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2008, 1, ISBN 9780123742476, 408
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2.
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Long-Distance Growth and Connectivity of Neural Stem Cells after Severe Spinal Cord Injury
Cell (Cambridge), ISSN 0092-8674, 09/2012, Volume 150, Issue 6, pp. 1264 - 1273
Biochemistry & Molecular Biology | Life Sciences & Biomedicine | Science & Technology | Cell Biology | Cell Line | Green Fluorescent Proteins - analysis | Spinal Cord Regeneration | Humans | Rats, Inbred F344 | Rats | Axons - physiology | Neural Stem Cells - cytology | Rats, Nude | Animals | Spinal Cord - pathology | Neural Stem Cells - transplantation | Female | Spinal Cord - physiopathology | Spinal Cord Injuries - therapy | Fibrin | Neurosciences | Neurons | Growth | Stem cells | Transplantation | Spinal cord injuries | Universities and colleges | Index Medicus
Journal Article
The Journal of neuroscience, ISSN 0270-6474, 10/2011, Volume 31, Issue 42, pp. 15173 - 15187
Neurosciences | Neurosciences & Neurology | Life Sciences & Biomedicine | Science & Technology | Enzyme-Linked Immunosorbent Assay - methods | Locomotion - genetics | Recovery of Function - drug effects | Humans | Axons - physiology | Cell Transdifferentiation - genetics | Ganglia, Spinal - cytology | Green Fluorescent Proteins - genetics | Glial Fibrillary Acidic Protein - metabolism | Cell Movement - genetics | Spinal Cord Injuries - pathology | Transfection - methods | Cell Transdifferentiation - drug effects | Lamins - metabolism | Female | Bromodeoxyuridine - metabolism | Spinal Cord - cytology | Spinal Cord Injuries - therapy | ErbB Receptors - deficiency | Disease Models, Animal | Locomotion - drug effects | Transforming Growth Factor alpha - pharmacology | Astrocytes - drug effects | Green Fluorescent Proteins - metabolism | Recovery of Function - genetics | ErbB Receptors - metabolism | Mice, Inbred C57BL | Cells, Cultured | Neural Stem Cells - drug effects | Axons - drug effects | Up-Regulation - genetics | Transforming Growth Factor alpha - genetics | Mice, Knockout | Up-Regulation - drug effects | Cell Movement - drug effects | Phenotype | Animals | Analysis of Variance | Cell Proliferation - drug effects | Mice | Spinal Cord Injuries - physiopathology | Neurofilament Proteins - metabolism | Index Medicus
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Experimental strategies to promote spinal cord regeneration - An integrative perspective
Progress in neurobiology, ISSN 0301-0082, 02/2006, Volume 78, Issue 2, pp. 91 - 116
Regeneration | Growth inhibition | Spinal cord injury | Cellular transplantation | Neurosciences | Neurosciences & Neurology | Life Sciences & Biomedicine | Science & Technology | Neuroprotective Agents - therapeutic use | Spinal Cord Diseases - physiopathology | Humans | Nerve Regeneration - physiology | Neuroglia - physiology | Neurons - cytology | Axons - physiology | Spinal Cord Diseases - epidemiology | Recovery of Function | Nerve Growth Factors - therapeutic use | Animals | Spinal Cord Diseases - therapy | Neurons - physiology | Stem Cells - physiology | Spinal Cord Diseases - pathology | Cell Transplantation - methods | Disease Models, Animal | Proteins | Medical colleges | Spinal cord injuries | Vaccination | Index Medicus
Journal Article
Science (American Association for the Advancement of Science), ISSN 0036-8075, 2/2011, Volume 331, Issue 6019, pp. 928 - 931
COS cells | Axons | Spinal cord | Neuroscience | Neurons | Microtubules | REPORTS | Central nervous system | Physical trauma | Lesions | Vehicles | Spinal Cord Regeneration | polysaccharide | stabilization | Cicatrix | proteoglycan synthesis | nerve fiber regeneration | scar formation | Sprague-Dawley | hypertrophic scar | Paclitaxel | rodent | Female | Cultured | cell organelle | injury | priority journal | animal model | Kinesin | Transforming Growth Factor beta | neurology | spinal cord injury | sensory nerve cell | Signal Transduction | rat | chondroitin sulfate | Rats | Cells | Chondroitin Sulfate Proteoglycans | Ganglia | animal experiment | article | Protein Transport | Sensory Receptor Cells | Spinal | microtubule | functional morphology | Animals | Spinal Cord Injuries | Spinal Cord | controlled study | animal tissue | nonhuman | nerve fiber growth | Smad2 Protein | Science & Technology - Other Topics | Multidisciplinary Sciences | Science & Technology | Neurology | Biological and medical sciences | Medical sciences | Cerebrospinal fluid. Meninges. Spinal cord | Nervous system (semeiology, syndromes) | Paclitaxel - pharmacology | Spinal Cord - drug effects | Spinal Cord Injuries - drug therapy | Axons - physiology | Ganglia, Spinal - cytology | Spinal Cord Injuries - pathology | Microtubules - metabolism | Sensory Receptor Cells - physiology | Microtubules - drug effects | Spinal Cord - cytology | Paclitaxel - administration & dosage | Cicatrix - prevention & control | Cells, Cultured | Chondroitin Sulfate Proteoglycans - metabolism | Smad2 Protein - metabolism | Rats, Sprague-Dawley | Kinesin - metabolism | Cicatrix - pathology | Spinal Cord Injuries - physiopathology | Transforming Growth Factor beta - metabolism | Regeneration | Patient outcomes | Spinal cord injuries | Research | Health aspects | Cytoskeleton | Cellular biology | Rodents | Index Medicus
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Required growth facilitators propel axon regeneration across complete spinal cord injury
Nature (London), ISSN 0028-0836, 09/2018, Volume 561, Issue 7723, pp. 396 - 400
Science & Technology - Other Topics | Multidisciplinary Sciences | Science & Technology | Spinal cord injuries | Genetic aspects | Adults | Health aspects | Conduction | Fibroblast growth factor | Animal models | Spinal cord | Circuit design | Hydrogels | Recovery of function | Nervous system | Insulin-like growth factors | Spinal cord injury | Neuronal-glial interactions | Biomaterials | Biomedical materials | Epidermal growth factor | Rodents | Reinstatement | Fibroblasts | Biocompatibility | Lesions | Growth factors | Controlled release | Injuries | Fibroblast growth factor 2 | Neurons | Axonogenesis | Osteopontin | Regrowth | Insulin | Substrates | Regeneration | Axons | Functional morphology | Rehabilitation | Index Medicus
Journal Article
Artificial cells, nanomedicine, and biotechnology, ISSN 2169-1401, 07/2016, Volume 44, Issue 5, pp. 1254 - 1258
spinal cord injury | umbilical cord | nerve growth factor | interleukin-1β | Wharton's jelly cells | Nerve growth factor | Umbilical cord | Spinal cord injury | Interleukin-1β | Wharton’s jelly cells | Acute Disease | Nerve Growth Factor - biosynthesis | Spinal Cord Injuries - metabolism | Humans | Gene Expression Regulation | Rats | Rats, Sprague-Dawley | Spinal Cord Injuries - pathology | Animals | Heterografts | Mesenchymal Stromal Cells | Female | Interleukin-1beta - biosynthesis | Spinal Cord Injuries - therapy | Mesenchymal Stem Cell Transplantation | Index Medicus
Journal Article
Science (American Association for the Advancement of Science), ISSN 0036-8075, 9/2014, Volume 345, Issue 6204, pp. 1577 - 1577
RESEARCH ARTICLE SUMMARY | Science & Technology - Other Topics | Multidisciplinary Sciences | Science & Technology | Spinal Cord - embryology | Animals | Models, Biological | Body Patterning | Cell Differentiation | Mice | Stem Cells - cytology | Neural Tube - embryology | Chick Embryo | Neural Tube - cytology | Spinal cord | Poultry | Neurons | Developmental biology | Rodents | Index Medicus | Control | Specifications | Cells (biology) | Chicks | Tubes | Differentiation | Pools
Journal Article
Cell (Cambridge), ISSN 0092-8674, 2011, Volume 146, Issue 1, pp. 178 - 178.e1
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