ObjectiveTo prepare bionic spinal cord scaffold of collagen-heparin sulfate by three-dimensional (3-D) printing, and provide a cell carrier for tissue engineering in the treatment of spinal cord injury. MethodsCollagen-heparin sulfate hydrogel was prepared firstly, and 3-D printer was used to make bionic spinal cord scaffold. The structure was observed to measure its porosity. The scaffold was immersed in simulated body fluid to observe the quality change. The neural stem cells (NSCs) were isolated from fetal rat brain cortex of 14 days pregnant Sprague-Dawley rats and cultured. The experiment was divided into 2 groups: in group A, the scaffold was co-cultured with rat NSCs for 7 days to observe cell adhesion and morphological changes;in group B, the NSCs were cultured in 24 wells culture plate precoating with poly lysine. MTT assay was used to detect the cell viability, and immunofluorescence staining was used to identify the differentiation of NSCs. ResultsBionic spinal cord scaffold was fabricated by 3-D printer successfully. Scanning electron microscope (SEM) observation revealed the micro porous structure with parallel and longitudinal arrangements and with the porosity of 90.25%±2.15%. in vitro, the value of pH was not changed obviously. After 8 weeks, the scaffold was completely degraded, and it met the requirements of tissue engineering scaffolds. MTT results showed that there was no significant difference in absorbence (A) value between 2 groups at 1, 3, and 7 days after culture (P>0.05). There were a lot of NSCs with reticular nerve fiber under light microscope in 2 groups;the cells adhered to the scaffold, and axons growth and neurosphere formation were observed in group A under SEM at 7 days after culture. The immunofluorescence staining observation showed that NSCs could differentiated into neurons and glial cells in 2 groups;the differentiation rate was 29.60%±2.68% in group A and was 10.90%±2.13% in group B, showing significant difference (t=17.30, P=0.01). ConclusionThe collagen-heparin sulfate scaffold by 3-D-printed has good biocompatibility and biological properties. It can promote the proliferation and differentiation of NSCs, and can used as a neural tissue engineered scaffold with great value of research and application.
Objective To establish a better method of isolating andculturing ofneural stem cells(NSCs) in neonatal rat brain. Methods Tissue of brain was isolated from neonatal rats. Different medium and culture concentration were used toculture NSCs of neonatal rat. The culture concentration used were 1×10 4, 1×105, 1×106and 1×107/ml respectively. Ingredient of medium was classified into group 1 to 8 respectively according to whether to add 2% B27, epidermal growth factor (EGF) and basic fibroblast growth factor (bFGF) as well as the difference in culture concentration. The cells were induced to differentiate asto be confirmed as NSCs, and then were checked by phase contrast microscopy and identified by immunocytochemistry. Results The cells isolated and cultured gathered into neurospheres. The cells were capable of proliferating and maintaining longterm survival in vitro. The cells could be differentiated into neurons and glia.It was to the benefit of the survival of NSCs to add 5% fetal bovine serum(FBS)into the medium at the beginning of the culturing. When 10% FBS was added intothe medium, the neurospheres differentiated quickly. When concentration 1×106/ ml was used, the growth rate of the cells was the highest of all the concentrations. Reasonably higher cell concentration promoted the proliferation of NSCs. It was necessary to add 2% B27, EGF, and bFGF into the medium. The cells had the best growth when 2% B27, 20 ng/ml bFGF and 20 ng/ml EGF were added into the culture medium. EGF and bFGF had cooperative effect. Conclusion A better method of isolating and culturing of NSCs in neonatal rat brain is established and the foundation for future research is laid.
【Abstract】 Objective To review the progress in the treatment of spinal cord injury (SCI) by graft of neuralstem cells (NSCs) or bone marrow mesenchymal stem cells (BMSCs) as well as immune characteristics of two stemcells. Methods Different kinds of documents were widely collected, and then immunologic characteristics of NSCs andBMSCs were summarized. The therapy of SCI by stem cell transplantation was reviewed. Additionally, some problems intreatment were analyzed. Results Experimental study showed that graft of NSCs and BMSCs can promote the functionalrecovery of the injured spinal cord in animals. Due to immunologic properties of two stem cells, rejection reaction oftransplantation could produce a harmful effect on SCI treatment. Conclusion Transplantation of NSCs or BMSCs might bean effective measure for SCI treatment, but immunologic rejection reaction must be considered.
Objective To investigate the division, prol iferation and differentiation abil ities of nestin+/GFAP+cell after spinal cord injury and to identify whether it has the characteristic of neural stem cells (NSCs). Methods Twelvemale SD rats, aged 8 weeks and weighing 200-250 g, were randomized into 2 groups (n=6 per group): model group inwhich the spinal cord injury model was establ ished by aneurysm cl ip compression method, and control group in which no processing was conducted. At 5 days after model ing, T8 spinal cord segment of rats in each group were obtained and the gray and the white substance of spinal cord outside the ependymal region around central tube were isolated to prepare single cellsuspension. Serum-free NSCs culture medium was adopted to culture and serum NSCs culture medium was appl ied to induce differentiation. Immunohistochemistry detection and flow cytometry were appl ied to observe and analyze the type of cells and their capabil ity of division, prol iferation and differentiation. Results At 3-7 days after injury, the model group witnessed a plenty of nestin+/GFAP+ cells in the single cell suspension, while the control group witnessed few. Cell count of the model and the control group was 5.15 ± 0.71 and 1.12 ± 0.38, respectively, indicating there was a significant difference between two groups (P lt; 0.01). Concerning cell cycle, the proportion of S-phase cell and prol iferation index of the model group (15.49% ± 3.04%, 15.88% ± 2.56%) were obviously higher than those of the control group (5.84% ± 0.28%, 6.47% ± 0.61%), indicating there were significant differences between two groups (P lt; 0.01). In the model group, primary cells gradually formed threedimensional cell clone spheres, which were small in size, smooth in margin, protruding in center and positive for nestin immunofluorescence staining, and large amounts of cell clone spheres were harvested after multi ple passages. While in the control group, no obvious cell clone spheres was observed in the primary and passage culture of single cell suspension. At 5 days after induced differentiation of cloned spheres in the model group, immunofluorescence staining showed there were a number of galactocerebroside (GaLC) -nestin+ cells; at 5-7 days, there were abundance of β-tubul in III-nestin+ and GFAP-nestin+ cells; and at 5-14 days, GaLC+ ol igodendrocyte, β-tubul in II+ neuron and GalC+ cell body and protruding were observed. Conclusion Nestin+/GFAP+ cells obtained by isolating the gray and the white substance of spinal cord outside the ependymal region around central tube after compressive spinal cord injury in adult rat has the abil ity of self-renewal and the potential of multi-polarization and may be a renewable source of NSCs in the central nervous system.
ObjectiveTo investigate the effect of intravitreal injection of neural stem cells (NSC) derived from human umbilical cord mesenchymal stem cells (hUCMSC) on the expression of brain-derived neurotrophic factor (BDNF) and the number of retinal ganglion cells (RGC). MethodsFifty-two adult male Sprague-Dawley rats were randomly divided into normal group (group A) and diabetes mellitus group which received intraperitoneal injection of streptozocin to make diabetic rat models. One month after the diabetic rat models were confirmed successfully, diabetic rats were randomly divided into diabetic group (group B), hUCMSC group (group C) and hUCMSC-induced NSC group (group D). And thirteen diabetic rats were included in each group. Immuno-cytochemistry was applied to observe BDNF and thymosin-1(Thy-1) staining in the retina. Then mean integrated absorbance of the staining region on the retina slices were analyzed by Image-Pro Plus 6.0. The number of Thy-1 labeled RGC was record. ResultsBDNF and Thy-1 were positive on the retina slices from group A. The staining intensity from group B became weak and the expression of BDNF and Thy-1 gradually decrease with time (P < 0.05), and those from group C and group D were positively (P < 0.05), especially in group D (P < 0.05). The BDNF expression and Thy-1 labeled RGC were the same between group B and C (P > 0.05) at 2 weeks after injection, but were significant different for other time points (P < 0.05).Significant positive correlation between the expression of BDNF and the number of RGC were found by the Pearson correlation analysis (r=0.964, P < 0.05). ConclusionIntravitreal injection of hUCMSC-derived NSC to diabetic rat may protect the retina by promoting the expression of BDNF and increasing the number of RGC.
ObjectiveTo observe the effect of transplantation of neural stem cells (NSCs) induced by all-trans-retinoic acid (ATRA) combined with glial cell line derived neurotrophic factor (GDNF) and chondroitinase ABC (ChABC) on the neurological functional recovery of injured spinal cord in Sprague Dawley (SD) rats. MethodsSixty adult SD female rats, weighing 200-250 g, were randomly divided into 5 groups (n=12): sham operation group (group A), SCI model group (group B), NSCs+GDNF treatment group (group C), NSCs+ChABC treatment group (group D), and NSCs+GDNF+ChABC treatment group (group E). T10 segmental transversal injury model of the spinal cord was established except group A. NSCs induced by ATRA and marked with BrdU were injected into the site of injury at 8 days after operation in groups C-E. Groups C-E were treated with GDNF, ChABC, and GDNF+ChABC respectively at 8-14 days after operation;and group A and B were treated with the same amount of saline solution. Basso Beattie Bresnahan (BBB) score and somatosensory evoked potentials (SEP) test were used to study the functional improvement at 1 day before remodeling, 7 days after remodeling, and at 1, 2, 5, and 8 weeks after transplantation. Immunofluorescence staining and HE staining were performed to observe the cells survival and differentiation in the spinal cord. ResultsFive mouse died but another rats were added. At each time point after modeling, BBB score of groups B, C, D, and E was significantly lower than that of group A, and SEP latent period was significantly longer than that of group A (P<0.05), but no difference was found among groups B, C, D, and E at 7 days after remodeling and 1 week after transplantation (P>0.05). BBB score of groups C, D, and E was significantly higher than that of group B, and SEP latent period was significantly shorter than that of group B at 2, 5, and 8 weeks after transplantation (P<0.05);group E had higher BBB score and shorter SEP latent period than groups C and D at 5 and 8 weeks, showing significant difference (P<0.05). HE staining showed that there was a clear boundary between gray and white matter of spinal cord and regular arrangement of cells in group A;there were incomplete vascular morphology, irregular arrangement of cells, scar, and cysts in group B;there were obvious cell hyperplasia and smaller cysts in groups C, D, and E. BrdU positive cells were not observed in groups A and B, but could be found in groups C, D and E. Group E had more positive cells than groups C and D, and difference was significant (P<0.05). The number of glial fibrillary acidic protein positive cells of groups C, D, and E was significantly less than that of groups A and B, and it was significantly less in group E than groups C and D (P<0.05). The number of microtubule-associated protein 2 positive cells of groups C, D, and E was significantly more than that of groups A and B, and it was significantly more in group E than groups C and D (P<0.05). ConclusionThe NSCs transplantation combined with GDNF and ChABC could significantly promote the functional recovery of spinal cord injury, suggesting that GDNF and ChABC have a synergistic effect in the treatment of spinal cord injury.
To explore the expression of Wnt-1 during the process of inducing neural stem cells (NSCs) into neurons by using all-trans-retinoic acid (ATRA) in vitro and the effect of Wnt-1 on NSCs differentiation. Methods NSCs isolated from cerebral cortex of SD rat embryo (12-16 days’ gestation) were cultured. The concentration of cells at passage 3 were adjusted to 1 × 106 cells /mL and treated with ATRA at 0.5, 1.0, 5.0 and 10.0 μmol/L, respectively. Differentiation ratio of NSCsinto neurons in each group was detected by double-labelling immunofluorescence technique and flow cytometry, and 1.0 μmol/ L was selected as the best concentration for ATRA to promote NSCs differentiation. In experimental group, NSCs at passage 3 were cultured with ATRA at 1.0 μmol/L in vitro, and expression of Wnt-1 was detected by immunocytochemistry staining, realtime flurescent quantitive PCR and Western blot at 3, 5, 7 and 9 days after culture, respectively. The cells at passage 3 receiving no ATRA served as control group. Results Immunocytochemistry staining: in the control group, there was l ittle Wnt-1 protein expression; in the experimental group, peak expression of Wnt-1 and numerous positive cells occurred at 3 days after culture, the positive expression of Wnt-1 was still evident at 5 days after culture, and there was significant difference between two groups in integrated absorbance (IA) value at 3 and 5 days after culture(P lt; 0.05), obvious decrease of positive expression of Wnt-1 was evident, and no significant difference was evident between two groups in IA value at 7 and 9 days (P gt; 0.05). Real-time fluorescence quantitative PCR: the relative expression of Wnt-1 mRNA in the control group was 0.021 7 ± 0.072 1; the relative expression of Wnt-1 mRNA in the experimental group at 3, 5, 7 and 9 days was 0.512 2 ± 0.280 0, 0.216 4 ± 0.887 0, 0.038 5 ± 0.299 4 and 0.035 5 ± 0.309 5, respectively, indicating the value decreased over time, and there were significant difference between two groups at 3 and 5 days (P lt; 0.05), and no significant difference at 7 and 9 days (P gt; 0.05) . Western blot detection: specific and visible staining band was noted; in the control group, Wnt-1 protein expression was 0.005 1 ± 0.558 3; in the experimental group, Wnt-1 protein expression at 3, 5, 7 and 9 days was 0.451 7 ± 0.071 3, 0.311 7 ± 0.080 5, 0.007 3 ± 0.052 7 and 0.004 7 ± 0.931 4, respectively, suggesting the value decreased over time; there were significant differences between two groups at 3 and 5 days (P lt; 0.05), and no significant differences at 7 and 9 days (P gt; 0.05). Conclusion With the induction of ATRA at 1.0 μmol/L, Wnt-1 and NSCs differentiation in early stage are positively correlated. Its possible mechanism may rely on the activation of such signals as classic Wnt-1 signal pathway, indicating Wnt-1 relates to the differentation of NSCs into neurons.
To summarize Notch, basic hel ix-loop-hel ix (bHLH) and Wnt gene signal transduction pathways in the process of differentiation and development of neural stem cells. Methods The l iterature on the gene signal transduction pathway in the process of differentiation and development of neural stem cells was searched and then summarized and analyzed. Results The formation of Nervous System resulted from common actions of multi-signal transduction pathways. There may exist a fixed threshold in the compl icated selective system among Notch, bHLH and Wnt gene signal transduction pathways. Conclusion At present, the specific gene signal transduction pathway of multi pl ication and differentiation of neural stem cells is still unclear.
Objective To investigate the influence of Nogo extracellular peptide residues 1-40 (NEP1-40) gene modification on the survival and differentiation of the neural stem cells (NSCs) after transplantation. Methods NSCs were isolated from the cortex tissue of rat embryo at the age of 18 days and identified by Nestin immunofluorescence. The lentiviruses were transduced to NSCs to construct NEP1-40 gene modified NSCs. The spinal cords of 30 Sprague Dawley rats were hemisected at T9 level. The rats were randomly assigned to 3 groups: group B (spinal cord injury, SCI), group C (NSCs), and group D (NEP1-40 gene modified NSCs). Cell culture medium, NSCs, and NEP1-40 gene modified NSCs were transplanted into the lesion site in groups B, C, and D, respectively at 7 days after injury. An additional 10 rats served as sham-operation group (group A), which only received laminectomy. At 8 weeks of transplantation, the survival and differentiation of transplanted cells were detected with counting neurofilament 200 (NF-200), glial fibrillary acidic portein (GFAP), and myelin basic protein (MBP) positive cells via immunohistochemical method; the quantity of horseradish peroxidase (HRP) positive nerve fiber was detected via HRP neural tracer technology. Results At 8 weeks after transplantation, HRP nerve trace showed the number of HRP-positive nerve fibers of group A (85.17 ± 6.97) was significantly more than that of group D (59.25 ± 7.75), group C (33.58 ± 5.47), and group B (12.17 ± 2.79) (P lt; 0.01); the number of groups C and D were significantly higher than that of group B, and the number of group D was significantly higher than that of group C (P lt; 0.01). Immunofluorescent staining for Nestin showed no obvious fluorescence signal in group A, a few scattered fluorescent signal in group B, and b fluorescence signal in groups C and D. The number of NF-200-positive cells and MBP integral absorbance value from high to low can be arranged as an order of group A, group D, group C, and group B (P lt; 0.05); the order of GFAP-positive cells from high to low was group B, group D, group C, and group A (P lt; 0.05); no significant difference was found in the percentage of NF-200, MBP, and GFAP-positive cells between group C and group D (P gt; 0.05). Conclusion NEP1-40 gene modification can significantly improve the survival and differentiation of NSCs after transplantation, but has no induction on cell differentiation. It can provide a new idea and reliable experimental base for the study of NSCs transplantation for SCI.
ObjectiveTo explore the feasibility of co-transduction and co-expression of Nogo extracellular peptide residues 1-40 (NEP1-40) gene and neurotrophin 3 (NT-3) gene into neural stem cells (NSCs).MethodsNSCs were derived from the cortex tissue of Sprague Dawley rat embryo. The experiment included 5 groups: no-load lentiviral vector transducted NSCs (group A), NEP1-40 transducted NSCs (group B), NT-3 transducted NSCs (group C), NEP1-40 and NT-3 corporately transducted NSCs (group D), and blank control (group E). Target genes were transducted into NSCs by lentiviral vectors of different multiplicity of infection (MOI; 5, 10, 15) for different time (24, 48, 72 hours). Fluorescent microscope was used to observe the expression of fluorescence protein and acquire the optimum MOI and optimum collection time. Real-time fluorescence quantitative PCR and Western blot tests were utilized to evaluate the gene expressions of NEP1-40 and NT-3 in NSCs and protein expressions of NEP1-40 and NT-3 in NSCs and in culture medium.ResultsThe optimum MOI for both target gene was 10 and the optimum collection time was 48 hours. The real-time fluorescence quantitative PCR and Western blot results showed that the mRNA and protein relative expressions of NEP1-40 in groups B and D were significantly higher than those in groups A and C (P<0.05), but no significant difference was found between groups B and D, and between groups A and C (P>0.05). The mRNA and protein relative expressions of NT-3 in groups C and D were significantly higher than those in groups A and B (P<0.05), but no significant difference was found between groups A and B, and between groups C and D (P>0.05).ConclusionNEP1-40 and NT-3 gene can be successfully co-transducted into NSCs by the mediation of lentiviral vector. The expressions of the two target genes are stable and have no auxo-action or antagonism between each other.