The spatiotemporal development of intercalated disk in three-dimensional engineered heart tissues based on collagen/matrigel matrix.

Intercalated disk (ID), which electromechanically couples cardiomyocytes into a functional syncitium, is closely related to normal morphology and function of engineered heart tissues (EHTs), but the development mode of ID in the three-dimensional (3D) EHTs is still unclear. In this study, we focused on the spatiotemporal development of the ID in the EHTs constructed by mixing neonatal rat cardiomyocytes with collagen/Matrigel, and investigated the effect of 3D microenvironment provided by collagen/Matrigel matrix on the formation of ID. By histological and immmunofluorescent staining, the spatiotemporal distribution of ID-related junctions was detected. Furthermore, the ultra-structures of the ID in different developmental stages were observed under transmission electron microscope. In addition, the expression of the related proteins was quantitatively analyzed. The results indicate that accompanying the re-organization of cardiomyocytes in collagen/Matrigel matrix, the proteins of adherens junctions, desmosomes and gap junctions redistributed from diffused distribution to intercellular regions to form an integrated ID. The adherens junction and desmosome which are related with mechanical connection appeared earlier than gap junction which is essential for electrochemical coupling. These findings suggest that the 3D microenvironment based on collagen/Matrigel matrix could support the ordered assembly of the ID in EHTs and have implications for comprehending the ordered and coordinated development of ID during the functional organization of EHTs.

[Cordyceps sinensis enhances lymphocyte proliferation and CD markers expression in simulated microgravity environment].

This study was aimed to explore the effect of cordyceps sinensis enhancing lymphocyte proliferation and surface CD marker expression in simulated microgravity environment. The splenic lymphocytes were separated from mice and cultured in the rotary cell culture system simulated microgravity environment. The cells were treated with different concentration of cordyceps sinensis solution (0, 6.25, 12.5, 25 and 50 µg/ml) for 24, 48 and 72 h respectively, then the cells were harvested, and analyzed for cell proliferation and the expression of cell surface markers (CD4 and CD8). The results showed that under simulated microgravity environment, the lymphocyte proliferation was inhibited. When the concentration of cordyceps sinensis was 25 or 50 µg/ml, the lymphocyte proliferation, CD4 and CD8 expressions all increased, but 50 µg/ml cordyceps sinensis could inhibit the proliferation ability with the time prolonging. It is concluded that the suitable concentration of cordyceps sinensis displayed the ability to enhance the lymphocyte proliferation and CD marker expression in simulated microgravity environment. These results may be valuable for screening drugs which can be potentially against immunosuppression under simulated microgravity.

[Effect of lentinan against immunosuppression of lymphocytes cultured in simulated microgravity environment].

This study was aimed to evaluate the effect of lentinan on the immune function of splenic lymphocytes in rotary cell culture system (RCCS) microgravity environment. The splenic lymphocytes from mice were separated and cultured in the normal gravity and the microgravity environments. The cells were treated with lentinan solution (0, 10, 20 and 40 µg/ml). After incubated with lentinan for indicated times (24, 48 and 72 h), the cell proliferation, secretion of cytokine and the expression of cell surface markers were detected by MTT method, ELISA and flow cytometry respectively. The results indicated that lentinan of above mentioned concentrations did not obviously promote the lymphocyte proliferation, but increased the secretion of IL-2 and IFN-γ and enhanced the expression of lymphocyte surface markers CD4 and CD8 in microgravity environment. It is concluded that lentinan has the ability to enhance the lymphocyte immune function in microgravity environment.

RCCS enhances EOE cell proliferation and their differentiation into ameloblasts.

In this article we report on the culturing of dental enamel organ epithelia (EOE) using a rotary cell culture system (RCCS) bioreactor associated with a cytodex-3 microcarrier. This culture system enhanced the proliferation and differentiation of the EOE into ameloblasts. Primary dental EOE trypsinized from 4-day old post-natal rat pups were cultured in the RCCS associated with Cytodex-3. The results were analyzed in comparison to a conventional plate system (control). Cells grown in RCCS have shown higher viabilities (above 90%) and final cell densities in terms of cells/ml than in the control system. In the case of RCCS, 46±2 manifold increases were obtained, while significantly lower yields of 10.8±2.5 manifod were obtained for control plates. Throughout the experiments, glucose levels were maintained within the accepted physiological range. In this case, LDH levels are kept low (below 150 mmol/ml), which is in accordance with the low cell death observed in the RCCS. Scanning electron microscopy revealed cells that were spread and forming three dimensional aggregates on the surface of cytodex-3. Cells cultured in the RCCS exhibited a stronger positive immunofluorescence staining for ameloblastin than those in control plates. RT-PCR results revealed that cells cultured in RCCS have higher amelogenin mRNA levels compared to controls. We have done an exploratory study on biological characteristics and self-assembling of epithelium cellula intersitialis, which demonstrated that the special 3D environment enhanced the rat dental EOE cell proliferation and differentiation into ameloblasts. The study has revealed that RCCS could be used to study the reaction of the EOE cells, tooth enamel organ cells and mesenchymal cells under the spacial 3D culture system, which will also provide a novel hypothesis for dental regeneration.

Posterolateral spinal fusion with nano-hydroxyapatite-collagen/PLA composite and autologous adipose-derived mesenchymal stem cells in a rabbit model.

Spinal fusion is routinely performed to treat low back pain caused by degeneration of intervertebral discs. An autologous bone graft derived from the iliac crest is the standard procedure used for spinal fusion. However, several shortcomings, including pseudarthrosis, pain and the need for blood transfusion are known to be associated with the procedure. Our study analysed the effectiveness of a new mineralized collagen matrix, nano-hydroxyapatite-collagen-polylactic acid (nHAC-PLA), combined with autologous adipose-derived mesenchymal stem cells (ADMSCs) as a graft material for posterolateral spinal fusion in a rabbit model. Forty rabbits were randomly divided into four groups: autologous iliac crest bone group (ACB), nHAC-PLA composite group (nHAC-PLA), autologous iliac crest bone mixed with nHAC-PLA composite group (ACB + nHAC-PLA), and nHAC-PLA composite combined with ADMSCs (ADMSCs + nHAC-PLA). The viability and the proliferation of the ADMSCs seeded on the scaffolds were evaluated by live/dead kit and MTT assay in vitro, respectively. Lumbar posterolateral fusions were assessed by manual palpation, radiographical and histological procedures, mechanical strength and scanning electronic microscopy (SEM) in 10 weeks of observation. The results showed that the rate of fusion was significantly higher in the ACB and ADMSCs + nHAC-PLA groups than that in the nHAC-PLA and ACB + nHAC-PLA groups. It was not significantly higher in the ACB group than in the ADMSCs + nHAC-PLA group. From microstructural analysis of the samples using histological staining methods, there was more new bone-like tissue formation in the ACB and ADMSCs + nHAC-PLA groups than that in the other two groups at the 10th postoperative week. Our study demonstrated the effective impact of nHAC-PLA combined with ADMSCs in rabbit posterolateral spinal fusion.

The reconstruction of lung alveolus-like structure in collagen-matrigel/microcapsules scaffolds in vitro.

This study attempted to use collagen-Matrigel as extracellular matrix (ECM) to supply cells with three-dimensional (3D) culture condition and employ alginate-poly-l-lysine-alginate (APA) microcapsules to control the formation of alveolus-like structure in vitro. We tested mice foetal pulmonary cells (FPCs) by immunohistochemistry after 2D culture. The alveolus-like structure was reconstructed by seeding FPCs in collagen-Matrigel mixed with APA microcapsules 1.5 ml. A self-made mould was used to keep the structure from contraction. Meanwhile, it provided static stretch to the structure. After 7, 14 and 21 days of culture, the alveolus-like structure was analysed histologically and immunohistochemically, or by scanning transmission electron microscopy (TEM). We also observed these structures under inverted phase contrast microscope. The expression of pro-surfactant protein C (SpC) was detected by reverse transcription-polymerase chain reaction (RT-PCR). We obtained fibroblasts, epithelial cells and alveolar type II (AE2) cells in FPCs. In the reconstructed structure, seeding cells surrounding the APA microcapsules constructed alveolus-like structures, the size of them ranges from 200 to 300 µm. In each reconstructed lung tissue sheet, microcapsules had integrity. Pan-cytokeratin, vimentin and SpC positive cells were observed in 7- and 14-day cultured structures. TEM showed lamellar bodies of AE2 cells in the reconstructed tissues whereas RT-PCR expressed SpC gene. Primary mice FPCs could form alveolus-like structures in collagen-Matrigel/APA microcapsules engineered scaffolds, which could maintain a differentiated state of AE2 cells.

Reconstruction of endometrium in vitro via rabbit uterine endometrial cells expanded by sex steroid.

OBJECTIVE: To culture rabbit endometrial cells by using sex steroids to provide adequate seeding cells for endometrium reconstruction and uterine tissue engineering. DESIGN: Prospective experimental study. SETTING: Beijing Institute of Basic Medical Sciences and Tissue Engineering Research Center, Academy of Military Medical Sciences. ANIMAL(S): New Zealand rabbit and Kunming white strain mice. INTERVENTION(S): Rabbits were primed with pregnant mare serum gonadotropin and hCG. Endometrial cells were cultured with E(2) and P(4) of different concentrations. The endometrium was reconstructed by using endometrial cells as seeding cells and collagen-basement membrane matrix as scaffolds. MAIN OUTCOME MEASURE(S): Assay with 93-(4,5-dimethylthiazol-2-yl)2,5-diphenyl tetrazolium bromide, immunofluorescence staining, flow cytometric analysis, hematoxylin and eosin and immunohistochemical staining, and developmental rate of embryos. RESULT(S): The expression patterns of estrogen receptor and P receptor of rabbit endometrium were different before and after treatment with pregnant mare serum gonadotropin-hCG. One hundred nanomolar E(2) with 10 nmol/L P(4) facilitated the proliferation of epithelial cells whereas 100 nmol/L P(4) facilitated that of stromal cells. The epithelial cells could be stable if cultured for seven or eight passages. Cells in the epithelial layer of the reconstructed endometrium were cytokeratin positive. Some showed columnar morphology akin to the luminal epithelium in vivo. Reconstructed endometrium could improve the developmental rate and quality of one-cell mice embryos. CONCLUSION(S): Rabbit endometrial cells could be cultured with a long-standing proliferation capability by sex steroids and applied in uterine tissue engineering. Reconstructed endometrium with proliferated endometrial cells was akin to native endometrium in structure and function.

Reconstruction of engineered uterine tissues containing smooth muscle layer in collagen/matrigel scaffold in vitro.

OBJECTIVE: This study attempted to reconstruct engineered uterine tissues (EUTs) containing smooth muscle layer, akin to the normal uterine wall. METHODS: EUTs were reconstructed by seeding epithelial cells on top of the constructed stromal layer over smooth muscle layer. A self-made mold was used to keep the EUTs from contraction. At the same time, it provided static stretch to the EUTs. After 14 days of culture, the structure of the EUTs was analyzed histologically and immunohistochemically, or by scanning electron microscopy (SEM) and transmission electron microscopy (TEM). The expression of integrin beta3 subunit, heparin-binding epidermal growth factor (EGF)-like growth factor (HB-EGF), and HOXA-10 was detected by reverse transcription-polymerase chain reaction (RT-PCR). The ability of the EUTs supporting the development of embryos was estimated by coculturing embryos on the EUTs. We also tried a new method to reconstruct EUTs by mixing epithelial cell and stromal cells (1:2) in collagen/Matrigel to form an endometrial layer and putting it on top of the smooth muscle layer. The self-assembling ability of the endometrial epithelial cells and stromal cells in the reconstructed EUTs was analyzed histologically and immunohistochemically. RESULTS: The results found that the constructed EUTs with the first and the second method showed three-layered structures. The epithelial layer, stromal layer, and smooth muscle layer were stained by cytokeratin 18, vimentin, and alpha-actin, respectively. TEM showed that the cells in the EUTs reconstructed by the first method were attached to each other by apical tight junctions and rivet-like desmosomes. SEM showed protruded pinopodes, microvilli, and cilium of epithelial cells. The RT-PCR analysis showed that integrin beta3 subunit, HB-EGF, and HOXA-10 were expressed in EUTs. The coculture system of EUTs improved the development rate and quality of murine embryo significantly in comparison with those of control Chatot Ziomek Bavister culture. In the EUTs reconstructed by the second method, the epithelial cells demonstrated self-assembling ability and formed epithelial cell layer on top of the stromal layer and glandular tube-like structures in the stromal layer. Columnar epithelial cells existed in some parts of the epithelial layer. CONCLUSION: We engineered EUTs containing smooth muscle layer by two methods. The reconstructed EUTs could support the development of embryos. The epithelial cells showed self-assembling ability in the EUTs.

Functional improvement of infarcted heart by co-injection of embryonic stem cells with temperature-responsive chitosan hydrogel.

Transplantation of embryonic stem cells (ESCs) can improve cardiac function in treatment of myocardial infarction. The low rate of cell retention and survival within the ischemic tissues makes the application of cell transplantation techniques difficult. In this study, we used a temperature-responsive chitosan hydrogel (as scaffold) combined with ESCs to maintain viable cells in the infarcted tissue. Temperature-responsive chitosan hydrogel was prepared and injected into the infarcted heart wall of rat infarction models alone or together with mouse ESCs. The result showed that the 24-h cell retention and 4 week graft size of both groups was significantly greater than with a phosphate buffered saline control. After 4 weeks of implantation, heart function, wall thickness, and microvessel densities within the infarct area improved in the chitosan + ESC, chitosan, and ESC group more than the PBS control. Of the three groups, the chitosan + ESC performed best. Results of this study indicate that temperature-responsive chitosan hydrogel is an injectable scaffold that can be used to deliver stem cells to infarcted myocardium. It can also increase cell retention and graft size. Cardiac function is well preserved, too.

[Cloning of gdnf in the mouse testis and its expression in sertoli cells].

OBJECTIVE: To clone the glial cell line-derived neurotrophic factor (GDNF) from the mouse testis, construct the eukaryotic expression vector and transfect this vector into Sertoli cells in order to use the gdnf-transfected Sertoli cells as the feeder layer to cultivate spermatogonial stem cells (SSCs). METHODS: Total RNA was extracted from the testes of normal mature mice and gdnf was cloned and amplified using RT-PCR, inserted into the eukaryotic expression vector and transfected into sertoli cells (TM4 cell line). Immunofluorescence with anti-GDNF antibodies was performed at 40 h following the transfection. RESULTS: gdnf cDNA was cloned successfully, and GDNF expressed after transfected into Sertoli cells. CONCLUSION: This study provides a basis for culturing SSCs with gdnf-transfected Sertoli cells as the feeder layer.

17beta-estradiol stimulates proliferation of spermatogonia in experimental cryptorchid mice.

AIM: To investigate whether estrogen stimulates the proliferation of spermatogonia or induces spermatogenesis in cryptorchid mice. METHODS: Mice were surgically rendered cryptorchid, then treated with different doses of 17beta-estradiol (E2) s.c. once a day. Mice were killed at sexual maturity (45 days of age), and histological analysis and immunofluorescence were performed. Serum follicle stimulating hormone (FSH), estradiol, testosterone and luteinizing hormone (LH) were measured. RESULTS: Low doses of E2 had no notable effect on spermatogonia, but at higher doses, E2 stimulated the proliferation of spermatogonia. CONCLUSION: E2 has a dose-related mitogenic effect on spermatogonia.

Creation of engineered cardiac tissue in vitro from mouse embryonic stem cells.

BACKGROUND: Embryonic stem (ES) cells can terminally differentiate into all types of somatic cells and are considered a promising source of seed cells for tissue engineering. However, despite recent progress in in vitro differentiation and in vivo transplantation methodologies of ES cells, to date, no one has succeeded in using ES cells in tissue engineering for generation of somatic tissues in vitro for potential transplantation therapy. METHODS AND RESULTS: ES-D3 cells were cultured in a slow-turning lateral vessel for mass production of embryoid bodies. The embryoid bodies were then induced to differentiate into cardiomyocytes in a medium supplemented with 1% ascorbic acid. The ES cell-derived cardiomyocytes were then enriched by Percoll gradient centrifugation. The enriched cardiomyocytes were mixed with liquid type I collagen supplemented with Matrigel to construct engineered cardiac tissue (ECT). After in vitro stretching for 7 days, the ECT can beat synchronously and respond to physical and pharmaceutical stimulation. Histological, immunohistochemical, and transmission electron microscopic studies further indicate that the ECTs both structurally and functionally resemble neonatal native cardiac muscle. Markers related to undifferentiated ES cell contamination were not found in reverse transcriptase-polymerase chain reaction analysis of the Percoll-enriched cardiomyocytes. No teratoma formation was observed in the ECTs implanted subcutaneously in nude mice for 4 weeks. CONCLUSIONS: ES cells can be used as a source of seed cells for cardiac tissue engineering. Additional work remains to demonstrate engraftment of the engineered heart tissue in the case of cardiac defects and its functional integrity within the host's remaining healthy cardiac tissue.

Enrichment of cardiomyocytes derived from mouse embryonic stem cells.

BACKGROUND: Embryonic stem (ES) cell-derived cardiomyocytes transplantation and tissue engineering together represent a promising approach for the treatment of myocardial infarction, despite the limited supply of cardiac myocytes. This study examines whether functional cardiomyocytes can be efficiently enriched from mouse embryonic stem (mES) cells. METHODS: mES cells were induced by ascorbic acid to differentiate into cardiomyocytes. Beating cells were observed after 1 week and increased in number with time while under differentiation conditions. Furthermore, the differentiated cultures could be dissociated and enriched by Percoll gradient density centrifugation. RESULTS: The beating cells expressed markers characteristic of cardiomyocytes, such as cardiac troponin T (cTnT). The enriched population contained 88.7% cardiomyocytes and showed expression of cardiomyocyte markers of troponin T and cardiac genes, including alpha-MHC, beta-MHC, ANF and Nkx2.5. However, Oct-4, a marker of early-stage ES cells, was not expressed in the mES cell-derived cardiac cell clusters. Moreover, the mES cell-derived and Percoll-enriched cardiomyocytes responded appropriately to cardioactive drugs, as did normal neonatal rat cardiomyocytes. CONCLUSIONS: mES cell-derived functional cardiomyocytes can be enriched by the method of discontinuous Percoll gradient centrifugation. The ability to differentiate and enrich for functional mouse cardiomyocytes makes it possible for further development of these cells as a model of myocardial repair through cell transplantation or tissue engineering.

Comparison of two types of alginate microcapsules on stability and biocompatibility in vitro and in vivo.

Transplantation of encapsulated living cells is a promising approach for the treatment of a wide variety of diseases, especially diabetes. Range-scale application of the technique, however, is hampered by insufficient stability of the capsules. It is difficult to find the optimal membrane to meet all the properties required for cell transplantation. To overcome these difficulties, it is necessary to compare characteristics such as mechanical strength, cell proliferation and biocompatibility of different membranes. We prepared Ca-alginate-poly-L-lysine-alginate (APA) and Ba-alginate-poly-L-lysine-alginate (BPA) microcapsules using the electrostatic droplet method. The integrity of the microcapsules was measured by suspending them in a saline buffer and shaking at 150 rpm for 48 h. The microcapsules were cultured in simulated body fluid to analyze the osmotic pressure stability and implanted in the leg muscle pouch of SD rats to test in vivo transplantation stability. The microcapsules were implanted in the intraperitoneal cavity; then the biocompatibility of microcapsules was identified through analyzing fibrosis formation of microcapsules. The proliferation of cells (Cos-7 and HL-60) cultured in the microcapsules was measured by MTT assay. After 48 h shaking at 150 rpm, the percentages of intact microcapsules of BPA and APA microcapsules were 98.5 +/- 0.248% and 95.7 +/- 0.221% (p < 0.05), respectively. The intact percentages of APA and BPA microcapsules were 96.9% and 97.7%, respectively, after being soaked in SBF at 37 degrees C for 15 days. The empty APA and BPA microcapsules were not adhered to the muscle and there was light cellular overgrowth. There is no difference on biocompatibility in implantation into peritoneal cavities. After the cells were cultured in microcapsules, A(490 nm) of the 8th week was significantly higher than that of 1 day, and the 4th week was at the peak of the cell proliferation curve. After culture for 2 to 6 weeks, spheroids started to develop gradually within the beads. The mechanical strength of BPA microcapsules was higher than that of APA microcapsules. However, there was no difference between the two kinds of capsules in biocompatibility. Microencapsulation did not affect cell proliferation or increase the quantity of cells. In conclusion, BPA microcapsules were more suitable for transplantation in vivo.

[Scalable production of embryoid bodies with the rotay cell culture system.].

Embryonic stem (ES) cells are pluripotent cells capable of extensive proliferation while maintaining their potential to differentiate into any cell type in the body. ES cells can therefore be considered a renewable source of therapeutically useful cells. While ES-derived cells have tremendous potential in many experimental and therapeutic applications, the scope of their utility is dependent on the availability of relevant cell quantities. Therefore, most of the researches are being focused on the differentiation of ES cells. ES cell aggregation is important for embryoid body (EB) formation and the subsequent generation of ES cell derivatives. EB has been shown to recapitulate aspect of early embryogenesis, including the formation of a complex three-dimensional architecture wherein cell-cell and cell-matrix interactions are thought to support the development of the three embryonic germ layers and their derivatives. Standard methods of EB formation include hanging drop and liquid suspension culture. Both culture systems maintain a balance between allowing ES cell aggregation necessary for EB formation and preventing EB agglomeration for efficient cell growth and differentiation. However, they are limited in their production capacity. In this paper, we established a new approach for the mass production of EBs in a scalable culture system. The rotary cell culture system (RCCS, STLV type) was adopted to produce EBs. The vessel was placed on its rotary base and the experiment started with a beginning rotation rate of approximately 8 r/min which has been previously determined empirically as the optimal initial speed to yield randomized gravitational vectors while minimizing fluid shear stress. To keep the aggregations pfloating in simulated microgravityq, the rotation rate was increased as the EBs visibly grew. The EB production efficiency was calculated when different cell densities were inoculated. The kinetic change of EBs was measured during the time course of EB formation. Compared with the traditional method of producing EBs with hanging drop, the multi-potential of the resulting EBs in RCCS was analyzed by the capability of cardiomyocyte genesis. The results showed that EBs could be produced by RCCS with high efficiency. The optimal cell density inoculated in RCCS was 10000 cells/ml, in which EB production was about twice higher than that in the suspending culture. Day 4-5 was the optimal time point for harvesting EBs. To clarify whether the differentiated potential of EBs might be affected by the microgravity produced by the rotary cell culture system, cardiogenic induction during ES cell differentiation was evaluated in our study. It was manifested by appearance of spontaneously and rhythmically contracting myocytes. In addition, immuno-histological and RT-PCR detection showed that the harvested EBs in RCCS exhibited the expected cardiac genesis and morphology. So, scalable production of EBs is obtained by RCCS. It will provide a useful approach to generate a large quantity of ES-derived cells for further research or application.

[Experimental study of tissue-engineered heart tissue using type I collagen as scaffold].

OBJECTIVE: To construct tissue-engineered heart tissue (EHT) using liquid collagen as scaffold. METHODS: Neonatal rat cardiac myocytes were isolated, cultured, and mixed with liquid collagen type I and matrix factors and then cast in circular molds to construct circular cardiac myocytes/collagen strand. After a 7-day culture in circular molds, the strands were removed, and subjected to 10% static stretch for another 7 days. Microscopy and transmission electron microscopy, routine HE staining and immunohistochemical staining were used to analyze the engineered heart tissue. RESULTS: Beating areas could be seen on the surface of the EHTs at the second day after stretching; more beating areas could be seen thereafter. These areas beat stronger and stronger, and finally came to synchronzation. Histological and immunohistochemical analyses showed that the cardiac myocytes in the EHTs distributed evenly in the whole strand and the majority of the cells, with elongated nuclei, stretched along the stretching direction. The morphology of EHTs resembled that of the native adult cardiac tissue. Transmission electron microscopy revealed that the cardiac myocytes in EHTs contained arranged myofibrils oriented parallel to the longitudinal cell axis. Clearly defined sarcomeres and Z lines were observed. CONCLUSION: Liquid type I collagen is a good scaffold for generation of EHTs similar to the native heart tissue.

[Experimental study of the isolation, culture and in chondrogenic differentiation of human bone mesenchymal stem cell].

OBJECTIVE: To study the isolation of human bone marrow mesenchymal stem cells (MSCs) and in vitro differentiation into chondrocytes as potential seed cell for condyle cartilage tissue engineering. METHODS: Human MSCs were isolated by percoll solution from normal human bone marrow sample and cultured in flasks. Specific cell surface markers were identified by flow-cytometry. After the cells were treated with inductive medium containing insulin, transferrin, pyruvate, dexathemesone and TGF-beta for 7 - 14 days, microscopic, histological and immuno-histo-chemical studies were performed for chondrogenic phenotype identification. RESULTS: Primary cultures of human MSCs express CD29 and CD44 positively and meanly, but CD34, CD45 and HLA-DR negatively. After 14 days of induction, the cells were positively stained by safranin O. Immunohistochemical analysis proved strong type II collagen expression. CONCLUSIONS: Percoll helps to generate a better isolation of MSCs from human bone marrow aspirates with a purity more above 95%. The isolated MSCs can be expanded and induced in vitro to differentiate into chondrocytes by inductive medium.