Objective To study the effect of water soluble chitosan (WSC) on the apoptosis of peritoneal macrophage induced by lipopolysaccharides (LPS), and discuss the mechanism. Methods Peritoneal macrophages were divided to three groups: phosphate buffered saline (PBS) group, LPS group and LPS plus WSC group. At hour 24, apoptosis cell and active caspase-3 were detected by flow cytometry; nitric oxide (NO) was determined with Griess reagent. Results There were more apoptosis cells in the LPS group than the PBS group. The percentage of apoptosis cells was significantly decreased in the LPS plus WSC group than the LPS group. The expression of active caspase-3 and the secretion of NO were also inhibited by WSC after LPS intervention. Conclusion WSC inhibits apoptosis of peritoneal macrophage induced by LPS.
Objective To give a prel iminary experimental evidence and to prove chitosan and allogeneic morsel ized bone as potential bone substitutions in repairing rabbit radius segmental defect. Methods Chitosan and allogeneic morsel ized bone were mixed with various ratios (1 ∶ 5, 1 ∶ 10, 1 ∶ 25, 1 ∶ 50, and 1 ∶ 100). After preparation, the physicaland chemical properties of the composites were prel iminary detected; the composites at the ratios of 1 ∶ 50 and 1 ∶ 25 had good physical and chemical properties and were used for the animal experiment. The radius segmental defects of 15 mm in length were made in 50 adult New Zealand white rabbits (weighing 2.5-3.0 kg), then the animals were divided into 2 groups. In groups A and B, chitosan/allogeneic morsel ized bone composites were implanted at the ratio of 1 ∶ 50 and 1 ∶ 25, respectively. After 1, 2, 4, 8, and 12 weeks of operation, the gross, histological, immunohistochemical observations were performed. Before the rabbits were sacrified, X-ray films were taken; the serum calcium and alkal ine phosphatase (ALP) concentration were measured; and the biomechanical measurement was carried out at 12 weeks. Results The results of gross observation were essentially consistent with those of the X-ray films. The histological observation showed that the bone formation was earl ier in group A than in group B; the amount of new bone formation in group A was more than that in group B; and the bone forming area in group A was bigger than that in group B (P lt; 0.05) at 4 and 8 weeks after operation. The immunohistochemical staining showed that vascular endothel ial growth factor and insul in-l ike growth factor receptor II proteins expressed in the cytoplasm of 2 groups after 4 and 8 weeks, and the expression in group A was higher than that in group B (P lt; 0.05). There was no significant difference in the serum calcium concentration between 2 groups at each time point (P gt; 0.05). After 4 and 8 weeks, the ALP concentration in group A was significantly higher than that in group B (P lt; 0.05). After 12 weeks, the radius maximum bending loads of groups A and B were (299.75 ± 27.69) N and (278.54 ± 17.09) N, respectively, showing significant difference (t=4.045,P=0.002). Conclusion The composite of chitosan and allogeneic morsel ized bone has good osteogeneic activity and can beused as a bone tissue engineering scaffold, and the optimum ratio of chitosan to allogeneic morsel ized bone was 1 ∶ 50.
To develop a novel biodegradable collagen-chitosan-[poly(vinyl alcohol), PVA] composite artificial lacrimal canal iculus for treating tear overflowing (epiphora) caused by canal icular obstruction. Methods Homogeneously mixing solution composed of collagen, chitosan and PVA with different ratios was prepared. After several cycles of freezing/thawing process, the mixing solution was transferred into elastic hydrogel. Then the hydrogel was rinsed, punctured, dehydrated and trimmed, and three groups (T1, T2 and T3) of novel artificial lacrimal canal iculus were obtained. The appearance and diameter of all samples were observed under optical microscopy. The cross-section before and after drying as well as phase distribution of sample T2 was observed by SEM. The water absorption ratio and expanding ratio in PBS solution were calculated from three swell ing behavior curves. The degradabil ity of groups T1, T2 and T3 were prel iminary analyzed by degradation experiment in vitro. Results The micro-tubes with 0.5-0.7 mm in inner diameter, 0.9-1.5 mm in outer diameter and more than 20 mm in length were fabricated successfully through physical crossl inking without addition of toxic cross-l inker. SEM result showed that the sample had uniform phase distribution and smooth surface at dried state as well as interpenetrate network structure at hydrogel state. It was seen from the swell ing behavior curves that groups T1, T2 and T3 swelled rapidly within 10-30 minutes, and formed elastic composite hydrogel pipes. In addition, the expanding ratio of inner and outer diameter of the tube was 20%-30% and 100%-120% with swell ing, respectively. The equil ibrium water content of the hydrogel pipes increased with increase of collagen composition. Three groups of samples were immerged in PBS solution contained 2 mg/mL lysozyme at 37 for 1 month, their nozzle cracked, their wall became thin and more transparent. And also, there was small floc deposited on the tube surface. The samples were degraded into mash after they were soaked in PBS solution at 70 for 2 days. Conclusion The novel artificial lacrimal canal iculus with good mechanical property and high water absorption is in favor of operation, tear passing and anti-conglutination. It will be a potential candidate for treating the lacrimal passage occlusion.
Objective To develop a novel porous three-dimensional scaffold and to investigate its physico-chemical properties for tissue engineering cartilage.Methods Refined 88% deacetylation degree chitosan was prepared and dissolved in 0.2 mol/L acetate acid and fully mixed with highly purified porcine type Ⅱcollagen in 0.5 mol/L acetate acid solution in a ratio of 4 to 1 (wt/wt). Freeze-drying process was employed to fabricate the composite scaffold. The construct wascross-linked by use of 1-ethyl-3(3-dimethyl aminopropyl) carbodiimide (EDC) and Nhydroxysuccinimide (NHS). A mechanical tester was utilized to determine the tensilestrength change before and after cross-linking. The microstructure was observed via scanning electron microscopy (SEM). The lysozyme degradation was performedto evaluate the degradability of the scaffold in vitro. Results A bulk scaffold with desired configuration was obtained. The mechanical test showed that the crosslinking treatment could enhance the mechanical strength of the scaffold. The SEM results revealed that the two constituents evenly distributed in the scaffold and that the matrix was porous, sponge-like with interconnected pore sizing 100250 μm. In vitro lysozyme degradation indicated that crosslinked or uncross-linked composite scaffolds had faster degradation rate than the chitosan matrix. Conclusion Chitosan and typeⅡcollagen can be developed into a porous three-dimensional scaffold. The related physico-chemical tests suggest that the composite socaffold meets requirements for tissue engineered scaffold and may serve as an alternative cellcarrier for tissue engineering cartilage.
Objective To prepare nano polypyrrole (PPy)/chitin composite membrane and observe their biocompatibility. Methods The nano PPy was synthesized by microemulsion polymerization, blended with chitosan and then formed membranes. The membranes were then modified by acetylation to get the experimental membranes (nano PPy/chitin composite membranes, group A). The chitosan membranes (group B) and chitin ones (group C) modified by acetylation acted as control. Scanning electron microscopy and FT-IR spectra were used to identify the nano PPy and the membranes of each group. And the conductivity of membranes of each group was measured. Schwann cells were co-cultured in vitro with each group membranes to observe the biocompatibility by inverted microscope observing, living cell staining, cell counting, and immunofluorescence staining. The lysozyme solution was used to evaluate the degradation of the membranes in vitro. Results The FT-IR spectra showed that the characteristic vibrational absorption peaks of C=C from nano PPy appeared at 1 543.4 cm–1 and 1 458.4 cm–1. Scanning electron microscopy observation revealed that the size of nano PPy particles was about 100-200 nm. The nano PPy particles were synthesized. It was successful to turn chitosan to chitin by the acetylation, which was investigated by FT-IR analysis of membranes in groups A and C. The characteristic peaks of the amide Ⅱ band around 1 562 cm–1 appeared after acetylated modification. Conductivity test showed that the conductivity of membranes in group A was about (1.259 2±0.005 7)×10–3 S/cm, while the conductivity of the membranes in groups B and C was not detected. The nano PPy particles uniformly distributed on the surface of membranes in group A were observed by scanning electron microscope; the membranes in control groups were smooth. As a result, the nano PPy/chitin composite membranes with electrical conductivity were obtained. The cultured Schwann cells were found to survive with good function by fluorescein diacetate live cell staining, soluble protein-100 immunofluorescence staining, and inverted microscope observing. The cell counting showed that the proliferation of Schwann cells after 2 days and 4 days of group A was more than that of the two control groups, and the differences were significant (P<0.05). It indicated that the nano PPy/chitin composite membranes had better ability of adhesion and proliferation than those of chitosan and chitin membranes. The degradation of membranesin vitro showed that the degradation rates of membranes in groups A and C were significantly higher than those in group B at all time points (P<0.05). In a word, the degradation performance of the membranes modified by acetylation was better than that of chitosan membranes under the same condition. Conclusion The nano PPy and chitosan can be blended and modified by acetylation successfully. Nano PPy/chitin composite membranes had electrical conductivity, degradability, and good biocompatibility in vitro.
Objective To explore the in vitro osteogenesis of the chitosan-gelatin scaffold compounded with recombinant human bone morphogenetic protein 2 (rhBMP-2). Methods Recombinant human BMP-2 was compounded with chitosan-gelatin scaffolds by freezedrying. 2T3 mouse osteoblasts and C2C12 mouse myoblasts were cultured and seeded onto the complexes at thedensity of 2×104/ml respectively. The complexes were divided into two groups. Group A: 2T3 osteoblasts seeded, consisted of 14 rhBMP-2 modified complexes. Each time three scaffolds were taken on the 3rd, 7th, 14th, and 21st day of the culturing, then the expression of osteocalcin gene (as the marker of bone formation) in adherent cells was detected by semiquantitative RT-PCR with housekeeping gene β-tubulin as internalstandard. The other 2 rhBMP-2 modified complexes were stopped being cultured on 14th day after cell seeding, and the calcification of the complexes was detected by Alizarian Red S staining. Five scaffolds without rhBMP-2 modification as the control group A, they were stopped being cultured on 14th day after cell seeding. Of the 5 scaffolds, 3 were subjected tothe detection of osteocalcin gene expression and 2 were subjected to the detection of calcification. Group B: C2C12 myoblasts seeded, had equal composition andwas treated with the same as group A. Besides these 2 groups, another 2 rhBMP2 modified complexes with 2T3 osteoblasts seeding were cultured for 3 days and then scanned by electron microscope (SEM) as to detect the compatibility of the cell to the complex. ResultsSEM showed that cells attached closely to the complex and grew well. In group A, the expression level(1.28±0.17)of osteocalcin gene in cells on rhBMP-2 modified complexes was higher than that (0.56±0.09) of the control group A, being statistically -significantly different(P<0.05) control. C2C12 myoblasts which did not express osteocalcin normally could also express osteocalcin after being stimulated by rhBMP-2 for at least 7 days. Alizarian Red S staining showed that there was more calcification on rhBMP-2 modified complexes in both groups. There were more calcification in the group compounded with rhBMP-2, when the groups were seeded with the same cells. Conclusion The complexmade of rhBMP-2 and chitosan-gelatin scaffolds has b osteogenesis ability in vitro.
Objective To construct a ultraviolet-cross-linkable chitosan-carbon dots-morin (NMCM) hydrogel, observe whether it can repair cartilage injury by in vivo and in vitro experiments, and explore the related mechanism. Methods The chitosan was taken to prepare the ultraviolet (UV)-cross-linkable chitosan by combining methacrylic anhydride, and the carbon dots by combining acrylamide. The two solutions were mixed and added morin solution. After UV irradiation, the NMCM hydrogel was obtained, and its sustained release performance was tested. Chondrocytes were separated from normal and knee osteoarticular (KOA) cartilage tissue donated by patients with joint replacement and identified by toluidine blue staining. The 3rd generation KOA chondrocytes were co-cultured with the morin solutions with concentrations of 12.5, 25.0, 50.0 µmol/L and NMCM hydrogel loaded with morin of the same concentrations, respectively. The effects of morin and NMCM hydrogel on the proliferation of chondrocytes were detected by cell counting kit 8 (CCK-8). After co-cultured with NMCM hydrogel loaded with 50 µmol/L morin, the level of collagen type Ⅱ (COL-Ⅱ) of KOA chondrocytes was detected by immunofluorescence staining, and the level of reactive oxygen species (ROS) was detected by 2, 7-dichlorodihydrofluorescein diacetate (DCFH-DA) probe. Twenty 4-week old Sprague Dawley rats were selected to construct a articular cartilage injury of right hind limb model, and were randomly divided into two groups (n=10). The cartilage injury of the experimental group was repaired with NMCM hydrogel loaded with 25 µmol/L morin, and the control group was not treated. At 4 weeks after operation, the repair of cartilage injury was observed by micro-CT and gross observation and scored by the International Cartilage Repair Association (ICRS) general scoring. The cartilage tissue and subchondral bone tissue were observed by Safranine-O-fast green staining and COL-Ⅱ immunohistochemistry staining and scored by ICRS histological scoring. The expressions of tumor necrosis factor α (TNF-α), nuclear factor κB (NK-κB), matrix metalloproteinase 13 (MMP-13), and COL-Ⅱ were detected by Western blot and real-time fluorescence quantitative PCR. Results NMCM hydrogels loaded with different concentrations of morin were successfully constructed. The drug release rate was fast in a short period of time, gradually slowed down after 24 hours, and the amount of drug release was close to 0 at 96 hours. At this time, the cumulative drug release rate reached 88%. Morin with a concentration ≤50 µmol/L had no toxic effect on chondrocytes, and the proliferation of chondrocytes improved under the intervention of NMCM hydrogel (P<0.05). NMCM hydrogel loaded with morin could increase the level of COL-Ⅱ in KOA chondrocytes (P<0.05) and reduce the level of ROS (P<0.05), but it did not reach the normal level (P<0.05). Animal experiments showed that in the experimental group, the articular surface was rough and the defects were visible at 4 weeks after operation, but the surrounding tissues were repaired and the joint space remained normal; in the control group, the articular surface was rougher, and no repair tissue was found for cartilage defects. Compared with the control group, the experimental group had more chondrocytes, increased COL-Ⅱ expression, and higher ICRS gross and histological scores (P<0.05); the relative expressions of MMP-13, NF-κB, and TNF-α protein and mRNA significantly decreased (P<0.05), and the relative expressions of COL-Ⅱ protein/COL-2a1 mRNA significantly increased (P<0.05). Conclusion NMCM hydrogel can promote chondrocytes proliferation, down regulate chondrocyte catabolism, resist oxidative stress, protect chondrocytes from cartilage injury, and promote cartilage repair.
【Abstract】ObjectiveTo construct eukaryotic expression vector pSecTag2/HygroB-CD59 of human CD59 and transfect NIH3T3 cells after encapsulated by chitosan. MethodsThe human CD59 fragments were obtained by PCR form CD59-pGEM-T Easy Vector, cloned into the eukaryotic expression vector pSecTag2/HygroB, identified by restriction endonuclease’s digestion and DNA sequencing. After the particles of pSecTag2/HygroB-CD59 were encapsulated by chitosan, the NIH3T3 cells were transfected by chitosanCD59 nanoparticles and detected CD59 expression by immunohistochemistry stain. ResultsThe CD59 fragment was 312 bp. Its sequence was as same as CD59 cDNA in Genbank. After having been transfected by chitosan-CD59 nanoparticles in 24 hours, the 3T3 cells showed diffusely positive in the cytoplasms by anti-CD59 immunohistochemistry. ConclusionThe eukaryotic expression vector of human CD59 is constructed and transfected to NIH3T3 cells after encapsulated by chitosan. It will be very helpful for further study on transgenic livers.
Objective To investigate the preparation of a chitosanencapsulated porus calcium polyphosphate (CPP) bioceramic so as to provide a feasible approach to repair of the bone defect. Methods The chitosan microspheres were produced by chemical procedures. The CPP bioceramic was made by the following steps: annealing, ball milling, admixing, and calcinating. The chemical method was used to encapsule the calcinated bioceramic by the porus chitosan film. The physicochemical property, biomechanical property, and toxicity of the chitosanencapsulated porus CPP bioceramic were analyzed. Results The uniform holes were observed in the CPP bioceramic under a microscope. The diameter of the hole was 100300 μm. The chitosan microballoons were amber in color. The particles were uniform with a diameter of 200-400 μm, with a poor compressive strength. They could be easily ground by hand. Themaximally tolerated dose of the CPP bioceramic leaching liquor given to the Jimpy mice of both sexes was gt;24g/kg on average. The compressive strength reached 200 MPa, and the interval porosity was about 60%-80%, which could completely meet with the compressive strength of the bone substitute. Conclusion The chitosancncapsulated porous CPP bioceramic can be used as a good porous bioceramic scaffold material, which has a good biomechanical property withno acute toxicity, and so may be used as an excellent material for the bone substitute.
Objective To investigate the effect of carboxymethylated chitosan (CMCS) on the proliferation, cell cycle, and secretion of neurotrophic factors in cultured Schwann cells (SCs). Methods SCs were obtained from sciatic nerves of 20 Sprague Dawley rats (3-5 days old; male or female; weighing, 25-30 g) and cultured in vitro, SCs were identified and purified by immunofluorescence against S-100. The cell counting kit 8 (CCK-8) assay was used to determine the proliferation of SCs. The SCs were divided into 4 groups: 50 μg/mL CMCS (group B), 100 μg/mL CMCS (group C), 200 μg/mL CMCS (group D), and the same amount of PBS (group A) were added. The flow cytometry was used to analyze the cell cycle of SCs; the real-time quantitative PCR and Western blot analysis were used to detect the levels of never growth factor (NGF) and ciliary neurotrophic factor (CNTF) in cultured SCs induced by CMCS. Results The purity of cultured SCs was more than 90% by immunofluorescence against S-100; the CCK-8 results indicated that CMCS in concentrations of 10-1 000 μg/mL could promote the proliferation of SCs, especially in concentrations of 200 and 500 μg/mL (P lt; 0.01), but no significant difference was found between 200 and 500 μg/mL (P gt; 0.05). CMCS at a concentration of 200 μg/mL for 24 hours induced the highest proliferation, showing significant difference when compared with that at 0 hour (P lt; 0.01). The percentage of cells in phase S and the proliferation index were significantly higher in groups B, C, and D than in group A (P lt; 0.05), in groups C and D than in group B (P lt; 0.05); and there was no significant difference between group C and group D (P gt; 0.05). Real-time quantitative PCR and Western blot results showed that the levels of NGF and CNTF in groups B, C, and D were significantly higher than those in group A (P lt; 0.05), especially in group D. Conclusion CMCS can stimulate the proliferation, and induce the synthesis of neurotrophic factors in cultured SCs.