Inter-connecting pores of chitosan scaffold with basic fibroblast growth factor modulate biological activity on human mesenchymal stem cells

In this study, we developed bio-active molecules immobilized chitosan scaffolds with controlled pore architectures for enhanced viability of human mesenchymal stem cells (hMSCs). The decreasing in molecular weight of chitosan by ultrasonication of chitosan solution was effective in the formation of porous chitosan scaffolds, resulting in an increase of inter-connecting micropores (∼10 μm) between macropores. Using a layer-by-layer method, we then prepared heparin-coated chitosan scaffolds as depots for basic fibroblast growth factors (bFGF). Enzyme-linked immunosorbent assays confirmed that heparin-coated chitosan scaffolds could bind higher amount of bFGF (24.21 ng/mg) compared to 2.53 ng/mg of non-coated scaffold. Moreover, we were able to manipulate the release profiles of bFGF from the scaffolds for 7 days. In vitro studies showed that chitosan scaffolds induced the improved viability and proliferation of hMSCs through their synergetic effects of the inter-connecting micropores and the sustained released of bFGF. Our results suggest that bFGF immobilized chitosan scaffolds with controlled inter-connecting pores, in combination with other heparin-binding growth factors, have potential implants for controlling biological functions in regenerative medicine.     

Chondrogenesis on BMP‐6 loaded chitosan scaffolds in stationary and dynamic cultures

We originally investigated the suitability of chitosan scaffolds loaded with bone morphogenetic protein 6 (BMP‐6) in both stationary and dynamic conditions for cartilage tissue engineering. In the first part of the present study, ATDC5 murine chondrogenic cells were seeded in chitosan and BMP‐6 loaded chitosan scaffolds and cultured for 28 days under static conditions. In the following part, we examined the influence of dynamic cultivation conditions over BMP‐6 loaded chitosan scaffolds by using rotating bioreactor with perfusion (RCMW?). Tissue engineered constructs were characterized by 3‐(4,5‐dimethylthiazol‐2‐yl)‐2,5‐diphenyl‐tetrazoliumbromide (MTT) assay, scanning electron microscopy (SEM), confocal laser scanning microscopy (CLSM) and biochemical assays for glycosaminoglycans (GAG) deoxyribonucleic acid (DNA) and collagen Type II quantification. At the end of 4 weeks static incubation period high levels of GAG (21.22 mg/g dry weight), DNA amounts (1.37 mg/g dry weight) and collagen Type II amounts (1.94 µg/g dry weight) were achieved for BMP‐6 loaded chitosan scaffolds compared to chitosan scaffolds. However, the results obtained from morphological observations suggested hypertrophic differentiation of ATDC5 cells in the presence of BMP‐6 under stationary conditions. The influence of mechanical stimulation appeared significantly with differentiated cells, cultured under dynamic conditions, showing the effect of retaining their phenotypes without hypertrophy. Biotechnol. Bioeng. 2009; 104: 601–610 © 2009 Wiley Periodicals, Inc.     

Biodegradablescaffolds based on chitosan: Preparation,properties, and use for the cultivation of animal cells

The influence of the conditions of the formation of chitosan hydrogels crosslinked with glutaraldehyde (GA) or genipin (the polysaccharide molecular weight, pH level, and concentration of the chitosan solution) on the gel time and the properties of biopolymer scaffolds for tissue engineering obtained by the freeze-drying of hydrogels was studied. The resulting scaffolds had different structures (morphology, degree of anisotropy, average pore size) and moisture-retaining capacities. The cytotoxicity of biodegradable scaffolds based on chitosan with a low content of genipin and GA was studied for the first time. Using the L929 mouse fibroblasts model line, we demonstrated that scaffolds based on chitosan with a molecular weight of 320 and 190 kDa crosslinked with genipin and GA (0.005 and 0.01 mol/mol of chitosan amino groups) are biocompatible. Using confocal laser microscopy, we demonstrated that the cells are uniformly distributed in all scaffold samples and they successfully grew and proliferated when cultured in vitro for 4 days.     

Bioactive/Natural Polymeric Scaffolds Loaded with Ciprofloxacin for Treatment of Osteomyelitis

Local delivery of antibiotic into injured bone is a demand. In this work, different scaffolds of chitosan (C) with or without bioactive glass (G) were prepared using the freeze-drying technique in 2:1, 1:1, and 1:2 weight ratios. Chitosan scaffolds and selected formulas of chitosan to bioglass were loaded with ciprofloxacin in 5%, 10%, and 20% w/w. Scaffold morphology showed an interconnected porous structure, where the glass particles were homogeneously dispersed in the chitosan matrix. The kinetic study confirmed that the scaffold containing 1:2 weight ratio of chitosan to glass (CG12) showed optimal bioactivity with good compromise between Ca and P uptake capacities and Si release rate. Chitosan/bioactive glass scaffolds showed larger t ₅₀ values indicating less burst drug release followed by a sustained drug release profile compared to that of chitosan scaffolds. The cell growth, migration, adhesion, and invasion were enhanced onto CG12 scaffold surfaces. Samples of CG12 scaffolds with or without 5% drug induced vascular endothelial growth factor (VEGF), while those containing 10% drug diminished VEGF level. Only CG12 induced the cell differentiation (alkaline phosphatase activity). In conclusion, CG12 containing 5% drug can be considered a biocompatible carrier which would help in the localized osteomyelitis treatment.     

Isolation and characterization of collagen from marine fish (Thunnus obesus)

In the present study, we isolated collagen from Thunnus obesus bone, which was physiochemically characterized. Two different kinds of methods were used to isolate the collagen; they are the Acid Soluble Collagen (ASC) and Acid Soluble Enzyme Collagen (ASEC) methods. The isolated collagen was characterized with Fourier Transform Infrared Spectroscopy (FT-IR), SDS-polyacrylamide gel electrophoresis (SDS-PAGE), Optical Microscopy (OM) and Scanning Electron Microscopy (SEM). FT-IR results revealed the presence of collagen. SEM and OM results depicted that collagen was in the form of fiber sponge-like scaffolds. The isolated collagen scaffold was checked with pre-osteoblast (MC3T3-E1) cell line for biocompatibility. The in vitro results revealed that the collagen scaffolds were highly biocompatible and nontoxic in nature. Herewith, we are suggesting that marine fish-derived collagen will be an excellent material for leather, film industry, pharmaceutical, cosmetics, biomedical and food applications.     

Preparation and chemical and biological characterization of a pectin/chitosan polyelectrolyte complex scaffold for possible bone tissue engineering applications

In this work, porous scaffolds obtained from the freeze-drying of pectin/chitosan polyelectrolyte complexes were prepared and characterized by FTIR, SEM and weight loss studies. Additionally, the cytotoxicity of the prepared scaffolds was evaluated in vitro, using human osteoblast cells. The results obtained showed that cells adhered to scaffolds and proliferated. The study also confirmed that the degradation by-products of pectin/chitosan scaffold are noncytotoxic.     

The enzymatic degradation and swelling properties of chitosan matrices with different degrees of N-acetylation

In the design of chitosan-based drug delivery systems and implantable scaffolds, the biodegradation rate of the chitosan matrix represents a promising strategy for drug delivery and the function of carriers. In this study, we have investigated the degradation of chitosan with different degrees of N-acetylation, with respect to weight loss, water absorption, swelling behavior, molecular weight loss of bulk materials, and reducing sugar content in the media. Chitosan matrices were prepared by compression molding. The results revealed that the initial degradation rate, equilibrium water absorption, and swelling degree increased with decreasing degree of deacetylation (DD) and a dramatic rise began as DD of the chitosan matrix decreased to 62.4%. Chitosan matrices with DD of 52.6%, 56.1%, and 62.4% had the weight half-life of 9.8, 27.3, and more than 56 days, respectively, and the weight half-life of average molecular weight 8.4, 8.8, and 20.0 days, respectively. For chitosan matrices with DD of 71.7%, 81.7%, and 93.5%, both types of half-life exceeded 84 days because of the much slower degradation rate. The dimension of chitosan matrices during degradation was determined by the process of swelling and degradation. These findings may help to design chitosan-based biomedical materials with predetermined degradation timed from several days to months and proper swelling behaviors.     

MC 3T3-E1细胞在纳米羟基磷灰石/壳聚糖复合支架上的增殖和分化

用原位合成纳米羟基磷灰石的方法制备多孔纳米羟基磷灰石/壳聚糖复合支架;在支架上接种MC3T3-E1细胞,瑞氏染色检测细胞形态,MTT法检测其增殖情况;在诱导培养基中培养30d后,碱性磷酸酶染色比较其分化水平;定量检测细胞的碱性磷酸酶活性;RT-PCR检测成骨相关基因的表达情况。实验结果表明:MC3T3-E1细胞在纳米级羟基磷灰石/壳聚糖复合支架上粘附铺展良好,其增殖率显著高于培养于纯壳聚糖支架上的细胞。碱性磷酸酶染色表明复合支架上的细胞有较高水平的碱性磷酸酶表达。进一步定量检测细胞的碱性磷酸酶活性,结果说明在复合支架上细胞比纯壳聚糖支架上培养的细胞碱性磷酸酶活性提高了约8倍。此外,骨分化相关特征基因骨桥蛋白OPN在复合支架上培养的细胞中的表达水平也明显高于纯壳聚糖上培养的细胞。分化成熟标志基因骨钙素OC在复合支架上培养的细胞中有表达,但是纯壳聚糖支架上培养的细胞中却未检测到。支架中纳米羟基磷灰石的加入不仅提高了前成骨细胞在复合支架上的增殖,而且还促进了它的分化。纳米羟基磷灰石/壳聚糖复合支架表现出良好的生物相容性和生物活性,是极具前景的骨组织工程支架材料。     

MC 3T3-E1细胞在纳米羟基磷灰石/壳聚糖复合支架上的增殖和分化

用原位合成纳米羟基磷灰石的方法制备多孔纳米羟基磷灰石/壳聚糖复合支架;在支架上接种MC 3T3-E1细胞,瑞氏染色检测细胞形态,MTT法检测其增殖情况;在诱导培养基中培养30d后,碱性磷酸酶染色比较其分化水平;定量检测细胞的碱性磷酸酶活性;RT-PCR检测成骨相关基因的表达情况。实验结果表明：MC 3T3-E1细胞在纳米级羟基磷灰石/壳聚糖复合支架上粘附铺展良好,其增殖率显著高于培养于纯壳聚糖支架上的细胞。碱性磷酸酶染色表明复合支架上的细胞有较高水平的碱性磷酸酶表达。进一步定量检测细胞的碱性磷酸酶活性,结果说明在复合支架上细胞比纯壳聚糖支架上培养的细胞碱性磷酸酶活性提高了约8倍。此外,骨分化相关特征基因骨桥蛋白OPN在复合支架上培养的细胞中的表达水平也明显高于纯壳聚糖上培养的细胞。分化成熟标志基因骨钙素OC在复合支架上培养的细胞中有表达,但是纯壳聚糖支架上培养的细胞中却未检测到。支架中纳米羟基磷灰石的加入不仅提高了前成骨细胞在复合支架上的增殖,而且还促进了它的分化。纳米羟基磷灰石/壳聚糖复合支架表现出良好的生物相容性和生物活性,是极具前景的骨组织工程支架材料。     

Hydrogels and electrospun nanofibrous scaffolds of N-methylene phosphonic chitosan as bioinspired osteoconductive materials for bone grafting

In this work, N-methylene phosphonic chitosan (NMPC) based hydrogels and electrospun nanofibrous scaffolds are reported with objective to obtain osteoconductive and osteoinductive matrixes for bone grafting applications. NMPC, a phosphorylated derivative of chitosan, is known to mimic the function of non collagenous phosphoproteins in providing nucleation sites for biomineralization. NMPC hydrogels were prepared by crosslinking between NMPC and genipin. A detailed investigation of physicochemical properties of NMPC solutions is also carried out in order to obtain beads free nanofibers. Both NMPC gels and nanofibers were further evaluated for their biomineralization potential and biocompatibility with human osteoblast like cells. Results indicated that hydrogels and nanofibrous scaffolds NMPC are biocompatible and significantly osteoinductive compared to tissue culture plate controls. However, cells seeded on nanofibrous scaffolds exhibited greater proliferation measured by MTT assay, and higher expression of early markers for osteogenic differentiation proving the superior applicability of nanofibrous scaffolds for bone grafting applications.     

Sodium hyaluronate/chitosan polyelectrolyte complex scaffolds for dental pulp regeneration: synthesis and characterization

In the present study, small-sized porous scaffolds were obtained from the freeze-drying of sodium hyaluronate/chitosan polyelectrolyte complexes. The obtained materials were characterized by a set of techniques including attenuated total reflectance-Fourier transform infrared (ATR-FTIR) spectroscopy, swelling determination and weight loss studies. The morphology of the scaffolds was observed using scanning electron microscopy. Thermal characterization of the scaffolds was also performed by dynamic mechanical thermal analysis and thermogravimetric analysis. Finally, the cytotoxic profile of the prepared scaffolds was evaluated in vitro, using mesenchymal stem cells. The results obtained showed that cells adhered to scaffolds and proliferated. This study also confirmed that the degradation by-products of sodium hyaluronate/chitosan scaffold are noncytotoxic, which is fundamental for its application in the biomedical field.     

Enhanced Healing of Rat Calvarial Defects with MSCs Loaded on BMP-2 Releasing Chitosan/Alginate/Hydroxyapatite Scaffolds

In this study, we designed a chitosan/alginate/hydroxyapatite scaffold as a carrier for recombinant BMP-2 (CAH/B2), and evaluated the release kinetics of BMP-2. We evaluated the effect of the CAH/B2 scaffold on the viability and differentiation of bone marrow mesenchymal stem cells (MSCs) by scanning electron microscopy, MTS, ALP assay, alizarin-red staining and qRT-PCR. Moreover, MSCs were seeded on scaffolds and used in a 8 mm rat calvarial defect model. New bone formation was assessed by radiology, hematoxylin and eosin staining 12 weeks postoperatively. We found the release kinetics of BMP-2 from the CAH/B2 scaffold were delayed compared with those from collagen gel, which is widely used for BMP-2 delivery. The BMP-2 released from the scaffold increased MSC differentiation and did not show any cytotoxicity. MSCs exhibited greater ALP activity as well as stronger calcium mineral deposition, and the bone-related markers Col1α, osteopontin, and osteocalcin were upregulated. Analysis of in vivo bone formation showed that the CAH/B2 scaffold induced more bone formation than other groups. This study demonstrates that CAH/B2 scaffolds might be useful for delivering osteogenic BMP-2 protein and present a promising bone regeneration strategy.     

Novel hybrid scaffolds for the cultivation of osteoblast cells

In this study, natural biodegradable polysaccharide, chitosan, and synthetic biodegradable polymer, poly(?-caprolactone) (PCL) were used to prepare 3D, hybrid polymeric tissue scaffolds (PCL/chitosan blend and PCL/chitosan/PCL layer by layer scaffolds) by using the electrospinning technique. The hybrid scaffolds were developed through HA addition to accelerate osteoblast cell growth. Characteristic examinations of the scaffolds were performed by micrometer, SEM, contact angle measurement system, ATR-FTIR, tensile machine and swelling experiments. The thickness of all electrospun scaffolds was determined in the range of 0.010 ± 0.001-0.012 ± 0.002 mm. In order to optimize electrospinning processes, suitable bead-free and uniform scaffolds were selected by using SEM images. Blending of PCL with chitosan resulted in better hydrophilicity for the PCL/chitosan scaffolds. The characteristic peaks of PCL and chitosan in the blend and layer by layer nanofibers were observed. The PCL/chitosan/PCL layer by layer structure had higher elastic modulus and tensile strength values than both individual PCL and chitosan structures. The layer by layer scaffolds exhibited the PBS absorption values of 184.2; 197.2% which were higher than those of PCL scaffolds but lower than those of PCL/chitosan blend scaffolds. SaOs-2 osteosarcoma cell culture studies showed that the highest ALP activities belonged to novel PCL/chitosan/PCL layer by layer scaffolds meaning better cell differentiation on the surfaces.     

Preparation, characterization and antimicrobial activity of a bio-composite scaffold containing chitosan/nano-hydroxyapatite/nano-silver for bone tissue engineering

In this study, a bio-composite scaffold containing chitosan/nano-hydroxyapatite/nano-silver particles (CS/nHAp/nAg) was developed by freeze drying technique, followed by introduction of silver ions in controlled amount through reduction phenomenon by functional groups of chitosan. The scaffolds were characterized using SEM, FT-IR, XRD, swelling, and biodegradation studies. The testing of the prepared scaffolds with Gram-positive and Gram-negative bacterial strains showed antibacterial activity. The scaffold materials were also found to be non-toxic to rat osteoprogenitor cells and human osteosarcoma cell line. Thus, these results suggested that CS/nHAp/nAg bio-composite scaffolds have the potential in controlling implant associated bacterial infection during reconstructive surgery of bone.     

载荷壳聚糖微球的海藻酸钠水凝胶的制备

目的：在支架材料上引入具有控释行为的微球,旨在通过微球包裹生长因子,通过生长因子的缓慢释放从而促进种子细胞的生长分化。方法：本实验通过在海藻酸钠水凝胶中负载具有控释功能的壳聚糖微球,并通过在微球中包栽溶茵酶从而达到控制壳聚糖降解速率的功效。实验研究了不同搅拌速度下壳聚糖微球的形貌及粒径大小,通过扫描电镜对壳聚糖微球及复合支架的形貌进行了观察,通过紫外光吸收法测试了微球的载药量及包封率,并研究了壳聚糖微球在体外的降解行为等。结果：制备的壳聚糖微球表面较光滑,溶菌酶的包封率在25．78％41．89％之间,载药量在15．20％-24．44％之间。包封溶茵酶的微胶囊在降解9天后壳聚糖分子量下降了70．40％,载荷微球的复合凝胶孔洞增多,孔洞大小均匀。结论：此复合材料有望作为栽荷软骨相关生长因子的支架模型,从而解决软骨组织工程中种子细胞匮乏的问题。     

Novel fabrication of morphology tailored nanostructures with Gelatin/Chitosan Co-polymeric bio-composited hydrogel system to accelerate bone fracture healing and hard tissue nursing care management

In this study, we are successfully fabricated on a hydrogel consisting of TiO₂ nanoparticles loaded onto a gelatin/chitosan matrix to control the acceleration of bone fracture healing and improved the nursing care applications. Each specimen (chitosan, gelatin and titanium dioxide) were characterized and confirmed by using different techniques, Fourier transforms infrared spectroscopy, X-ray diffraction analysis, Scanning Electron Microscopy with Elemental dispersive X-ray analysis, Thermo-gravimetric and Differential thermal analysis. In addition, the cell cytotoxicity results verified that the TiO₂/gelatin-chitosan hydrogel are nontoxic to osteoblasts. And cell fixation outcome after 5 days of incubation condition revels that the enhanced in vitro cell survival and cell spreading on the prepared TiO₂ incorporated hydrogel with respect to gelatin/chitosan hydrogel. Furthermore, TiO₂/gelatin-chitosan hydrogel nanostructures can modulate the bone fracture healing, indicating a potential application on nursing care.     

Controlling chitosan’s molecular weight via multistage deacetylation

Chitosan samples with different molecular weights (Mw) and degree of deacetylation (DD) were prepared by controlling operating conditions throughout the multistage alkali treatment. The temperature of the reaction, time duration and number of reaction steps were considered effective parameters. A database was developed for chitosan preparation in order to achieve high degrees of deacetylation and control the molecular weight of chitosan without changing other molecular structures. The number of treatments and the duration of each step of deacetylation significantly affected molecular weight so that two samples were obtained with a DD of 99% and two different molecular weights ranging from 4.66×10⁵ to 2.93×10⁵ Based on these results, the highest molecular weight obtained using the multistage treatment without decreasing DD was 5.32×10⁵, with a DD of 96.67%. Also, the morphological studies indicate that the molecular weight of chitosan has a significant effect on the pore size of the prepared scaffolds. However, this effect is critical. In other words, the pore size will increase by increasing molecular weight of chitosan from low upto medium molecular weight and when it reached to high molecular weight the pore size is decreased.     

Cartilage regeneration by novel polyethylene oxide/chitin/chitosan scaffolds

This study presents the application of novel PEO/chitin/chitosan scaffolds for the cultivation of bovine knee chondrocytes (BKCs). The results reveled that the composition strongly affected physicochemical characteristics of the ternary scaffolds. Based on the contours of porosity, the percentage of void space in these scaffolds was estimated to be higher than 90%. In regard to mechanical strength, the composition of 50% chitin and 50% chitosan in the scaffold led to the maximum of Young's modulus. Moreover, large extensibility of the scaffolds occurred at the following range of the composition: PEO > 37.5%, chitin < 25%, and chitosan <62.5%. After cultivation of BKCs over 4 weeks, the percentage of biodegradation was normally between 30 and 60%. The formation of neocartilage was assessed by the amounts of BKCs, glycosaminoglycans and collagens in the cultured BKC-polymer constructs. Better chondrogenesis was obtained at the following range of the composition: 25% < PEO < 40%, 12.5% < chitin < 37.5%, and 30% < chitosan < 50%. Thus, the regeneration of cartilaginous components could be manipulated simply by controlling the composition of PEO, chitin, and chitosan in the hybrid scaffolds.     

Heparin-functionalized chitosan scaffolds for bone tissue engineering

The aim of this study is to investigate the effects of heparin-functionalized chitosan scaffolds on the activity of preosteoblasts. The chitosan scaffolds having the pore size of ∼100 μm were prepared by a freeze-drying method. Two different methods for immobilization of heparin to chitosan scaffolds were successfully performed. In the first method, functionalization of the scaffolds was achieved by means of electrostatic interactions between negatively charged heparin and positively charged chitosan. The covalent immobilization of heparin to chitosan scaffolds by 1-(3-dimethylaminopropyl)-3-ethylcarbodiimide (EDAC) and N-hydroxysuccinimide (NHS) was used as a second immobilization method. Morphology, proliferation, and differentiation of MC3T3-E1 preosteoblasts on heparin-functionalized chitosan scaffolds were investigated in vitro. The results indicate that covalently bound heparin containing chitosan scaffolds (CHC) stimulate osteoblast proliferation compared to other scaffolds, that is, unmodified chitosan scaffolds (CH), electrostatically bound heparin containing chitosan scaffolds (EHC), and CH+free heparin (CHF). SEM images also proved the stimulative effect of covalently bound heparin on the proliferation of preosteoblasts. Alkaline phosphatase (ALP) and osteocalcin (OCN) levels of cells proliferated on CHC and EHC were also higher than those for CH and CHF. In vitro studies have demonstrated that chitosan scaffolds increase viability and differentiation of MC3T3-E1 cells especially in the presence of immobilized heparin.     

Novel textile chitosan scaffolds promote spreading, proliferation, and differentiation of osteoblasts

Two novel scaffold models made of chitosan fibers were designed, fabricated, and investigated. Raw chitosan fibers were either tightened between plastic rings or were processed into stand-alone scaffolds. Chitosan fiber scaffolds were further modified by coating with a thin layer of fibrillar collagen type I to biologize the surface. Cell culture experiments were carried out using murine osteoblast-like cells (7F2). Confocal laser scanning microscopy (cLSM) as well as scanning electron microscopy (SEM) revealed fast attachment and morphological adaptation of the cells on both the raw chitosan fibers and the collagen-coated scaffolds. Cells were cultivated for up to 4 weeks on the materials and proliferation as well as osteogenic differentiation was quantitatively analyzed in terms of lactate dehydrogenase (LDH) and alkaline phosphatase (ALP) activity. We found a 14-16-fold increase of cell number and the typical pattern of ALP activity, whereas the collagen coating does not remarkably influence these parameters. The maintenance of osteogenic phenotype on the novel materials was furthermore confirmed by immunostaining of osteocalcin and study of matrix mineralization. The feature of the collagen-coated but also the raw chitosan fiber scaffolds to support the attachment, proliferation, and differentiation of osteoblast-like cells suggest a potential application of chitosan fibers and textile chitosan scaffolds for the tissue engineering of bone.