-drying the mixture of collagen and chitosan solutions. Glutaraldehyde (GA) was used to treat the scaffolds to improve their biostability. Confocal laser scanning microscopy observation confirmed the even distribution of these two constituent materials in the scaffold. The GA concentrations have a slight effect on the cross-section morphology and the swelling ratios of the cross-linked scaffolds. The collagenase digestion test proved that the presence of chitosan can obviously improve the biostability of the collagen/chitosan scaffold under the GA treatment, where chitosan might function as a cross-linking bridge. A detail investigation found that a steady increase of the biostability of the collagen/chitosan scaffold was achieved when GA concentration was lower than 0.1%, then was less influenced at a still higher GA concentration up to 0.25%. In vitro culture of human dermal fibroblasts proved that the GA-treated scaffold could retain the original good cytocompatibility of collagen to effectively accelerate cell infiltration and proliferation. In vivo animal tests further revealed that the scaffold could sufficiently support and accelerate the fibroblasts infiltration from the surrounding tissue. Immunohistochemistry analysis of the scaffold embedded for 28 days indicated that the biodegradation of the 0.25% GA-treated scaffold is a long-term process. All these results suggest that collagen/chitosan scaffold cross-linked by GA is a potential candidate for dermal equivalent with enhanced biostability and good biocompatibility.     

Tailored laminin-332 α3 sequence is tethered through an enzymatic linker to a collagen scaffold to promote cellular adhesion

Surface modification techniques have been used to develop biomimetic scaffolds by incorporating cell adhesion peptides, which facilitates cell adhesion, migration and proliferation. In this study, we evaluated the cell adhesion properties of a tailored laminin-332 α3 chain tethered to a type I collagen scaffold using microbial transglutaminase (mTGase) by incorporating transglutaminase substrate peptide sequences containing either glutamine (peptide A: PPFLMLLKGSTREAQQIVM) or lysine (peptide B: PPFLMLLKGSTRKKKKG). The degree of cross-linking was studied by amino acid analysis following proteolytic digestion and the structural changes in the modified scaffold further investigated using Fourier transform infrared spectroscopy and atomic force microscopy. Fibroblasts were used to evaluate the cellular behaviour of the functionalized collagen scaffold. mTGase supports cell growth but tethering of peptide A and peptide B to the mTGase cross-linked collagen scaffold caused a significant increase in cell proliferation when compared with native and mTGase cross-linked collagen scaffolds. Both peptides enabled cell-spreading, attachment and normal actin cytoskeleton organization with slight increase in the cell proliferation was observed in peptide A when compared with the peptide B and mTGase cross-linked scaffold. An increase in the amount of ε(γ-glutamyl) lysine isopeptide was observed in peptide A conjugated scaffolds when compared with peptide B conjugated scaffolds, mTGase cross-linked scaffold without peptide. Changes in D-spacing were observed in the cross-linked scaffolds with tethered peptides. These results demonstrate that mTGase can play a bifunctional role in both conjugation of the glutamine and lysine containing peptide sequences and also in the cross-linking of the collagen scaffold, thus providing a suitable substrate for cell growth.     

聚乳酸-羟基乙酸输尿管支架植入后犬输尿管周围的组织学变化

背景：泌尿系统组织工程支架不仅需要生物相容性良好的生物材料,而且一定要利于组织周围细胞的生长。 目的：制备聚乳酸-羟基乙酸共聚物可降解输尿管支架,观察其植入后犬输尿管周围组织学变化。 方法：制备纳米聚乳酸-羟基乙酸共聚物输尿管支架,并以多聚赖氨酸对支架进行交联、改性,将交联后支架截成长约0.8 cm小段,植入犬损伤输尿管中进行体内观察实验。 结果与结论：①支架制备：支架具有纳米结构,孔隙率约90%,孔径(30±18) µm,多聚赖氨酸交联改性后纤维表面略显粗糙。②支架变化：支架植入30 d时已完全失去原始形态,与周边组织融合,可见裂解小块。③支架植入后输尿管周围组织学变化：植入后15 d炎症表现最为明显,主要是移行上皮脱落,肌层结构被破坏,固有层水肿明显;30 d后,炎症已经明显好转,但组织结构依然不规则;植入后45 d,输尿管全层组织基本恢复正常,组织结构成规则分布。说明聚乳酸-羟基乙酸共聚物输尿管支架具有良好的组织相容性,符合泌尿系统组织工程支架的要求。      

Photochemically cross-linked collagen gels as three-dimensional scaffolds for tissue engineering

Collagen gels have many favorable attributes for tissue engineering, but the gels undergo dramatic contraction when cells are added because of the weak noncovalent bonds that form during spontaneous gelation. We hypothesized that photochemically cross-linking collagen gels would make suitable scaffolds for tissue engineering with favorable cell viability and minimal gel contraction. Rose Bengal and riboflavin were chosen as candidate photo-initiators for gel cross-linking using 532- and 458-nm-light wavelengths, respectively. Chondrocyte viability was measured after initial gelation for several concentrations of initiators. Cell viability and gel contraction were then measured using chondrocytes and fibroblasts over 7 days of culture. Rose Bengal used at concentrations necessary for gelation resulted in little or no cell viability. Short-term viability results showed that 0.25- or 0.5-mM concentrations of riboflavin, and 40 s of illumination permitted more than 90% cell viability. Using riboflavin concentrations of 0.25 or 0.5 mM, long-term chondrocyte viability was 113.1 +/- 11.6% and 25.4 +/- 2.7%, respectively, at day 7. Although non-cross-linked chondrocyte constructs contracted to 59.9 +/- 11.8% of their original diameter and fibroblasts contracted to 24.9 +/- 5.0% of their original diameter by day 7, the cross-linked constructs retained 88.8 +/- 7.4% and 85.5 +/- 5.0% of the original diameter, respectively. In conclusion, by photochemically cross-linking collagen gels using riboflavin and visible light, stable gel scaffolds with favorable cell survival can be produced.     

Growth and metabolism of human hepatocytes on biomodified collagen poly(lactic-co-glycolic acid) three-dimensional scaffold

Hepatic tissue engineering offers a promising approach toward alleviating the need for donor liver, yet many challenges must be overcome including choice of scaffold, cell source, and immunologic barriers. Poly(lactic-co-glycolic acid) (PLGA) polymers are innovative biodegradable materials that have been shown to be useful as scaffolds for seeding and culturing various types of cells. In this study, a porous sponge scaffold of modified PLGA polymer with collagen was investigated for its ability to improve the growth and metabolism of human hepatocytes. We evaluated the biocompatibility of collagen-modified PLGA (C-PLGA) scaffolds with hepatocytes isolated from human liver. Cell adhesion and function (cell density, culture lifespan, albumin synthesis, urea synthesis, and ammonia elimination and diazepam clearance) were assessed during different culture periods. The number of hepatocytes cultured in C-PLGA scaffolds was higher compared with those cultured in PLGA scaffolds without collagen modification, and the lifespan of hepatocytes cultured in C-PLGA scaffolds was longer than that of cells cultured in PLGA scaffolds. Albumin and urea synthesis and ammonia elimination from attached hepatocytes were greater in C-PLGA than in PLGA scaffolds, with the exception of diazepam clearance. Collagen-modified PLGA scaffold is a promising biomaterial for hepatic tissue engineering.     

Biofunctionalization of collagen for improved biological response: scaffolds for corneal tissue engineering

Residual dendrimer amine groups were modified with incorporate COOH group containing biomolecules such as cell adhesion peptides into collagen scaffolds. YIGSR, as a model cell adhesion peptide, was incorporated into both the bulk structure of the gels and onto the gel surface. The effects of the peptide modified collagen gels on corneal epithelial cell behavior were examined with an aim of improving the potential of these materials as tissue-engineering scaffolds. YIGSR was first chemically attached to dendrimers and the YIGSR attached dendrimers were then used as collagen crosslinkers, incorporating the peptide into the bulk structure of the collagen gels. YIGSR was also attached to the surface of dendrimer crosslinked collagen gels through reaction with excess amine groups. The YIGSR modified dendrimers were characterized by H-NMR and MALDI mass spectra. The amount of YIGSR incorporated into collagen gels was determined by (125)I radiolabelling at maximum to be 3.1-3.4 x 10(-2)mg/mg collagen when reacted with the bulk and 88.9-95.6 microg/cm(2) when attached to the surface. The amount of YIGSR could be tuned by varying the amount of peptide reacted with the dendrimer or the amount of modified dendrimer used in the crosslinking reaction. It was found that YIGSR incorporation into the bulk and YIGSR modification of surface promoted the adhesion and proliferation of human corneal epithelial cells as well as neurite extension from dorsal root ganglia.     

Biocompatibility of subcutaneously implanted marine macromolecules cross-linked bio-composite scaffold for cartilage tissue engineering applications

There is an intense interest in developing innovative biomaterials which support the invasion and proliferation of living cells for potential applications in tissue engineering and regenerative medicine. Present study demonstrated the in vivo biocompatibility and toxicity of a macromolecules cross-linked biocomposite scaffold composed of hydroxyapatite, alginate, chitosan and fucoidan abbreviated as HACF. The in vivo biocompatibility and toxicity of HACF scaffold were tested by comparing them with those of a biocompatible surgical metal implant (SMI) in a subcutaneous rat model. Following the implantation, animals were sacrificed and the scaffolds were resected at 1st, 4th, and 8th weeks; the surrounding tissue along with the implant was removed to evaluate its biocompatibility. The effects of implanted biomaterial scaffolds on vital organ systems such as liver, kidney, etc., have been studied by hematology and serum biochemistry. The activities of pro-inflammatory marker enzymes such as COX, 5-LOX, 15-LOX, and NOS were normal in rats implanted with HACF scaffold. Hematological parameters, antioxidant and lipid peroxidation status were also found to be normal in implanted rats same as that of control and SMI. The modulatory effect of implanted scaffold over inflammatory and stress signaling cascades were confirmed by the normalized mRNA expressions of NF-κB, TNF-α and IL-6. The histopathological analysis of liver, kidney and tissue support our results. Taken together, these results demonstrated that HACF biocomposite scaffold signifies its suitability for further research as a scaffold material for cartilage tissue engineering applications.     

Shape-memory porous alginate scaffolds for regeneration of the annulus fibrosus: Effect of TGF-β3 supplementation and oxygen culture conditions

Disc herniation as a result of degenerative or traumatic injury is believed to be the primary instigator of low back pain. At present there is a lack of viable treatment options to repair damaged annulus fibrosus (AF) tissue. Developing alternative strategies to fill and repair ruptured AF tissue is a key challenge. In this work we developed a porous alginate scaffold with shape-memory properties which can be delivered using minimally invasive approaches and recover its original geometry once hydrated. Covalently cross-linked alginate hydrogels were created using carbodiimide chemistry, followed by a freeze-drying step to impart porosity and create porous scaffolds. Results showed that porous alginate scaffolds exhibited shape-memory recovery and mechanical behaviour that could be modulated depending on the cross-linker concentrations. The scaffold can be repeatedly compressed and expanded, which provides the potential to deliver the biomaterial directly to the damaged area of the AF tissue. In vitro experiments demonstrated that scaffolds were cytocompatible and supported cell seeding, penetration and proliferation under intervertebral-disc-like microenvironmental conditions (low glucose media and low oxygen concentration). Extracellular matrix (ECM) was secreted by AF cells with TGF-β3 stimulation and after 21 days had filled the porous scaffold network. This biological matrix was rich in sulfated glycosaminoglycan and collagen type I, which are the main compounds of native AF tissue. Successful ECM deposition was also confirmed by the increase in the peak stress of the scaffold. However, the immaturity of the matrix network after only 21 days of in vitro culture was not sufficient to attain native AF tissue mechanical properties. The ability to deliver porous scaffolds using minimal invasive approaches that can potentially promote the regeneration of AF defects provides an exciting new avenue for disc repair.     

A denatured collagen microfiber scaffold seeded with human fibroblasts and keratinocytes for skin grafting

Biomaterial scaffolds are categorized into artificial or natural polymers, or combinations of the two. Artificial polymers often undergo serum protein adsorption, elicit foreign body and encapsulation immune responses post-implantation. Large pore bovine electrospun collagen I was therefore screened as a candidate for human keratinocyte and fibroblast cell scaffolds. Human HaCaT keratinocyte and dermal fibroblasts were seeded on electrospun denatured collagen I microfiber (DCM) scaffolds and after 72 h Livedead(?) assays performed to determine adhesive cell, survival and scaffold penetration. Both keratinocytes and fibroblasts attached to and survived on DCM scaffolds, however only fibroblasts migrated over and into this biomaterial. HaCaT keratinocytes remained largely stationary on the scaffold surface in discrete islands of monolayered cells. For this reason, normal human epidermal keratinocyte (NHEK) scaffold interactions were assessed using scanning and transmission electron microscopy (EM) that demonstrated DCM scaffolds comprised networks of interlocking and protruding collagen fibers with a mean diameter of 2-5 μm, with a mean inter-fiber pore size of 6.7 μm (range 3-10 μm) and scaffold thickness 50-70 μm. After 72 h the keratinocytes and fibroblasts on DCM scaffolds had attached, flattened and spread over the entire scaffold with assembly of lamellapodia and focal adhesion (FA)-like junctions. Using transmission EM, NHEKs and HaCaT keratinocytes assembled desmosomes, lamellapodia and FA junctions, however, neither hemidesmosomes nor basal lamina were present. In long term (21 day) co-culture fibroblasts migrated throughout the scaffold and primary keratinocytes (and to a lesser extend HaCaTs) stratified on the scaffold surface forming a human skin equivalent (HSE). In vivo testing of these HSEs on immunocompetent (BalbC) and immunodeficient (SCID) excisionally wounded model mice demonstrated scaffold wound biocompatibility and ability to deliver human cells after scaffold biodegradation.     

Multilineage differentiation of human mesenchymal stem cells in a three-dimensional nanofibrous scaffold

Functional engineering of musculoskeletal tissues generally involves the use of differentiated or progenitor cells seeded with specific growth factors in biomaterial scaffolds. Ideally, the scaffold should be a functional and structural biomimetic of the native extracellular matrix and support multiple tissue morphogenesis. We have previously shown that electrospun, three-dimensional nanofibrous scaffolds that morphologically resemble collagen fibrils are capable of promoting favorable biological responses from seeded cells, indicative of their potential application for tissue engineering. In this study, we tested a three-dimensional nanofibrous scaffold fabricated from poly(epsilon-caprolactone) (PCL) for its ability to support and maintain multilineage differentiation of bone marrow-derived human mesenchymal stem cells (hMSCs) in vitro. hMSCs were seeded onto pre-fabricated nanofibrous scaffolds, and were induced to differentiate along adipogenic, chondrogenic, or osteogenic lineages by culturing in specific differentiation media. Histological and scanning electron microscopy observations, gene expression analysis, and immunohistochemical detection of lineage-specific marker molecules confirmed the formation of three-dimensional constructs containing cells differentiated into the specified cell types. These results suggest that the PCL-based nanofibrous scaffold is a promising candidate scaffold for cell-based, multiphasic tissue engineering.     

Incorporation of cell-adhesion peptides into collagen scaffolds promotes corneal epithelial stratification

The objective of this study was to examine the effects of cell-adhesion peptides incorporated into collagen scaffolds on corneal epithelial cell stratification. Peptides (YIGSR, YIGSRIKVAV, IKVAVYIGSR and negative control YISGR) were first chemically attached to dendrimers. The peptide-modified dendrimers were then used as collagen cross-linkers. This permitted the incorporation of the peptides into the bulk structure of the collagen gels. The amount of peptide incorporated into the collagen gels was determined by 125I radiolabelling to be between 0.064 and 6.4 microg/mg collagen for YIGSR, and between 0.1187 to 11.87 microg/mg collagen for YIGSRIKVAV and IKVAVYIGSR. Corneal epithelial cell monolayers were grown on the surface of the collagen scaffolds and then exposed to conditions that promoted stratification as a stratified epithelial layer is desired in a tissue-engineered cornea. It was found that all of the incorporated peptides promoted stratification of the cells with the exception of the negative control YISGR. A synergistic effect of the combined sequences from laminin was observed, with the orientation of the peptide sequences having a great impact on the ability of the materials to promote cell stratification.