神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

神经干细胞移植延缓失神经肌萎的作用机制

Objective To study the effect and mechanism of transplanting spinal fetal neural stem cells (NSCs) into the peripheral nerve for delaying muscle denervation atrophy. Methods Spinal. fetal NSCs were separated from spinal cord of enceinte 10 to 12 days SD rats, cultured and purified. After three passages, the formed NSC spheres were blew into single cell suspension ( 106/μl×5 μl) and transplanted into the distal part of the transected tibial nerve. 5 μl of cell culture medium was injected into the distal tibial nerve in the control group. Three and 5 months after the transplantation, the distal part of the tibial nerve and the triceps suraes were harvested and identified with specific markers, by means of indirect immunofluorescent staining to evaluate survival and differentiation of transplanted NSCs in the nerve, and to observe the neuromuscular junctions.Results Compare to the control group, atrophy of the triceps suraes muscle was less severe 3 and 5 months after NSCs transplantation. Postsynaptic membrane was also better preserved in NSCs transplanted group. Five months after NSCs transplantation, new synapses (neuromuscular junction) formed in the denervated muscle.Conclusion NSCs transplantation can delay atrophy denervated muscles. NSCs transplantation can not only maintain the structure of postsynaptic membrane, but also form new synapse with the denervated muscle.     

Influences of olfactory ensheathing cells transplantation on axonal regeneration in spinal cord of adult rats

Objective: To observe whether offactory ensheathing cells could be used to promote axonal regeneration in a slmntaneously nonregenerating system. Methods: After laminectomy at the lower thoracic level, the spinal cords of adult rats were exposed and completely transected at T10. A suspension of ensheathing cells was injected into the lesion site in 12 adult rats, and control D/F-12 (1:1 mixture of DMEM and Ham‘s F-12) was injected in 12 adult rats. Six weeks and ten weeks after cell transplantation, the rats were evaluated by climbing test and motor evoked potentials (MEPs) monitoring. The samples were procured and studied with histologiel and immounohistochemical methods. Results: At the 6th week after cell transplantation,d the rats in both the transplanted and control groups were paraplegic and the MEPs could not be recorded. At the 10th week after cell transplantation, of 7 rats in the control group, 2 rats had muscles‘ contraction of the lower extremities, 2 rats had hips and/or knees‘ active movement; and 5 rats‘ MEPs could be recorded in the hind limbs in the transplanted group ( n = 7). None of the rats in the control group had functional improvement and no MEPs recorded ( n = 7 ). Numerous regenerating axons were observed through the transplantation and continued to regenerate into the denervated host tract. Cell labelling using anti-Myelin Basic Protein (MBP) and anti-Nerve Growth Factor Receptor (anti-NGFR) indicated that the regenerated axons were derived from the appropriate neuronal source and that donor cells migrated into the denervated host tract. But axonal degeneration existed and regenerating axons were not observed within the spinalcords of the adult rats with only D/F-12 injection. Conclusions: The axonal regeneration in the transected adult rat spinal cord is possible after eusheathing cells transplantation.