Objective To explore the effect of rolling compression loading bioreactor on chondrogenesis of rabbit bone marrow mesenchymal stem cells (BMSCs) with different loading parameters. Methods BMSCs were isolated from New Zealand rabbits, aged 2.5 months. BMSCs at passage 3 were used to prepare BMSCs-agarose gels (4 mm in diameter and height, respectively). Samples were divided into 8 groups: 10% (group A1), 20% (group A2), and 30% (group A3) compression groups (0.4 Hz, 3 h/ d) and 20 minutes (group B1), 3 hours (group B2), and 12 hours (group B3) rolling time groups and static culture (control groups). The living cell rate, the collagen type II and Aggrecan gene expressions, and glycosaminoglycan (GAG) content were determined, and histological staining was done at 24 hours, 7 days, 14 days, and 21 days after culture. Results At 14 and 21 days, the living cell rates of groups A1 and A2 were significantly higher than that of group A3 (P lt; 0.05), groups B1 and B2 were significantly higher than group B3 (P lt; 0.05). Collagen type II and Aggrecan gene expressions of the experimental groups at each time point were significantly higher than those of the control groups (P lt; 0.05); at 14 and 21 days, collagen type II and Aggrecan gene expressions of groups A1 and A2 were significantly higher than those of group A3, and groups B1 and B2 were also significantly higher than group B3 (P lt; 0.05). At 14 and 21 days, the GAG contents of groups A1 and A2 were significantly higher than those of group A3 (P lt; 0.05); groups B1 and B2 were also significantly higher than group B3 (P lt; 0.05). At 21 days, toluidine blue staining showed that obvious blue-staining and even cartilage lacunae were seen in groups A2 and B2, but light and quite rare blue-staining in groups A1, A3, B1, and B3. Conclusion The rolling compression loading bioreactor has great promotion effect on chondrogenesis of rabbit BMSCs with rolling parameters of 0.4 Hz, 3 hours, and 20% compression.
Objective To elucidate the latest research progress and application of tissue engineered meniscus. Methods The literature concerning the advance in tissue engineered meniscus was extensively reviewed, then closely-related issues including seed cells, scaffolds, and bioreactors were analyzed. Results With more and more attention being paid to meniscus tissue engineering, different approaches and strategies for seed cells, scaffolds, and bioreactors have contributed to the generation of meniscal constructs, which are capable of restoring meniscal lesions to some extent, but translating successes in basic science research to clinical application is still limited. Conclusion More research for the optimal combination of the appropriate cell source, the scaffold type, and the proper physical and chemical factors for the stimulation of cells differentiation into tissue with optimal phenotypes in tissue engineered meniscus is still in needed, but the overall future looks promising.
Objective To review the recent research progress of the bioreactor biophysical factors in cartilage tissue engineering. Methods The related literature concerning the biophysical factors of bioreactor in cartilage tissue engineering was reviewed, analyzed, and summarized. Results Oxygen concentration, hydrostatic pressure, compressive force, and shear load in the bioreactor system have no unified standard parameters. Hydrostatic pressure and shear load have been in controversy, which restricts the application of bioreactors. Conclusion The biophysical factors of broreactor in cartilage tissue engineering have to be studied deeply.
Objective To investigate the effect of dynamic compression and rotation motion on chondrogenesis of the 3rd passage cell-loaded three-dimensional scaffold in a joint-specific bioreactor in vitro so as to provide theoretical basis of the autologous chondrocyte transplantation in clinical practice. Methods Primary chondrocytes were isolated and cultured from the knee cartilage of 3-4 months old calves. The 3rd passage cells were seeded onto fibrin-polyurethane scaffolds (8 mm × 4 mm). Experiment included 5 groups: unloaded culture for 2 weeks (group A), direct load for 2 weeks (group B), unloaded culture for 4 weeks (group C), direct load for 4 weeks (group D), and unload for 2 weeks followed by load for 2 weeks (group E). The cell-scaffold was incubated in incubator (unload) or in a joint-specific bioreactor (load culture). At different time points, the samples were collected for DNA and glycosaminoglycan (GAG) quantification detect; mRNA expressions of chondrogenic marker genes such as collagen type I, collagen type II, Aggrecan, cartilage oligomeric matrix protein (COMP), and superficial zone protein (SZP) were detected by real-time quantitative PCR; and histology observations were done by toluidine blue staining and immunohistochemistry staining. Results No significant difference was found in DNA content, GAG content, and the ratio of GAG to DNA among 5 groups (P gt; 0.05). After load, there was a large number of GAG in the medium, and the GAG significantly increased with time (P lt; 0.05). The mRNA expression of collagen type I showed no significant difference among 5 groups (P gt; 0.05). The mRNA expression of collagen type II in group B was significantly increased when compared with group A (P lt; 0.01), and groups D and E were significantly higher than group C (P lt; 0.01); the mRNA expression of Aggrecan in groups D and E were significantly increased when compared with group C (P lt; 0.01), and group E was significantly higher than group D (P lt; 0.01); the mRNA expression of COMP in group B was significantly increased when compared with group A (P lt; 0.01), and group E was significantly higher than group C (P lt; 0.01); and the mRNA expression of SZP in group E was significantly increased when compared with groups C and D (P lt; 0.05). The toluidine blue staining and immunohistochemistry staining displayed that synthesis and secretion of GAG could be enhanced after load; no intensity changes of collagen type I and collagen type II were observed, but intensity enhancement of Agrrecan was seen in groups D and E. Conclusion Different dynamic loads can promote chondrogenesis of the 3rd passage chondrocytes. Culture by load after unload may be the best culture for chondrogenesis, while the 3rd passage chondrocytes induced by mechanical load hold less capacity of chondrogenesis.
Objective To review the recent progress of the researches in construction of tissue engineered osteochondral composites, and to discuss the challenges in construction of tissue engineered osteochondral composites. Methods The recent literature on the construction of tissue engineered osteochondral composites was extensively reviewed and analyzed. Results The studies on the construction of tissue engineered osteochondral composites are relatively more in vivo, the current focus is that different tissues derived mesenchymal stem cells are widely used to be seed cells; single-phase scaffold has been limited, studies on biphase scaffold and triphase scaffold are new trends; the design and performance of bioreactor need to be further optimized in the future. Conclusion The construction of tissue engineered osteochondral composites will be a promising method for the treatment of cartilage defects.
Objective To review new progress of related research of bone tissue engineering in recent years. Methods Domestic and international l iterature concerning bone tissue engineering was reviewed and analyzed. Results In the recent years, great progression had been made in the research and development of bone tissue engineering, it had been used in more and more hospitals, and relevant national regulations and protocols had been set up. As to seed cells of bone tissue engineering, autologous and allogeneic stem cells had been widely used, while recently embryonic stem cells and induced pluri potent stem cells had attracted most attentions. In the field of scaffolds materials, significant improvementshad been made, from natural extractions to artificial polymers; from single construction to multiple compounds with surface modifications. As to the methods of construction, the static seeding approach had been widely accepted, and the appl ications of bioreactor had provided a stable and various micro-enviroment for the vitro-culture of different stem cells, which had beenregarded as an alternative way of vitro-culture and construction for bone tissue engineering. Conclusion With the tremendous help of the techniques and approaches above, we shall expect a promising future of a new generation bone tissue engineering based medical products in the years to come.
Objective To investigate the effects of flow shear stress and mass transport on the construction of largescale tissue engineered bone using a perfusion bioreactor. Methods Bone marrow (20 mL) was harvested from the il iac crestof the healthy volunteer, and then hBMSCs were isolated, cultured and identified. The hBMSCs at passage 3 were seeded on the critical-size β-TCP scaffold and cultured in a perfusion bioreactor for 28 days. Different flow shear stress (1 ×, 2 × and 3 ×) and different mass transport (3, 6 and 9 mL/min) were exerted on the cells seeded on the scaffold by changing the viscosity of media or perfusion flow rate. The cell prol iferation and ALP activity of cells seeded on the scaffold were detected, and histology observation and morphology measurement of cell/scaffold complex were conducted. Results When the perfusion flow rabe was 3 mL/min, the cell viabil ity of 2 × group was higher than that of other groups (P lt; 0.05). When the flow shear stress was 3 ×, no significant differences were found among 3, 6 and 9 mL/min in cell viabil ity (P gt; 0.05). When the perfusion flow rate was 3 mL/min, the activity of ALP of 2 × and 3 × groups was higher than that of 1 × group (P lt; 0.05). When the flow shear stress was 3 ×, the activity of ALP of 6 mL/min group was the highest (P lt; 0.05). After 28 days of perfusion culture, the ECM of all the groups distributed throughout the scaffold, and the formation and mineral ization of ECM was improved with the increase of flow shear stress when the perfusion flow rate was 3 mL/min. However, the increase of perfusion flow rate decreased the mineral ization of ECM when the flow shear stress was 3 ×. Conclusion As two important fluid dynamics parameters affecting the construction of large-scale tissue engineered bone, the flow shear stress and the mass transport should be measured duringthe process of constructing large-scale tissue engineered bone so as to maximize their roles.
Objective To examine the biological characteristic changes in thededifferenciated human articular chondrocytes by the bioreactor culturing in vitvo.Methods The cartilage tissue was obtained from the joints of the adult human. The chondrocytes were isolated from the cartilage tissue with the type Ⅱ collagenase digestion(0.2%, 37℃, 3 h)and were cultured in DMEMF12 supplemented with 20% fetal bovine serum (FBS) with 1 ng/ml of TGF-β1and 5 ng/mlof FGF-2. After about 20 passages by the monolayer culture,the cells were then transferred to the bioreactor culturing of the rotational cell culture system (RCCS) for a 3-week sequence culture. The cell counting was performed with the platelet counter, and the doubling time for each passage of thecells was determined. The frozen section was stained with HE. The differentiated phenotype was evaluated by histochemistry or immunohistochemistry. Results When the monolayer culture was performed without any growth factors, the chondrocytes were rapidly proliferated within 3 passages (average doubling time, 59 h),but at the same time, dedifferentiation was also progressing rapidly. After the4th passage, most of the cells were dedifferenciated and the proliferation was decreased. With the growth factors (TGF-β1/FGF-2), the speed of the expansion was accelerated (average doubling time, 47 h), but the speed of the dedifferentiation was slowed down. After 20 passages were performed with the monolayer culture, the dedifferentiated chondrocytes could be redifferentiated when they were cultured for 3 weeks with RCCS. Then, the Safranine-O staining was bly positive for the cells, positive for aggrecan and collagen Ⅱ, but negative for collagen Ⅰ, with a wellregained phenotype. Conclusion The bioreactor culturing of the dedifferenciated human articular condrocytes can regain the differentiated phenotype and it is a useful method of obtaining the human articular chondrocytes in large amounts and in a differentiated phenotype in vitro.
Objective To demonstrate the importance of bioreactor to tissue engineering and to disscuss the direction of bioreactor- researching. Methods Alarge quantity of literature was reviewed, analyzed and summarized. Results Bioreactor has greatly promoted the progress of tissue engineering in heoretics and practice,and has become one of the most important parts of tissue engineering. Conclusion Bioreactor is indispensable for tissue engineering,and it should be developed along integration,automation and intelligentificaton.Its application should run through the whole process of tissue engineering.
Objective To investigate the growth, expansion, and metabolic characteristics of the human dermal fibroblasts cultured in a bioreactor with batch and medium exchange modes. Methods Human dermal fibroblasts separated from foreskin were seeded into a 1.5 liter CelliGen bioreactor with 5mg/ml of microcarriers. The cell growth, glucose consumption and lactate accumulation in both batch and medium exchange cultures were measured. Results The growth density of fibroblasts cultured in the bioreactor with medium-exchange mode reached 2.08×106 cell/ml, expande 29.7 folds, which was 1.81 times as high as that in batch culture. By comparison with the results obtained in T-flasks and spinners under the same medium-exchange conditions, the cell density in the bioreactor was 9.16 and 1.43 times as high as those in T-flasks and spinners respectively owing to that the limitation effect the attachment surface, nutrient exhaust, and by-product accumulation on the growth of fibroblasts in the bioreactor by using microcarriers, medium-exchange, as well as gas aeration was elimnated. Conclution The above results indicate that suspended cultures with microcarriers in bioreactors are an effective approach to rpovide large amounts of seeding cells for tissue engineering.