A neural stem/precursor cell monolayer for neural tissue engineering

The purpose of this study was to prepare a monolayer of neural stem/precursor cells (NSPCs) for neural tissue engineering applications. Two components present in serum, fibronectin and epidermal growth factor (EGF) were added into DMEM/F12 medium (termed medium B) to examine the effect of the migration-, proliferation- and differentiation-promoting potential on the cultured NSPCs, isolated from embryonic rat cerebral cortex. Compared with the serum effect, medium B also permitted neurosphere attachment onto the substrate surface and cell migration out of neurospheres extensively, but enhanced more extensive cell division and slowed down NSPC differentiation to generate a confluent NSPC monolayer. It was found the medium B-treated NSPCs possessed the capability to form typical neurospheres or to undergo differentiation into neuron-related cell types on various biomaterial surfaces. Therefore, we proposed a two-stage process for wound healing or nerve conduit preparation. Extensive NSPC division and MAP2-positive neuron differentiation were manipulated in NSPCs cultured in the medium B followed by the neuronal differentiation-favorable medium. These results should be useful for controlling the proliferation and differentiation of NSPCs on various biomaterials and conduits in neuroscience research.     

Effect of inflammatory cytokines on major histocompatibility complex expression and differentiation of human neural stem/progenitor cells

To develop transplantation of neural stem/progenitor cells (NSPCs) as a successful treatment of neurodegenerative disorders, the possible induction of an inflammatory response following implantation needs to be taken into consideration. Inflammatory cytokines can upregulate major histocompatibility complex (MHC) expression on transplanted cells, thereby rendering them more susceptible to graft rejection. Furthermore, cytokines also have a profound effect on cell differentiation, migration, and proliferation, which can greatly affect the outcome of transplantation. Here we studied the effect of three inflammatory cytokines, interferon-gamma (IFN-gamma), tumor necrosis factor-alpha (TNF-alpha), and interleukin-6 (IL-6), from three different species (human, monkey, rat) on expression of MHC molecules and differentiation of two human NSPC lines derived from striatum and hippocampus. Human and monkey IFN-gamma strongly upregulate MHC expression in both NSPC lines in a dose-dependent manner, whereas rat IFN-gamma has an effect on MHC expression only in hippocampal cells. Furthermore, TNF-alpha, but not IL-6, upregulates MHC expression in both NSPC lines. Differentiation of NSPCs in the presence of cytokines showed that IFN-gamma increased the neuronal yield threefold in striatal NSPC cultures and increased the number of oligodendrocytes twofold in hippocampal NSPC cultures. Addition of TNF-alpha enhanced gliogenesis in both cell lines, whereas IL-6 stimulated neurogenesis. Human NSPC lines' response to cytokines is therefore species specific and also dependent on the NSPCs' region of origin. The successful translation of different cell lines from animal models to clinical trials could be substantially influenced by the species-specific regulation of MHC and differentiation as reported here. Disclosure of potential conflicts of interest is found at the end of this article.     

Brain injury activates microglia that induce neural stem cell proliferation ex vivo and promote differentiation of neurosphere-derived cells into neurons and oligodendrocytes

Brain damage, such as ischemic stroke, enhances proliferation of neural stem/progenitor cells (NSPCs) in the subventricular zone (SVZ). To date, no reliable in vitro systems, which can be used to unravel the potential mechanisms underlying this lesion-induced effect, have been established. Here, we developed an ex vivo method to investigate how the proliferation of NSPCs changes over time after experimental stroke or excitotoxic striatal lesion in the adult rat brain by studying the effects of microglial cells derived from an injured brain on NSPCs. We isolated NSPCs from the SVZ of brains with lesions and analyzed their growth and differentiation when cultured as neurospheres. We found that NSPCs isolated from the brains 1-2 weeks following injury consistently generated more and larger neurospheres than those harvested from naive brains. We attributed these effects to the presence of microglial cells in NSPC cultures that originated from injured brains. We suggest that the effects are due to released factors because we observed increased proliferation of NSPCs isolated from non-injured brains when they were exposed to conditioned medium from cultures containing microglial cells derived from injured brains. Furthermore, we found that NSPCs derived from injured brains were more likely to differentiate into neurons and oligodendrocytes than astrocytes. Our ex vivo system reliably mimics what is observed in vivo following brain injury. It constitutes a powerful tool that could be used to identify factors that promote NSPC proliferation and differentiation in response to injury-induced activation of microglial cells, by using tools such as proteomics and gene array technology.     

The effect of substrate stiffness on adult neural stem cell behavior

Adult stem cells reside in unique niches that provide vital cues for their survival, self-renewal and differentiation. In order to better understand the contribution of substrate stiffness to neural stem/progenitor cell (NSPC) differentiation and proliferation, a photopolymerizable methacrylamide chitosan (MAC) biomaterial was developed. Photopolymerizable MAC is particularly compelling for the study of the central nervous system stem cell niche because Young's elastic modulus (E_Y) can be tuned from less than 1 kPa to greater than 30 kPa. Additionally, the numerous free amine functional groups enable inclusion of biochemical signaling molecules that, together with the mechanical environment, influence cell behavior. Herein, NSPCs proliferated on MAC substrates with Young's elastic moduli below 10 kPa and exhibited maximal proliferation on 3.5 kPa surfaces. Neuronal differentiation was favored on the softest surfaces with E_Y < 1 kPa as confirmed by both immunohistochemistry and qRT-PCR. Oligodendrocyte differentiation was favored on stiffer scaffolds (>7 kPa); however, myelin oligodendrocyte glycoprotein (MOG) gene expression suggested that oligodendrocyte maturation and myelination was best on <1 kPa scaffolds where more mature neurons were present. Astrocyte differentiation was only observed on <1 and 3.5 kPa surfaces and represented less than 2% of the total cell population. This work demonstrates the importance of substrate stiffness to the proliferation and differentiation of adult NSPCs and highlights the importance of mechanical properties to the success of scaffolds designed to engineer central nervous system tissue.     

Transplanted adult spinal cord-derived neural stem/progenitor cells promote early functional recovery after rat spinal cord injury

We examined the effect of spinal cord-derived neural stem/progenitor cells (NSPCs) after delayed transplantation into the injured adult rat spinal cord with or without earlier transplantation of bone marrow-derived mesenchymal stromal cells (BMSCs). Either BMSCs or culture medium were transplanted immediately after clip compression injury (27 g force), and then, 9 days after injury, NSPCs or culture medium were transplanted. Cell survival and differentiation, functional recovery, retrograde axonal tracing, and immunoelectron microscopy were assessed. A significant improvement in functional recovery based on three different measures was seen only in the group receiving NSPCs without BMSCs, and the improved recovery was evident within 1 week of transplantation. In this group, NSPCs differentiated mainly into oligodendrocytes and astrocytes, there was ensheathing of axons at the injury site by transplanted NSPCs, an increase in host oligodendrocytes, and a trend toward an increase in retrogradely labeled supraspinal nuclei. Transplantation of the BMSC scaffold resulted in a trend toward improved survival of the NSPCs, but there was no increase in function. Thus, transplantation of adult rat NSPCs produced significant early functional improvement after spinal cord injury, suggesting an early neuroprotective action associated with oligodendrocyte survival and axonal ensheathment by transplanted NSPCs.     

Gallium nitride induces neuronal differentiation markers in neural stem/precursor cells derived from rat cerebral cortex

In the present study, gallium nitride (GaN) was used as a substrate to culture neural stem/precursor cells (NSPCs), isolated from embryonic rat cerebral cortex, to examine the effect of GaN on the behavior of NSPCs in the presence of basic fibroblast growth factor (bFGF) in serum-free medium. Morphological studies showed that neurospheres maintained their initial shape and formed many long and thick processes with the fasciculate feature on GaN. Immunocytochemical characterization showed that GaN could induce the differentiation of NSPCs into neurons and astrocytes. Compared to poly-d-lysine (PDL), the most common substrate used for culturing neurons, there was considerable expression of synapsin I for differentiated neurons on GaN, suggesting GaN could induce the differentiation of NSPCs towards the mature differentiated neurons. Western blot analysis showed that the suppression of glycogen synthase kinase-3β (GSK-3β) activity was one of the effects of GaN-promoted NSPC differentiation into neurons. Finally, compared to PDL, GaN could significantly improve cell survival to reduce cell death after long-term culture. These results suggest that GaN potentially has a combination of electric characteristics suitable for developing neuron and/or NSPC chip systems.     

Essential roles of sphingosine 1-phosphate/S1P1 receptor axis in the migration of neural stem cells toward a site of spinal cord injury

Neural stem/progenitor cells (NSPCs) migrate toward a damaged area of the central nervous system (CNS) for the purpose of limiting and/or repairing the damage. Although this migratory property of NSPCs could theoretically be exploited for cell-based therapeutics of CNS diseases, little is known of the mechanisms responsible for migratory responses of NSPCs. Here, we found that sphingosine 1-phosphate (Sph-1-P), a physiological lysophospholipid mediator, had a potent chemoattractant activity for NSPCs, in which, of Sph-1-P receptors, S1P(1) was abundantly expressed. Sph-1-P-induced NSPC migration was inhibited by the pretreatment with pertussis toxin, Y-27632 (a Rho kinase inhibitor), and VPC23019 (a competitive inhibitor of S1P(1) and S1P(3)). Sph-1-P does not act as intracellular mediator or in an autocrine manner, because [(3)H]sphingosine, incorporated into NSPCs, was mainly converted to ceramide and sphingomyeline intracellularly, and the stimulation-dependent formation and extracellular release of Sph-1-P were not observed. Further, Sph-1-P concentration in the spinal cord was significantly increased at 7 days after a contusion injury, due to accumulation of microglia and reactive astrocytes in the injured area. This locally increased Sph-1-P concentration contributed to the migration of in vivo transplanted NSPCs through its receptor S1P(1), given that lentiviral transduction of NSPCs with a short hairpin RNA interference for S1P(1) abolished in vivo NSPC migration toward the injured area. This is the first report to identify a physiological role for a lipid mediator in NSPC migration toward a pathological area of the CNS and further indicates that the Sph-1-P/S1P(1) pathway may have therapeutic potential for CNS injuries.     

Optimizing gelling parameters of gellan gum for fibrocartilage tissue engineering

Gellan gum is an attractive biomaterial for fibrocartilage tissue engineering applications because it is cell compatible, can be injected into a defect, and gels at body temperature. However, the gelling parameters of gellan gum have not yet been fully optimized. The aim of this study was to investigate the mechanics, degradation, gelling temperature, and viscosity of low acyl and low/high acyl gellan gum blends. Dynamic mechanical analysis showed that increased concentrations of low acyl gellan gum resulted in increased stiffness and the addition of high acyl gellan gum resulted in greatly decreased stiffness. Degradation studies showed that low acyl gellan gum was more stable than low/high acyl gellan gum blends. Gelling temperature studies showed that increased concentrations of low acyl gellan gum and CaCl? increased gelling temperature and low acyl gellan gum concentrations below 2% (w/v) would be most suitable for cell encapsulation. Gellan gum blends were generally found to have a higher gelling temperature than low acyl gellan gum. Viscosity studies showed that increased concentrations of low acyl gellan gum increased viscosity. Our results suggest that 2% (w/v) low acyl gellan gum would have the most appropriate mechanics, degradation, and gelling temperature for use in fibrocartilage tissue engineering applications.     

Identification of astrocyte-expressed factors that modulate neural stem/progenitor cell differentiation

Multipotent neural stem/progenitor cells (NSPCs) can be isolated from many regions of the adult central nervous system (CNS), yet neurogenesis is restricted to the hippocampus and subventricular zone in vivo. Identification of the molecular cues that modulate NSPC fate choice is a prerequisite for their therapeutic applications. Previously, we demonstrated that primary astrocytes isolated from regions with higher neuroplasticity, such as newborn and adult hippocampus and newborn spinal cord, promoted neuronal differentiation of adult NSPCs, whereas astrocytes isolated from the nonneurogenic region of the adult spinal cord inhibited neural differentiation. To identify the factors expressed by these astrocytes that could modulate NSPC differentiation, we performed gene expression profiling analysis using Affymetrix rat genome arrays. Our results demonstrated that these astrocytes had distinct gene expression profiles. We further tested the functional effects of candidate factors that were differentially expressed in neurogenesis-promoting and -inhibiting astrocytes using in vitro NSPC differentiation assays. Our results indicated that two interleukins, IL-1beta and IL-6, and a combination of factors that included these two interleukins could promote NSPC neuronal differentiation, whereas insulin-like growth factor binding protein 6 (IGFBP6) and decorin inhibited neuronal differentiation of adult NSPCs. Our results have provided further evidence to support the ongoing hypothesis that, in adult mammalian brains, astrocytes play critical roles in modulating NSPC differentiation. The finding that cytokines and chemokines expressed by astrocytes could promote NSPC neuronal differentiation may help us to understand how injuries induce neurogenesis in adult brains.     

Controlled epi-cortical delivery of epidermal growth factor for the stimulation of endogenous neural stem cell proliferation in stroke-injured brain

One of the challenges in treating central nervous system (CNS) disorders with biomolecules is achieving local delivery while minimizing invasiveness. For the treatment of stroke, stimulation of endogenous neural stem/progenitor cells (NSPCs) by growth factors is a promising strategy for tissue regeneration. Epidermal growth factor (EGF) enhances proliferation of endogenous NSPCs in the subventricular zone (SVZ) when delivered directly to the ventricles of the brain; however, this strategy is highly invasive. We designed a biomaterials-based strategy to deliver molecules directly to the brain without tissue damage. EGF or poly(ethylene glycol)-modified EGF (PEG-EGF) was dispersed in a hyaluronan and methylcellulose (HAMC) hydrogel and placed epi-cortically on both uninjured and stroke-injured mouse brains. PEG-modification decreased the rate of EGF degradation by proteases, leading to a significant increase in protein accumulation at greater tissue depths than previously shown. Consequently, EGF and PEG-EGF increased NSPC proliferation in uninjured and stroke-injured brains; and in stroke-injured brains, PEG-EGF significantly increased NSPC stimulation. Our epi-cortical delivery system is a minimally-invasive method for local delivery to the brain, providing a new paradigm for local delivery to the brain.     

Leptomeningeal-derived doublecortin-expressing cells in poststroke brain

Increasing evidence indicates that neural stem/progenitor cells (NSPCs) reside in many regions of the central nervous system (CNS), including the subventricular zone (SVZ) of the lateral ventricle, subgranular zone of the hippocampal dentate gyrus, cortex, striatum, and spinal cord. Using a murine model of cortical infarction, we recently demonstrated that the leptomeninges (pia mater), which cover the entire cortex, also exhibit NSPC activity in response to ischemia. Pial-ischemia-induced NSPCs expressed NSPC markers such as nestin, formed neurosphere-like cell clusters with self-renewal activity, and differentiated into neurons, astrocytes, and oligodendrocytes, although they were not identical to previously reported NSPCs, such as SVZ astrocytes, ependymal cells, oligodendrocyte precursor cells, and reactive astrocytes. In this study, we showed that leptomeningeal cells in the poststroke brain express the immature neuronal marker doublecortin as well as nestin. We also showed that these cells can migrate into the poststroke cortex. Thus, the leptomeninges may participate in CNS repair in response to brain injury.     

Direct-current electrical field guides neuronal stem/progenitor cell migration

Direct-current electrical fields (EFs) promote nerve growth and axon regeneration. We report here that at physiological strengths, EFs guide the migration of neuronal stem/progenitor cells (NSPCs) toward the cathode. EF-directed NSPC migration requires activation of N-methyl-d-aspartate receptors (NMDARs), which leads to an increased physical association of Rho GTPase Rac1-associated signals to the membrane NMDARs and the intracellular actin cytoskeleton. Thus, this study identifies the EF as a directional guidance cue in controlling NSPC migration and reveals a role of the NMDAR/Rac1/actin signal transduction pathway in mediating EF-induced NSPC migration. These results suggest that as a safe physical approach in clinical application, EFs may be developed as a practical therapeutic strategy for brain repair by directing NSPC migration to the injured brain regions to replace cell loss. Disclosure of potential conflicts of interest is found at the end of this article.     

干细胞在神经创伤修复中的应用

背景：干细胞具有很强的增殖和分化能力,已在神经组织损伤修复方面展示了不可估量的临床应用前景。但是,目前有关神经干细胞的组织来源、定向诱导分化、移植技术和神经功能修复的功能判定等方面尚存在诸多难题。 目的：阐述干细胞在神经创伤修复中的应用研究进展。 方法：检索干细胞在神经创伤修复应用中的相关研究文献,检索词为“干细胞(stem cell),骨髓间充质干细胞(bone marrow mesenchymal stem cells),神经干细胞(neural stem cell),胚胎干细胞(embryonic stem cell),脂肪干细胞(adipose-derived stem cells),脐血干细胞(umbilical cord blood stem cells),成体干细胞(adult stem cells),脑损伤/创伤性脑损伤(traumatic brain injury),脊髓损伤(spinal cord injury),神经创伤(traumatic nerve injury),生长因子(growth factor),修复(repair)”,语言分别设定为中文和英文,对骨髓间充质干细胞、神经干细胞、胚胎干细胞、脐血干细胞及脂肪干细胞在神经创伤修复中的应用研究进行深入分析。 结果与结论：干细胞是一类具有自我更新、高度增殖和多向分化潜能的特殊细胞,其最显著的生物学特性是既有自我更新的能力,又具有多向分化的潜能。目前,已经从许多组织或器官中成功地分离出,其中包括胚胎干细胞,造血干细胞和骨髓间质干细胞等。此外,还有近来研究渐多的神经干细胞、肌肉干细胞、成骨干细胞、内胚层干细胞及视网膜干细胞等。干细胞的多向分化潜能为神经创伤修复开辟了新的途径,其在脑损伤以及脊髓损伤后的神经修复以及功能重建的研究方面已取得很大的进展,被认为具有广阔的应用前景,与之相关的问题均有待于进一步的研究     

不同时期局部移植人脐带间充质干细胞修复脊髓损伤的组织学观察

BACKGROUND:Spinal cord injury (SCI) is a disease causing a variety of motor and sensory dysfunctions, abnormal muscle tone and pathological reflex. Clinically, human umbilical cord mesenchymal stem cell transplantation has become an employed therapy for SCI. OBJECTIVE:To investigate the effect of local transplantation of human umbilical cord mesenchymal stem cells in different time after spinal cord injury in rats. METHODS:100 SPF male adult Sprague-Dawley rats were randomly divided into five groups: blank control group, SCI group, post-SCI 3-, 7-, 21-day transplantation groups (n=20 per group). Animal models of T₁₀ SCI were made by Allen’s method in the latter four groups, and rats in the three transplantation groups were given HUCMSCs transplantation at 3, 7, 21 days after SCI, respectively. RESULTS AND CONCLUSION:Compared with the SCI group, improved motor function scores, decreased interleukin-2 level, and increased serum interleukin-10 level were observed in the three transplantation groups at 49 days after modeling, indicating SCI was improved significantly in the three transplantation groups, especially in the post-SCI 7-day transplantation group. These findings suggest that human umbilical cord mesenchymal stem cell transplantation for SCI repair improves the movement function of rats, and cell transplantation at 7 days after modeling has achieved best outcomes.     

骨髓间充质干细胞移植联合吡拉西坦修复大鼠脊髓损伤

背景：单纯的干细胞移植对脊髓损伤的修复作用并不理想,主要是因为脊髓损伤后损伤区域神经组织的水肿、缺血、缺氧等引起继发性损伤造成的。 目的：在骨髓间充质干细胞移植治疗大鼠脊髓损伤的同时应用吡拉西坦,观察两者对大鼠脊髓损伤恢复的影响。 方法：雌性Wistar大鼠参照改良Allen打击法制备大鼠脊髓损伤模型。随机分成3组,即单纯损伤组、骨髓间充质干细胞移植组及骨髓间充质干细胞移植联合吡拉西坦组。于伤后1,2,4,6,8周进行BBB评分和斜板实验等运动功能检测。第4周取材行病理切片苏木精-伊红染色,通过SRY-PCR检测雄性大鼠Y染色体上特有的基因SRY,从而得知移植骨髓间充质干细胞是否存活。8周后取材,行辣根过氧化物酶示踪观察,并通过透射电镜观察轴突的再生情况。 结果与结论：伤后4周,骨髓间充质干细胞移植组、联合治疗组大鼠后肢运动功能均有较明显恢复,联合治疗组较骨髓间充质干细胞移植组恢复快(P < 0.05)。单纯损伤组亦有所恢复,但程度较轻。病理切片单纯损伤组未见神经轴索通过;骨髓间充质干细胞移植组可见少量神经轴索样结构;联合治疗组可见较多神经轴索样结构。骨髓间充质干细胞移植组、联合治疗组有SRY基因表达,单纯损伤组未检测到SRY基因。辣根过氧化物酶阳性神经纤维数联合治疗组﹥骨髓间充质干细胞移植组>单纯损伤组,差异具有显著性意义(P < 0.05)。透射电镜下,骨髓间充质干细胞移植组、联合治疗组正中横断面可见新生的无髓及有髓神经纤维。提示骨髓间充质干细胞移植联合吡拉西坦促进大鼠损伤脊髓结构和功能恢复的效果明显优于单纯细胞移植组,两者联用具有协同效应。     

Encapsulated Neural Stem Cell Neuronal Differentiation in Fluorinated Methacrylamide Chitosan Hydrogels

Neural stem/progenitor cells (NSPCs) are able to differentiate into the primary cell types (neurons, oligodendrocytes and astrocytes) of the adult nervous system. This attractive property of NSPCs offers a potential solution for neural regeneration. 3D implantable scaffolds should mimic the microstructure and dynamic properties found in vivo, enabling the natural exchange of oxygen, nutrients, and growth factors for cell survival and differentiation. We have previously reported a new class of materials consisting of perfluorocarbons (PFCs) conjugated to methacrylamide chitosan (MAC), which possess the ability to repeatedly take-up and release oxygen at beneficial levels for favorable cell metabolism and proliferation. In this study, the neuronal differentiation responses of NSPCs to fluorinated methacrylamide chitosan (MACF) hydrogels were studied for 8 days. Two treatments, with oxygen reloading or without oxygen reloading, were performed during culture. Oxygen concentration distributions within cell-seeded MACF hydrogels were found to have higher concentrations of oxygen at the edge of the hydrogels and less severe drops in O₂ gradient as compared with MAC hydrogel controls. Total cell number was enhanced in MACF hydrogels as the number of conjugated fluorines via PFC substitution increased. Additionally, all MACF hydrogels supported significantly more cells than MAC controls (p < 0.001). At day 8, MACF hydrogels displayed significantly greater neuronal differentiation than MAC controls (p = 0.001), and among MACF groups methacrylamide chitosan with 15 fluorines per addition (MAC(Ali15)F) demonstrated the best ability to promote NSPC differentiation.     

Extramedullary chitosan channels promote survival of transplanted neural stem and progenitor cells and create a tissue bridge after complete spinal cord transection

Transplantation of neural stem and progenitor cells (NSPCs) is a promising strategy for repair after spinal cord injury. However, the epicenter of the severely damaged spinal cord is a hostile environment that results in poor survival of the transplanted NSPCs. We examined implantation of extramedullary chitosan channels seeded with NSPCs derived from transgenic green fluorescent protein (GFP) rats after spinal cord transection (SCT). At 14 weeks, we assessed the survival, maturation, and functional results using NSPCs harvested from the brain (brain group) or spinal cord (SC group) and seeded into chitosan channels implanted between the cord stumps after complete SCT. Control SCT animals had empty chitosan channels or no channels implanted. Channels seeded with brain or spinal cord-derived NSPCs showed a tissue bridge, although the bridges were thicker in the brain group. Both cell types showed long-term survival, but the number of surviving cells in the brain group was approximately five times as great as in the SC group. In both the brain and SC groups at 14 weeks after transplantation, many host axons were present in the center of the bridge in association with the transplanted cells. At 14 weeks astrocytic and oligodendrocytic differentiation in the channels was 24.8% and 17.3%, respectively, in the brain group, and 31.8% and 9.7%, respectively, in the SC group. The channels caused minimal tissue reaction in the adjacent spinal cord. There was no improvement in locomotor function. Thus, implantation of chitosan channels seeded with NSPCs after SCT created a tissue bridge containing many surviving transplanted cells and host axons, although there was no functional improvement.     

The effect of long-term release of Shh from implanted biodegradable microspheres on recovery from spinal cord injury in mice

After spinal cord injury (SCI), loss of cells and damage to ascending and descending tracts can result in paralysis. Current treatments for SCI are based on patient stabilization, and much-needed regenerative therapies are still under development. To activate and instruct stem and progenitor cells or injured tissue to aid SCI repair, it is important to modify the injury environment for a protracted period, to allow time for cell activation, proliferation and appropriate fate differentiation. Shh plays a critical role in spinal cord formation, being involved in multiple processes: it promotes production of motor neurons and oligodendrocytes from ventral cord progenitor cells and serves as an axon guidance molecule. Hence Shh is a candidate pleiotropic beneficial environmental factor for spinal cord regeneration. Here we show that administration of biodegradable microspheres that provide sustained, controlled delivery of Shh resulted in significant functional improvement in two different mouse models of SCI: contusion and dorsal hemioversection. The mechanism is multifactorial, involving increased proliferation of endogenous NG2+ oligodendrocyte lineage cells, decreased astrocytic scar formation and increased sprouting and growth of corticospinal (CST) and raphespinal tract (RST) fibers. Thus, long-term administration of Shh is a potential valuable therapeutic intervention for SCI.     

Significance of remyelination by neural stem/progenitor cells transplanted into the injured spinal cord

Previous reports of functional recovery from spinal cord injury (SCI) in rodents and monkeys after the delayed transplantation of neural stem/progenitor cells (NS/PCs) have raised hopes that stem cell therapy could be used to treat SCI in humans. More research is needed, however, to understand the mechanism of functional recovery. Oligodendrocytes derived from grafted NS/PCs remyelinate spared axons in the injured spinal cord. Here, we studied the extent of this remyelination's contribution to functional recovery following contusive SCI in mice. To isolate the effect of remyelination from other possible regenerative benefits of the grafted cells, NS/PCs obtained from myelin-deficient shiverer mutant mice (shi-NS/PCs) were used in this work alongside wild-type NS/PCs (wt-NS/PCs). shi-NS/PCs behaved like wt-NS/PCs in vitro and in vivo, with the exception of their myelinating potential. shi-NS/PC-derived oligodendrocytes did not express myelin basic protein in vitro and formed much thinner myelin sheaths in vivo compared with wt-NS/PC-derived oligodendrocytes. The transplantation of shi-NS/PCs promoted some locomotor and electrophysiological functional recovery but significantly less than that afforded by wt-NS/PCs. These findings establish the biological importance of remyelination by graft-derived cells for functional recovery after the transplantation of NS/PCs into the injured spinal cord.