Functional recovery following traumatic spinal cord injury mediated by a unique polymer scaffold seeded with neural stem cells.
about
Human neural stem cells differentiate and promote locomotor recovery in an early chronic spinal cord injury NOD-scid mouse modelMatrices with compliance comparable to that of brain tissue select neuronal over glial growth in mixed cortical cultures.Directed migration of neural stem cells to sites of CNS injury by the stromal cell-derived factor 1alpha/CXC chemokine receptor 4 pathwaySelf-assembling nanofibers inhibit glial scar formation and promote axon elongation after spinal cord injuryBiomaterials approach to expand and direct differentiation of stem cellsNeural stem cells: involvement in adult neurogenesis and CNS repairBiomaterial Approaches to Enhancing Neurorestoration after Spinal Cord Injury: Strategies for Overcoming Inherent Biological ObstaclesNovel Stroke Therapeutics: Unraveling Stroke Pathophysiology and Its Impact on Clinical TreatmentsBiomaterial-based interventions for neuronal regeneration and functional recovery in rodent model of spinal cord injury: a systematic reviewTranslational spinal cord injury research: preclinical guidelines and challengesAnalysis of host-mediated repair mechanisms after human CNS-stem cell transplantation for spinal cord injury: correlation of engraftment with recoveryBiochemical Monitoring of Spinal Cord Injury by FT-IR Spectroscopy--Effects of Therapeutic Alginate Implant in Rat ModelsSyndromics: a bioinformatics approach for neurotrauma researchMesenchymal stem cell and regenerative medicine: regeneration versus immunomodulatory challengesBiotechnology in the treatment of sensorineural hearing loss: foundations and future of hair cell regeneration.Neural stem cells injected into the sound-damaged cochlea migrate throughout the cochlea and express markers of hair cells, supporting cells, and spiral ganglion cells.Drug-eluting microfibrous patches for the local delivery of rolipram in spinal cord repairEngraftment of nonintegrating neural stem cells differentially perturbs cortical activity in a dose-dependent manner.Enhanced cellular uptake and long-term retention of chitosan-modified iron-oxide nanoparticles for MRI-based cell tracking.Neurogenic and non-neurogenic functions of endogenous neural stem cells.Alginate composition effects on a neural stem cell-seeded scaffoldTransplantation of human neural precursor cells in Matrigel scaffolding improves outcome from focal cerebral ischemia after delayed postischemic treatment in rats.Plasmid releasing multiple channel bridges for transgene expression after spinal cord injuryTransplantation of ciliary neurotrophic factor-expressing adult oligodendrocyte precursor cells promotes remyelination and functional recovery after spinal cord injury.Constraining the Pluripotent Fate of Human Embryonic Stem Cells for Tissue Engineering and Cell Therapy - The Turning Point of Cell-Based Regenerative Medicine.Importance of oligodendrocyte protection, BBB breakdown and inflammation for remyelination.In vitro analysis of PNIPAAm-PEG, a novel, injectable scaffold for spinal cord repair.Multichannel polymer scaffold seeded with activated Schwann cells and bone mesenchymal stem cells improves axonal regeneration and functional recovery after rat spinal cord injury.The stem cell secretome and its role in brain repair.Ferulic Acid Improves Functional Recovery after Acute Spinal Cord Injury in Rats by Inducing Hypoxia to Inhibit microRNA-590 and Elevate Vascular Endothelial Growth Factor Expressions.Blockade of peroxynitrite-induced neural stem cell death in the acutely injured spinal cord by drug-releasing polymer.Transplantation of canine umbilical cord blood-derived mesenchymal stem cells in experimentally induced spinal cord injured dogsDynamic reassembly of peptide RADA16 nanofiber scaffoldAdvances in progenitor cell therapy using scaffolding constructs for central nervous system injury.Biomaterial design strategies for the treatment of spinal cord injuries.Transplantation of Nogo-66 receptor gene-silenced cells in a poly(D,L-lactic-co-glycolic acid) scaffold for the treatment of spinal cord injury.Neural stem cell transplantation in a double-layer collagen membrane with unequal pore sizes for spinal cord injury repair.Cultivation of human neural progenitor cells in a 3-dimensional self-assembling peptide hydrogelEstablishing a model spinal cord injury in the African green monkey for the preclinical evaluation of biodegradable polymer scaffolds seeded with human neural stem cells.Enhanced cellular responses of human bone marrow stromal cells cultured on pretreated surface with allogenic platelet-rich plasma.
P2860
Q21136171-DAA3F3DF-213D-486C-8F54-46D8EB08F6CFQ24541519-B77525FD-FEAE-49B1-844E-AA8A4AF405BBQ24558745-45F47832-CFBA-43F2-83B0-82A74FAB2F10Q24646208-DBD38803-FFEB-492E-8256-FD43B216F21FQ24647654-5EC17971-14B3-4EED-AFD8-B42813C2295CQ24656935-01DC06F6-C655-48A5-B63E-1BB50823BEE7Q26780494-5B56D629-7C93-41CF-9814-E06D9244E991Q26800178-E5D98B29-4DB3-4574-9E05-7B5CC7301E4AQ26998135-C053C44A-1468-44A3-A444-625592B5166EQ27025285-7A2D1310-7F18-4CBD-9455-1E7EBB015CABQ28475604-133C5EEA-252B-4685-B4E1-F15E58180590Q28550864-54833036-8701-4F8C-8FB5-3CE763AD1AFFQ28741573-0593058E-2AD8-43E5-99C4-F698F66C9160Q30009860-C8BDC100-0652-4B05-8AE0-D6EC70271107Q30472053-7A3E4D15-ED5F-4DCD-B703-87CC7B857305Q30493182-FDB31C20-5E39-49C8-8B6E-6E5AC20B3A0BQ30541073-428A9A13-23C5-456E-AC05-59513460B6EEQ30559499-1F62F9C7-8FA3-48CA-8B0F-7E2947CCD30CQ30560823-11B022AB-8242-4426-AFC8-4FD0479842DCQ33569259-03C976D8-3730-4975-91AC-5E5196E15BFFQ33643851-40D38C46-BC81-4D1D-9CA1-92A9A1C3B1BEQ33699018-D647FB57-231B-441E-A81A-4A3E608D17B3Q33713237-2D71E1F3-7302-4C1B-BCBA-E75BE93D2608Q33720720-7662A320-9494-4D14-BFF7-E5B36EC2CBF9Q33732794-C0C877D7-EE50-4992-8C9C-89A02E54EF90Q33740931-5D7F0107-D8AD-42B4-B962-8E8C973125A9Q33750781-036D3DBC-E44E-4A9D-8D27-165464A9F3B1Q33759973-4F03A8FB-292B-4B12-AE3C-5BAD3B71FA9BQ33771698-6F6DC1E4-B174-4777-8A00-26BDEF14D324Q33774850-3493B39F-A382-4846-B73C-D27FE9599C66Q33805034-44A4FADB-3F3A-4F72-8AC6-29B37B2FCB1EQ33843806-1AF857CF-70B0-48C7-996E-267BAF9D8765Q33853794-649821A1-ED59-47BB-9767-812AF69BE3D3Q33870573-FF4D8810-1375-467E-80B8-2583CED68383Q34076638-F5CEFF6D-F3C0-4188-9D08-8F5F224E5F31Q34095317-B8809E31-0244-4C83-8CC6-D6D97DCABB73Q34096253-C9D14837-425A-4E3B-947A-55BAF8E2C54AQ34132752-0A5131E4-2A3B-49E7-9218-68ECB808A877Q34149632-6E9C79CC-BEE9-4807-A644-942EA4504821Q34157503-23107155-0E37-4B5E-842B-61C80E711E24
P2860
Functional recovery following traumatic spinal cord injury mediated by a unique polymer scaffold seeded with neural stem cells.
description
2002 nî lūn-bûn
@nan
2002 թուականի Փետրուարին հրատարակուած գիտական յօդուած
@hyw
2002 թվականի փետրվարին հրատարակված գիտական հոդված
@hy
2002年の論文
@ja
2002年論文
@yue
2002年論文
@zh-hant
2002年論文
@zh-hk
2002年論文
@zh-mo
2002年論文
@zh-tw
2002年论文
@wuu
name
Functional recovery following ...... seeded with neural stem cells.
@ast
Functional recovery following ...... seeded with neural stem cells.
@en
type
label
Functional recovery following ...... seeded with neural stem cells.
@ast
Functional recovery following ...... seeded with neural stem cells.
@en
prefLabel
Functional recovery following ...... seeded with neural stem cells.
@ast
Functional recovery following ...... seeded with neural stem cells.
@en
P2093
P2860
P356
P1476
Functional recovery following ...... seeded with neural stem cells.
@en
P2093
Erin B Lavik
Evan Y Snyder
Jitka Ourednik
Kook I Park
Robert Langer
Yang D Teng
P2860
P304
P356
10.1073/PNAS.052678899
P407
P577
2002-02-26T00:00:00Z