OBJECTIVE To testify the inductive osteogenesis of allogeneic bone matrix gelatin (BMG) in promoting intervertebral fusion. METHODS The gelatin sponge, allogeneic BMG, decalcified bone matrix (DBM) and alcohol conserved bone were implanted respectively into the intervertebral space of rabbit, whose intervertebral discs were removed before implantation. The intervertebral spaces were evaluated by X-ray and histological examination at 4, 8, and 12 weeks after operation. RESULTS No obvious immune rejection was observed. Amounts of new bone were formed in the intervertebral spaces at 4 and 8 weeks. And complete infusion of the intervertebral spaces were appeared at 12 weeks. CONCLUSION Allogeneic BMG can promote bone fusion of intervertebral spaces through osteoinduction, which suggests that allogeneic BMP is an ideal substitute for bone replacement.
Objective To investigate the effect of homograft of marrow mesenchymal stem cells (MSCs) seeded onto poly-L-lactic acid (PLLA)/gelatin on repair of articular cartilage defects. Methods The MSCs derived from36 Qingzilan rabbits, aging 4 to 6 months and weighed 2.5-3.5 kg were cultured in vitroand seeded onto PLLA/gelatin. The MSCs/ PLLA/gelatin composite was cultured and transplanted into full thickness defects on intercondylar fossa. Thirty-six healthy Qingzilan rabbits were made models of cartilage defects in the intercondylar fossa. These rabbits were divided into 3 groups according to the repair materials with 12 in each group: group A, MSCs and PLLA/gelatin complex(MSCs/ PLLA/gelatin); group B, only PLLA/gelatin; and group C, nothing. At 4,8 and 12 weeks after operation, the gross, histological and immunohistochemical observations were made, and grading scales were evaluated. Results At 12 weeks after transplantation, defect was repaired and the structures of the cartilage surface and normal cartilage was in integrity. The defects in group A were repaired by the hylinelike tissue and defects in groups B and C were repaired by the fibrous tissues. Immunohistochemical staining showed that cells in the zones of repaired tissues were larger in size, arranged columnedly, riched in collagen Ⅱ matrix and integrated satisfactorily with native adjacent cartilages and subchondral bones in group A at 12 weeks postoperatively. In gross score, group A(2.75±0.89) was significantly better than group B (4.88±1.25) and group C (7.38±1.18) 12 weeks afteroperation, showing significant differences (P<0.05); in histological score, group A (3.88±1.36) was better than group B (8.38±1.06) and group C (13.13±1.96), and group B was better than group C, showing significant differences (P<0.05). Conclusion Transplantation of mesenchymal stem cells seeded onto PLLA/gelatin is a promising way for the treatment of cartilage defects.
Objective To introduce an injectable andin situ gelling gelatin hydrogel, and to explore the possibility as a carrier for demineralized bone matrix (DBM) powder delivery. Methods First, thiolated gelatin was prepared and the thiol content was determined by Ellman method, and then the injectable andin situ gelling gelatin hydrogel (Gel) was formed by crosslinking of the thiolated gelatin and poly (ethylene oxide) diacrylate and the gelation time was determined by inverted method. Finally, the DBM-Gel composite was prepared by mixing Gel and DBM powder. The cytotoxicity was tested by live/dead staining and Alamar blue assay of the encapsulated cells in the DBM-Gel. Forin vitro cell induction, C2C12 cells were firstly incubated onto the surface of the DBM and then the composite was prepared. The experiment included two groups: DBM-Gel and DBM. The alkaline phosphatase (ALP) activity was determined at 1, 3, 5,and 7 days after culture.In vivo osteoinductivity was evaluated using ectopic bone formation model of nude rats. Histological observation and the ALP activity was measured in DBM-Gel and DBM groups at 4 weeks after implantation. Results The thiol content in the thiolated gelatin was (0.51±0.03) mmol/g determined by Ellman method. The gelation time of the hydrogel was (6±1) minutes. DBM powder can be mixed with the hydrogel and injected into the implantation site within the gelation time. The cells in the DBM-Gel exhibited spreading morphology and connected each other in part with increasing culture time. The viability of the cells was 95.4%±1.9%, 97.3%±1.3%, and 96.1%±1.6% at 1, 3, and 7 days after culture, respectively. The relative proliferation was 1.0±0.0, 1.1±0.1, 1.5±0.1, and 1.6±0.1 at 1, 3, 5, and 7 days after culture respectively.In vitro induction showed that the ALP activity of the DBM-Gel group was similar to that of the DBM group, showing no significant difference (P>0.05). With increasing culture time, the ALP activities in both groups increased gradually and the activity at 5 and 7 days was significantly higher than that at 1 and 3 days (P<0.05), while there was no significant difference between at 1 and 3 days, and between 5 and 7 days (P>0.05). At 4 weeks after implantationin vivo, new bone and cartilage were observed, but no bone marrow formation in DBM-Gel group; in DBM group, new bone, new cartilage, and bone marrow formation were observed. The histological osteoinduction scores of DBM-Gel and DBM groups were 4.0 and 4.5, respectively. The ALP activities of DBM-Gel and DBM groups were respectively (119.4±22.7) and (146.7±13.0) μmol/mg protein/min, showing no significant difference (t=–2.085,P=0.082). Conclusion The injectable andin situ gelling gelatin hydrogel for delivery of DBM is feasible.
OBJECTIVE To study the function of the composite of bone matrix gelatin(BMG) and plaster in the repairing process of bone defects. METHODS Sixteen New Zealand rabbits which were defected in corpus radii were made as implant zone of bone. Sixteen sides of radii were implanted with the composite of BMG and plaster as experimental group. Others were implanted with BMG(8 sides) and bone stored in alcohol(8 sides) as control groups. The repairing process in bone defects were observed by X-ray and histological examination. RESULTS There was an obvious osteogenesis in experimental group. The defects of radii were almost healed at 12th week after operation. There were osteogenesis in both control groups, but the repairing process was slower than that of the experimental group. CONCLUSION The composite of BMG and plaster is a good material for bone transplantation.
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 fabricate a novel porous bioactivecomposite biomaterial consisting of poly lactic acid (PLA)bone matrix gelatin(BMG) by using the supercritical carbon dioxide fluid technique (SC-CO2) and to evaluate its osteoinductive activity. Methods The cortical bones selected from healthy adult donors were processed into BMG by the defatting, demineralizing, and deproteinizing processes. PLA and BMG were mixed at a volume radio of 3∶1; then, the PLA-BMG mixed material and the pure PLA material were respectively placed in the supercritical carbon dioxide reaction kettles, and were respectively added by the NaCl particles 100200 μm in diameter for theporosity of the materials so that the porous PLA-BMG composite material and the porous PLA composite material could be formed. The mouse osteoblastlike MC3T3-E1 cells were cultured in the dulbecco’s modified eagle medium (DMEM) supplemented with 10% fetal bovine serum. Then, 20 μl of the MC3T3E1 cell suspensions containing 2 ×106 cells /ml were delivered into the culturing plate (24 wells/plate) made of the different materials, which were co-cultured for 2 weeks. In the PLA-BMG group, 100 μg of the crushed PLA-BMG material was contained in each well; in the PLA group, 100 μg of the crushed PLA material was containedin each well; and in the DMEM group, only DMEM was contained, which served as the control group. There were 6 wells in each group. The quantitative analysis onthe calcification area was performed by the staining of the alizarin red S. Theco-cultured cells were harvested and lysated in 1 ml of 0.2% Nonidet P-40 by the ultrasonic lysating technique. Then, the ALP activity and the Ca content were measured according to the illuminations of the reagent kits. Results The porous PLABMG composite material showed a good homological porosity with a pore diameter of 50-150 μm and a good connectivity between the pores. The ALP activity, the Ca content, and the calcification area were significantly greater in the PLABMG group than in the PLA group and the control group (325.59±70.40 U/gprot, 3.51±1.64 mmol/gprot, 42.98±4.44% vs. 63.62±30.01 U/gprot, 1.04±0.21 mmol/gprot, 9.55±1.94%, and 2.40±1.47 U/gprot, 0.70±0.24 mmol/gprot, 0.86±0.41%; Plt;0.05). Meanwhile, there was a statistically significant difference between the PLA group and the control group in the ALP activity and the calcification area (Plt;0.05). Conclusion The porous PLABMG composite material prepared by the use of SC-CO2 has a good steoinductive activity and can be used as a promising bone biomaterial and a bone tissue engineered scaffold.
ObjectiveTo study the expression of lipid associated with neutrophil gelatinase associated lipocalin (NGAL) in nude mice orthotopic pancreatic cancer tissues and the relationship between the occurred and development of pancreatic cancer. MethodsThe expressions of NGAL mRNA and protein of pancreatic cancer tissues and their adjacent tissues, and normal pancreatic tissues in nude mice were detected by using RT-PCR and immunohistochemical methods. ResultsThe expressions of NGAL mRNA in pancreatic cancer tissues and adjacent tissues were significantly higher than that in normal pancreatic tissues (P < 0.05), and the expression of NGAL mRNA in pancreatic carcinoma tissues was significantly higher than that in para carcinoma tissues (P < 0.05). The strong positive expression rate of NGAL protein in pancreatic carcinoma tissues was significantly higher than thoes in para carcinoma tissues and normal pancreatic tissues (P < 0.05). ConclusionsNGAL is highly expressed in pancreatic cancer tissues, and NGAL may be an important regulatory factor in the development of pancreatic cancer.
Objective To investigate the effect of “two-phase” tissue engineered cartilage constructed by autologous marrow mesenchymal stem cells(MSCs) and allogeneic bone matrix gelatin(BMG) in repairing articular cartilage defects. Methods Thirty-twoNew Zealand white rabbits were involved in the experiment. “Two-phase” allogeneic BMG scaffold (one side of porous cancellous bone and the other side of cortical bone; 3 mm both in diameter and in thickness) was prepared from iliac bone and limb bone of 5 rabbits by sequentially chemical method. The MSCs wereseparated from 18 New Zealand white rabbits and induced to express chondrocyticphenotype. The chondrocyte precursor cells were seeded onto “two-phase” allogeneic BMG to construct tissue engineering cartilage. Masson’s trichrome staining, PAS staining and scanning electronic microscopic observation were carried out at 1, 3 and 5 weeks. The defects of full thickness articular cartilage(3 mm both in diameter and in depth) were made at both sides of femoral medial condyles in 27 rabbits(including 18 of separated MSCs and the remaining 9). The defects were repaired with the tissue engineered cartilage at the right side (group A, n=18), with BMG at the left side(group B, n=18), and without any implant at both sides in the remaining 9 rabbits as a control( group C, n=18). After 1, 3 and6 months, the 6 specimens of femoral condyles were harvested in 3 groups, respectively. Gross observation, Masson’s trichrome and Alcian blue staining, modified Wakitani scoring and in situ hybridization of collagen type Ⅱ were carried out to assess the repair efficacy of tissue engineered cartilage. Results The “two-phase” BMG consisted of the dense cortical part and the loose cancellous part. In cancellous part, the pore size ranged 100-800 μm, in which the chondrocyte precursor cells being induced from MSCs proliferated and formed the cell-rich cartilaginous part of tissue engineered cartilage. In cortical part, the pore size ranged 10-40 μm, on which the cells arranged in a layer and formed the hard part of subchondral bone. After 1 month of transplantation, the cartilage and subchondral bone were regenerated in group A; during observation, the regenerated cartilage graduallythinned, but defect was repaired and the structure of the articular surface ansubchondral bone was in integrity. In groups B and C, defects were not repaired, the surrounding cartilage of defect was abrased. According to the modified Wakitani scoring, the indexes in group A were significantly higher than those in group B and C(Plt;0.01) except the thickness of cartilage at 6 months. The positive cell rate of in situ hybridization for collagen type Ⅱ in group A was also higher than those in groups B and C(Plt;0.01). Conclusion “Two-phase” allogeneic BMG is a prospective scaffold for tissue engineered cartilage,which combines with autologous chondrocyte precursor cells induced from MSCs toconstruct the tissue engineering cartilage. The tissue engineered cartilage can repair defects of articular cartilage and subchondral bone.
Objective To evaluate the biocompatibil ity of a new nano TCP/ gelatin / velvet antler polypeptide material. Methods The nano TCP/ gelatin / velvet antler polypeptide material was prepared, and the morphous was observed by scanning electron microscope. L929 and NIH/3T3 cell l ines were cultured conventionally. Acute toxicity test, hemolysis test, cell prol iferation and cytotoxicity test were used to evaluate the biocompatibil ity of the material. Results The compositemicrosphere material was about 10 μm in diamerter and had good spherical geometry, high monodispersity with nanometer size holes on the surface. Toxic symptoms such as hyperspasmia, palsy and death did not appear during the observing stage in acute toxicity test. Maximum hemolysis rate of the material was less than 5% which met the requirement of hemolysis test standard as a medical material. Different concentrations of the materials leaching l iquor could enhance the prol iferation of NIH/3T3 cells, which showed the good biologic activity. Toxicity grade was 0, and the material was no cytotoxic. Conclusion Nano TCP/ gelatin / velvet antler polypeptide material has good biocompatibil ity.
Objective To evaluate the biomechanicalproperties and structuralcharacteristics of various composites of partially decalcified allogenic bone matrix gelatin and bone cement at different ratios. Methods According to Urist method, partially decalcified allogenic bone matrix gelatin was prepared and mixedwith bone cement at different ratios of 0, 400, 500, and 600mg/g. Then the comparisons of these composites were performed in microstructure, ultimate compression strength and ultimate bending strength properties. Results The electronic microscope showed that the bone particles and bone cement were distributed evenly in the composite, irregularly connecting by multiple points; with the increase ofbone particles and decrease of bone cement in the composite, there were more and more natural crevices, varying from 100 μm to 400 μm in width, in the biomaterials. Of all the composites with the ratios of 0, 400,500, and 600 mg/g, the measurements of ultimate compression strength were (71.7±2.0) MPa, (46.9±3.3) MPa, (39.8±4.1) MPa, and (32.2±3.4) MPa, respectively; and the measurements ofultimate bending strength were (65.0±3.4) MPa, (38.2±4.0) MPa, (33.1±4.3) MPa and (25.3±4.6) MPa, respectively. Conclusion The compositeof partially decalcified allogenic bone matrix gelatin and bone cement has a good biomechanical property and could be easily fabricated and re-shaped, which make it available to be used clinically as an idea bone graft biomaterial.