| Publication |
Sentence |
Publish Date |
Extraction Date |
Species |
| Alexei Verkhratsky, Alexey Semyano. Physiology of neuroglia of the central nervous system. Handbook of clinical neurology. vol 209. 2025-03-23. PMID:40122632. |
the extended class of astroglia (which includes numerous parenchymal astrocytes, such as protoplasmic, fibrous, velate, marginal, etc., radial astrocytes such as bergmann glia, muller glia, etc., and ependymoglia lining the walls of brain ventricles and central canal of the spinal cord) is primarily responsible for overall homeostasis of the nervous tissue. |
2025-03-23 |
2025-03-26 |
Not clear |
| Thomas Lozito, Ricardo Londono, Zheyu Pan, Megan Hudnal. Simulation of adult limb regeneration with lizard tail spinal cord implants reveals distinct roles of radial glia and microglia populations. Research square. 2025-03-17. PMID:40092433. |
simulation of adult limb regeneration with lizard tail spinal cord implants reveals distinct roles of radial glia and microglia populations. |
2025-03-17 |
2025-03-20 |
human |
| Thomas Lozito, Ricardo Londono, Zheyu Pan, Megan Hudnal. Simulation of adult limb regeneration with lizard tail spinal cord implants reveals distinct roles of radial glia and microglia populations. Research square. 2025-03-17. PMID:40092433. |
lizard blastema formation is dependent upon tail spinal cord tissue, which contains distinct populations of radial glia and microglia. |
2025-03-17 |
2025-03-20 |
human |
| Thomas Lozito, Ricardo Londono, Zheyu Pan, Megan Hudnal. Simulation of adult limb regeneration with lizard tail spinal cord implants reveals distinct roles of radial glia and microglia populations. Research square. 2025-03-17. PMID:40092433. |
taken together, these results indicate that lizard limbs contain all the necessary cell types and biological responses necessary for blastema formation but lack the proliferative and anti-fibrotic signals provided by tail spinal cord radial glia and microglia, respectively. |
2025-03-17 |
2025-03-20 |
human |
| Ting He, DongDong Wang, Linman Wu, Liuyin Ji. The role of glial cells in neuralgia: a bibliometric exploration. Frontiers in neurology. vol 16. 2025-02-24. PMID:39990265. |
keyword analysis highlights research hotspots focusing on glial cell activation, spinal cord injury, satellite glial cells, oxidative stress, and neuroinflammation. |
2025-02-24 |
2025-02-26 |
Not clear |
| Philip Hasel, Melissa L Cooper, Anne E Marchildon, Uriel Rufen-Blanchette, Rachel D Kim, Thong C Ma, Adam M R Groh, Emily J Hill, Eleanor M Lewis, Michał Januszewski, Sarah E W Light, Cody J Smith, Jo Anne Stratton, Steven A Sloan, Un Jung Kang, Moses V Chao, Shane A Liddelo. Defining the molecular identity and morphology of glia limitans superficialis astrocytes in vertebrates. Cell reports. vol 44. issue 3. 2025-02-21. PMID:39982817. |
here, we report that astrocytes forming the glia limitans superficialis, the outermost border of the brain and spinal cord, are a highly specialized astrocyte subtype and can be identified by a single marker: myocilin (myoc). |
2025-02-21 |
2025-02-24 |
zebrafish |
| Philip Hasel, Melissa L Cooper, Anne E Marchildon, Uriel Rufen-Blanchette, Rachel D Kim, Thong C Ma, Adam M R Groh, Emily J Hill, Eleanor M Lewis, Michał Januszewski, Sarah E W Light, Cody J Smith, Jo Anne Stratton, Steven A Sloan, Un Jung Kang, Moses V Chao, Shane A Liddelo. Defining the molecular identity and morphology of glia limitans superficialis astrocytes in vertebrates. Cell reports. vol 44. issue 3. 2025-02-21. PMID:39982817. |
we show that glia limitans superficialis astrocytes cover the entire brain and spinal cord surface, exhibit an atypical morphology, and are evolutionarily conserved from zebrafish, rodents, and non-human primates to humans. |
2025-02-21 |
2025-02-24 |
zebrafish |
| Wen-Ya Shang, Ya-Feng Ren, Jing Huang, Bing Li, Xiao-Meng Huang, Zhi-Lan Zhan. [Progress of researches on acupuncture treatment of spinal cord injury by promoting axonal regeneration]. Zhen ci yan jiu = Acupuncture research. vol 50. issue 1. 2025-02-17. PMID:39961764. |
acupuncture can promote the repairment of sci by (1) regulating the expressions of spinal cord growth factors (such as nerve growth factor, brain derived neurotrophic factor, neurotrophin-3, glial cell line-derived neurotrophic factor, ciliary neurotrophic factor, insulin-like growth factor, etc.) |
2025-02-17 |
2025-02-23 |
Not clear |
| Kelsey M Hooper, Vedant D Jain, Celeste J Gormly, Brian J Sanderson, Erik A Lundquis. Short- and long-range roles of UNC-6/Netrin in dorsal-ventral axon guidance in vivo in Caenorhabditis elegans. PLoS genetics. vol 21. issue 1. 2025-01-17. PMID:39823521. |
in both cases, short-range or even haptotactic mechanisms are invoked: in vertebrate spinal cord, interactions of growth cones with radial glia expressing netrin-1; and in c. elegans, a potential close-range interaction that polarizes the growth cone. |
2025-01-17 |
2025-01-20 |
caenorhabditis_elegans |
| Yue Wang, Yongmin Chen, Jing Lu, Qinqin Xiao, Ge Li, Rong Wang, Rong Chen, Da-Qi Zhan. Forsythoside B Ameliorates Neuroinflammation via Inhibiting NLRP3 Inflammasome of Glial Cells in Experimental Autoimmune Encephalomyelitis Mice. Brain research bulletin. 2024-12-27. PMID:39730017. |
in addition, fts·b administration reduced inflammatory response and demyelination by inhibiting glial cell activation in the spinal cord of eae mice. |
2024-12-27 |
2024-12-30 |
mouse |
| Ying Ye, Xinjin Su, Jun Tang, Chao Zh. Neuropathic Pain Induced by Spinal Cord Injury from the Glia Perspective and Its Treatment. Cellular and molecular neurobiology. vol 44. issue 1. 2024-11-28. PMID:39607514. |
neuropathic pain induced by spinal cord injury from the glia perspective and its treatment. |
2024-11-28 |
2024-11-30 |
Not clear |
| So-Hee Kim, Vishnumolakala Sindhuri, Min-Jae Koo, Seung Heon Jeon, Seungtae Kim, Sungtae Ko. Effects of Repeated Exposure to Ambient Cold on the Development of Inflammatory Pain in a Rat Model of Knee Arthritis. Life (Basel, Switzerland). vol 14. issue 11. 2024-11-27. PMID:39598225. |
this study investigated the effects of ambient cold exposure on inflammatory pain development, synovial cytokine levels, and spinal cord glial cell activation. |
2024-11-27 |
2024-11-29 |
rat |
| Kristy L Townsen. One Nervous System: Critical Links Between Central and Peripheral Nervous System Health and Implications for Obesity and Diabetes. Diabetes. vol 73. issue 12. 2024-11-20. PMID:39401394. |
there are key differences between the central nervous system (cns) (brain and spinal cord) and peripheral nervous system (pns), such as glial cell types, whether there is protection by the blood-brain barrier, modes of synaptic connections, etc. |
2024-11-20 |
2024-11-23 |
Not clear |
| Bianca G Evangelista, Aline C Giardini, Natália G Hösch, Morena B Sant Anna, Barbara B Martins, Beatriz S Neto, Marucia Chacur, Rosana L Pagano, Gisele Picolo, Vanessa O Zambell. ALDEHYDE DEHYDROGENASE-2 DEFICIENCY AGGRAVATES NEUROINFLAMMATION, NOCICEPTION, AND MOTOR IMPAIRMENT IN A MOUSE MODEL OF MULTIPLE SCLEROSIS. Free radical biology & medicine. 2024-10-31. PMID:39481766. |
the deleterious clinical signs are followed by glial cell activation in the spinal cord and increased 4-hne levels in the spinal cord and serum. |
2024-10-31 |
2024-11-03 |
mouse |
| Roberta Amoriello, Clara Ballerin. Immunofluorescence Staining of Murine Spinal Cord Sections to Evaluate Microglial Activation and Astrogliosis. Methods in molecular biology (Clifton, N.J.). vol 2857. 2024-09-30. PMID:39348064. |
we here present a protocol for the study of glial cell activation in the spinal cord tissue of eae mice. |
2024-09-30 |
2024-10-02 |
mouse |
| Danyang Li, Kaihong Yang, Jinlu Li, Xiaoqian Xu, Lanlan Gong, Shouwei Yue, Hui Wei, Zhenyu Yue, Yikun Wu, Sen Yi. Single-cell sequencing reveals glial cell involvement in development of neuropathic pain via myelin sheath lesion formation in the spinal cord. Journal of neuroinflammation. vol 21. issue 1. 2024-08-31. PMID:39217340. |
single-cell sequencing reveals glial cell involvement in development of neuropathic pain via myelin sheath lesion formation in the spinal cord. |
2024-08-31 |
2024-09-04 |
Not clear |
| Catrina Reyes, Mayssa H Mokalle. Astrocyte-Neuron Interactions in Spinal Cord Injury. Advances in neurobiology. vol 39. 2024-08-27. PMID:39190077. |
a detailed molecular and phenotypic catalog of the continuum of astrocyte reactivity states is an essential first step toward the development of glial cell manipulations for spinal cord repair. |
2024-08-27 |
2024-08-30 |
Not clear |
| Robin I Brown, Heather M Barber, Sarah Kucena. Satellite glial cell manipulation prior to axotomy enhances developing dorsal root ganglion central branch regrowth into the spinal cord. Glia. vol 72. issue 10. 2024-08-14. PMID:39141572. |
satellite glial cell manipulation prior to axotomy enhances developing dorsal root ganglion central branch regrowth into the spinal cord. |
2024-08-14 |
2024-08-17 |
zebrafish |
| Akihito Takeda, Minami Teshima, Kengo Funakosh. Involvement of vimentin- and BLBP-positive glial cells and their MMP expression in axonal regeneration after spinal cord transection in goldfish. Cell and tissue research. 2024-08-09. PMID:39120736. |
in intact spinal cord, ependymo-radial glial cell bodies express blbp and their radial processes express vimentin, suggesting that vimentin-positive glial processes derive from migrating ependymo-radial glial cells. |
2024-08-09 |
2024-08-12 |
Not clear |
| Shibo Zhu, Hongpeng Ma, Mengfan Hou, Hailiang Li, Guangzhi Nin. Schwann Cell-Derived Exosomes Induced Axon Growth after Spinal Cord Injury by Decreasing PTP-σ Activation on CSPGs via the Rho/ROCK Pathway. Neurochemical research. vol 49. issue 8. 2024-07-09. PMID:38819695. |
this process leads to the upregulation of chondroitin sulfate proteoglycans (cspgs) by reactive glia, which impedes repair and regeneration in the spinal cord. |
2024-07-09 |
2024-07-12 |
mouse |