Objective To investigate a new composite matrix (BMSCs seeded on the denuded human amniotic membrane, BMSCs-DHAM) bridging the both stumps of spinal cord injury in rats to promote axon regeneration and improve motor function of hind l imbs. Methods The human amniotic membrane (HAM) was voluntarily donated by the healthy pregnant women after a caesarean section. The cells on the HAM were completely removed with a tryptic and mechanical approach to prepare DHAM. The BMSCs were separated and cultured from 4-week-old female rats (n=4), then the forth passage of BMSCs were labeled by PKH26 and seeded on DHAM (BMSCs-DHAM). The growing state of BMSCs was observed under themicroscopy. Moreover, 40 female rats (8-week-old, weighting 200-220 g) were made spinal cord injury models by transecting at T9 level, and were randomly divided into 4 groups (each group, n=10). The both stumps were respectively wrapped by BMSCs- DHAM or simple DHAM in groups A and C, and the same dose of BMSCs or physiological sal ine were also respectively injected the central lesion in groups B and D. At 12 weeks after surgery, the functional recovery of the hindl imbs was evaluated by the BBB locomotor rating score, and other indexes were tested including cortical motion evoked potential (MEP), anterograde biopinylated dextan amine (BDA) tracing, and immunofluorescence of neurofilament protein 200 (NF-200). Results HE staining proved that the DHAM was devoid of cellular components by this way, and BMSCs grew well on the substrate under the microscopy. At 12 weeks after operation, the BBB score (12.50 ± 1.26) in group A was significantly higher than those of other groups (P lt; 0.05), and the recovery in latency (3.52 ± 2.45) ms and ampl itude (480.68 ± 18.41) μV of MEP was also obviously improved in group A (P lt; 0.05) when compared with other groups. In addition, anterograde BDA tracing revealed that the rate of the positive BDA axons 54.12% ± 3.30% under the lesion level in group A was higher than those of other groups (P lt; 0.05), and lots of the regeneration axons (positive NF-200) were found to grow into the spinal cord under the composite matrix in group A. Conclusion The BMSCs-DHAM composite matrix can improve hindl imb motor function to some extent after spinal cord injury. It will be widely appl ied as the matrix material in the future.
Objective To investigate the feasibil ity of inducing canine BMSCs to differentiate into epithel ial cells in vitro with epithel ial cell conditioned medium (ECCM). Methods Five mL BMSCs were obtained from il iac spine of a healthy adult male canine with weighing 10 kg, and then isolated and cultured. The oral mucosa was harvested and cut into 4 mm × 4 mm after the submucosa tissue was el iminated; ECCM was prepared. BMSCs of the 2nd passage were cultured and divided into two groups, cultured in ECCM as experimental group and in L-DMEM as control group. The cell morphological characteristics were observed and the cell growth curves of two groups were drawn by the continual cell counting. The cells were identified by immunohistochemical staining through detecting cytokeratin 19 (CK-19) and anti-cytokeratin AE1/AE3 on the21st day of induction. The ultra-structure characteristics were observed under transmission electron microscope. Results The cells of two groups showed long-fusiform in shape and distributed uniformly under inverted phase contrast microscope. The cell growth curves of two groups presented S type. The cell growth curve of the experimental group was right shifted, showing cell prol iferation inhibition in ECCM. The result of immunohistochemical staining for CK-19 and anti-cytokeratin AE1/AE3 was positive in the experimental group, confirming the epithel ial phenotype of the cells; while the result was negative in the control group. The cells were characterized by tight junction under transmission electron microscope. Conclusion The canine ECCM can induce allogenic BMSCs to differentiate into epithel ial cells in vitro.
Objective To study repair of osteochondral defects by using composite of autologous BMSCs and chitosan/HAP (CS/HAP) bilayered scaffold in rabbits and its feasibil ity as osteochondral tissue engineering scaffolds. Methods CS/HAP bilayered scaffolds were produced with CS and HAP using a lyophil ization and sintering method. The pore size of the scaffold was observed by scanning electron microscopy (SEM). Anhydrous ethanol substitution method determined its porosity. BMSCs were isolated from bone marrow and cultured by general bone marrow methods. Both CD44 and CD45 on the BMSCs surface were detected with immunocytochemistry to identify BMSCs. Cell-scaffold complex was made with BMSCs as seed cells and CS/HAP bilayered scaffold as carrier by fibrin glue planting technique. The distribution ofBMSCs in CS/HAP scaffold was tested by SEM. The osteochondral defect (4 mm in diameter and 3 mm in height) model was made in the right knee joint of 36 Japanese white rabbits, which were randomly divided into 3 groups. Defects were repaired with CS/HAP and BMSCs composite ( group A, n=12) and with CS/HAP implants (group B, n=12); defects were not treated as a control (group C, n=12). Histological evaluation and gross observation were carried out at 6 weeks (n=6 in each group) and 12 weeks (n=6 in each group) postoperatively. Semi-quantitative histomorphological analysis was done to evaluate the repair cartilage tissue according to the modified Wakitani grading scale. Results CS/HAP bilayered scaffold possessed a porosity of 76.00% ± 5.01% and pore size of 200-400 μm (mean 300 μm ) in CS layer, and 72.00% ± 4.23% and 200-500 μm (mean 350 μm) in HAP layer, respectively. BMSCs formed colonies within 10-14 days. Immunocytochemistry results showed BMSCs had positive CD44 expression and negative CD45 expression. At 6 and 12 weeks after operation, gross and histological observation showed that the cartilage defects were fully filled with regenerated tissue, but bone defects were partially repaired in group A; the cartilage and bone defects were partially filled with regenerated tissue in group B and group C. The modified Wakitani grading scale were 5.17 ± 1.17 and 3.20 ± 0.75 in group A, 9.00 ± 0.63 and 6.00 ± 0.89 in group B, and 10.00 ± 0.89 and 9.60 ± 0.82 in group C at 6 weeks and 12 weeks postoperatively, respectively; showing significant differences between group A and groups B, C (P lt; 0.05). Conclusion The novel CS/HAP bilayered scaffold possesses porous structure and will possibly become a newbiomaterial of osteochondral tissue engineering.
【Abstract】 Objective To investigate the secretion of target gene and differentiation of BMSCs transfected by TGF-β1 and IGF-1 gene alone and together into chondrocytes and to provide a new method for culturing seed cells in cartilage tissue engineering. Methods The plasmids pcDNA3.1-IGF-1 and pcDNA3.1-TGF-β1 were ampl ified and extracted, then cut by enzymes, electrophoresed and analyzed its sequence. BMSCs of Wistar rats were separated and purificated by the density gradient centrifugation and adherent separation. The morphologic changes of primary and passaged cells were observed by inverted phase contrast microscope and cell surface markers were detected by immunofluorescence method. According to the transfect situation, the BMSCs were divided into 5 groups, the non-transfected group (Group A), the group transfected by empty vector (Group B), the group transfected by TGF-β1 (Group C), the group transfected by IGF-1 (Group D) and the group transfected both by TGF-β1 and IGF-1 (Group E). After being transfected, the cells were selected, then the prol iferation activity was tested by MTT and expression levels were tested by RT-PCR and Western blot. Results The result of electrophoresis showedthat sequence of two bands of the target genes, IGF-1 and TGF-β1, was identical with the sequence of GeneBank cDNA. A few adherent cells appeared after 24 hours culture, typical cluster formed on the forth or fifth days, and 80%-90% of the cells fused with each other on the ninth or tenth days. The morphology of the cells became similar after passaging. The immunofluorescence method showed that BMSCs were positive for CD29 and CD44, but negative for CD34 and CD45. A few cells died after 24 hoursof transfection, cell clone formed at 3 weeks after selection, and the cells could be passaged at the forth week, most cells became polygonal. The boundary of some cells was obscure. The cells were round and their nucleus were asymmetry with the particles which were around the nucleus obviously. The absorbency values of the cells tested by MTT at the wavelength of 490 nm were0.432 ± 0.038 in group A, 0.428 ± 0.041 in group B, 0.664 ± 0.086 in group C, 0.655 ± 0.045 in group D and 0.833 ± 0.103 in group E. The differences between groups A, B and groups C, D, E were significant (P lt; 0.01). The differences between groups A and B or between C, D and E were not significant (P gt; 0.05)。RT-PCR and Western blot was served to detect the expression of the target gene and protein. TGF-β1 was the highest in group C, 0.925 0 ± 0.022 0, 124.341 7 ± 2.982 0, followed by group E, 0.771 7 ± 0.012 0, 101.766 7 ± 1.241 0(P lt; 0.01); The expression of IGF-1 was the highest in group E, 1.020 0 ± 0.026 0, 128.171 7 ± 9.152 0, followed by group D, 0.465 0 ± 0.042 0, 111.045 0 ± 6.248 0 (P lt; 0.01). And the expression of collagen II was the hignest in group E, 0.980 0 ± 0.034 0, 120.355 0 ± 12.550 0, followed by group C, 0.720 0 ± 0.026 0, 72.246 7 ± 7.364 0(P lt; 0.01). Conclusion The repairment of cartilage defects by BMSCs transfected with TGF-β1 and IGF-1 gene together hasa good prospect and important significance of cl inic appl ication in cartilage tissue engineering.
Objective To investigate the effects of intermittent negative pressure on the mRNA expression of osteoprotegerin (OPG) and osteoprotegerin l igand (OPGL) in human BMSCs cultured in vitro. Methods BMSCs were isolated from adult marrow donated by 2 hip osteoarthritis patients with prosthetic replacement in January 2008 and cultured in vitro. The third passage cells were divided into experimental group and control group. The experimental group was induced by negative pressure intermittently for 2 weeks (pressure: 50 kPa, 30 minutes each time, twice per day) and the control groupwas routinely cultured. After 2 weeks of culture, cell morphology was observed by inverted phase contrast microscope, and the mRNA expressions of OPG and OPGL in BMSCs were analyzed by real-time PCR. Results The cell prol iferation speed of the experimental group was slower than that of the control group. The cell morph changed from shuttle to megagon with some prominences in experimental group and the cell morph kept shuttle in the control. The mRNA expression of OPG in experimental group increased significantly (P lt; 0.01) and the mRNA expression of OPGL in experimental group decreased significantly compared with control group (P lt; 0.01) 2 weeks later. Conclusion Intermittent negative pressure is capable of promoting the expression of OPG, while inhibiting the expression of OPGL in human BMSCs.
【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.
【Abstract】 Objective To investigate the in vivo osteogenic feasibil ity of tissue engineered periosteum constructedby porcine SIS and BMSCs in allogenic New Zealand rabbit. Methods The tissue engineered periosteum constructed by SIS scaffold and BMSCs was prepared in vitro .Twelve 2-month-old New Zealand rabbits were used in the experiments. The 1.5-2.0 cm critical bone defects were made in the both sides of radius of the animals. The tissue engineered periosteum was grafted into one side defect randomly, while the other side defect was only grafted SIS. Four weeks after operation, the forearms of all animals were checked by X-ray. Then, animals were sacrificed to harvest the specimen which were treated promptly for HE and Masson staining.The X-ray film and the morphological tissue staining outcome were evaluated qual itatively. Results After operation,all animals had a normal behavior and diet; the incision healed normally; the forearm could move normally for bearing weight.The tissue engineered periosteum constructed by allogenic BMSCs and heterogeneic SIS scaffold could form new bone tissue, andbridged the bone defect which could be confirmed either in X-ray film or histological staining. The newly formed bone tissue had similar bone density to normal bone. A lot of irregular newly formed vessels and medullary cavity inserted in the newly borned tissue. No lymphocytes infiltrated in histological examination. While the control side had no any osteogenesis neithter in X-ray, nor in HE and Masson staining inspecting; the defect space only occupied with some connective tissue. Conc lu sion Tissue engineered periosteum can form new bone in allogenic rabbit and has the feasibil ity to repair the segmental diaphysis defect.
Objective To evaluate the adhesion, prol iferation and osteogenic differentiation of rabbit BMSCs after cultured on freeze-dried demineral ized bone matrix (FDBM) modified with type II cadherin ectodomain (Cad- II). Methods BMSCs isolated from 10 Japanese white rabbits (male and female, 4-week-old, 0.61-0.88 kg) were cultured. The second generation of BMSCs (cell density 1 × 106 /mL) were seeded onto the Cad-II modified allogenic FDBM (experimental group) and only FDBM (control group) respectively, and then cocultured in vitro. The densities of seeded cells, the adhesion rate and their ALP activity were measured. The complex was observed through inverted phase contrast microscope and scanning electron microscope to evaluate the interaction between cells and FDBM. Another group of second generation of BMSCs (cell density 5 × 105 /mL) were seeded onto the Cad-II modified FDBM (experimental group) and only FDBM (control group) respectively, and then cocultured in vitro too. The ALP activity and osteocalcin immunohistochemical was measured. Results There was no significant difference in cell prol iferation between experimental group and control group. The adhesion rate of cells in the experimental group was 87.41% ± 5.19%, higher than that in the the control group 35.56% ± 1.75% (P lt; 0.01); the densities of seeded cells reached 5.0 × 105, showing significant difference compared with the control group (2.6 × 104, P lt; 0.05). Inverted phase contrast microscope showed that in the experimental group, more cultured BMSCs pasted in the hole and edge of the scaffold than that in the control group. HE staining showed the densities of seeded cells in the experimental group was higher than that in the control group. Scanning electron microscope showed that in the experimental group, a lot of cultured BMSCs adhered, spreaded in the scaffold, in the control group only a few BMSCs unevenly distributed in the scaffold. After 7 days of culture, the cultured BMSCs on modified FDBM expressed higher ALP activity; after 14 days of culture, the ALP activity (29.33 ± 1.53) was higher than that cultured on unmodified FDBM (18.31 ± 1.32), the positive rates of osteocucl in were 83% ± 7% in the experimental group and 56% ± 7% in the control group, showing significant difference (P lt; 0.01). Conclusion Cad-II enhanced cell adhesion to FDBM and promoted BMSCs differentiate to osteoblast, but no obvious effects were observed in cell prol iferation.
Objective To investigate the cl inical effect of MSCs transplantation derived from human umbil ical cord on bone nonunion. Methods From December 2005 to December 2007, 72 patients with traumatic bone nonunion were treated. Auto-il iac bone transplantation was used in 36 patients (group A), including 27 males and 9 females, aging (34.0 ± 2.1) years; including 18 cases of femoral fracture and 18 cases of tibia fracture; and the time of bone nonunion being (9.1 ± 1.7)months. Percutaneous MSCs transplantation derived from human umbil ical cord was used in 36 patients (group B), including 28 males and 8 females, aging (36.0 ± 1.6) years; including 18 cases of femoral fracture and 18 cases of tibia fracture; and the time of bone nonunion being (6.4 ± 1.9) months. There were no statistically significant differences in general data between two groups (P gt; 0.05). In group A, the site of bone nonunion was filled with relevant auto-il iac bone. In group B, the mixture of 6-8 mL platelet-rich plasma prepared by centrifugal izing venous blood and 1 × (106-107) P5 MSCs extracted from human umbil ical cord denoted by volunteers was injected into the region of bone nonunion with 0.2 g demineral ized bone powder. Results Incision healed by first intention in group A. No puncture, deep infection, rejection and general fever reaction occurred in group B. All patients in two groups were followed up for (13.2 ± 4.6) months. No loosening and breakage of internal fixation were observed in two groups. The motil ity and function of hip, knee and ankle were good. The time of bone union was (10.3 ± 2.8) months in group A and (5.6 ± 0.8) months in groups B, showing significant difference between two groups (P lt; 0.05). Conclusion The percutaneous MSCs transplantation derived from human umbil ical cord is more effective on bone nonunion than the traditional treatment, it is easily-to-operate, safe, rel iable, and rapid for union. It is one of effective methods in treating bone nonunion.
Objective To investigate the effect of extract of ginkgo biloba leaves (EGb50) on the prol iferation of SCs cultured in vitro. Methods The SCs were isolated from 3-day-old SD rats’ sciatic nerves by the method of enzyme gradationdigestion (n=20) and the purified 2nd passage of SCs were divided into 2 groups: the experimental group, in which SCs were cultured in FBS-DMEM medium with EGb50 (terminal concentration: 50 μg/mL); the control group, in which SCs were cultured in the FBS-DMEM medium without EGb50. The absorbance (A) value was detected by the 2, 3-bis- (2-methoxy-4-nitro-5- sulfophenyl)-2H-tetrazol ium-5-carboxanil ide (XTT) method 1, 3, 5, 7 and 9 days after culture, then the growth curves was drawn. Cell cycle was detected by flow cytometry (FCM). Disintegration per minute (DPM) of SCs was detected by the method of 3H-thymine nucleoside (3H-TdR) 2 and 3 days after culture and nerve growth factor (NGF) synthesis in SCs culture media was detected by ELISA method. Results Most SCs were spindle-shaped with a purity above 90%. XTT detection showed that A value of SCs in the control group was gradually increased 3 days after culture, reached the peak 5 days after culture and gradually decreased from then; the A value in the experimental group experienced the similar changes, but it was higher than that in the control group at each time point (P lt; 0.01). 3H-TdR showed that the DPM of the experimental group was 1 961.78 ± 231.13 and 4 601.51 ± 605.08 at 2 and 3 days after culture, while for the control group, the A value was 1 347.15 ± 121.57 and 3 740.42 ± 158.73 at the same time point, indicating a significant difference between two groups (P lt; 0.01). FCM observation indicated that the SCs prol iferation index of the experimental group and the control group was 18.6% ± 3.2% and 9.7% ± 2.9%, indicating a significant difference between two groups (P lt; 0.01). ELISA observation showed that the NGF concentration in the experimental and the control group was (0.065 6 ± 0.003 9) ng/mL and (0.038 6 ± 0.003 6) ng/mL, indicating a significant difference (P lt; 0.01). Conclusion EGb50 is capable of enhancing the prol iferation of SCs cultured in vitro, which may be one of the important mechanisms to promote peripheral nerve regeneration.