Delayed transplantation of adult neural precursor cells promotes remyelination and functional neurological recovery after spinal cord injury.
about
Human neural stem cells differentiate and promote locomotor recovery in an early chronic spinal cord injury NOD-scid mouse modelSelf-assembling nanofibers inhibit glial scar formation and promote axon elongation after spinal cord injuryRecent advances in managing a spinal cord injury secondary to traumaInduced Pluripotent Stem Cell Therapies for Cervical Spinal Cord InjuryMyelin damage and repair in pathologic CNS: challenges and prospectsThe Potential for iPS-Derived Stem Cells as a Therapeutic Strategy for Spinal Cord Injury: Opportunities and ChallengesPotential role of stem cells in severe spinal cord injury: current perspectives and clinical dataRestoration of sensorimotor functions after spinal cord injuryAnalysis of host-mediated repair mechanisms after human CNS-stem cell transplantation for spinal cord injury: correlation of engraftment with recoverySyndromics: a bioinformatics approach for neurotrauma researchNeural stem/progenitor cell properties of glial cells in the adult mouse auditory nerve.Transplantation of human neural stem cells transduced with Olig2 transcription factor improves locomotor recovery and enhances myelination in the white matter of rat spinal cord following contusive injury.Transplantation of human glial restricted progenitors and derived astrocytes into a contusion model of spinal cord injury.Two-photon imaging of remyelination of spinal cord axons by engrafted neural precursor cells in a viral model of multiple sclerosis.Transplantation of neural stem cells clonally derived from embryonic stem cells promotes recovery after murine spinal cord injury.Cell therapy for spinal cord injury informed by electromagnetic waves.Delayed administration of a bio-engineered zinc-finger VEGF-A gene therapy is neuroprotective and attenuates allodynia following traumatic spinal cord injury.Histological and functional benefit following transplantation of motor neuron progenitors to the injured rat spinal cordComparison of immunopathology and locomotor recovery in C57BL/6, BUB/BnJ, and NOD-SCID mice after contusion spinal cord injuryCyclosporin A increases recovery after spinal cord injury but does not improve myelination by oligodendrocyte progenitor cell transplantation.Transplantation of ciliary neurotrophic factor-expressing adult oligodendrocyte precursor cells promotes remyelination and functional recovery after spinal cord injury.Safety of neural stem cell transplantation in patients with severe traumatic brain injurySwim training initiated acutely after spinal cord injury is ineffective and induces extravasation in and around the epicenter.Controlled release of neurotrophin-3 and platelet-derived growth factor from fibrin scaffolds containing neural progenitor cells enhances survival and differentiation into neurons in a subacute model of SCI.Effects of dibutyryl cyclic-AMP on survival and neuronal differentiation of neural stem/progenitor cells transplanted into spinal cord injured rats.Neuro-immune interactions of neural stem cell transplants: from animal disease models to human trials.Chondroitinase and growth factors enhance activation and oligodendrocyte differentiation of endogenous neural precursor cells after spinal cord injury.Tissue-engineered fibrin scaffolds containing neural progenitors enhance functional recovery in a subacute model of SCIThe generation of definitive neural stem cells from PiggyBac transposon-induced pluripotent stem cells can be enhanced by induction of the NOTCH signaling pathway.Survival, Differentiation, and Migration of High-Purity Mouse Embryonic Stem Cell-derived Progenitor Motor Neurons in Fibrin Scaffolds after Sub-Acute Spinal Cord InjuryExamination of the combined effects of chondroitinase ABC, growth factors and locomotor training following compressive spinal cord injury on neuroanatomical plasticity and kinematics.Neural progenitor cell implants modulate vascular endothelial growth factor and brain-derived neurotrophic factor expression in rat axotomized neuronsLaminin α1 is essential for mouse cerebellar developmentGrafting of human bone marrow stromal cells into spinal cord injury: a comparison of delivery methods.Genome-wide gene expression profiling of stress response in a spinal cord clip compression injury modelChronic oligodendrogenesis and remyelination after spinal cord injury in mice and rats.Oligodendrocyte fate after spinal cord injury.Sensory afferents regenerated into dorsal columns after spinal cord injury remain in a chronic pathophysiological state.Stem cell therapy and curcumin synergistically enhance recovery from spinal cord injury.A systematic review of cellular transplantation therapies for spinal cord injury.
P2860
Q21136171-CC85A4D5-392A-490D-9254-E6CA4DBECD60Q24646208-5BD80367-E762-4D9D-8A68-14136A9A38A9Q26745909-F06873DD-6BBF-472D-8A14-8EF9B7FE10EDQ26748907-00642FC2-67B2-4BA2-98C0-AF7E643F161DQ26797407-B724CA05-465D-42C9-8A11-ACCEFC217C1BQ26860309-AF7061FC-2C7F-4A71-B18D-79E956AD1EDFQ26996685-D18C1AF6-6883-4876-8E92-BC2C85D10C60Q26999051-0F3D74C1-B186-4FEE-A448-A609AE3ED964Q28475604-395F0429-ECAB-4B5D-BABF-2B52FADA0FDCQ28741573-1B8341EF-9C65-495D-B502-DEE1A54C1B06Q30404411-B5736558-0FBF-4A2D-9A49-7CE2DEBED3B2Q30490845-38606E87-E693-4C3E-8B8C-AACE45EEFB0FQ30499309-5AAF4B9B-D37E-4833-B26B-BBBC603F84A7Q30580359-07C44D80-0282-4775-8941-20CA97F4B364Q30610413-48B1656E-78EC-4CE9-A832-F8A66059F8A4Q33363830-9EA4FFCA-2ECF-4578-8788-11E81910FAD4Q33638148-21D22EB9-17A9-400A-8104-76A20FF464F7Q33649636-774B491B-A1F6-4CD2-83F2-B802615949EDQ33710820-43EBA6A5-C637-4793-916C-F08708401E7FQ33715129-D7B640E0-582E-44D5-9C0A-1E5F08E1E148Q33720720-99D9E631-A85E-4068-95B7-EB20858F13AEQ33745122-23A043F9-8C9A-4617-9178-B113149E8E86Q33767279-31A02FEF-D9BA-4C5E-B11D-53CFC3257A1AQ33774561-045BC79C-6414-4663-B03B-2ECFDB83AC79Q33955348-E66EB1AC-45D3-4921-9717-F3FE3F8C290AQ34172960-05BB2A6B-F6A1-4EBF-BEE3-D46981F7DCD2Q34282030-78EDFC2F-3143-4C0F-9906-74873286C139Q34285940-487A0B21-107A-421B-AE97-54811B9692AEQ34293770-634F9E14-2275-4311-9C6A-D4A44C1D96A4Q34385981-4CDF5F7B-638D-43F3-905F-2E17BB1D5FB6Q34414830-9267DE25-98B6-4CE2-B493-7EEBB65C856FQ34563233-59FBC5BD-BD61-4581-8C1F-D3BBF58CAE7AQ34632931-3617DD60-7A7B-4700-96B3-EF2400AE1E99Q34776506-E8DFA1BD-9615-45B6-A66A-97AC1F332F18Q34975709-011629E4-B9CA-42B5-A24F-EC9D4A955A25Q34989976-0C36E9BE-BF19-4DDB-B4AE-B4C08CAC0653Q35006477-F56BF9A2-71F3-4A05-8D00-AA8278405CB3Q35012930-B75EE563-5FF2-4A4E-A427-158BCC0AE11FQ35099723-C7B539C2-8D8F-4294-82CF-C8927F1CA6A0Q35127777-DE033714-FC53-45EE-BE37-40C7C9453E7D
P2860
Delayed transplantation of adult neural precursor cells promotes remyelination and functional neurological recovery after spinal cord injury.
description
2006 nî lūn-bûn
@nan
2006 թուականի Մարտին հրատարակուած գիտական յօդուած
@hyw
2006 թվականի մարտին հրատարակված գիտական հոդված
@hy
2006年の論文
@ja
2006年学术文章
@wuu
2006年学术文章
@zh-cn
2006年学术文章
@zh-hans
2006年学术文章
@zh-my
2006年学术文章
@zh-sg
2006年學術文章
@yue
name
Delayed transplantation of adu ...... very after spinal cord injury.
@ast
Delayed transplantation of adu ...... very after spinal cord injury.
@en
Delayed transplantation of adu ...... very after spinal cord injury.
@nl
type
label
Delayed transplantation of adu ...... very after spinal cord injury.
@ast
Delayed transplantation of adu ...... very after spinal cord injury.
@en
Delayed transplantation of adu ...... very after spinal cord injury.
@nl
prefLabel
Delayed transplantation of adu ...... very after spinal cord injury.
@ast
Delayed transplantation of adu ...... very after spinal cord injury.
@en
Delayed transplantation of adu ...... very after spinal cord injury.
@nl
P50
P1476
Delayed transplantation of adu ...... overy after spinal cord injury
@en
P2093
Cindi M Morshead
P304
P356
10.1523/JNEUROSCI.4184-05.2006
P407
P577
2006-03-01T00:00:00Z