Objective To study the effect of two cytokines, basic fibroblast growth factor(bFGF) and insulin-like growth factor-I(IGF-I), on cell proliferation in chondrocytes of adult rabbits. Methods The primary chondrocytes of adult rabbits were harvested and cultured with bFGF and IGF-I at different concentrations,respectively, as well as with the mixture of the two cytokines; the quantity of cultured chondrocytes was detected by MTT assay at the 24th, 48th and 72th hours; and the final fold increase of different groups was measured by cell count for the 3rd passage; and the proliferation index of the groups was recorded by flowing cytometer on the 14th day. Results ① The cultured chondrocytes with either bFGF, IGF-I or their mixture were significantly more than that of control group at the 24th, 48th and 72th hours (P<0.01). ② After the 3rd passage, the final folds of proliferation were significantly higher in the groups with cytokinesthan in the control group (P<0.01); and the final fold with the mixture ofcytokines was significantly higher than that of both IGF-I and bFGF (P<0.01). ③ Theproliferation index was significantly higher in the groups with cytokines than in the control group (P<0.01); the proliferation index with the mixture of cytokines was significantly higher than that of both IGF-I and bFGF (P<0.05); besides, proliferation index was higher when cytokine was applied twice than once (P<0.05). Conclusion bFGF and IGF-I could promote chondrocytes proliferation of adult rabbits obviously and they are synergistic in cell proliferation.
OBJECTIVE: To study chondrogenesis of calcium alginate-chondrocytes predetermined shapes. METHODS: Chondrocytes isolated from ears of rabbit by type II collagenase digestion, and then were mixed with 1.5% solidium alginate solution. The suspension was gelled to create three spatial shapes as triangle, circle and quadrilateral by immersed into 2.5% CaCl2 for 90 minutes, and then was implanted into the subcutaneous pocket on the dorsum of the rabbit. Samples were harvested at 6 and 12 weeks after implantation. RESULTS: Gross examination of excised specimens at 6 and 12 weeks after implantation revealed the presence of new cartilage of approximately the same dimensions as the original construct. Histologic evaluation using hematoxylin and eosin stains confirmed the presence of cartilage nodules at 6 weeks after implantation. After 12 weeks, mature cartilage was observed and histologic analysis confirmed the presence of well formed cartilaginous matrix. CONCLUSION: Predetermined shapes neocartilage can be regenerated using calcium alginate as a carrier of chondrocytes in the bodies of immune animals.
Objective To evaluate the synergistic effect of bone morphogenetic protein 14 (BMP-14) and chondrocytes co-culture on chondrogenesis of adipose-derived stem cells (ADSCs) so as to optimize the source of seed cells for cartilage tissue engineering. Methods ADSCs and chondrocytes were isolated and cultured respectively from articular cartilage and subcutaneous fat of 2 male New Zealand white rabbits (weighing, 1.5 kg and 2.0 kg). The cells at passage 3 were harvested for experiment. ADSCs were identified by osteogenic induction (alizarin red staining), chondrogenic induction (alcian blue staining), and adipogenic induction (oil red O staining). The optimum multiplicity of infection (MOI) of transfection of adenovirus-cytomegalovirus (CMV)-BMP-14-internal ribosome entry site (IRES)-human renilla reniformis green fluorescent protein 1 (hrGFP-1) was determined and then ADSCs were transfected by the optimum MOI. The experiment was divided into 5 groups: group A, co-culture of ADSCs transfected by BMP-14 and chondrocytes (1 ∶ 1 in Transwell chambers); group B, co-culture of ADSCs and chondrocytes (1 ∶ 1 in Transwell chambers); group C, culture of ADSCs transfected by BMP-14; group D, simple chondrocytes culture; and group E, simple ADSCs culture. After 3 weeks, the glycosaminoglycan (GAG) content was detected by alcian blue staining; the expressions of collagen type II and BMP-14 protein were detected by Western blot; expression of Sox-9 gene was detected by RT-PCR. Results The cultured cells were proved to be ADSCs by identification. Inverted fluorescence microscope showed optimum transfection effect when MOI was 150. GAG content, expressions of collagen type II and BMP-14 protein, expression of Sox-9 gene were significantly higher in groups A and C than in the other 3 groups, in group A than in group C (P lt; 0.05), and groups B and D were significantly higher than group E (P lt; 0.05), but no significant difference was found between groups B and D (P gt; 0.05). Conclusion It can promote differentiation of ADSCs into chondrocytes by BMP-14 co-culture with chondrocytes, and they have a synergistic effect.
OBJECTIVE: To observe the effect of engineered epiphyseal cartilage regenerated in vitro with 3-D scaffold by chondrocytes from epiphyseal plate in repairing the tibial epiphyseal defect, and to explore the methods to promote the confluence between engineered cartilage and epiphyseal plate. METHODS: Chondrocytes were isolated enzymatically from the epiphyseal plates of immature rabbits, and then planted into the tissue culture flasks and cultivated. The first passage chondrocytes were collected and mixed fully with the self-made liquid biological gel at approximately 2.5 x 10(7) cells/ml to form cell-gel fluid. The cell-gel fluid was dropped into the porous calcium polyphosphate fiber/poly-L-lactic acid(CPPf/PLLA)scaffold, and a cell-gel-scaffold complex formed after being solidified. The defect models of 40% upper tibial epiphyseal plate were made in 72 immature rabbits; they were divided into 4 groups: group A(the cell-gel-scaffold complex was transplanted into the defect and the gap filled with chondrocyte-gel fluid), group B (with noncell CPPf/PLLA scaffold), group C(with fat) and group D(with nothing). The changes of roentgenograph, gross and histology were investigated after 2, 4, 6, 8, 12 and 16 weeks of operation. RESULTS: In group A, the typical histological structure of epiphyseal plate derived from the engineered cartilage with a fine integration between host and donor tissues after 2 weeks. The repaired epiphyseal plate had normal histological structure without deformation of tibia after 4 weeks. The early histological change of epiphyseal closure appeared in the repaired area with varus and shortening deformation of the tibia after 8 weeks. The epiphyseal plate was closed in the repaired area with more evident deformation of tibia; the growth function of repaired epiphyseal plate was 43.6% of the normal one. In groups B, C and D, deformation of tibia occurred after 2 weeks; the defect area of epiphyseal plate was completely closed after 4 weeks. The deformation was very severe without growth of the injured epiphyseal plate after 16 weeks, and no significant difference was observed between the three groups. CONCLUSION: Engineered epiphyseal cartilage can repair the epiphyseal defect in the histological structure with partial recovery of the epiphyseal growth capability. Injecting the suspension of fluid chondrocyte-gel into the defects induces a fine integration of host and donor tissues.
Objective To study the effects of the periosteum,synovium andcartilage tissues on the gene expressions of proteoglycan, collagen Ⅱ, andnuclear factor kappa B (NF-κB) and to investigate the different effects of these tissues on cartilage regeneration. Methods In 20 New Zealand white rabbits, 20 cartilage explants were taken from the knee joints in each rabbit, the sizeof which was 4 mm×4 mm×4 mm. All the cartilages were divided into the following 4 groups and cultured for 7 days: Group A, with 5 pieces (2 mm×2 mm) of the synovium of theknee joints in each dish; Group B, with 5 pieces (2 mm×2 mm) of the periosteum ineach dish; Group C, with 5 pieces (2 mm×2 mm×2 mm) of the cartilage in each dish; and Group D, with no addition of other tissues (control group). RNA was extracted from the cells of the cartilage explants (4 mm×4 mm×4 mm) in all the dishes. Thegene expressions of proteoglycan, collagen Ⅱ and NF-κB were defected by a reversetranscription-polymerase chain reaction (RT-PCR).Results In group A, the gene expression of proteoglycan was significantly decreased. The relative density of this gene expression had a significant difference when compared with that in group D (1.09±0.21 vs. 1.25±0.25, Plt;0.05); the gene expressions of collagen Ⅱ and NF-κB were also decreased, but they had no significant differences when compared with those in group D (Pgt;0.05). In groupB, the gene expressions of proteoglycan, collagen Ⅱ, and NF-κB were significantly increased. The relative densities of these gene expressions were 1.60±0.26, 1.57±0.24, and 4.20±2.22, respectively, which had significant differences when compared with those in group D (Plt;0.05). In group C, the relative density of the gene expression of collagen Ⅱ was 1.43±0.28, which had a significant difference when compared with that in group D (Plt;0.05), but therelative densities of the gene expressions of proteoglycan and NF-κB had no significant differences when compared with those in group D (Pgt;0.05). Conclusion The results indicate that the periosteum can up-regulate the gene expressions of proteoglycan, collagen Ⅱ and NF-κB. The NF-κB is likely to be an important nuclear transcription factor related to cartilage regeneration. The results also suggest that the periosteum maybe better in facilitating the cartilage repair and regeneration in clinical practice.
Objective To investigate the feasibil ity of alendronate (ALN) in treating osteoarthritis (OA) by observing the effects of ALN on interleukin 1β (IL-1β) induced chondrocytes of rat in vitro. Methods The chondrocytes of knee articular surface from 15 SD rats (1-month-old, female or male, weighing 100-150 g) were cultured. The chondrocytes were observed by inverted phase contrast microscope and identified by toluidine blue staining and HE staining. The third passage chondrocytes were divided into 3 groups: the chondrocytes were cultured with DMEM for 5 days in group A, with 10 ng/mL IL-1β for 2 days and with DMEM for 3 days in group B, and with 10 ng/mL IL-1β for 2 days and with 1 × 10-6 mol/L ALN for 3 days in group C. Immunocytochemistry and real-time PCR were performed to determine the expression levels of collagen type II (Col II), matrix metalloproteinase 13 (MMP-13), and β-catenin. Results Toluidine blue staining proved that the cultured cells were chondrocytes. The integrated absorbency (IA) value of Col II in group C (10.290 7 ± 0.499 2) was lower than that in group A (15.377 0 ± 0.571 8) and higher than that in group B (5.463 2 ± 0.450 4), showing significant differences (P lt; 0.05). The IA value of MMP-13 in group C (3.068 6 ± 0.205 6) was significantly lower than that in group B (6.998 1 ± 0.329 7, P lt; 0.05), but there was no significant differenc when compared with group A (2.777 5 ± 0.199 6, P gt; 0.05). The IA value of β-catenin in group C (6.611 7 ± 0.381 8) was lower than that in group B (11.799 9 ± 0.348 7) and higher than that in group A (4.390 3 ± 0.551 9), showing significant differences (P lt; 0.05). The mRNA expression of Col II in group C was significantly higher than those in groups A and B (P lt; 0.05), the mRNA expression of MMP-13 in group C was significantly lower than that in group B (P lt; 0.05) but there was no significant difference when compared with group A (P gt; 0.05). The mRNA expression of β-catenin in group C was significantly lower than that in group B (P lt; 0.05) and higher than that in group A (P lt; 0.05). Conclusion ALN can protect rat chondrocyte from OA induced by IL-1β in vitro possibly by upregulating Col II and inhibiting the expression of MMP-13 and β-catenin in the chondrocytes.
Objective To observe the main biological characteristics and chondrogenesis potency of bone marrow -derived stromal cells(MSCs) after cytokinesinduction or gene modification in vitro. Methods MSCs from an adult New Zealand white rabbit were isolated and cultivated, and then MSCs were divided into the common medium group(Group A, 15%FBS in DMEM), the induced group by cytokines (Group B), the transfected group(Group C)with adenovirus-hepatocyte growth factor transgene (adHGF). The medium of group B consisted of transforming growth factor-β1(TGF-β1,10 ng/ml), basic fibroblast growth factor(bFGF,25 ng/ml) addexamethasone (DEX,10-7mol/L) with 15%FBS in DMEM. Cartilage slices wereobtained from femoral condyles and patellar grove in the same rabbit. The minced cartilage was digested in Ⅱ collagenase (3 mg/ml) to obtain chondrocytes(Group D). The change of cell appearance, proliferation capacity, glycosaminoglycans(GAG), immunohistochemical staining for type Ⅰ, Ⅱ collagen were observed during the 5th passage MSCs and MSCs after induction or gene modification. Expression of mRNA for type Ⅰ and Ⅱ collagen was detected by RT-PCR. Results Primary MSCs proliferated as shortspindle shape, while the 5th MSCs showed longspindle shape. Positive stain of type Ⅰ collagen could be found in groups A, B and C, while positivestain of type Ⅱ collagen was shown in groups B and D. The content of GAG in group B was higher than that in group A, but there was no significant difference between them(Pgt;0.05), and there was significant difference between groups A and D(Plt;0.05). No significant difference was noted in groups A,B and C on proliferation by MTT(Pgt;0.05),except that of at the fourth day after transfection between groups A and C(Plt;0.05). RT-PCR demonstrated that MSCs always had higher levelsof mRNA type Ⅰ collagen in groups A, B and C. The expression of mRNA type Ⅱ collagen was identified in groups B and D, and only low levels of mRNA type Ⅱ collagen in group C. Conclusion The above results indicate MSCs have a natural tendency of osteogenic differentiation in vitro culture, and also demonstrate the chondrogenic potency with the technique of cytokines induction or gene modification after passage. MSCs can be transfected efficiently being seed cells in tissue engineered bone or cartilage to accept target genes such as adHGF, and have a higher levels of expression in vitro, which lasted 4 weeks at least.
ObjectiveTo bioinformatically analyze the gene chip data of chondrocytes from osteoarthritis patients from the Gene Expression Omnibus (GEO) database, and explore the molecular mechanisms of osteoarthritis.MethodsWe searched the GEO database (up to April 23rd, 2021) for data of chondrocytes and gene expression profiling in human knee osteoarthritis via the key words of “osteoarthritis OR cartilage OR chondrocyte*”. Then, we selected the samples by our inclusion criteria. The data were normalized before analysis. After differentially expressed genes were identified, Gene Ontology, Kyoto Encyclopedia of Genes and Genomes, Search Tool for the Retrival of Interacting Genes/Proteinsm, R language, Perl language, Cytoscape software, and DAVID database were used to perform differentially expressed gene analysis, functional annotation, and enrichment analysis.ResultsThe differentially expressed genes were mostly enriched in cell components and some extracellular regions, which participated in cell division, mitosis, cell proliferation and inflammatory response mainly via the regulation of protein kinase activity. The differentially expressed genes were mainly involved in the cell proliferation signaling pathway, mitogen-activated protein kinase signaling pathway, oocyte meiosis, cell cycle and so on.ConclusionsMultiple signaling pathways are involved in the changes of chondrocytes in human knee osteoarthritis, mainly about cell cycle and protein metabolism genes/pathways. Inflammatory factors and cytokines may be the most important links in the pathogenesis of osteoarthritis.
Objective To investigate the role of transforming growth factor β(TGF-β)in the regulation of the gene expression of matrix metalloproteinase 13(MMP-13)in the human hyaline chondrocytes. Methods The human hyaline chondrocytes harvested enzymatically and cultured in DMEM supplemented with 20% fetus calf serum were divided into 7 groups. Group 1 was used as a contol, and 1 ng/ml TGF-β(group 2), 10 ng/ml TGF-β(group 3), 100 ng/ml TGF-β(group 4), 1 ng/ml TGF-β+10 ng/ml IL-1β(group 5), 10 ng/ml TGF-β+10 ng/ml IL-1β(group 6),and 100 ng/ml TGF-β+10 ng/ml IL1β(group 7) were given for 12-hour coculture. The MMP-13 mRNA levels of passaged human hyaline chondrocytes were assessed by reverse transcriptionpolymerase chain reaction(RT-PCR) and real-time fluorescent quantitative PCR. Results TGF-β can increase the MMP-13 mRNA level respectively in the passagedhyaline chondrocytes. In the multifactor treated groups, TGF-β can decrease the MMP-13 mRNA level respectively and there was significant difference between groups (Plt;0.05).The level of MMP-13 mRNA expression had significant coherence withthe dosage of TGF-β. Conclusion The above results show that human chondrocytes express MMP-13 mRNA. TGF-β could cause a dosedependent stimulation on MMP-13 gene expression in human chondrocytes and have a potent effect of antagonizing IL-1β in osteoarthritis. TGF-β may play a crucial role in the occurrence anddevelopment of osteoarthritis through regulating MMP-13.
Objective To study the biological characteristic and potential of chondrocytes grafting cultured on fascia in repairing large defect of articular cartilage in rabbits. Methods Chondrocytes of young rabbits were isolated and subcultured on fascia. The large defect of articular cartilage was repaired by grafts of freeze-preserved and fresh chondrocytes cultured on fascia, and free chondrocytes respectively; the biological characteristic and metabolism were evaluated bymacroscopic, histological and immunohistochemical observations, autoradiography method and the measurement of nitric oxide content 6, 12, 24 weeks after grafting. Results The chondrocytes cultured on fascia maintained normal growth feature and metabolism, and there was no damage to chondrocytes after cryopreservation; the repaired cartilage was similar to the normal cartilage in cellular morphology and biological characteristics. Conclusion Chondrocytes could be cultured normally on fascia, which could be used as an ideal carrier of chondrocytes.