Your search keyword '"axonal regeneration"' showing total 1,716 results

51. Tackling the glial scar in spinal cord regeneration: new discoveries and future directions.

Author

Shafqat, Areez, Albalkhi, Ibrahem, Magableh, Hamzah M., Saleh, Tariq, Alkattan, Khaled, and Yaqinuddin, Ahmed

Subjects

AXONS, SPINAL cord, NERVOUS system regeneration, SCARS, CENTRAL nervous system, SPINAL cord injuries

Abstract

Axonal regeneration and functional recovery are poor after spinal cord injury (SCI), typified by the formation of an injury scar. While this scar was traditionally believed to be primarily responsible for axonal regeneration failure, current knowledge takes a more holistic approach that considers the intrinsic growth capacity of axons. Targeting the SCI scar has also not reproducibly yielded nearly the same efficacy in animal models compared to these neuron-directed approaches. These results suggest that the major reason behind central nervous system (CNS) regeneration failure is not the injury scar but a failure to stimulate axon growth adequately. These findings raise questions about whether targeting neuroinflammation and glial scarring still constitute viable translational avenues. We provide a comprehensive review of the dual role of neuroinflammation and scarring after SCI and how future research can produce therapeutic strategies targeting the hurdles to axonal regeneration posed by these processes without compromising neuroprotection. [ABSTRACT FROM AUTHOR]

Published

2023

52. Intravitreal injection of Huperzine A promotes retinal ganglion cells survival and axonal regeneration after optic nerve crush.

Author

Lai-Yang Zhou, Di Chen, Xin-Ran Guo, Yu-Qian Niu, Yong-Sai Xu, Dong-Fu Feng, and Tie-Chen Li

Subjects

RETINAL ganglion cells, OPTIC nerve, INTRAVITREAL injections, CELL survival, NERVOUS system regeneration

Abstract

Traumatic optic neuropathy (TON) is a condition that causes massive loss of retinal ganglion cells (RGCs) and their axonal fibers, leading to visual insufficiency. Several intrinsic and external factors can limit the regenerative ability of RGC after TON, subsequently resulting in RGC death. Hence, it is important to investigate a potential drug that can protect RGC after TON and enhance its regenerative capacity. Herein, we investigated whether Huperzine A (HupA), extracted from a Chinese herb, has neuroprotective effects and may enhance neuronal regeneration following the optic nerve crush (ONC) model. We compared the three modes of drug delivery and found that intravitreal injection of HupA could promote RGC survival and axonal regeneration after ONC. Mechanistically, HupA exerted its neuroprotective and axonal regenerative effects through the mTOR pathway; these effects could be blocked by rapamycin. To sum up, our findings suggest a promising application of HupA in the clinical treatment of traumatic optic nerve. [ABSTRACT FROM AUTHOR]

Published

2023

53. Restoring Axonal Organelle Motility and Regeneration in Cultured FUS-ALS Motoneurons through Magnetic Field Stimulation Suggests an Alternative Therapeutic Approach.

Author

Kandhavivorn, Wonphorn, Glaß, Hannes, Herrmannsdörfer, Thomas, Böckers, Tobias M., Uhlarz, Marc, Gronemann, Jonas, Funk, Richard H. W., Pietzsch, Jens, Pal, Arun, and Hermann, Andreas

Subjects

*MOTOR neurons, *PERIPHERAL nervous system, *INDUCED pluripotent stem cells, *MAGNETIC fields, *AMYOTROPHIC lateral sclerosis, *CENTRAL nervous system, *NERVOUS system regeneration

Abstract

Amyotrophic lateral sclerosis (ALS) is a devastating motoneuron disease characterized by sustained loss of neuromuscular junctions, degenerating corticospinal motoneurons and rapidly progressing muscle paralysis. Motoneurons have unique features, essentially a highly polarized, lengthy architecture of axons, posing a considerable challenge for maintaining long-range trafficking routes for organelles, cargo, mRNA and secretion with a high energy effort to serve crucial neuronal functions. Impaired intracellular pathways implicated in ALS pathology comprise RNA metabolism, cytoplasmic protein aggregation, cytoskeletal integrity for organelle trafficking and maintenance of mitochondrial morphology and function, cumulatively leading to neurodegeneration. Current drug treatments only have marginal effects on survival, thereby calling for alternative ALS therapies. Exposure to magnetic fields, e.g., transcranial magnetic stimulations (TMS) on the central nervous system (CNS), has been broadly explored over the past 20 years to investigate and improve physical and mental activities through stimulated excitability as well as neuronal plasticity. However, studies of magnetic treatments on the peripheral nervous system are still scarce. Thus, we investigated the therapeutic potential of low frequency alternating current magnetic fields on cultured spinal motoneurons derived from induced pluripotent stem cells of FUS-ALS patients and healthy persons. We report a remarkable restoration induced by magnetic stimulation on axonal trafficking of mitochondria and lysosomes and axonal regenerative sprouting after axotomy in FUS-ALS in vitro without obvious harmful effects on diseased and healthy neurons. These beneficial effects seem to derive from improved microtubule integrity. Thus, our study suggests the therapeutic potential of magnetic stimulations in ALS, which awaits further exploration and validation in future long-term in vivo studies. [ABSTRACT FROM AUTHOR]

Published

2023

54. PLG Bridge Implantation in Chronic SCI Promotes Axonal Elongation and Myelination.

Author

Smith, Dominique R, Dumont, Courtney M, Ciciriello, Andrew J, Guo, Amina, Tatineni, Ravindra, Munsell, Mary K, Cummings, Brian J, Anderson, Aileen J, and Shea, Lonnie D

Subjects

axonal regeneration, biomaterials, chronic spinal cord injury, tissue engineering, Injury - Trauma - (Head and Spine), Neurosciences, Spinal Cord Injury, Regenerative Medicine, Injury (total) Accidents/Adverse Effects, Neurodegenerative, Neurological, Biomedical Engineering

Abstract

Spinal cord injury (SCI) is a devastating condition that may cause permanent functional loss below the level of injury, including paralysis and loss of bladder, bowel, and sexual function. Patients are rarely treated immediately, and this delay is associated with tissue loss and scar formation that can make regeneration at chronic time points more challenging. Herein, we investigated regeneration using a poly(lactide-co-glycolide) multichannel bridge implanted into a chronic SCI following surgical resection of necrotic tissue. We characterized the dynamic injury response and noted that scar formation decreased at 4 and 8 weeks postinjury (wpi), yet macrophage infiltration increased between 4 and 8 wpi. Subsequently, the scar tissue was resected and bridges were implanted at 4 and 8 wpi. We observed robust axon growth into the bridge and remyelination at 6 months after initial injury. Axon densities were increased for 8 week bridge implantation relative to 4 week bridge implantation, whereas greater myelination, particularly by Schwann cells, was observed with 4 week bridge implantation. The process of bridge implantation did not significantly decrease the postinjury function. Collectively, this chronic model follows the pathophysiology of human SCI, and bridge implantation allows for clear demarcation of the regenerated tissue. These data demonstrate that bridge implantation into chronic SCI supports regeneration and provides a platform to investigate strategies to buttress and expand regeneration of neural tissue at chronic time points.

Published

2019

55. Origins of Neural Progenitor Cell-Derived Axons Projecting Caudally after Spinal Cord Injury.

Author

Lu, Paul, Gomes-Leal, Walace, Anil, Selin, Dobkins, Gabriel, Huie, J Russell, Ferguson, Adam R, Graham, Lori, and Tuszynski, Mark

Subjects

Pyramidal Tracts, Neurons, Animals, Mice, Rats, Spinal Cord Injuries, Fluorescent Antibody Technique, Stem Cell Transplantation, Transduction, Genetic, Nerve Regeneration, Cell Differentiation, Gene Expression, Biological Transport, Genes, Reporter, Neural Stem Cells, Neuronal Outgrowth, axonal growth, axonal regeneration, neural progenitor cells, neural stem cells, spinal cord injury, Injury (total) Accidents/Adverse Effects, Stem Cell Research - Nonembryonic - Non-Human, Transplantation, Regenerative Medicine, Neurosciences, Spinal Cord Injury, Stem Cell Research, Neurodegenerative, Injury - Trauma - (Head and Spine), Aetiology, 2.1 Biological and endogenous factors, Neurological, Biochemistry and Cell Biology, Clinical Sciences

Abstract

Neural progenitor cells (NPCs) transplanted into sites of spinal cord injury (SCI) extend large numbers of axons into the caudal host spinal cord. We determined the precise locations of neurons in the graft that extend axons into the caudal host spinal cord using AAV9-Cre-initiated retrograde tracing into floxed-TdTomato-expressing NPC grafts. 7,640 ± 630 grafted neurons extended axons to a single caudal host spinal cord site located 2 mm beyond the lesion, 5 weeks post injury. While caudally projecting axons arose from neurons located in all regions of the graft, the majority of caudally projecting graft neurons (53%) were located within the caudal one-third of the graft. Numerous host corticospinal axons formed monosynaptic projections onto caudally projecting graft neurons; however, we find that the majority of host axonal neuronal projections formed by neural progenitor cell interneuronal "relays" across sites of SCI are likely polysynaptic in nature.

Published

2019

56. Bu Shen Huo Xue decoction promotes functional recovery in spinal cord injury mice by improving the microenvironment to promote axonal regeneration

Author

Yonghui Hou, Dan Luo, Yu Hou, Jiyao Luan, Jiheng Zhan, Zepeng Chen, Shunmei E, Liangliang Xu, and Dingkun Lin

Subjects

Spinal cord injury, Bu-Shen-Huo-Xue decoction, Microenvironment, Axonal regeneration, Inflammatory response, Other systems of medicine, RZ201-999

Abstract

Abstract Background Bu-Shen-Huo-Xue (BSHX) decoction has been used in the postoperative rehabilitation of patients with spinal cord injury in China. In the present study, we aim to reveal the bioactive compounds in BSHX decoction and comprehensively explore the effects of BSHX decoction and the underlying mechanism in spinal cord injury recovery. Methods The main chemical constituents in BSHX decoction were determined by UPLC–MS/MS. SCI mice were induced by a pneumatic impact device at T9–T10 level of the vertebra, and treated with BSHX decoction. Basso–Beattie–Bresnahan (BBB) score, footprint analysis, hematoxylin–eosin (H&E) staining, Nissl staining and a series of immunofluorescence staining were performed to investigate the functional recovery, glial scar formation and axon regeneration after BSHX treatment. Immunofluorescent staining of bromodeoxyuridine (BrdU), neuronal nuclei (NeuN) and glial fibrillary acidic protein (GFAP) was performed to evaluate the effect of BSHX decoction on neural stem cells (NSCs) proliferation and differentiation. Results We found that the main compounds in BSHX decoction were Gallic acid, 3,4-Dihydroxybenzaldehyde, (+)-Catechin, Paeoniflorin, Rosmarinic acid, and Diosmetin. BSHX decoction improved the pathological findings in SCI mice through invigorating blood circulation and cleaning blood stasis in the lesion site. In addition, it reduced tissue damage and neuron loss by inhibiting astrocytes activation, and promoting the polarization of microglia towards M2 phenotype. The functional recovery test revealed that BSHX treatment improved the motor function recovery post SCI. Conclusions Our study provided evidence that BSHX treatment could improve the microenvironment of the injured spinal cord to promote axonal regeneration and functional recovery in SCI mice.

Published

2022

57. A new microfluidic model to study dendritic remodeling and mitochondrial dynamics during axonal regeneration of adult zebrafish retinal neurons

Author

Annelies Van Dyck, Luca Masin, Steven Bergmans, Giel Schevenels, An Beckers, Benoit Vanhollebeke, and Lieve Moons

Subjects

axonal regeneration, zebrafish, in vitro, microfluidics, mitochondria, dendrites, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Unlike mammals, adult zebrafish are able to fully regenerate axons and functionally recover from neuronal damage in the mature central nervous system (CNS). Decades of research have tried to identify the mechanisms behind their spontaneous regenerative capacity, but the exact underlying pathways and molecular drivers remain to be fully elucidated. By studying optic nerve injury-induced axonal regrowth of adult zebrafish retinal ganglion cells (RGCs), we previously reported transient dendritic shrinkage and changes in the distribution and morphology of mitochondria in the different neuronal compartments throughout the regenerative process. These data suggest that dendrite remodeling and temporary changes in mitochondrial dynamics contribute to effective axonal and dendritic repair upon optic nerve injury. To further elucidate these interactions, we here present a novel adult zebrafish microfluidic model in which we can demonstrate compartment-specific alterations in resource allocation in real-time at single neuron level. First, we developed a pioneering method that enables to isolate and culture adult zebrafish retinal neurons in a microfluidic setup. Notably, with this protocol, we report on a long-term adult primary neuronal culture with a high number of surviving and spontaneously outgrowing mature neurons, which was thus far only very limitedly described in literature. By performing time-lapse live cell imaging and kymographic analyses in this setup, we can explore changes in dendritic remodeling and mitochondrial motility during spontaneous axonal regeneration. This innovative model system will enable to discover how redirecting intraneuronal energy resources supports successful regeneration in the adult zebrafish CNS, and might facilitate the discovery of new therapeutic targets to promote neuronal repair in humans.

Published

2023

58. Tackling the glial scar in spinal cord regeneration: new discoveries and future directions

Author

Areez Shafqat, Ibrahem Albalkhi, Hamzah M. Magableh, Tariq Saleh, Khaled Alkattan, and Ahmed Yaqinuddin

Subjects

spinal cord injury, axonal regeneration, glial scar, neuroinflammation, astrocyte heterogeneity, microglia heterogeneity, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Axonal regeneration and functional recovery are poor after spinal cord injury (SCI), typified by the formation of an injury scar. While this scar was traditionally believed to be primarily responsible for axonal regeneration failure, current knowledge takes a more holistic approach that considers the intrinsic growth capacity of axons. Targeting the SCI scar has also not reproducibly yielded nearly the same efficacy in animal models compared to these neuron-directed approaches. These results suggest that the major reason behind central nervous system (CNS) regeneration failure is not the injury scar but a failure to stimulate axon growth adequately. These findings raise questions about whether targeting neuroinflammation and glial scarring still constitute viable translational avenues. We provide a comprehensive review of the dual role of neuroinflammation and scarring after SCI and how future research can produce therapeutic strategies targeting the hurdles to axonal regeneration posed by these processes without compromising neuroprotection.

Published

2023

59. Axonal Regeneration Mediated by a Novel Axonal Guidance Pair, Galectin-1 and Secernin-1.

Author

Yang, Ximeng and Tohda, Chihiro

Abstract

Galectin-1 (Gal-1), a member of the Galectin family, is expressed in various tissues and responsible for multiple biological activities. Previous studies reported that extracellular Gal-1 participated in axonal growth and repair, and Gal-1 knockout mice exhibited memory impairment. However, no study has demonstrated the direct contribution of intracellular Gal-1 upregulation in neurons to promoting axonal regeneration in the brain and recovering memory function. In the present study, we found that axonal growth is promoted by overexpression of Gal-1 via adeno-associated virus serotype 9 delivery in primary cultured hippocampal neurons. Moreover, Gal-1 was expressed on the membranes of growth cones in hippocampal neurons and interacted with a novel axonal guidance molecule, Secernin-1, which was secreted from prefrontal cortex (PFC) neurons. Gal-1-overexpression-driven axonal growth was enhanced when recombinant (extracellular) Secernin-1 was treated to the axonal site in a neuron device chamber. Direct binding of extracellular Secernin-1 with Gal-1 was detected through immunoprecipitation and immunocytochemistry, demonstrating that Gal-1 possibly works as an axonal guidance receptor for Secernin-1 in hippocampal neurons. In the PFC, the expression of Gal-1 in axonal shafts and terminals of hippocampal neurons was decreased in the 5XFAD mouse model of Alzheimer's disease (AD). Overexpression of Gal-1 in hippocampal neurons recovered memory deficits and induced axonal regeneration toward the PFC in 5XFAD mice. This study suggests that the enhanced interaction of Secernin-1 and Gal-1 can be harnessed as a therapeutic strategy for long-distance and direction-specific axonal regeneration in AD. [ABSTRACT FROM AUTHOR]

Published

2023

60. Artificial Nerve Containing Stem Cells, Vascularity and Scaffold; Review of Our Studies.

Author

Kakinoki, Ryosuke and Akagi, Masao

Subjects

*STEM cells, *NERVES, *MESENCHYMAL stem cells, *NERVE grafting, *NERVOUS system regeneration, *SCIATIC nerve, *AXONS

Abstract

To promote nerve regeneration within a conduit (tubulation), we have performed studies using a tube model based on four important concepts for tissue engineering: vascularity, growth factors, cells, and scaffolds. A nerve conduit containing a blood vascular pedicle (vessel-containing tube) accelerated axon regeneration and increased the axon regeneration distance; however, it did not increase the number or diameter of the axons that regenerated within the tube. A vessel-containing tube with bone-marrow-derived mesenchymal stem cell (BMSC) transplantation led to the increase in the number and diameter of regenerated axons. Intratubularly transplanted decellularized allogenic nerve basal lamellae (DABLs) worked as a frame to maintain the fibrin matrix structure containing neurochemical factors and to anchor the transplanted stem cells within the tube. For the clinical application of nerve conduits, they should exhibit capillary permeability, biodegradability, and flexibility. Nerbridge® (Toyobo Co. Ltd., Osaka, Japan) is a commercially available artificial nerve conduit. The outer cylinder is a polyglycolic acid (PGA) fiber mesh and possesses capillary permeability. We used the outer cylinder of Nerbridge as a nerve conduit. A 20-mm sciatic nerve deficit was bridged by the PGA mesh tube containing DABLs and BMSCs, and the resulting nerve regeneration was compared with that obtained through a 20-mm autologous nerve graft. A neve-regeneration rate of about 70%–80% was obtained in 20-mm-long autologous nerve autografts using the new conduits. [ABSTRACT FROM AUTHOR]

Published

2023

61. 小胶质细胞极化介导炎症反应在脊髓损伤中的作用.

Author

史 旭, 李瑞语, 张 兵, 陈 奇, and 左 华

Subjects

*SPINAL cord injuries, *MESENCHYMAL stem cells, *MICROGLIA, *PHENOTYPIC plasticity, *NERVE tissue, *NERVOUS system regeneration, *NATURAL products

Abstract

BACKGROUND: Microglia polarization participates in and plays a key role in the inflammatory response after spinal cord injury. Related studies have shown that effectively inducing the polarization of microglia from M1 pro-inflammatory phenotype to M2 anti-inflammatory phenotype can reduce the inflammatory response after spinal cord injury and promote tissue repair and regeneration and the recovery of nerve function. OBJECTIVE: To review the inflammatory response after spinal cord injury, function and polarization of microglia and the effect of microglia polarization on spinal cord injury and its potential regulation strategies. METHODS: Databases of PubMed, Web of Science, and CNKI were searched for the articles with the keywords of “microglia, polarization, spinal cord injury, inflammation” in English and Chinese respectively. Finally, a total of 80 articles were included according to the inclusion and exclusion criteria. RESULTS AND CONCLUSION: (1) Stable and persistent inflammatory response mediated by microglia is very important for the prognosis of spinal cord injury. (2) Under physiological conditions, microglia are in the resting phenotype of M0. After spinal cord injury, microglia are activated and then polarized into M1 proinflammatory phenotype, resulting in decreased tissue repair ability and persistent neuroinflammation. (3) During inflammation, regulating the polarization of microglia to M2 phenotype or at least tilting to M2 is beneficial to inhibit oxidative stress, regulate synaptic remodeling, and promote axonal regeneration and angiogenesis. It is an effective control strategy. (4) At present, the main strategies to regulate the phenotypic transition of microglia between M1 and M2 are mesenchymal stem cells, exosomes, clinical drugs, natural products, miRNAs and target molecules. It provides a new idea for the repair of nerve tissue after spinal cord injury. In the future, it is necessary to further study the detailed mechanism of microglia to regulate polarization during spinal cord injury. [ABSTRACT FROM AUTHOR]

Published

2023

62. Forced Remyelination Promotes Axon Regeneration in a Rat Model of Spinal Cord Injury.

Author

Zawadzka, Małgorzata, Yeghiazaryan, Marine, Niedziółka, Sylwia, Miazga, Krzysztof, Kwaśniewska, Anna, Bekisz, Marek, and Sławińska, Urszula

Subjects

*SPINAL cord injuries, *RAPHE nuclei, *AXONS, *ANIMAL disease models, *SEROTONIN receptors, *PROGENITOR cells

Abstract

Spinal cord injuries result in the loss of motor and sensory functions controlled by neurons located at the site of the lesion and below. We hypothesized that experimentally enhanced remyelination supports axon preservation and/or growth in the total spinal cord transection in rats. Multifocal demyelination was induced by injection of ethidium bromide (EB), either at the time of transection or twice during transection and at 5 days post-injury. We demonstrated that the number of oligodendrocyte progenitor cells (OPCs) significantly increased 14 days after demyelination. Most OPCs differentiated into mature oligodendrocytes by 60–90 dpi in double-EB-injected rats; however, most axons were remyelinated by Schwann cells. A significant number of axons passed the injury epicenter and entered the distant segments of the spinal cord in the double-EB-injected rats. Moreover, some serotoninergic fibers, not detected in control animals, grew caudally through the injury site. Behavioral tests performed at 60–90 dpi revealed significant improvement in locomotor function recovery in double-EB-injected rats, which was impaired by the blockade of serotonin receptors, confirming the important role of restored serotonergic fibers in functional recovery. Our findings indicate that enhanced remyelination per se, without substantial inhibition of glial scar formation, is an important component of spinal cord injury regeneration. [ABSTRACT FROM AUTHOR]

Published

2023

63. Optic nerve injury-induced regeneration in the adult zebrafish is accompanied by spatiotemporal changes in mitochondrial dynamics.

Author

An Beckers, An Beckers, Masin, Luca, Van Dyck, Annelies, Bergmans, Steven, Vanhunsel, Sophie, Zhang, Anyi, Verreet, Tine, Poulain, Fabienne E., Farrow, Karl, and Moons, Lieve

Published

2023

64. Molecular approaches for spinal cord injury treatment.

Author

de Almeida, Fernanda Martins, Adriani Marques, Suelen, Rodrigues dos Santos, Anne Caroline, Andrade Prins, Caio, dos Santos Cardoso, Fellipe Soares, dos Santos Heringer, Luiza, Rocha Mendonça, Henrique, and Blanco Martinez, Ana Maria

Published

2023

65. Salidroside facilitates neuroprotective effects in ischemic stroke by promoting axonal sprouting through promoting autophagy.

Author

Lai, Wenfang, He, Yanfeng, Zhou, Binbin, Wu, Qingqing, Wu, Huiling, Chen, Jingquan, Zheng, Xuerui, Jia, Ru, Lin, Pu, Hong, Guizhu, and Chen, Jianyu

Abstract

• Salidroside significantly reduces cerebral infarct volume induced by MCAO/IR. • The neuroprotective effect of salidroside is attributed to its enhancement of axonal sprouting. • The mechanism of salidroside for axonal sprouting is involved in promoting autophagy. • The novelty of the study reveals the positive correlation between axonal sprouting and autophagy, moreover, salidroside enhances axonal sprouting through promoting autophagy. Ischemic stroke is a common cerebrovascular disease characterized by high incidence, disability, mortality, and recurrence. The limitations of current pharmacological treatments, which have primarily single neuroprotective action and a narrow therapeutic time window, lead to unsatisfactory therapeutic efficacy. Activation of autophagy can facilitate neural regeneration. To clarify whether salidroside can promote axonal sprouting through autophagy resulting in protecting neurons. In vivo, a Middle Cerebral Artery Occlusion/reperfusion (MCAO/IR) model was used, and in vitro, an Oxygen-Glucose Deprivation/Reoxygenation (OGD/R)-induced primary neuronal cell model was employed to evaluate the neuroprotective effects of salidroside. BDA neurotracer, immunofluorescence, and Western blot (WB) were utilized to determine its impact on axonal sprouting and the levels of related proteins (MAP2, GAP43, and PSD-95). Proteomics, transmission electron microscopy (TEM), and WB were applied to identify the effects on autophagy-related proteins (beclin1, LC3, p62, and LAMP2), autophagosomes and lysosomes. The mechanism of salidroside in promoting axonal sprouting through inducing autophagy was further confirmed by blocking with the autophagy inhibitor 3-MA. Salidroside reduced neurologic deficits and infarct volume induced by MCAO/IR in vivo and protected OGD/R induced primary neuronal cells in vitro. Both in vivo and in vitro, it increased the number and length of axons and upregulated the expression of key axonal proteins (MAP2, GAP43, and PSD-95) and mediated autophagy-related proteins. Mechanistic studies showed that the promoting effects of salidroside on autophagy and axonal sprouting disappeared after the blockade by 3-MA. This study reports for the first time that the neuroprotective effect of salidroside in ischemic stroke can be executed through mediating autophagy-related protein (beclin1, LC3, p62, and LAMP2), resulting in induced axonal sprouting or mature protein (MAP2, GAP43, and PSD-95). [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2024

66. Effects of transcranial magnetic stimulation on axonal regeneration in the corticospinal tract of female rats with spinal cord injury.

Author

Hu, Mengxuan, Tang, Zewen, Li, Huijun, Lei, Qian, Xu, Qingqin, Su, Junhong, Huang, Ying, Chen, Shi, and Chen, Hemu

Subjects

*TRANSCRANIAL magnetic stimulation, *NERVOUS system regeneration, *SPINAL cord injuries, *BRAIN physiology, *EFFERENT pathways, *PYRAMIDAL tract

Abstract

This study investigates the potential of transcranial magnetic stimulation (TMS) to enhance spinal cord axon regeneration by modulating corticospinal pathways and improving motor nerve function recovery in rats with spinal cord injury (SCI). TMS is a non-invasive neuromodulation technique that generates a magnetic field to activate neurons in the brain, leading to depolarization and modulation of cortical activity. Initially utilized for brain physiology research, TMS has evolved into a diagnostic and prognostic tool in clinical settings, with increasing interest in its therapeutic applications. However, its potential for treating motor dysfunction in SCI has been underexplored. The TMS intervention group exhibited significant improvements compared to the control group across behavioral assessments, neurophysiological measurements, pathological analysis, and immunological markers. Unlike most studies that focus on localized spinal cord injury or muscle treatments, this study leverages the non-invasive, painless, and highly penetrating nature of TMS to focus on the corticospinal tracts, exploring its therapeutic potential for SCI. TMS enhances motor function recovery in rats with SCI by restoring corticospinal pathway integrity and promoting axonal regeneration. These findings highlight TMS as a promising therapeutic option for SCI patients with currently limited treatment alternatives. • TMS enhances motor function recovery in rats with spinal cord injury. • rTMS improves corticospinal pathway integrity and promotes axonal regeneration. • The study shows TMS as a non-invasive and effective treatment for SCI. • Findings suggest the potential of TMS to offer new therapeutic avenues for SCI. • Further research is needed to optimize TMS parameters and understand its mechanisms. [ABSTRACT FROM AUTHOR]

Published

2024

67. Eml1 promotes axonal growth by enhancing αTAT1-mediated microtubule acetylation.

Author

Zhang, Yufang, Guan, Tuchen, Li, Zhen, Guo, Beibei, Luo, Xiaoqian, Guo, Longyu, Li, Mingxuan, Xu, Man, Liu, Mei, and Liu, Yan

Subjects

*MICROTUBULE-associated proteins, *DORSAL root ganglia, *NERVOUS system regeneration, *SCIATIC nerve, *TUBULINS

Abstract

Microtubule stabilization is critical for axonal growth and regeneration, and many microtubule-associated proteins are involved in this process. In this study, we found that the knockdown of echinoderm microtubule-associated protein-like 1 (EML1) hindered axonal growth in cultured cortical and dorsal root ganglion neurons. We further revealed that EML1 facilitated the acetylation of microtubules and that the impairment of axonal growth due to EML1 inhibition could be restored by treatment with deacetylase inhibitors, suggesting that EML1 affected tubulin acetylation. Moreover, we verified an interaction between EML1 and the alpha-tubulin acetyltransferase 1, which is responsible for the acetylation of alpha-tubulin. We thus proposed that EML1 might regulate microtubule acetylation and stabilization via alpha-tubulin acetyltransferase 1 and then promote axon growth. Finally, we verified that the knockdown of EML1 in vivo also inhibited sciatic nerve regeneration. Our findings revealed a novel effect of EML1 on microtubule acetylation during axonal regeneration. [Display omitted] • Knockdown of Echinoderm Microtubule Associated Protein Like 1 (EML1) hinders axon growth in cultured neurons. • Over expression of EML1 significantly increases microtubule acetylation. • EML1 interacts with Alpha Tubulin Acetyltransferase 1 (αTAT1). • Knockdown of EML1 inhibits rat sciatic nerve regeneration. [ABSTRACT FROM AUTHOR]

Published

2024

68. Oscillating field stimulation promotes axon regeneration and locomotor recovery after spinal cord injury

Author

Yi-Xin Wang, Jin-Zhu Bai, Zhen Lyu, Guang-Hao Zhang, and Xiao-Lin Huo

Subjects

astrocyte orientation, astrocyte proliferation, axonal regeneration, locomotor recovery, neural regeneration, neural repair, oscillating field stimulation, spinal cord injury, stimulus duration, Neurology. Diseases of the nervous system, RC346-429

Abstract

Oscillating field stimulation (OFS) is a potential method for treating spinal cord injury. Although it has been used in spinal cord injury (SCI) therapy in basic and clinical studies, its underlying mechanism and the correlation between its duration and nerve injury repair remain poorly understood. In this study, we established rat models of spinal cord contusion at T10 and then administered 12 weeks of OFS. The results revealed that effectively promotes the recovery of motor function required continuous OFS for more than 6 weeks. The underlying mechanism may be related to the effects of OFS on promoting axon regeneration, inhibiting astrocyte proliferation, and improving the linear arrangement of astrocytes. This study was approved by the Animal Experiments and Experimental Animal Welfare Committee of Capital Medical University (supplemental approval No. AEEI-2021-204) on July 26, 2021.

Published

2022

69. Graphene and graphene-based materials in axonal repair of spinal cord injury

Author

Shi-Xin Wang, Yu-Bao Lu, Xue-Xi Wang, Yan Wang, Yu-Jun Song, Xiao Wang, and Munkhtuya Nyamgerelt

Subjects

axonal regeneration, graphene, graphene oxide, nerve axon regeneration, reduced graphene oxide, spinal cord contusions, spinal cord injury, spinal cord trauma, Neurology. Diseases of the nervous system, RC346-429

Abstract

Graphene and graphene-based materials have the ability to induce stem cells to differentiate into neurons, which is necessary to overcome the current problems faced in the clinical treatment of spinal cord injury. This review summarizes the advantages of graphene and graphene-based materials (in particular, composite materials) in axonal repair after spinal cord injury. These materials have good histocompatibility, and mechanical and adsorption properties that can be targeted to improve the environment of axonal regeneration. They also have good conductivity, which allows them to make full use of electrical nerve signal stimulation in spinal cord tissue to promote axonal regeneration. Furthermore, they can be used as carriers of seed cells, trophic factors, and drugs in nerve tissue engineering scaffolds to provide a basis for constructing a local microenvironment after spinal cord injury. However, to achieve clinical adoption of graphene and graphene-based materials for the repair of spinal cord injury, further research is needed to reduce their toxicity.

Published

2022

70. Exosomes combined with biomaterials in the treatment of spinal cord injury

Author

Xuanxuan Zhang, Wenwei Jiang, Yan Lu, Tiantian Mao, Yu Gu, Dingyue Ju, and Chuanming Dong

Subjects

spinal cord injury, exosomes, biomaterial scaffold, stem cells, axonal regeneration, Biotechnology, TP248.13-248.65

Abstract

Spinal cord injury (SCI) is a serious and disabling disease with a high mortality rate. It often leads to complete or partial sensory and motor dysfunction and is accompanied by a series of secondary outcomes, such as pressure sores, pulmonary infections, deep vein thrombosis in the lower extremities, urinary tract infections, and autonomic dysfunction. Currently, the main treatments for SCI include surgical decompression, drug therapy, and postoperative rehabilitation. Studies have shown that cell therapy plays a beneficial role in the treatment of SCI. Nonetheless, there is controversy regarding the therapeutic effect of cell transplantation in SCI models. Meanwhile exosomes, as a new therapeutic medium for regenerative medicine, possess the advantages of small size, low immunogenicity, and the ability to cross the blood-spinal cord barrier. Certain studies have shown that stem cell-derived exosomes have anti-inflammatory effects and can play an irreplaceable role in the treatment of SCI. In this case, it is difficult for a single treatment method to play an effective role in the repair of neural tissue after SCI. The combination of biomaterial scaffolds and exosomes can better transfer and fix exosomes to the injury site and improve their survival rate. This paper first reviews the current research status of stem cell-derived exosomes and biomaterial scaffolds in the treatment of SCI respectively, and then describes the application of exosomes combined with biomaterial scaffolds in the treatment of SCI, as well as the challenges and prospects.

Published

2023

71. AKBA Promotes Axonal Regeneration via RhoA/Rictor to Repair Damaged Sciatic Nerve.

Author

Wang, Yao, Xiong, Zongliang, Zhou, Chong, Zhang, Qiyuan, Liu, Shuang, Dong, Sainan, Jiang, Xiaowen, and Yu, Wenhui

Subjects

*SCIATIC nerve injuries, *SCIATIC nerve, *NERVOUS system regeneration, *PERIPHERAL nerve injuries, *MYELIN sheath, *CELL anatomy, *CELL cycle proteins

Abstract

The existing studies by our team demonstrated the pro-recovery effect of 3-Acetyl-11-keto-beta-boswellic acid (AKBA) on a sciatic nerve injury. To further investigate the role of AKBA in peripheral nerve injury repair, The TMT quantitative proteomics technique was used to obtain differentially significant proteins in a Sham group, Model group, and AKBA group. After that, three time points (5, 14, and 28 d) and four groups (Sham + AKBA, Sham, Model, and AKBA) were set up, and immunoblotting, immunofluorescence, and cellular assays were applied to investigate the expression of CDC42, Rac1, RhoA, and Rictor in the sciatic nerve at different time points for each group in more depth. The results showed that AKBA enriched the cellular components of the myelin sheath and axon regeneration after a sciatic nerve injury and that AKBA upregulated CDC42 and Rac1 and downregulated RhoA expression 5 d after a sciatic nerve injury, promoting axon regeneration and improving the repair of a sciatic nerve injury in rats. Rictor is regulated by AKBA and upregulated in PC12 cells after AKBA action. Our findings provide a new basis for AKBA treatment of a peripheral nerve injury. [ABSTRACT FROM AUTHOR]

Published

2022

72. Axonal Regeneration Through Autologous Grafts: Does the Axonal Load Influence Regeneration?

Author

Leckenby, Jonathan I., Chacon, Miranda A., Milek, David, Lichtman, Jeff W., and Grobbelaar, Adriaan O.

Subjects

*NERVOUS system regeneration, *AUTOTRANSPLANTATION, *NERVE grafting, *FACIAL paralysis, *RECOVERY movement

Abstract

Two-stage free functional muscle transfers for long-standing facial palsy can yield unpredictable results. Earlier studies have demonstrated incomplete regeneration across neurorrhaphies in native nerve and higher donor axonal counts correlating with improved outcomes but axonal count in nerve grafts have not been as thoroughly reviewed. To investigate the impact of varying axonal counts in autologous grafts on functional outcomes of repair. Animals were allocated into three groups: Direct Nerve Repair (DNR, n = 50), Small Nerve Graft (SNG, n = 50), and Large Nerve Graft (LNG, n = 50). All grafts were inset into the Posterior Auricular Nerve with ear movement recovery (EMR) monitored as functional outcome. At various postoperative weeks (POWs), excised specimens were imaged with electron microscopy. Axonal counts were measured proximal to, distal (DAC) to, and within grafts. Total Success Ratio (TSR) was calculated. In DNR, DAC was significantly lower than proximal axonal counts at all POWs, with maximum TSR of 80%. TSR for LNG and SNG were significantly lower at all POWs when compared to DNR, with maximums of 56% and 38%, respectively. LNG had a significantly larger DAC than SNG at POW12 and beyond. A direct relationship was present between DAC and EMR for all values. Higher native axonal count of autologous nerve grafts resulted in higher percentage of regeneration across neurorrhaphies. [ABSTRACT FROM AUTHOR]

Published

2022

73. A Nanofiber‐embedded Microfluidic Platform for Studying Neurobiology.

Author

Lee, Donghee, Shree Sharma, Navatha, Shatil Shahriar, S. M., Yang, Kai, Yan, Zheng, and Xie, Jingwei

Subjects

MEDICAL equipment design, MICROFLUIDIC devices, NEUROBIOLOGY, HIGH throughput screening (Drug development), NERVOUS system injuries, NERVOUS system regeneration, BIOMIMETIC materials

Abstract

Due to their biomimetic properties, electrospun nanofibers have been widely used in neurobiology studies. However, mechanistic understanding of cell‐nanofiber interactions is challenging based on the current in vitro culture systems due to the lack of control of spatiotemporal patterning of cells and difficulty in monitoring single cell behavior. To overcome these issues, we apply microfluidic technology in combination with electrospun nanofibers for in vitro studies of interactions between neurons and nanofiber materials. We demonstrate a unique nanofiber embedded microfluidic device which contains patterned aligned or random electrospun nanofibers as a new culture system. With this device, we test how different topographies affect axonal growth. Also, we conduct laser based axotomy on neurons cultured on our device to investigate axonal regeneration. The proposed device could be a useful tool for investigating nerve injury mechanisms and high‐throughput screening of biomaterials or drugs for nerve repair. The knowledge obtained using this device can be applicable to design medical devices such as nerve conduits for effective nerve regeneration. [ABSTRACT FROM AUTHOR]

Published

2022

74. Axonal Regeneration: Underlying Molecular Mechanisms and Potential Therapeutic Targets.

Author

Akram, Rabia, Anwar, Haseeb, Javed, Muhammad Shahid, Rasul, Azhar, Imran, Ali, Malik, Shoaib Ahmad, Raza, Chand, Khan, Ikram Ullah, Sajid, Faiqa, Iman, Tehreem, Sun, Tao, Han, Hyung Soo, and Hussain, Ghulam

Subjects

NERVOUS system regeneration, CHONDROITIN sulfate proteoglycan, PERIPHERAL nervous system, DRUG target, NERVOUS system injuries, CENTRAL nervous system

Abstract

Axons in the peripheral nervous system have the ability to repair themselves after damage, whereas axons in the central nervous system are unable to do so. A common and important characteristic of damage to the spinal cord, brain, and peripheral nerves is the disruption of axonal regrowth. Interestingly, intrinsic growth factors play a significant role in the axonal regeneration of injured nerves. Various factors such as proteomic profile, microtubule stability, ribosomal location, and signalling pathways mark a line between the central and peripheral axons' capacity for self-renewal. Unfortunately, glial scar development, myelin-associated inhibitor molecules, lack of neurotrophic factors, and inflammatory reactions are among the factors that restrict axonal regeneration. Molecular pathways such as cAMP, MAPK, JAK/STAT, ATF3/CREB, BMP/SMAD, AKT/mTORC1/p70S6K, PI3K/AKT, GSK-3β/CLASP, BDNF/Trk, Ras/ERK, integrin/FAK, RhoA/ROCK/LIMK, and POSTN/integrin are activated after nerve injury and are considered significant players in axonal regeneration. In addition to the aforementioned pathways, growth factors, microRNAs, and astrocytes are also commendable participants in regeneration. In this review, we discuss the detailed mechanism of each pathway along with key players that can be potentially valuable targets to help achieve quick axonal healing. We also identify the prospective targets that could help close knowledge gaps in the molecular pathways underlying regeneration and shed light on the creation of more powerful strategies to encourage axonal regeneration after nervous system injury. [ABSTRACT FROM AUTHOR]

Published

2022

75. Lithium promotes long-term neurological recovery after spinal cord injury in mice by enhancing neuronal survival, gray and white matter remodeling, and long-distance axonal regeneration.

Author

Balçıkanlı, Zeynep, Culha, Irem, Dilsiz, Pelin, Aydin, Mehmet Serif, Ates, Nilay, Beker, Mustafa Caglar, Baltaci, Saltuk Bugra, Koc, Halil I., Yigitbasi, Ahmet, Gündogar, Mustafa, Doeppner, Thorsten R., Hermann, Dirk M., and Kilic, Ertugrul

Subjects

NERVOUS system regeneration, SPINAL cord injuries, WHITE matter (Nerve tissue), SPINAL cord, MOTOR ability, HINDLIMB, GRAY matter (Nerve tissue), LONG-distance running, MOTOR learning

Abstract

Spinal cord injury (SCI) induces neurological deficits associated with longterm functional impairments. Since the current treatments remain ineffective, novel therapeutic options are needed. Besides its effect on bipolar mood disorder, lithium was reported to have neuroprotective activity in different neurodegenerative conditions, including SCI. In SCI, the effects of lithium on long-term neurological recovery and neuroplasticity have not been assessed. We herein investigated the effects of intraperitoneally administered lithium chloride (LiCl) on motor coordination recovery, electromyography (EMG) responses, histopathological injury and remodeling, and axonal plasticity in mice exposed to spinal cord transection. At a dose of 0.2, but not 2.0 mmol/kg, LiCl enhanced motor coordination and locomotor activity starting at 28 days post-injury (dpi), as assessed by a set of behavioral tests. Following electrical stimulation proximal to the hemitransection, LiCl at 0.2 mmol/kg decreased the latency and increased the amplitude of EMG responses in the denervated hindlimb at 56 dpi. Functional recovery was associated with reduced gray and white matter atrophy rostral and caudal to the hemitransection, increased neuronal survival and reduced astrogliosis in the dorsal and ventral horns caudal to the hemitransection, and increased regeneration of long-distance axons proximal and distal to the lesion site in mice receiving 0.2 mmol/kg, but not 2 mmol/kg LiCl, as assessed by histochemical and immunohistochemical studies combined with anterograde tract tracing. Our results indicate that LiCl induces long-term neurological recovery and neuroplasticity following SCI. [ABSTRACT FROM AUTHOR]

Published

2022

76. Mechanisms of fibrinogen trans-activation of the EGFR/Ca2+ signaling axis to regulate mitochondrial transport and energy transfer and inhibit axonal regeneration following cerebral ischemia.

Author

Zhou S, Li B, Wu D, Chen Y, Zeng W, Huang J, Tan L, Mao G, and Liu F

Abstract

Ischemic stroke results in inhibition of axonal regeneration but the roles of fibrinogen (Fg) in neuronal signaling and energy crises in experimental stroke are under-investigated. We explored the mechanism of Fg modulation of axonal regeneration and neuronal energy crisis after cerebral ischemia using a permanent middle cerebral artery occlusion (MCAO) rat model and primary cortical neurons under low glucose-low oxygen. Behavioral tests assessed neurological deficits; immunofluorescence, immunohistochemistry, and Western-blot analyzed Fg and protein levels. Fluo-3/AM fluorescence measured free Ca2+ and ATP levels were gauged via specific assays and F560nm/F510nm ratio calculations. Mito-Tracker Green labeled mitochondria and immunoprecipitation studied protein interactions. Our comprehensive study revealed that Fg inhibited axonal regeneration post-MCAO as indicated by reduced GAP43 expression along with elevated free Ca2+, both suggesting an energy crisis. Fg impeded mitochondrial function and mediated impairment through the EGFR/Ca2+ axis by trans-activating EGFR via integrin αvβ3 interaction. These results indicate that the binding of Fg with integrin αvβ3 leads to the trans-activation of the EGFR/Ca2+ signaling axis thereby disrupting mitochondrial energy transport and axonal regeneration and exacerbating the detrimental effects of ischemic neuronal injury., (© The Author(s) 2024. Published by Oxford University Press on behalf of American Association of Neuropathologists, Inc. All rights reserved. For permissions, please email: journals.permissions@oup.com.)

Published

2024

77. Inosine Improves Functional Recovery and Cell Morphology Following Compressive Spinal Cord Injury in Mice.

Author

Cardoso R, Cardoso FSDS, Ramalho BDS, Maria GDS, Cavalcanti RR, Taboada TB, de Almeida JS, Martinez AMB, and de Almeida FM

Abstract

Spinal cord injury (SCI) is one of the most serious conditions of the central nervous system, causing motor and sensory deficits that lead to a significant impairment in the quality of life. Previous studies have indicated that inosine can promote regeneration after SCI. Here we investigated the effects of inosine on the behavioral and morphological recovery after a compressive injury. Adult female C57BL/6 mice were subjected to laminectomy and spinal cord compression using a vascular clip. Inosine or saline injections were administered intraperitoneally, with the first dose performed 24 h after injury and daily for 7 days after injury. The mice were evaluated using Basso Mouse Scale (BMS), locomotor rating scale, and pinprick test for 8 weeks. At the end, the animals were anesthetized and euthanized, and the spinal cords were collected for morphological evaluation. Inosine-treated animals presented better results in the immunostaining for oligodendrocytes and in the number of myelinated fibers through semithin sections compared to saline-treated animals, showing that there was a greater preservation of the white matter. Analysis of the immunoreactivity of astrocytes and evaluation of the inflammatory profile with macrophage labeling revealed that the animals of the inosine group had a lower immunoreactivity when compared to control, which suggests a reduction of the glial scar and less inflammation, respectively, leading to a more favorable microenvironment for spinal cord regeneration. Indeed, inosine-treated animals scored higher on the BMS scale and presented better results on the pinprick test, indicating that the treatment contributed to motor and sensory recovery. After the animals were sacrificed, we obtained the electroneuromyography, where the inosine group showed a greater amplitude of the compound muscle action potential. These results indicate that inosine contributed to the regeneration process in the spinal cord of mice submitted to compressive injury and should be further investigated as a candidate for SCI therapy., (© The Author(s) 2024. Published by Mary Ann Liebert, Inc.)

Published

2024

78. Iatrogenic Injury

Author

Paniello, Randal C., Weissbrod, Philip A., editor, and Francis, David O., editor

Published

2020

79. Self-curling electroconductive nerve dressing for enhancing peripheral nerve regeneration in diabetic rats

Author

Can Liu, Lei Fan, Zhenming Tian, Huiquan Wen, Lei Zhou, Pengfei Guan, Yian Luo, Chuncheung Chan, Guoxin Tan, Chengyun Ning, Limin Rong, and Bin Liu

Subjects

Diabetic peripheral nerve injury, Electroconductive hydrogel, Axonal regeneration, Nerve remyelination, Materials of engineering and construction. Mechanics of materials, TA401-492, Biology (General), QH301-705.5

Abstract

Conductive scaffolds have been shown to exert a therapeutic effect on patients suffering from peripheral nerve injuries (PNIs). However, conventional conductive conduits are made of rigid structures and have limited applications for impaired diabetic patients due to their mechanical mismatch with neural tissues and poor plasticity. We propose the development of biocompatible electroconductive hydrogels (ECHs) that are identical to a surgical dressing in this study. Based on excellent adhesive and self-healing properties, the thin film-like dressing can be easily attached to the injured nerve fibers, automatically warps a tubular structure without requiring any invasive techniques. The ECH offers an intimate and stable electrical bridge coupling with the electrogenic nerve tissues. The in vitro experiments indicated that the ECH promoted the migration and adhesion of the Schwann cells. Furthermore, the ECH facilitated axonal regeneration and remyelination in vitro and in vivo through the MEK/ERK pathway, thus preventing muscle denervation atrophy while retaining functional recovery. The results of this study are likely to facilitate the development of non-invasive treatment techniques for PNIs in diabetic patients utilizing electroconductive hydrogels.

Published

2021

80. Editorial: Axonal growth in normal and pathological conditions

Author

Takao Omura

Subjects

axonal regeneration, cAMP, lecticans, let-7-7a-5p, PLPPRs, Ctcf, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Published

2022

81. Lithium promotes long-term neurological recovery after spinal cord injury in mice by enhancing neuronal survival, gray and white matter remodeling, and long-distance axonal regeneration

Author

Zeynep Balçıkanlı, Irem Culha, Pelin Dilsiz, Mehmet Serif Aydin, Nilay Ates, Mustafa Caglar Beker, Saltuk Bugra Baltaci, Halil I. Koc, Ahmet Yigitbasi, Mustafa Gündogar, Thorsten R. Doeppner, Dirk M. Hermann, and Ertugrul Kilic

Subjects

axonal plasticity, axonal regeneration, motor coordination, neurological recovery, spinal cord hemitransection, spinal cord trauma, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Spinal cord injury (SCI) induces neurological deficits associated with long-term functional impairments. Since the current treatments remain ineffective, novel therapeutic options are needed. Besides its effect on bipolar mood disorder, lithium was reported to have neuroprotective activity in different neurodegenerative conditions, including SCI. In SCI, the effects of lithium on long-term neurological recovery and neuroplasticity have not been assessed. We herein investigated the effects of intraperitoneally administered lithium chloride (LiCl) on motor coordination recovery, electromyography (EMG) responses, histopathological injury and remodeling, and axonal plasticity in mice exposed to spinal cord transection. At a dose of 0.2, but not 2.0 mmol/kg, LiCl enhanced motor coordination and locomotor activity starting at 28 days post-injury (dpi), as assessed by a set of behavioral tests. Following electrical stimulation proximal to the hemitransection, LiCl at 0.2 mmol/kg decreased the latency and increased the amplitude of EMG responses in the denervated hindlimb at 56 dpi. Functional recovery was associated with reduced gray and white matter atrophy rostral and caudal to the hemitransection, increased neuronal survival and reduced astrogliosis in the dorsal and ventral horns caudal to the hemitransection, and increased regeneration of long-distance axons proximal and distal to the lesion site in mice receiving 0.2 mmol/kg, but not 2 mmol/kg LiCl, as assessed by histochemical and immunohistochemical studies combined with anterograde tract tracing. Our results indicate that LiCl induces long-term neurological recovery and neuroplasticity following SCI.

Published

2022

82. GPR3 expression in retinal ganglion cells contributes to neuron survival and accelerates axonal regeneration after optic nerve crush in mice

Author

Shun Masuda, Shigeru Tanaka, Hiroko Shiraki, Yusuke Sotomaru, Kana Harada, Izumi Hide, Yoshiaki Kiuchi, and Norio Sakai

Subjects

GPR3, cAMP, Axonal regeneration, Retinal granular cells, Neuronal survival, Optic nerve injury, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Glaucoma is an optic neuropathy and is currently one of the most common diseases that leads to irreversible blindness. The axonal degeneration that occurs before retinal ganglion neuronal loss is suggested to be involved in the pathogenesis of glaucoma. G protein-coupled receptor 3 (GPR3) belongs to the class A rhodopsin-type GPCR family and is highly expressed in various neurons. GPR3 is unique in its ability to constitutively activate the Gαs protein without a ligand, which elevates the basal intracellular cAMP level. Our earlier reports suggested that GPR3 enhances both neurite outgrowth and neuronal survival. However, the potential role of GPR3 in axonal regeneration after neuronal injury has not been elucidated. Herein, we investigated retinal GPR3 expression and its possible involvement in axonal regeneration after retinal injury in mice. GPR3 was relatively highly expressed in retinal ganglion cells (RGCs). Surprisingly, RGCs in GPR3 knockout mice were vulnerable to neural death during aging without affecting high intraocular pressure (IOP) and under ischemic conditions. Primary cultured neurons from the retina showed that GPR3 expression was correlated with neurite outgrowth and neuronal survival. Evaluation of the effect of GPR3 on axonal regeneration using GPR3 knockout mice revealed that GPR3 in RGCs participates in axonal regeneration after optic nerve crush (ONC) under zymosan stimulation. In addition, regenerating axons were further stimulated when GPR3 was upregulated in RGCs, and the effect was further augmented when combined with zymosan treatment. These results suggest that GPR3 expression in RGCs helps maintain neuronal survival and accelerates axonal regeneration after ONC in mice.

Published

2022

83. Neuronal activity-dependent ATP enhances the pro-growth effect of repair Schwann cell extracellular vesicles by increasing their miRNA-21 loading.

Author

Saquel, Cristian, Catalan, Romina J., Lopez-Leal, Rodrigo, Ramirez, Ramon A., Necuñir, David, Wyneken, Ursula, Lamaze, Christophe, and Court, Felipe A.

Subjects

EXTRACELLULAR vesicles, NERVOUS system regeneration, AXONS, SCHWANN cells, PERIPHERAL nerve injuries, NEURONS

Abstract

Functional recovery after peripheral nerve injuries is critically dependent on axonal regeneration. Several autonomous and non-cell autonomous processes regulate axonal regeneration, including the activation of a growth-associated transcriptional program in neurons and the reprogramming of dierentiated Schwann cells (dSCs) into repair SCs (rSCs), triggering the secretion of neurotrophic factors and the activation of an inflammatory response. Repair Schwann cells also release pro-regenerative extracellular vesicles (EVs), but is still unknown whether EV secretion is regulated non-cell autonomously by the regenerating neuron. Interestingly, it has been described that nerve activity enhances axonal regeneration by increasing the secretion of neurotrophic factors by rSC, but whether this activity modulates proregenerative EV secretion by rSC has not yet been explored. Here, we demonstrate that neuronal activity enhances the release of rSC-derived EVs and their transfer to neurons. This eect is mediated by activation of P2Y receptors in SCs after activity-dependent ATP release from sensory neurons. Importantly, activation of P2Y in rSCs also increases the amount of miRNA-21 present in rSC-EVs. Taken together, our results demonstrate that neuron to glia communication by ATP-P2Y signaling regulates the content of SC-derived EVs and their transfer to axons, modulating axonal elongation in a non-cell autonomous man. [ABSTRACT FROM AUTHOR]

Published

2022

84. Free radical biology in neurological manifestations: mechanisms to therapeutics interventions.

Author

Tripathi, Rahul, Gupta, Rohan, Sahu, Mehar, Srivastava, Devesh, Das, Ankita, Ambasta, Rashmi K, and Kumar, Pravir

Subjects

FREE radicals, CELL death, LIPID peroxidation (Biology), CIRCULAR RNA, REACTIVE oxygen species, HEAT shock proteins, NERVOUS system regeneration, BIOLOGICAL systems

Abstract

Recent advancements and growing attention about free radicals (ROS) and redox signaling enable the scientific fraternity to consider their involvement in the pathophysiology of inflammatory diseases, metabolic disorders, and neurological defects. Free radicals increase the concentration of reactive oxygen and nitrogen species in the biological system through different endogenous sources and thus increased the overall oxidative stress. An increase in oxidative stress causes cell death through different signaling mechanisms such as mitochondrial impairment, cell-cycle arrest, DNA damage response, inflammation, negative regulation of protein, and lipid peroxidation. Thus, an appropriate balance between free radicals and antioxidants becomes crucial to maintain physiological function. Since the 1brain requires high oxygen for its functioning, it is highly vulnerable to free radical generation and enhanced ROS in the brain adversely affects axonal regeneration and synaptic plasticity, which results in neuronal cell death. In addition, increased ROS in the brain alters various signaling pathways such as apoptosis, autophagy, inflammation and microglial activation, DNA damage response, and cell-cycle arrest, leading to memory and learning defects. Mounting evidence suggests the potential involvement of micro-RNAs, circular-RNAs, natural and dietary compounds, synthetic inhibitors, and heat-shock proteins as therapeutic agents to combat neurological diseases. Herein, we explain the mechanism of free radical generation and its role in mitochondrial, protein, and lipid peroxidation biology. Further, we discuss the negative role of free radicals in synaptic plasticity and axonal regeneration through the modulation of various signaling molecules and also in the involvement of free radicals in various neurological diseases and their potential therapeutic approaches. [ABSTRACT FROM AUTHOR]

Published

2022

85. MiRNAs as Promising Translational Strategies for Neuronal Repair and Regeneration in Spinal Cord Injury.

Author

Silvestro, Serena and Mazzon, Emanuela

Subjects

*SPINAL cord injuries, *NERVOUS system regeneration, *MICRORNA, *REPAIRING, *NERVOUS system injuries, *STEM cell transplantation, *AXONS

Abstract

Spinal cord injury (SCI) represents a devastating injury to the central nervous system (CNS) that is responsible for impaired mobility and sensory function in SCI patients. The hallmarks of SCI include neuroinflammation, axonal degeneration, neuronal loss, and reactive gliosis. Current strategies, including stem cell transplantation, have not led to successful clinical therapy. MiRNAs are crucial for the differentiation of neural cell types during CNS development, as well as for pathological processes after neural injury including SCI. This makes them ideal candidates for therapy in this condition. Indeed, several studies have demonstrated the involvement of miRNAs that are expressed differently in CNS injury. In this context, the purpose of the review is to provide an overview of the pre-clinical evidence evaluating the use of miRNA therapy in SCI. Specifically, we have focused our attention on miRNAs that are widely associated with neuronal and axon regeneration. "MiRNA replacement therapy" aims to transfer miRNAs to diseased cells and improve targeting efficacy in the cells, and this new therapeutic tool could provide a promising technique to promote SCI repair and reduce functional deficits. [ABSTRACT FROM AUTHOR]

Published

2022

86. Bu Shen Huo Xue decoction promotes functional recovery in spinal cord injury mice by improving the microenvironment to promote axonal regeneration.

Author

Hou, Yonghui, Luo, Dan, Hou, Yu, Luan, Jiyao, Zhan, Jiheng, Chen, Zepeng, E, Shunmei, Xu, Liangliang, and Lin, Dingkun

Subjects

*ORGANIC compound analysis, *CELL differentiation, *HERBAL medicine, *MEDICINAL plants, *SPINAL cord injuries, *NEURONS, *STAINS & staining (Microscopy), *PHENOLS, *FLAVONOIDS, *TERPENES, *CONVALESCENCE, *REGENERATION (Biology), *ANIMAL experimentation, *LIQUID chromatography, *SCARS, *FLUOROIMMUNOASSAY, *DEOXYRIBONUCLEOSIDES, *CYTOSKELETAL proteins, *GLYCOSIDES, *PHYTOCHEMICALS, *MASS spectrometry, *STEM cells, *CELL proliferation, *ALDEHYDES, *DESCRIPTIVE statistics, *BLOOD circulation, *NEUROGLIA, *CHINESE medicine, *MOTOR ability, *MICE, *PHENOTYPES, *PHARMACODYNAMICS

Abstract

Background: Bu-Shen-Huo-Xue (BSHX) decoction has been used in the postoperative rehabilitation of patients with spinal cord injury in China. In the present study, we aim to reveal the bioactive compounds in BSHX decoction and comprehensively explore the effects of BSHX decoction and the underlying mechanism in spinal cord injury recovery. Methods: The main chemical constituents in BSHX decoction were determined by UPLC–MS/MS. SCI mice were induced by a pneumatic impact device at T9–T10 level of the vertebra, and treated with BSHX decoction. Basso–Beattie–Bresnahan (BBB) score, footprint analysis, hematoxylin–eosin (H&E) staining, Nissl staining and a series of immunofluorescence staining were performed to investigate the functional recovery, glial scar formation and axon regeneration after BSHX treatment. Immunofluorescent staining of bromodeoxyuridine (BrdU), neuronal nuclei (NeuN) and glial fibrillary acidic protein (GFAP) was performed to evaluate the effect of BSHX decoction on neural stem cells (NSCs) proliferation and differentiation. Results: We found that the main compounds in BSHX decoction were Gallic acid, 3,4-Dihydroxybenzaldehyde, (+)-Catechin, Paeoniflorin, Rosmarinic acid, and Diosmetin. BSHX decoction improved the pathological findings in SCI mice through invigorating blood circulation and cleaning blood stasis in the lesion site. In addition, it reduced tissue damage and neuron loss by inhibiting astrocytes activation, and promoting the polarization of microglia towards M2 phenotype. The functional recovery test revealed that BSHX treatment improved the motor function recovery post SCI. Conclusions: Our study provided evidence that BSHX treatment could improve the microenvironment of the injured spinal cord to promote axonal regeneration and functional recovery in SCI mice. [ABSTRACT FROM AUTHOR]

Published

2022

87. Increasing toll-like receptor 2 on astrocytes induced by Schwann cell-derived exosomes promotes recovery by inhibiting CSPGs deposition after spinal cord injury

Author

Dayu Pan, Yongjin Li, Fuhan Yang, Zenghui Lv, Shibo Zhu, Yixin Shao, Ying Huang, Guangzhi Ning, and Shiqing Feng

Subjects

Schwann cell, Exosomes, Axonal regeneration, Spinal cord injury, Toll-like receptor 2, Astrocyte, Neurology. Diseases of the nervous system, RC346-429

Abstract

Abstract Background Traumatic spinal cord injury (SCI) is a severely disabling disease that leads to loss of sensation, motor, and autonomic function. As exosomes have great potential in diagnosis, prognosis, and treatment of SCI because of their ability to easily cross the blood–brain barrier, the function of Schwann cell-derived exosomes (SCDEs) is still largely unknown. Methods A T10 spinal cord contusion was established in adult female mice. SCDEs were injected into the tail veins of mice three times a week for 4 weeks after the induction of SCI, and the control group was injected with PBS. High-resolution transmission electron microscope and western blot were used to characterize the SCDEs. Toll-like receptor 2 (TLR2) expression on astrocytes, chondroitin sulfate proteoglycans (CSPGs) deposition and neurological function recovery were measured in the spinal cord tissues of each group by immunofluorescence staining of TLR2, GFAP, CS56, 5-HT, and β-III-tublin, respectively. TLR2f/f mice were crossed to the GFAP-Cre strain to generate astrocyte specific TLR2 knockout mice (TLR2−/−). Finally, western blot analysis was used to determine the expression of signaling proteins and IKKβ inhibitor SC-514 was used to validate the involved signaling pathway. Results Here, we found that TLR2 increased significantly on astrocytes post-SCI. SCDEs treatment can promote functional recovery and induce the expression of TLR2 on astrocytes accompanied with decreased CSPGs deposition. The specific knockout of TLR2 on astrocytes abolished the decreasing CSPGs deposition and neurological functional recovery post-SCI. In addition, the signaling pathway of NF-κB/PI3K involved in the TLR2 activation was validated by western blot. Furthermore, IKKβ inhibitor SC-514 was also used to validate this signaling pathway. Conclusion Thus, our results uncovered that SCDEs can promote functional recovery of mice post-SCI by decreasing the CSPGs deposition via increasing the TLR2 expression on astrocytes through NF-κB/PI3K signaling pathway.

Published

2021

88. Neuronal activity-dependent ATP enhances the pro-growth effect of repair Schwann cell extracellular vesicles by increasing their miRNA-21 loading

Author

Cristian Saquel, Romina J. Catalan, Rodrigo Lopez-Leal, Ramon A. Ramirez, David Necuñir, Ursula Wyneken, Christophe Lamaze, and Felipe A. Court

Subjects

Schwann cell, extracellular vesicles, ATP, purinergic receptors, axonal growth, axonal regeneration, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Functional recovery after peripheral nerve injuries is critically dependent on axonal regeneration. Several autonomous and non-cell autonomous processes regulate axonal regeneration, including the activation of a growth-associated transcriptional program in neurons and the reprogramming of differentiated Schwann cells (dSCs) into repair SCs (rSCs), triggering the secretion of neurotrophic factors and the activation of an inflammatory response. Repair Schwann cells also release pro-regenerative extracellular vesicles (EVs), but is still unknown whether EV secretion is regulated non-cell autonomously by the regenerating neuron. Interestingly, it has been described that nerve activity enhances axonal regeneration by increasing the secretion of neurotrophic factors by rSC, but whether this activity modulates pro-regenerative EV secretion by rSC has not yet been explored. Here, we demonstrate that neuronal activity enhances the release of rSC-derived EVs and their transfer to neurons. This effect is mediated by activation of P2Y receptors in SCs after activity-dependent ATP release from sensory neurons. Importantly, activation of P2Y in rSCs also increases the amount of miRNA-21 present in rSC-EVs. Taken together, our results demonstrate that neuron to glia communication by ATP-P2Y signaling regulates the content of SC-derived EVs and their transfer to axons, modulating axonal elongation in a non-cell autonomous manner.

Published

2022

89. Plasma membrane phospholipid phosphatase-related proteins as pleiotropic regulators of neuron growth and excitability

Author

Joachim Fuchs, Shannon Bareesel, Cristina Kroon, Alexandra Polyzou, Britta J. Eickholt, and George Leondaritis

Subjects

phospholipid phosphatases, LPA, plasticity-related genes, filopodia, synaptic transmission, axonal regeneration, Neurosciences. Biological psychiatry. Neuropsychiatry, RC321-571

Abstract

Neuronal plasma membrane proteins are essential for integrating cell extrinsic and cell intrinsic signals to orchestrate neuronal differentiation, growth and plasticity in the developing and adult nervous system. Here, we shed light on the family of plasma membrane proteins phospholipid phosphatase-related proteins (PLPPRs) (alternative name, PRGs; plasticity-related genes) that fine-tune neuronal growth and synaptic transmission in the central nervous system. Several studies uncovered essential functions of PLPPRs in filopodia formation, axon guidance and branching during nervous system development and regeneration, as well as in the control of dendritic spine number and excitability. Loss of PLPPR expression in knockout mice increases susceptibility to seizures, and results in defects in sensory information processing, development of psychiatric disorders, stress-related behaviors and abnormal social interaction. However, the exact function of PLPPRs in the context of neurological diseases is largely unclear. Although initially described as active lysophosphatidic acid (LPA) ecto-phosphatases that regulate the levels of this extracellular bioactive lipid, PLPPRs lack catalytic activity against LPA. Nevertheless, they emerge as atypical LPA modulators, by regulating LPA mediated signaling processes. In this review, we summarize the effects of this protein family on cellular morphology, generation and maintenance of cellular protrusions as well as highlight their known neuronal functions and phenotypes of KO mice. We discuss the molecular mechanisms of PLPPRs including the deployment of phospholipids, actin-cytoskeleton and small GTPase signaling pathways, with a focus on identifying gaps in our knowledge to stimulate interest in this understudied protein family.

Published

2022

90. Exosomes derived from miR-26a-modified MSCs promote axonal regeneration via the PTEN/AKT/mTOR pathway following spinal cord injury

Author

Yuyong Chen, Zhenming Tian, Lei He, Can Liu, Nangxiang Wang, Limin Rong, and Bin Liu

Subjects

Mesenchymal stem cells, Exosomes, Spinal cord injury, Axonal regeneration, miR-26a/PTEN axis, Medicine (General), R5-920, Biochemistry, QD415-436

Abstract

Abstract Background Exosomes derived from the bone marrow mesenchymal stem cell (MSC) have shown great potential in spinal cord injury (SCI) treatment. This research was designed to investigate the therapeutic effects of miR-26a-modified MSC-derived exosomes (Exos-26a) following SCI. Methods Bioinformatics and data mining were performed to explore the role of miR-26a in SCI. Exosomes were isolated from miR-26a-modified MSC culture medium by ultracentrifugation. A series of experiments, including assessment of Basso, Beattie and Bresnahan scale, histological evaluation, motor-evoked potential recording, diffusion tensor imaging, and western blotting, were performed to determine the therapeutic influence and the underlying molecular mechanisms of Exos-26a in SCI rats. Results Exos-26a was shown to promote axonal regeneration. Furthermore, we found that exosomes derived from miR-26a-modified MSC could improve neurogenesis and attenuate glial scarring through PTEN/AKT/mTOR signaling cascades. Conclusions Exosomes derived from miR-26a-modified MSC could activate the PTEN-AKT-mTOR pathway to promote axonal regeneration and neurogenesis and attenuate glia scarring in SCI and thus present great potential for SCI treatment. Graphical abstract

Published

2021

91. Myelin basic protein enhances axonal regeneration from neural progenitor cells

Author

Zhengjian Yan, Lei Chu, Xiaojiong Jia, Lu Lin, and Si Cheng

Subjects

Spinal cord injury, Axonal regeneration, Neural progenitor, Myelin, Mbp, Biotechnology, TP248.13-248.65, Biology (General), QH301-705.5, Biochemistry, QD415-436

Abstract

Abstract Introduction Stem cell therapy using neural progenitor cells (NPCs) shows promise in mitigating the debilitating effects of spinal cord injury (SCI). Notably, myelin stimulates axonal regeneration from mammalian NPCs. This led us to hypothesize that myelin-associated proteins may contribute to axonal regeneration from NPCs. Methods We conducted an R-based bioinformatics analysis to identify key gene(s) that may participate in myelin-associated axonal regeneration from murine NPCs, which identified the serine protease myelin basic protein (Mbp). We employed E12 murine NPCs, E14 rat NPCs, and human iPSC-derived Day 1 NPCs (D1 hNPCs) with or without CRISPR/Cas9-mediated Mbp knockout in combination with rescue L1-70 overexpression, constitutively-active VP16-PPARγ2, or the PPARγ agonist ciglitazone. A murine dorsal column crush model of SCI utilizing porous collagen-based scaffolding (PCS)-seeded murine NPCs with or without stable Mbp overexpression was used to assess locomotive recovery and axonal regeneration in vivo. Results Myelin promotes axonal outgrowth from NPCs in an Mbp-dependent manner and that Mbp’s stimulatory effects on NPC neurite outgrowth are mediated by Mbp’s production of L1-70. Furthermore, we determined that Mbp/L1-70’s stimulatory effects on NPC neurite outgrowth are mediated by PPARγ-based repression of neuron differentiation-associated gene expression and PPARγ-based Erk1/2 activation. In vivo, PCS-seeded murine NPCs stably overexpressing Mbp significantly enhanced locomotive recovery and axonal regeneration in post-SCI mice. Conclusions We discovered that Mbp supports axonal regeneration from mammalian NPCs through the novel Mbp/L1cam/Pparγ signaling pathway. This study suggests that bioengineered, NPC-based interventions can promote axonal regeneration and functional recovery post-SCI.

Published

2021

92. SGK1 in Schwann cells is a potential molecular switch involved in axonal and glial regeneration during peripheral nerve injury.

Author

Okura, Atsuhiko, Inoue, Koichi, Sakuma, Eisuke, Takase, Hiroshi, Ueki, Takatoshi, and Mase, Mitsuhito

Subjects

*PERIPHERAL nerve injuries, *SCHWANN cells, *NERVOUS system regeneration, *GLIAL fibrillary acidic protein, *MOLECULAR switches, *MYELIN proteins, *CELL death

Abstract

Schwann cells play an important role in peripheral myelination, and dysfunction of these cells leads to axonal damage. Schwann cells degenerate following peripheral nerve injury. Immature Schwann cells proliferate, differentiate, and support axonal regeneration and extension during recovery. There are a lot of intracellular signals involved in the myelination process. Although serum- and glucocorticoid-inducible kinase (SGK1) in Schwann cells is supposedly involved in developmental myelination, its significance during peripheral nerve injury and repair remains unknown. In this study, we examined the dynamics of SGK1 during peripheral nerve repair and the potential role of SGK in the process. Axonal crush injury was first generated in the right sciatic nerve under anesthesia in mice, which exhibited apparent paralysis and subsequent recovery of the injured hindlimbs. Immunohistochemical analysis revealed the appearance of glial fibrillary acidic protein (GFAP)-positive immature Schwann cells around injured nerves, and SGK1 was present in these cells. Next, we employed S16 cells, a Schwann cell line, to explore the impact of SGK1 on Schwann cells. Administration of the SGK inhibitor gsk650394 decreased cell proliferation and increased cell size. SGK inhibition did not cause cellular injury, suggesting that it suppresses proliferation and enlarges Schwann cells without causing cell death. Furthermore, quantitative PCR and immunoblotting revealed that SGK inhibition upregulated the gene expression of BDNF, MBP, and Krox20, which are facilitating factors for myelination and neural regeneration, and downregulated that of Sox10. Taken together, these findings indicate that SGK1 inactivation in Schwann cells diverts cell fate from proliferation to differentiation. • We examined SGK effects in Schwann cells during peripheral nerve injury and repair. • We used a mouse sciatic nerve axonal crush model and the S16 Schwann cell line. • SGK inhibition decreased cell proliferation and increased cell size. • SGK inhibition did not cause significant cellular injury. • BDNF, MBP, and Krox20 expression was upregulated, and Sox10 was downregulated. [ABSTRACT FROM AUTHOR]

Published

2022

93. miR-182-5p Regulates Nogo-A Expression and Promotes Neurite Outgrowth of Hippocampal Neurons In Vitro.

Author

Soto, Altea, Nieto-Díaz, Manuel, Reigada, David, Barreda-Manso, María Asunción, Muñoz-Galdeano, Teresa, and Maza, Rodrigo M.

Subjects

*MYELIN proteins, *NERVOUS system regeneration, *NEUROPLASTICITY, *NEURONS, *CENTRAL nervous system, *HIPPOCAMPUS (Brain), *REPORTER genes

Abstract

Nogo-A protein is a key myelin-associated inhibitor of axonal growth, regeneration, and plasticity in the central nervous system (CNS). Regulation of the Nogo-A/NgR1 pathway facilitates functional recovery and neural repair after spinal cord trauma and ischemic stroke. MicroRNAs are described as effective tools for the regulation of important processes in the CNS, such as neuronal differentiation, neuritogenesis, and plasticity. Our results show that miR-182-5p mimic specifically downregulates the expression of the luciferase reporter gene fused to the mouse Nogo-A 3′UTR, and Nogo-A protein expression in Neuro-2a and C6 cells. Finally, we observed that when rat primary hippocampal neurons are co-cultured with C6 cells transfected with miR-182-5p mimic, there is a promotion of the outgrowth of neuronal neurites in length. From all these data, we suggest that miR-182-5p may be a potential therapeutic tool for the promotion of axonal regeneration in different diseases of the CNS. [ABSTRACT FROM AUTHOR]

Published

2022

94. Exosomes‐Loaded Electroconductive Hydrogel Synergistically Promotes Tissue Repair after Spinal Cord Injury via Immunoregulation and Enhancement of Myelinated Axon Growth.

Author

Fan, Lei, Liu, Can, Chen, Xiuxing, Zheng, Lei, Zou, Yan, Wen, Huiquan, Guan, Pengfei, Lu, Fang, Luo, Yian, Tan, Guoxin, Yu, Peng, Chen, Dafu, Deng, Chunlin, Sun, Yongjian, Zhou, Lei, and Ning, Chengyun

Subjects

*SPINAL cord injuries, *NEURAL stem cells, *EXOSOMES, *OLIGODENDROGLIA, *NERVOUS system regeneration, *TISSUE mechanics, *IMMUNOREGULATION, *HYDROGELS

Abstract

Electroconductive hydrogels are very attractive candidates for accelerated spinal cord injury (SCI) repair because they match the electrical and mechanical properties of neural tissue. However, electroconductive hydrogel implantation can potentially aggravate inflammation, and hinder its repair efficacy. Bone marrow stem cell‐derived exosomes (BMSC‐exosomes) have shown immunomodulatory and tissue regeneration effects, therefore, neural tissue‐like electroconductive hydrogels loaded with BMSC‐exosomes are developed for the synergistic treatment of SCI. These exosomes‐loaded electroconductive hydrogels modulate microglial M2 polarization via the NF‐κB pathway, and synergistically enhance neuronal and oligodendrocyte differentiation of neural stem cells (NSCs) while inhibiting astrocyte differentiation, and also increase axon outgrowth via the PTEN/PI3K/AKT/mTOR pathway. Furthermore, exosomes combined electroconductive hydrogels significantly decrease the number of CD68‐positive microglia, enhance local NSCs recruitment, and promote neuronal and axonal regeneration, resulting in significant functional recovery at the early stage in an SCI mouse model. Hence, the findings of this study demonstrate that the combination of electroconductive hydrogels and BMSC‐exosomes is a promising therapeutic strategy for SCI repair. [ABSTRACT FROM AUTHOR]

Published

2022

95. Radix Astragalus Polysaccharide Accelerates Angiogenesis by Activating AKT/eNOS to Promote Nerve Regeneration and Functional Recovery.

Author

Zhang, Geyi, Huang, Jinsheng, Hao, Shuang, Zhang, Jingchao, and Zhou, Nan

Subjects

POLYSACCHARIDES, NERVOUS system regeneration, ASTRAGALUS (Plants), PERIPHERAL nerve injuries, SCIATIC nerve injuries, ENDOTHELIAL cells, NEOVASCULARIZATION

Abstract

Peripheral nerve injury (PNI) results in loss of neural control and severe disabilities in patients. Promoting functional nerve recovery by accelerating angiogenesis is a promising neuroprotective treatment strategy. Here, we identified a bioactive Radix Astragalus polysaccharide (RAP) extracted from traditional Chinese medicine (TCM) as a potent enhancer of axonal regeneration and remyelination. Notably, RAP promoted functional recovery and delayed gastrocnemius muscle atrophy in a rat model of sciatic nerve crush injury. Further, RAP treatment may induce angiogenesis in vivo. Moreover, our in vitro results showed that RAP promotes endothelial cell (EC) migration and tube formation. Altogether, our results show that RAP can enhance functional recovery by accelerating angiogenesis, which was probably related to the activation of AKT/eNOS signaling pathway, thereby providing a polysaccharide-based therapeutic strategy for PNI. [ABSTRACT FROM AUTHOR]

Published

2022

96. The Role of Tissue Geometry in Spinal Cord Regeneration.

Author

Pettigrew, David B., Singh, Niharika, Kirthivasan, Sabarish, and Crutcher, Keith A.

Subjects

SPINAL cord, NERVOUS system regeneration, CHONDROITIN sulfate proteoglycan, REGENERATION (Biology), CENTRAL nervous system, PERIPHERAL nervous system

Abstract

Unlike peripheral nerves, axonal regeneration is limited following injury to the spinal cord. While there may be reduced regenerative potential of injured neurons, the central nervous system (CNS) white matter environment appears to be more significant in limiting regrowth. Several factors may inhibit regeneration, and their neutralization can modestly enhance regrowth. However, most investigations have not considered the cytoarchitecture of spinal cord white matter. Several lines of investigation demonstrate that axonal regeneration is enhanced by maintaining, repairing, or reconstituting the parallel geometry of the spinal cord white matter. In this review, we focus on environmental factors that have been implicated as putative inhibitors of axonal regeneration and the evidence that their organization may be an important determinant in whether they inhibit or promote regeneration. Consideration of tissue geometry may be important for developing successful strategies to promote spinal cord regeneration. [ABSTRACT FROM AUTHOR]

Published

2022

97. Experimental Laceration Spinal Cord Injury Model in Rodents

Author

Zhang, Yi Ping, Shields, Lisa B. E., Shields, Christopher B., Zhang, John, Series Editor, Chen, Jun, editor, Xu, Zao C., editor, Xu, Xiao Ming, editor, and Zhang, John H., editor

Published

2019

98. Adipose-Derived Stem Cells (ASCs) for Peripheral Nerve Regeneration

Author

Tremp, Mathias, Kalbermatten, Daniel F., Duscher, Dominik, editor, and Shiffman, Melvin A., editor

Published

2019

99. DNA methylation and hydroxymethylation have distinct genome-wide profiles related to axonal regeneration

Author

Andy Madrid, Laura E. Borth, Kirk J. Hogan, Nithya Hariharan, Ligia A. Papale, Reid S. Alisch, and Bermans J. Iskandar

Subjects

folate, transgenerational, dna methylation, transcriptome, epigenetics, axonal regeneration, Genetics, QH426-470

Abstract

Alterations in environmentally sensitive epigenetic mechanisms (e.g., DNA methylation) influence axonal regeneration in the spinal cord following sharp injury. Conventional DNA methylation detection methods using sodium bisulphite treatment do not distinguish between methylated and hydroxymethylated forms of cytosine, meaning that past studies report a composite of 5-methylcytosine (5mC) and 5-hydroxymethylcytosine (5hmC). To identify the distinct contributions of DNA methylation modifications to axonal regeneration, we collected spinal cord tissue after sharp injury from untreated adult F3 male rats with enhanced regeneration of injured spinal axons or controls, derived from folate- or water-treated F0 lineages, respectively. Genomic DNA was profiled for genome-wide 5hmC levels, revealing 658 differentially hydroxymethylated regions (DhMRs). Genomic profiling with whole genome bisulphite sequencing disclosed regeneration-related alterations in composite 5mC + 5hmC DNA methylation levels at 2,260 differentially methylated regions (DMRs). While pathway analyses revealed that differentially hydroxymethylated and methylated genes are linked to biologically relevant axon developmental pathways, only 22 genes harbour both DhMR and DMRs. Since these differential modifications were more than 60 kilobases on average away from each other, the large majority of differential hydroxymethylated and methylated regions are unique with distinct functions in the axonal regeneration phenotype. These data highlight the importance of distinguishing independent contributions of 5mC and 5hmC levels in the central nervous system, and denote discrete roles for DNA methylation modifications in spinal cord injury and regeneration in the context of transgenerational inheritance.

Published

2021

100. Axonal regeneration and sprouting as a potential therapeutic target for nervous system disorders

Author

Katherine L Marshall and Mohamed H Farah

Subjects

amyotrophic lateral sclerosis, axonal regeneration, dying-back axonopathy, in vitro neuromuscular junction, ipsc-derived motor neurons, microfluidic device, motor axon sprouting, Neurology. Diseases of the nervous system, RC346-429

Abstract

Nervous system disorders are prevalent health issues that will only continue to increase in frequency as the population ages. Dying-back axonopathy is a hallmark of many neurologic diseases and leads to axonal disconnection from their targets, which in turn leads to functional impairment. During the course of many of neurologic diseases, axons can regenerate or sprout in an attempt to reconnect with the target and restore synapse function. In amyotrophic lateral sclerosis (ALS), distal motor axons retract from neuromuscular junctions early in the disease-course before significant motor neuron death. There is evidence of compensatory motor axon sprouting and reinnervation of neuromuscular junctions in ALS that is usually quickly overtaken by the disease course. Potential drugs that enhance compensatory sprouting and encourage reinnervation may slow symptom progression and retain muscle function for a longer period of time in ALS and in other diseases that exhibit dying-back axonopathy. There remain many outstanding questions as to the impact of distinct disease-causing mutations on axonal outgrowth and regeneration, especially in regards to motor neurons derived from patient induced pluripotent stem cells. Compartmentalized microfluidic chambers are powerful tools for studying the distal axons of human induced pluripotent stem cells-derived motor neurons, and have recently been used to demonstrate striking regeneration defects in human motor neurons harboring ALS disease-causing mutations. Modeling the human neuromuscular circuit with human induced pluripotent stem cells-derived motor neurons will be critical for developing drugs that enhance axonal regeneration, sprouting, and reinnervation of neuromuscular junctions. In this review we will discuss compensatory axonal sprouting as a potential therapeutic target for ALS, and the use of compartmentalized microfluidic devices to find drugs that enhance regeneration and axonal sprouting of motor axons.

Published

2021