ObjectiveTo explore the relationship between subchondral bone reconstruction and articular cartilage regeneration in a rabbit model of spontaneous osteochondral repair. MethodsTwenty-four 6-month-old New Zealand white rabbits were included. The osteochondral defects (4 mm in diameter and 3 mm in depth) were created in the trochlear groove of the unilateral femur, which penetrated the subchondral bone without any treatment. The rabbits were sacrificed at 1, 4, 12, and 24 weeks after operation, respectively. The specimens were obtained for macroscopic, histological, and immunohistochemical observations. According to the International Cartilage Repair Society (ICRS) histological scoring, the effect of cartilage repair was assessed. The histomorphometrical parameters of subchondral bone were analyzed by micro-CT scan and reconstruction, and the relationship between cartilage repair and the histomorphometrical parameters of the subchondral bone were also analyzed. ResultsOsteochondral defects could be repaired spontaneously in rabbit model. With time, defect was gradually filled with repaired tissue, subchondral bone plate under the defect region gradually migrated upward. Bone mineral density, bone volume fraction, tissue mineralized density, trabecula number, and trabecula thickness were increased, while trabecula spacing was decreased. Significant difference was found in the other parameters between different time points (P<0.05) except for trabecula thickness between at 4 and 12 weeks after operation (P>0.05). Histological examination showed that fibrous repair was predominant with rare hyaline cartilage. With time, ICRS scores increased gradually, showing significant differences between other time points (P<0.05) except for between at 4 and 12 weeks after operation (P>0.05). Among the histomorphometrical parameters of subchondral bone, the trabecula spacing was negatively correlated with ICRS score (r=-0.584, P=0.039), and the other histomorphometrical parameters were positively correlated with ICRS score (r=0.680-0.891). ConclusionThere is relevant correlation as well as independent process between cartilage regeneration and subchondral bone reconstruction in the rabbit model of spontaneous osteochondral repair, and fast subchondral bone remodeling may adversely affect articular cartilage repair.
ObjectiveTo investigate the effect of three-dimensional cultivation with dynamic compressive stimulation on promotion of cartilage growth in vitro, by constructing tissue engineered cartilage with three-dimensional porous articular cartilage extracellular matrix (ECM) scaffolds laden with rabbit chondrocytes and performing mechanical stimulation by compressive stress in bioreactor. MethodsChondrocytes of healthy adult New Zealand rabbits were isolated, and passage 2 chondrocytes were seeded onto three-dimensional porous articular cartilage ECM scaffolds for 5 days pre-cultivation, and then were divided into 2 groups:Group A continued static culture as control; group B (dynamic culture condition) underwent dynamic compressive strain stimulation (compressive strain of 15%, frequence of 1 Hz) in a bioreactor. Cell viability and distribution in scaffolds were observed; the glycosaminoglycan (GAG) content, collagen content, and total DNA content were measured after 3 weeks of culturing; and elastic modulus was evaluated by mechanical test. ResultsLaser scanning confocal microscopy indicated that cells grew well and evenly distributed in the scaffold of group B, while poor cells growth and loss of staining in the central region of the scaffolds were observed in group A. Scanning electron microscopy showed that chondrocytes possessed good adhesion, proliferation, and growth on the scaffolds of group B; while the number of chondrocytes was significantly reduced, and cells scattered in group A. Biochemical composition analysis showed that collagen, GAG, and DNA contents of cell-scaffold constructs were (675.85±27.93) μg/mg, (621.72±26.75) μg/mg, and (16.98±3.23) μg/sample in group B, and were (438.72±6.35) μg/mg, (301.63±30.51) μg/mg, and (10.18±4.39) μg/sample in group A respectively, which were significantly higher in group B than in group A (t=18.512, P=0.000;t=17.640, P=0.000;t=2.790, P=0.024). Mechanical testing indicated that the elastic modulus of group B[(0.67±0.09) MPa] was significantly higher than that of group A[(0.49±0.16) MPa] and cell-free scaffolds[(0.43±0.12) MPa] (P < 0.05). ConclusionMimetic compressive stress with three-dimensional dynamic conditions created in the bioreactor is superior to the ordinary static three-dimensional cultivation, it can provide the optimal environment for chondrocytes on the ECM scaffolds, which may be a good way to construct tissue engineered cartilage in vitro.
ObjectiveTo explore the degradation of AZ31 magnesium alloy and poly (lactic-co-glycolic acid) (PLGA) in the femoral condyle, and then evaluate the laws of degradation of AZ31 magnesium alloy by Micro-CT images and data. MethodsForty 3-month-old male New Zealand white rabbits (weighing, 2.5 kg) were randomly divided into 4 groups, 10 rabbits each group. Forty micro-arc-oxidized AZ31 magnesium alloy pins and 40 PLGA pins were implanted into the right and left femoral condyle, respectively. Micro-CT images and data analysis were used to evaluate the degradation at 4, 8, 12, and 16 weeks after operation (n=10). Degradation was evaluated by weight difference between pre-and post-implantation. The inflammatory response was observed around the implants by HE staining. The weight loss of magnesium alloy and Micro-CT results were compared. ResultsThe Micro-CT images showed that PLGA pins had gray low signal, which was similar to the soft tissue around. At 4 weeks after operation, no signs of degradation were observed, and there were little corrosion pitting on the magnesium alloy. At 8 weeks, corrosion pitting gradually expanded, the boundary between the longitudinal axis and the cross section became blurred; at 16 weeks, corrosion pitting became bigger, and the boundary was discontinuous. Micro-CT quantitative analysis showed that the volume fraction of magnesium pins decreased slowly at 4 and 8 weeks; it was significantly lower at 12 and 16 weeks than 4 and 8 weeks (P < 0.05). The magnesium cylinder mineral density continuously decreased during the study period, it had a rapidly speed from 12 to 16 weeks (P < 0.05). However, the magnesium CT image density showed a slight change (P>0.05). The surface-to-volume ratio of the pins constantly increased, and the ratio was significantly larger at 12 and 16 weeks than 4 and 8 weeks, and at 16 weeks than 12 weeks (P < 0.05). There was more and more corrosion pitting on the surface with time, which resulted in a decrease in the radius that mean trabecular thickness gradually decreased, showing significant difference between different time points after 8 weeks (P < 0.05). The weight loss detection showed that the degradation of magnesium pin and PLGA gradually increased with time (P < 0.05), and the degradation rate of magnesium pin was significantly lower than that of PLGA at 8-12 weeks (P < 0.05), but the degradation rate of magnesium pin was higher than that of PLGA at 16 weeks. At each time point, the weight loss of magnesium alloy was similar to that by Micro-CT, but mass fraction was lower than volume fraction and had significant differences at 8, 12, and 16 weeks (P < 0.05). HE staining revealed that slight inflammatory response was observed around the magnesium pins at 4 weeks, and inflammatory reaction gradually reduced with time and disappeared at 16 weeks, but no inflammatory reaction was seen around PLGA. ConclusionMicro-CT has the advantages of non-trauma, in vivo detection, quantitative analysis, and precise data in evaluating the degradation of AZ31 magnesium alloy. Regarding the degradation of the magnesium alloy and PLGA in vivo, the degradation rate is slow in the early stage, and then increases with time. The degradation of PLGA is faster and earlier but it is then overtaken by AZ31 magnesium alloy at 16 weeks. During the degradation, the density of the magnesium has almost no change. The biomaterials can not firmly attach to the surrounding tissues due to inadequate holding forces.
ObjectiveTo introduce a technique of frozen sections for undecalcified bone and discuss its feasibility by observing the fluorescence distribution of the bone and cartilage. MethodsThe male Sprague Dawley transgenic rats at the age of 8 weeks, which express green fluorescent protein were selected to isolate the whole knee sectioned by the undecalcified bone frozen section technique. Under the fluorescence and light microscopy, the fluorescence and structure were observed within the organization of slice. Immunohistochemical staining (collagen type Ⅰ and Ⅱ), HE staining, toluidine blue staining, and Alizarin red staining were performed to observe the distribution of fluorescent substance and cartilage and bone structure. ResultsThe thickness of sections prepared by this technology was 6 μm. General observation showed that the structure of sectioned joint was complete. Under the light microscope, the morphology of cartilage cells, the arrangement of subchondral bone, and trabecular bone traveling could be clearly distinguished. Under fluorescence microscope, green fluorescence was shown in the joint soft tissue, cartilage tissue, and bone tissue; collagen type Ⅰ expressed in the bone tissue, collagen type Ⅱ in cartilage tissue. HE staining and toluidine blue staining could clearly distinguish the morphology of the cartilage layer. Alizarin red staining showed the structural integrity of subchondral bone plate and the organization within the meniscus, and proximal tibia cortical bone continuity. ConclusionThe fluorescence distribution can be directly observe in the bone and cartilage by sectioning of frozen undecalcified bone. This new technology can shorten the cycle of preparing sections.