Objective To investigate the possibility of differentiation of theisolated and cultured adipose-derived adult stem cells into chondrocytes, which is induced by the recombinant human bone morphogenetic protein 2 (rhBMP-2). Methods The rabbit adipose tissue was minced and digested by collagenase Type Ⅰ. The adposederived adult stem cells were obtained and then they were cultured inthe micropellet condition respectively in the rhBMP-2 group, the rhTGF-β1 group, the combination group, and the control group for 14 days. The differentiation of the adiposederived stem cells into chondrocytes was identifiedby the histological methods including HE, Alcian blue, Von kossa, and immunohistochemical stainings. Results After the continuous induction by rhBMP-2 and continuous culture for 14 days, the HE staining revealed a formation of the cartilage lacuna; Alcian blue indicated that proteoglycan existed in the extracellular matrix; the immunohistochemical staining indicated that collagen Ⅱ was in the cellular matrix; and Von kossa indicated that the adipose-derived stem cells couldnot differentiate into the osteoblasts by an induction of rhBMP-2. Conclusion In the micropellet condition, the adipose-derived adult stemcells can differentiate into the chondrocytes, which is initially induced by rhBMP-2. This differentiation can provide a foundation for the repair of the cartilage injury.
Objective To sum up the experimental and clinical history as wellas latest development of repair of growth plate injury Methods Recent articles about repair of growth plate injury were extensively reviewed and major reparative methods were introduced, especially including tissue engineering research on growth plate.Results Repair of growth plate injury was a great difficulty inexperimental study and clinical treatment of pediatric orthopedics. Transplantation of free growth plate and cartilage were unfavorably used because of lack ofblood supplement. Although circulation problem was solved by transplantation ofvascularized growth plate, autografts of epiphyseal cartilage were involved in limitation of donor, and allografts of epiphyseal cartilage induced immunological reaction. Noncartilaginous tissue and material could only prevent formation of bony bridge in small defect of growth plate and lacked ability of regenerative repair. Transplantationof tissue engineered cartilage and chondrocytes might be a choice for repair ofgrowth plate injury Conclusion Owing to lack of safe and effective methods ofrepairing growth plate injury, research on chondrocyte and tissue engineered cartilage should be further done.
To investigate the feasibility of using the pedicled patella for repaire of the superior articular surface of the medial tibial condyle, 37 lower limbs were studied by perfusion. In this series, there were 34 obsolete specimens and 3 fresh specimens of lower legs. Firstly, the vessels which supply to patella were observed by the methods of anatomy, section and casting mould. Then, the form and area of the patellar and tibial medial conylar articular surface were measured in 30 cases. The results showed: (1) the arteries supplied to patella formed a prepatellar arterial ring around patella, and the ring gave branches to patella; (2) medial inferior genicular artery and inferior patellar branches of the descending genicular arterial articular branch merge and acceed++ to prepatellar ring at inferior medial part of patella; (3) the articular surface of patella is similar to the superior articular surface of the tibial medial condyle on shape and area. It was concluded that the pedicled patella can be transposed to medial tibial condyle for repaire of the defect of the superior articular surface. The function of the knee can be reserved by this method.
OBJECTIVE: To study the feasibility of the formation of allogeneic tissue-engineered cartilage of certain shape in immunocompetent animal using the injectable biomaterial. METHODS: Fresh newborn rabbits’ articular cartilages were obtained under sterile condition (lt; 6 hours after death) and incubated in the sterile 0.3% type II collagenase solution. After digestion of 8 to 12 hours, the solution was filtered through a 150 micron nylon mesh and centrifuged, then the chondrocytes were washed twice with phosphate buffered saline (PBS) and mixed with the biomaterial to create a final cell density of 5 x 107/ml. The cell-biomaterial admixture was injected into rabbits subcutaneously 0.3 ml each point while we drew the needle back in order to form the neocartilage in the shape of cudgel, and the control groups were injected with only the biomaterial or the suspension of chondrocytes with the density of 5 x 10(7)/ml. After 4, 6, 8 and 12 weeks, the neocartilages were harvested to analyze. RESULTS: The new nodes could be touched subcutaneously after 2 weeks. In the sections of the samples harvested after 4 weeks, it was found that the matrix secreted and the collagen formed. After 6 weeks and later than that, the neocartilages were mature and the biomaterial was almost completely degraded. The cudgel-shaped samples of neocartilage could be formed by injection. In the experiment group, there was no obvious immune rejection response. On the contrary, there were no neocartilage formed in the control group. CONCLUSION: The injectable biomaterial is a relatively ideal biomaterial for tissue engineering, and it is feasible to form allogeneic tissue engineered cartilage of certain shape by injection in an immunocompetent animal.
ObjectiveTo observe the effect of using tungsten drills to prepare mouse knee osteochondral injury model by comparing with the needle modeling method, in order to provide an appropriate animal modeling method for osteochondral injury research.MethodsA total of 75 two-month-old male C57BL/6 mice were randomly divided into 3 groups (n=25). Mice in groups A and B were used to prepare the right knee osteochondral injury models by using needles and tungsten drills, respectively; group C was sham-operation group. The general condition of the mice was observed after operation. The samples were taken at 1 day and 1, 2, 4, and 8 weeks after modeling, and HE staining was performed. The depth, width, and cross-sectional area of the injury site at 1 day in groups A and B were measured, and the percentage of the injury depth to the thickness of the articular cartilage (depth/thickness) was calculated. Toluidine blue staining and immunohistochemical staining for collagen type Ⅱ were performed at 8 weeks, and the International Cartilage Research Society (ICRS) score was used to evaluate the osteochondral healing in groups A and B.ResultsAll mice survived to the completion of the experiment. HE staining showed that group C had normal cartilage morphology. At 1 day after modeling, the injury in group A only broke through the cartilage layer and reached the subchondral bone without entering the bone marrow cavity; the injury in group B reached the bone marrow cavity. The depth, width, cross-sectional area, and depth/thickness of the injury in group A were significantly lower than those in group B (P<0.05). At 1, 2, 4, and 8 weeks after modeling, there was no obvious tissue filling in the injured part of group A, and no toluidine blue staining and expression of collagen type Ⅱ were observed at 8 weeks; while the injured part of group B was gradually filled with tissue, the toluidine blue staining and the expression of collagen type Ⅱ were seen at 8 weeks. At 8 weeks, the ICRS score of group A was 8.2±1.3, which was lower than that of group B (13.6±0.9), showing significant difference (t=−7.637, P=0.000).ConclusionThe tungsten drills can break through the subchondral bone layer and enter the bone marrow cavity, and the injury can heal spontaneously. Compared with the needle modeling method, it is a better method for modeling knee osteochondral injury in mice.
Objective To fabricate a novel gelatinchondroitin sulfate-sodium hyaluronate tri-copolymer scaffold and to confirm the feasibility of serving as ascaffold for cartilage tissue engineering. Methods Different scaffolds was prepared with gelatin-chondroitin sulfatesodium hyaluronate tri-copolymer by varying the freezing temperatures (-20℃,-80℃ and liquid nitrogen). Pore size, porosity, inter pores and density were observed with light microscopy and scanning electron microscopy (SEM). The load-stiffness curves were compared between different scaffolds and normal cartilage. The number of MSCs attaching to different scaffolds and the function of cells were also detected with MTT colorimetric microassay. Results The pore size was 300±45, 230±30 and 45±10 μm; the porosity was 81%, 79% and 56%; the density was 9.41±0.25, 11.50±0.36 and 29.50±0.61 μg/mm3 respectively in different scaffolds fabricated at -20℃,-80℃ and liquid nitrogen; the latter two scaffolds had nearly the same mechanical property with normal cartilage; the cell adhesion rates were 85.0%, 87.5% and 56.3% respectively in different scaffolds and the scaffolds can mildly promote the proliferation of MSCs. Conclusion Gelatin-chondroitin sulfatesodium hyaluronate tricopolymer scaffold fabricated at -80℃ had proper pore size, porosity and mechanical property. It is a novel potential scaffold for cartilage tissue engineering.
【Abstract】 Objective To develop a novel cartilage acellular matrix (CACM) scaffold and to investigate its performance for cartilage tissue engineering. Methods Human cartilage microfilaments about 100 nm-5 μm were prepared after pulverization and gradient centrifugation and made into 3% suspension after acellularization treatment. After placing the suspension into moulds, 3-D porous CACM scaffolds were fabricated using a simple freeze-drying method. The scaffolds were cross-l inked by exposure to ultraviolet radiation and immersion in a carbodiimide solution 1-ethyl-3-(3-dimethylaminopropyl) carbodiimide hydrochloride and N-hydroxysucinimide. The scaffolds were investigated by histological staining, SEM observation and porosity measurement, water absorption rate analysis. MTT test was also done to assess cytotoxicity of the scaffolds. After induced by conditioned medium including TGF-β1, canine BMSCs were seeded into the scaffold. Cell prol iferation and differentiation were analyzed using inverted microscope and SEM. Results The histological staining showed that there are no chondrocytefragments in the scaffolds and that toluidine blue, safranin O and anti-collagen II immunohistochemistry staining werepositive. The novel 3-D porous CACM scaffold had good pore interconnectivity with pore diameter (155 ± 34) μm, 91.3% ± 2.0% porosity and 2 451% ± 155% water absorption rate. The intrinsic cytotoxicity assessment of novel scaffolds using MTT test showed that the scaffolds had no cytotoxic effect on BMSCs. Inverted microscope showed that most of the cells attached to the scaffold. SEM micrographs indicated that cells covered the scaffolds uniformly and majority of the cells showed the round or ell iptic morphology with much matrix secretion. Conclusion The 3-D porous CACM scaffold reserved most of extracellular matrix after thoroughly decellularization, has good pore diameter and porosity, non-toxicity and good biocompatibil ity, which make it a suitable candidate as an alternative cell-carrier for cartilage tissue engineering.
Objective To describe the characteristics of short arm deformity in patients with achondroplasia, and summarize the progress of its lenthening and reconstruction, so as to provide reference for clinical diagnosis and treatment. MethodsThe literature on the lenthening of upper limb with achondroplastic short arm deformity at home and abroad in recent years was reviewed, and the characteristics, extension methods, postoperative management, effectiveness evaluation, and related complications of short arm deformity were summarized. Results Achondroplastic short arm deformity affect the patient’s daily perineal hygiene activities. Although the upper limb is proportionately shortened, the humerus is mainly short limb deformity. Bilateral humeral lengthening is a common treatment method, and the traditional lengthening tools are mainly external fixation, guided by Ilizarov distraction osteogenesis concept; intramedullary lengthening is the latest treatment method. Lengthening percentage and healing index are commonly used for clinical evaluation indexes, and complications such as nerve injury may occur during upper limb lengthening. Conclusion In addition to appearance improvement, achondroplastic short arm lengthening is of great significance in achieving self-management of individual perineal hygiene. Lenthening and reconstruction methods are constantly being innovated and improved.
Objective To investigate the effect of collagen type I concentration on the physical and chemical properties of the collagen hydrogel, and to analyze the effect of different concentrations of collagen type I hydrogel on the phenotype and gene expression of the chondrocytes in vitro. Methods Three kinds of collagen hydrogels with concentrations of 12, 8, and 6 mg/ mL (C12, C8, and C6) were prepared, respectively. The micro-structure, compressive modulus, and swelling ratio of the hydrogels were measured and analyzed. The chondrocytes at 2nd passage were cocultured with three kinds of collagen hydrogels in vitro, respectively. After 1-day culture, the samples were stained with fluorescein diacetate (FDA) / propidium iodide (PI) and the cell activity was observed under confocal laser microscope. After 14-day culture, HE staining and toluidine blue staining were carried out to observe the histological morphology, and mRNA expressions of chondrocytes related genes (collagen type II, Aggrecan, collagen type I, collagen type X, Sox9) were determined by real-time fluorescent quantitative PCR. Results With the increase of collagen type I concentration from 6 to 12 mg/mL, the physical and chemical properties of the collagen hydrogels changed significantly: the fiber network became dense; the swelling ratios of C6, C8, and C12 were 0.260 ± 0.055, 0.358 ± 0.072, and 0.539 ± 0.033 at 192 hours, respectively, showing significant differences among 3 groups (P lt; 0.05); and the compression modulus were (4.86 ± 0.96), (7.09 ± 2.33), and (11.08 ± 3.18) kPa, respectively, showing significant differences among 3 groups (P lt; 0.05). After stained with FDA/PI, most cells were stained green, and few were stained red. The histological observation results showed that the chondrocytes in C12 hydrogels aggregated obviously with b heterochromia, chondrocytes in C8 hydrogels aggregated partly with obvious heterochromia, and chondrcytes in C6 hydrogels uniformly distributed with weak heterochromia. Real-time fluorescent quantitative PCR results showed that the mRNA expressions of collagen type II and Aggrecan were at the same level in C12, C8, and C6; the expressions of collagen type I, Sox9, and collagen type X were up-regulated with the increase of collagen type I hydrogels concentration, and the expressions were the highest at 12 mg/mL and were the lowest at 6 mg/mL, showing significant differences among 3 groups (P lt; 0.05). Conclusion Increasing the concentration of collagen hydrogels leads to better mechanical properties and higher shrink-resistance, but it may induce the up-regulation of cartilage fibrosis and hypertrophy related gene expression.