Objective To evaluate sex determining region of the Y (Sry) as a engrafting track of the transplanted BMSCs survival and new bone formation in the osteonecrosis of the femoral head (ONFH) of rabbit. Methods Fortynine 4-5-month-old New Zealand White rabbits were included, weighing 2.0-2.5 kg, 48 females and 1 male. BMSCs of the rabbits were isolated by density gradient separation method, the third passage cells were marked by 1, 1’-dioctadecyl-3, 3, 3’, 3’-tetramethyl indocarbocyanine perchlorate (DiI) and the concentration of cell suspension was 2.5 × 108/ mL. The animal model of ONFH were establ ished with 48 female rabbits by injecting l iquid nitrogen, and femoral head was not dislocated.The animal model were divided into 3 groups, 16 rabbits in each group. Group A only establ ished animal model as control. Autologous BMSCs (4 μL) marked by DiI was transplanted in the ONFH models of the group B. Allogenic BMSCs (4 μL) marked by DiI was transplanted in ONFH models of the group C. The femoral head were observed by X-ray, HE staining and Masson staining, and the regenerating trabecular volume percentages was determined at 2, 4, 6 and 8 weeks after operation respectively. The examples of the heart, lung, l iver, spleen and kidney were obtained. The transplanted BMSCs were traced by fluorescence microscope, the Sry gene expression was detected by PCR for cells survival. Results All rabbits survived till the end of experiment. The X-ray showed gradual necrosis in the femoral head of group A. HE and Masson staining results indicated that compared with the group A, the recovery condition of the necrotic femoral head in the groups B and C was better. At each time of groups B and C, the regenerating trabecular volume percentages were higher than that of the group A significantly (P lt; 0.01). There was no significant difference between groups B and C (P gt; 0.05). The cells marked by DiI were not founded in the tissues of the heart, lung, l iver, spleen and kidney in groups B and C at each time. PCR showed that the expression of Sry gene were not observed at the heart, lung, l iver, spleen and kidney of three groups at each time. The expression of Sry gene was clearly identified in the femoral head of all 16 rabbits in the group C at each time point. Conclusion Allografting of BMSCs transplanted into the femoral head can survive and induce new bone formation without redistribution.
Objective To explorer the survival time of autogeneic BMSCs labeled by superparamagnetic iron oxide (SPIO) in rabbit intervertebral discs and the rule of migration so as to prove bases of gene therapy preventing intervertebral disc degeneration. Methods Twelve rabbits were used in this experiment, aged 8-10 weeks, weighing 1.5-2.0 kg and neglecting their gender. BMSCs were separated from rabbits bone marrow by density gradient centrifugation and cultivated, and the 3rd generation of BMSCs were harvested and labeled with SPIO, which was mixed with poly-l-lysine. The label ing efficiency was evaluated by Prussian blue staining and transmission electron microscope. Trypanblau stain and MTT were performed to calculate the cell’ s activity. Rabbits were randomly divided into experimental group (n=8) and control group (n=4), the labeled BMSCs and non-labeled BMSCs (5 × 105/mL) were injected into their own intervertebral discs (L1,2, L2,3, L3,4 and L4,5), respectively. At 2, 4, 6 and 8 weeks, the discs were treated with Perl’s fluid to observe cell survival and distribution. Results The label ing efficiency of BMSCs with SPIO was 95.65% ± 1.06%, the cell activity was 98.28% ± 0.85%. There was no statistically significant difference in cell prol iferation within 7 days between non-labeled and labeled cells (P gt; 0.05). After 8 weeks of operation, the injected cells was al ive. ConclusionLabeled BMSCs with SPIO is feasible in vitro and in vivo, and the cells can survive more than 8 weeks in rabbit discs.
Objective To investigate the effect and mechanism of leptin (LEP) on the osteoblastic differentiation of hBMSCs in vitro. Methods Whole bone marrow culture method was appl ied to culture hMBSCs and hBMSCs at passage 3 were divided into groups A, B, C, D, E and F, and when cell attachment was evident, 400, 200, 100 and 50 ng/mL LEP, 100 ng/mLBMP and common nutrient medium were added into each group, respectively. ALP staining and mineral ized nodules staining were conducted at 7 and 21 days after culture, respectively. And inverted phase contrast microscope observation was performed. ALP activity and osteocalcin (OCN) level of hBMSCs in each group was detected at 7, 14 and 21 days after culture to select the best induced concentration of LEP on osteoblastic differentiation. For groups of B, E and F at 7 days after culture, RT-PCR was adopted to detect the expression of such osteogenesis-related genes as core-binding factor α 1 (Cbfα1), ALP, Col I and OCN mRNA. Results At 7 days after induced culture, the ALP staining result showed that the endochylema in groups A, B, C, D and E were stained blue and the endochylema in the group F was sl ightly positive. At 21 days after induced culture, the mineralized nodules staining showed that cells in groups A, B, C, D and E were stained positively and cells in group F were negative. At 7, 14 and 21 days after culture, ALP and OCN activities in group B were less than that of group E (P lt; 0.05), but significant higher than that of groups A, C, D and F (P lt; 0.05), the optimal concentration of LEP was 200 ng/mL. At 7 days after culture, group F witnessed no expression of Cbfα1, ALP, Col I and OCN mRNA, while groups B and E witnessed expressions of all those indexes, but the expressions in group B were less than those of group E. Conclusion LEP can stimulate osteoblastic differentiation of hBMSCs in vitro, and the possible mechanism is its role of promoting the expression of osteoblastic related genes.
Objective To compare the effect of two different methods of cell seeding on spatial distribution and gene expression of hBMSCs in biocoral scaffold in vitro cultures. Methods The composite of hBMSCs and biocoral scaffold was prepared by traditional seeding (group A) and fibrin glue seeding (group B). The seeding efficiency was measured after 30 minutes of incubation in group B and after 3 hours in group A. At 2, 7, 14 and 21 days after culture, the samples were harvestedand the serial longitudinal sections were cut for each embedded composite. The sections were stained with DAPI and were measured using fluorescence microscope with apotome under serial optical sections. The cell number in every 10 × objective field was automatically measured by AxioVision image analysis software and levels (from seeding surface to bottom L1-L5) or columns (from centre to margin) for comparing cell distribution were set up. The specific osteogenic genes [osteonectin (ON), core binding factor α1 (Cbfα1), osteocalcin (OC)] expression was measured by RT-PCR. Results The seeding efficiency was significantly higher in group B (88.32% ± 4.2%) than in group A (66.51% ± 12.33%, P lt; 0.01). At 2 days after culture, the cell number from L1 to L4 decreased gradully in two groups (P lt; 0.05); in the cell number of different columns, there was no significant difference in group A (Pgt; 0.05) whereas significant difference in group B (P lt; 0.05); there was no significant difference in gene expression between two groups (P gt; 0.05). At 7 days after culture, the cell number was less than that at 2 days in group A and there was significant difference among levels (P lt; 0.05). The cell number and osteogenic gene expression increased sharply and there appeared uniform cell distribution in group B (P gt; 0.05). The gene expression of ON and Cbfα1 in group B was higher than that in group A (Plt; 0.05). At 14 days after culture, the cell number in levels or columns in group A decreased sharply and was less than that at 7 days (P lt; 0.05); whereas the cell number was similar to that at 7 days in group B (P gt; 0.05). The OC gene expression reached the highest level in group B at 14 days. The gene expression was higher in group B than in group A (P lt; 0.05). At 21 days after culture, there was significant difference in the cell number among levels and in the gene expression between group A and group B (P lt; 0.05); there was no significant difference in the cell number among columns in two groups (Pgt; 0.05). In addition, the cell number of most levels and columns in group B was more than that in group A at 7, 14 and 21 days after culture (P lt; 0.05). Conclusion More uniform cell distribution with rapid prol iferation and osteogenic differentiation is available in different levels or columns of scaffold by fibrin glue seeding than by traditional seeding.
To investigate the effect of BMSCs on the repair of digestive tract injury and its mechanisms.Methods Recent l iterature on the effect of BMSCs on the repair of digestive tract injury was reviewed. Results BMSCs had the potency of self-repl ication, prol iferation and multipotential differentiation, which played an important role in the repair of digestive tract injury. The probable mechanisms included: BMSCs’ abil ity of migrating to the injured tissue and inhibiting the host immune response; BMSCs’ dedifferentiation and redifferentiation; BMSCs’ direct differentiation into the epithel ial cellsor the stem cells of digestive tract; BMSCs’ fusion with the stem cells or the mature epithel ial cells of digestive tract; BMSCs’ participation in the reconstruction of injured microenvironment. Conclusion BMSCs participates in the repair of digestive tract injury and has a bright future in the treatment of digestive system disease.
Objective To observe the effect of BMSCs transplantation on gene and protein expression of VEGF receptor fetal l iver kinase 1 (Flk-1) after spinal cord injury (SCI), and to investigate the mechanism of repairing the SCI by BMSCs transplantation. Methods BMSCs were isolated and cultured from five 4-week-old male Wistar rats weighing100-120 g. The SCI model was made by using the modified Allen’s impactor device. Eighty-one adult female Wistar rats weighing 220-250 g were randomly divided into 3 groups: sham-operated group (group A, n=21), in which spinous process and vertebral plate of thorax 8-10 spinal cord segment were removed; DMEM group (group B, n=30), in which rats received four injections of DMEM in the peri-lesion area; and BMSCs group (group C, n=30), in which rats received four injections of BMSCs in the peri-lesion area. The changes of Flk-1 mRNA expression in rats’ spinal cord tissues were detected with RT-PCR method 1, 3 and 5 days after transplantation. The expression of Flk-1 protein was observed by using immunohistochemical technology in spinal cord 3, 7 and 14 days after transplantation. Results Morphology of the primary cultured BMSCs was various. Cell morphology tended to be uniform with the accumulation of passages, which appeared flat and spindle-shaped. RT-PCR results showed that there was no significant differences (P gt; 0.05) in Flk-1 mRNA expression between group C and group B at different time points after transplantation. But Flk-1 mRNA levels of group B and group C significantly increased and peaked 1 day after transplantation (P lt; 0.01), and then decreased 3 days after transplantation (P lt; 0.01) compared with that of group A, and were still higher than that of group A 5 days after transplantation (P lt; 0.05). Immunohistochemical staining results revealed that the expression of Flk-1 in group B was enhanced 3 and 7 days after transplantation compared with group A, which was significantly different (P lt; 0.01). There was no significant difference in the expression of Flk-1 between group B and groupp A 14 days after transplantation (P gt; 0.05). There was no significant difference in Flk-1 protein expression between group C and group B 3 days after transplantation (P gt; 0.05). The expression of Flk-1 protein in group C was significantly higher than that in group B 7 and14 days after transplantation (P lt; 0.01). Conclusion BMSCs transplantation after SCI does not have regulatary effect onthe expression of Flk-1 mRNA, but it does upregulate the Flk-1 protein expression, which may be one of the mechanisms of repairing SCI.
Objective To explore the label ing efficiency and cellular viabil ity of rabbit BMSCs labeled with different concentrations of superparamagnetic iron oxide (SPIO) particles, and to determine the feasibil ity of magnetically labeled stem cells with MR imaging. Methods The BMSCs were collected from il iac marrow of 10 adult rabbits (weighing 2.5-3.0 kg) and cultured. The SPIO-poly-L-lysine compound by different ratios mixed with medium, therefore, the final concentration of Fe2+ was 150 (group A), 100 (group B), 50 (group C) and 25 μg (group D) per mL, respectively, the 3rd generation BMSCs culture edium was added to lable; non-labeled cells served as a control (group E). MR imaging of cell suspensions was performed by using T1WI and T2WI sequences at a cl inical 1.5 T MRI system. Results BMSCs were efficiently labeled with SPIO, labeled SPIO particles were stained in all cytoplasms of groups A, B, C and D. With the increasing of Fe2+ concentration, blue dye particles increased. The staining result was negative in group E. The cell viabil ity in groups A, B, C, D and E was 69.20% ± 6.11%, 80.41% ± 2.42%, 94.32% ± 0.67%, 96.24% ± 0.34% and 97.43% ± 0.33%, respectively. There were statistically significant differences between groups A, B and groups C, D and E (P lt; 0.05), and between group A and group B (P lt; 0.05). T1WI images had no specific difference among 5 groups, T2WI images decreased significantly in groups A, B, C, decreased sl ightly in group D, and had l ittle change in group E. The T2WI signal intensities of groups A, B, C, D and E were 23.37 ± 6.21, 26.73 ± 3.60, 29.63 ± 2.82, 45.03 ± 6.76 and 783.15 ± 7.38, respectively, showing significant difference between groups A, B, C, D and group E (P lt; 0.05), and between groups A, B, C and group D (Plt; 0.05). Conclusion BMSCs can be easily and efficiently labeled by SPIO without interference on the cell viabil ity in labled concentration of 20-50 μg Fe2+ per mL. MRI visual ization of SPIO labeled BMSCs is feasible, which may be critical for future experimental studies.
Objective To study the effect of hypoxia on the prol iferation of hBMSCs and human placental decidua basal is-MSCs (hPDB-MSCs), and to provide the theoretical basis for discovering the new seed cells source for tissue engineering. Methods Density gradient centrifugation method was adopted to isolate and culture hBMSCs and hPDB-MSCs,flow cytometry (FCM) was appl ied to detect cell surface marker. After establ ishing the experimental model of CoC12 chemical hypoxia, MTT method was appl ied to evaluate the prol iferation of hBMSCs and hPDB-MSCs at different time points (6, 12, 24, 48, 72, 96 hours) with various CoC12 concentration (0, 50, 75, 100, 125, 150, 175, 200 μmol/L). Results FCM analysis revealed that hPDB-MSCs and hBMSCs expressed CD9, CD29, CD44, CD105, CD106 and human leucocyte antigen ABC (HLA-ABC), but both were absent for CD34, CD40L and HLA-DR. Compared with hBMSCs, hPDB-MSCs expressed stage-specific embryonic antigen 1 (SSEA-1), SSEA-3, SSEA-4, TRA-1-60 and TRA-1-81 better. The prol iferations of hPDB-MSCs and hBMSCs were inhibited within the first 12 hours under hypoxia condition, but promoted after 12 hours of hypoxia. Compared with the control group, the hBMSCs were remarkably prol iferated 24 hours after hypoxia with CoC12 concentration of 150 µmol/L (P lt; 0.05), while hPDB-MSCs were significantly prol iferated 12 hours after hypoxia with CoC12 concentration of 75 µmol/L (P lt; 0.05). Conclusion Compared with hBMSCs, hPDB-MSCs express more specific surface antigens of embryonic stem cells and are more sensitive to the prol iferation effects of chemical hypoxia, indicating it may be a new seed cells source for tissue engineering.
【Abstract】 Objective To explore the interventional effect of platelet lysate (PL) on osteogenic differentiation ofBMSCs by induction in rats in vitro. Methods Twenty-four clean-grade adult Wistar rats, weighing from 250 g to 300 g, maleor female, were included in this study. PL was obtained through three times of centrifugation and repeated freeze-thaw for the blood aspirated from cardiac cavities in 16 Wistar rats. ELISA assay was conducted to detect the concentration of growth factors PDGF, TGF-β1, IGF-1 and VEGF in PL. The BMSCs harvested by flushing femurs of 8 adult Wistar rats were isolated, cultivated and expanded in vitro. The cells at the 4 passage were performed for osteogenic differentiation by induction in three groups of A (5% PL of final concentration in basic induction medium), B (1% PL of final concentration in basic induction medium), and C (no presence of PL in basic induction medium as a control). The morphological changes of the cells were dynamically observed with inverted phase contrast microscope during the whole period. At different time-points, ALP staining (7 days) and ALP/TP (2, 8, 12 days) of the cells were detected to evaluate ALP activity, and the mineral formation in extracellular martrix was examined with Al izarin red staining which provided quantitative analysis of mineral deposits. Results ELISA assay showed that the content of PDGF, TGF-β1, IGF-1 and VEGF in PL reached (300 ± 30), (140 ± 25), (80 ± 35), (70 ± 20) pg/mL, respectively. Morphological observation displayed BMSCs in group A or B gradually turned from spindle-shape to square- or polygon-shape as the morphorlogical type of osteoblast-l ike cells at 7 days. The cells in group A showed slower shape changesbut higher prol iferation than that in group B or C. Moreover, at the 20 days, the cells in group A still displayed dense gro wth and produced obviously decreased amount of mineral deposits in ECM when compared with group B or C. At the 7 days, the cells ofgroup A showed smaller amount of granules positive for ALP staining in cytoplasm when compared with groups B and C, and displayed marked reduction in ALP activity assay at the 2, 8, and 10 days compared with that of groups B and C (P lt; 0.05). At the 20 days, Al izarin red staining showed the number of mineral deposits in groups A, B and C were 7.67 ± 1.10, 12.87 ± 0.81 and 15.59 ± 0.25, respectively, while the area of mineral deposits were (161 778.70 ± 44 550.80), (337 349.70 ± 56 083.24), and (415 921.70 ± 71 725.39) pixels, respectively. The number of mineral deposits and the area of mineral deposits in group A were smaller than those in groups B and C (P lt;0.05). But there was no statistically significant difference between groups B and C (P gt; 0.05). Conclusion PL is a kind of system carrying various growth factors. Exposure of PL inhibits both ALP activity and mineral formation of BMCs in a dose-dependent way under the osteogenic induction environment.
Objective To supply references to tissue-engineered skin cl inical appl ications with autogenic BMSCs composited collagen membrane to repair swine full-thickness cutaneous deficiency. Methods Twenty mL bone marrow were obtained respectively from 4 swine, autogenic BMSCs were cultured and passed to the 3rd passage. The fresh bovine tendontreated by means of chemically cross-l inked was made 5 cm diameter collagen I (Col I) membrane. The 2 × 107/mL P3 swine autogenic BMSCs labeled DAPI were planted to sterile Col I membrane for 24 hours incubation, then the tissue-engineered skin was constructed. The five full-thickness skin defect of 5 cm diameter was excised to the muscle from forward to backward on the back midl ine two sides of swine. The tissue-engineered skin were implanted in the experimental group, while Col I membrane was implanted in control group. After 3 and 8 weeks of implantation, the two swine wound surface heal ing circumstance was observed and further evaluated with histology analysis and TEM. After 3 weeks of implantation, the experimental group were observed with fluorescence microscopy and staining for glycogen. Results After 3 weeks of implantation, the wound surface of control group were observed nigrescence, scab and putrescence, and after 8 weeks of implantation, also evident putrescence and scar. The wound surface of experiment group was al ive after 3 weeks implantation, appearance was leveled off and flexible without evident scar. The wound surface recovered well after 8 weeks of implantation, wound surface heal ing rate was significantly difference between the two groups (P lt; 0.01). After 3 weeks of implantation, control group were observed acestoma hyperplasia and no epidermal coverage by histology analysis. The experimental group was showed integrity epidermis and dermis structure. The basal layer was crimson and continuously positive with glycogen staining. After 8 weeks of implantation, the experimental group and control group were emerged normal skin structure. After 3 weeks of implantation in control group, a lot of neutrophil ic granulocytes and fibroblasts were noticed, but no epidermal structure was observed under TEM. In the experimental group, a lot of epidermal cells were observed, dermatome connection among epidermal cells and hemidermosome connection between basilar membrane cells and basal membrane were observed in epidermis. In the dermis experimental group, blood capillary endothel ial cells were noticed. Furthermore, considerable collagen fiber deposit was found in the surrounding tissue of fibroblasts. After 3 weeks of implantation, BMSCs labeled with DAPI were located reconstructed epidermal basement membrane and dermis by fluorescence microscopy. Conclusion Tissue-engineered skin which is composited with autogenic BMSCs as seed cells and collagen membrane were potential prospects in appl ication of repairing swine full-thickness cutaneous deficiency.