| Q89073858 | A Laser-Guided Spinal Cord Displacement Injury in Adult Mice |
| Q30363270 | A Novel Closed-Head Model of Mild Traumatic Brain Injury Using Focal Primary Overpressure Blast to the Cranium in Mice. |
| Q33615581 | A bilateral cervical contusion injury model in mice: assessment of gripping strength as a measure of forelimb motor function |
| Q28389732 | A novel closed-body model of spinal cord injury caused by high-pressure air blasts produces extensive axonal injury and motor impairments |
| Q41686038 | A recoverable state of axon injury persists for hours after spinal cord contusion in vivo. |
| Q84780728 | A simple behavioral test for locomotor function after brain injury in mice |
| Q92035511 | A zebrafish drug screening platform boosts the discovery of novel therapeutics for spinal cord injury in mammals |
| Q28509307 | ADAM8 is selectively up-regulated in endothelial cells and is associated with angiogenesis after spinal cord injury in adult mice |
| Q33625945 | Aberrant sensory responses are dependent on lesion severity after spinal cord contusion injury in mice. |
| Q34347173 | Anatomical and functional outcomes following a precise, graded, dorsal laceration spinal cord injury in C57BL/6 mice. |
| Q45230631 | Anti-CD11d integrin antibody treatment restores normal serotonergic projections to the dorsal, intermediate, and ventral horns of the injured spinal cord. |
| Q55280839 | Apolipoprotein E Deficiency Exacerbates Spinal Cord Injury in Mice: Inflammatory Response and Oxidative Stress Mediated by NF-κB Signaling Pathway. |
| Q44481450 | Ascending sensory, but not other long-tract axons, regenerate into the connective tissue matrix that forms at the site of a spinal cord injury in mice |
| Q89746924 | Astrocytic YAP Promotes the Formation of Glia Scars and Neural Regeneration after Spinal Cord Injury |
| Q34101187 | Automatic segmentation of rodent spinal cord diffusion MR images |
| Q51828084 | Autonomic dysreflexia after spinal cord transection or compression in 129Sv, C57BL, and Wallerian degeneration slow mutant mice. |
| Q28592877 | Axonal regeneration and lack of astrocytic gliosis in EphA4-deficient mice |
| Q50010839 | Battery of Behavioral Tests Assessing General Locomotion, Muscular Strength, and Coordination in Mice |
| Q33724653 | Blood‐spinal cord barrier after spinal cord injury: Relation to revascularization and wound healing |
| Q90268811 | Bone Marrow-Derived Monocytes Drive the Inflammatory Microenvironment in Local and Remote Regions after Thoracic Spinal Cord Injury |
| Q48900936 | Cannabidiol-treated rats exhibited higher motor score after cryogenic spinal cord injury |
| Q33710820 | Comparison of immunopathology and locomotor recovery in C57BL/6, BUB/BnJ, and NOD-SCID mice after contusion spinal cord injury |
| Q34145761 | Compression induces acute demyelination and potassium channel exposure in spinal cord |
| Q34021372 | Connexin43, the major gap junction protein of astrocytes, is down-regulated in inflamed white matter in an animal model of multiple sclerosis |
| Q24645659 | Deficiency in complement C1q improves histological and functional locomotor outcome after spinal cord injury |
| Q47970704 | Deficiency of TREK-1 potassium channel exacerbates secondary injury following spinal cord injury in mice |
| Q36463599 | Degeneration of phrenic motor neurons induces long-term diaphragm deficits following mid-cervical spinal contusion in mice |
| Q33631758 | Development of a rat model of graded contusive spinal cord injury using a pneumatic impact device |
| Q33998588 | Diffusion tensor imaging as a predictor of locomotor function after experimental spinal cord injury and recovery. |
| Q33841235 | Diffusion tensor imaging at 3 hours after traumatic spinal cord injury predicts long-term locomotor recovery |
| Q37280456 | Don't fence me in: harnessing the beneficial roles of astrocytes for spinal cord repair. |
| Q42871813 | Efficacy of the coadministration of granulocyte colony-stimulating factor and stem cell factor in the activation of intrinsic cells after spinal cord injury in mice |
| Q37076332 | Elevated MMP-9 in the lumbar cord early after thoracic spinal cord injury impedes motor relearning in mice. |
| Q47403782 | Enhanced axonal growth into a spinal cord contusion injury site in a strain of mouse (129X1/SvJ) with a diminished inflammatory response. |
| Q33828872 | EphA4 deficient mice maintain astroglial-fibrotic scar formation after spinal cord injury |
| Q41685002 | Experimental animal models of neurogenic bladder dysfunction |
| Q34541109 | Experimental modelling of human spinal cord injury: a model that crosses the species barrier and mimics the spectrum of human cytopathology |
| Q39825563 | Expression of alpha5 integrin rescues fibronectin responsiveness in NT2N CNS neuronal cells |
| Q33618985 | Gait analysis in normal and spinal contused mice using the TreadScan system |
| Q51842937 | Gender-related differences in recovery of locomotor function after spinal cord injury in mice. |
| Q36274173 | Genetic approaches to autonomic dysreflexia. |
| Q30309882 | Genetic influences on secondary degeneration and wound healing following spinal cord injury in various strains of mice |
| Q52927068 | Ginsenoside Rg3 Improves Recovery from Spinal Cord Injury in Rats via Suppression of Neuronal Apoptosis, Pro-Inflammatory Mediators, and Microglial Activation. |
| Q37326075 | Griffonia simplicifolia isolectin B4 identifies a specific subpopulation of angiogenic blood vessels following contusive spinal cord injury in the adult mouse |
| Q44329443 | Hierarchically Ordered Porous and High-Volume Polycaprolactone Microchannel Scaffolds Enhanced Axon Growth in Transected Spinal Cords |
| Q33772565 | Impact speed does not determine severity of spinal cord injury in mice with fixed impact displacement |
| Q34539846 | Injured mice at the gym: review, results and considerations for combining chondroitinase and locomotor exercise to enhance recovery after spinal cord injury |
| Q41979994 | L1 cell adhesion molecule is essential for the maintenance of hyperalgesia after spinal cord injury. |
| Q38080805 | Locomotor recovery after spinal cord hemisection/contusion injures in bonnet monkeys: footprint testing--a minireview |
| Q27335334 | Longitudinal evaluation of an N-ethyl-N-nitrosourea-created murine model with normal pressure hydrocephalus |
| Q42444424 | Lumbar Myeloid Cell Trafficking into Locomotor Networks after Thoracic Spinal Cord Injury. |
| Q64054986 | Macrophage centripetal migration drives spontaneous healing process after spinal cord injury |
| Q40208826 | Mechanical Design and Analysis of a Unilateral Cervical Spinal Cord Contusion Injury Model in Non-Human Primates. |
| Q36485118 | Modulating Sema3A signal with a L1 mimetic peptide is not sufficient to promote motor recovery and axon regeneration after spinal cord injury. |
| Q31096336 | Monocyte recruitment and myelin removal are delayed following spinal cord injury in mice with CCR2 chemokine receptor deletion |
| Q43764737 | Neuroprotective effect of endogenous pituitary adenylate cyclase-activating polypeptide on spinal cord injury |
| Q36852642 | PINK1 deficiency attenuates astrocyte proliferation through mitochondrial dysfunction, reduced AKT and increased p38 MAPK activation, and downregulation of EGFR. |
| Q35795062 | Peripheral Nerve Transplantation Combined with Acidic Fibroblast Growth Factor and Chondroitinase Induces Regeneration and Improves Urinary Function in Complete Spinal Cord Transected Adult Mice |
| Q37251418 | Postinjury niches induce temporal shifts in progenitor fates to direct lesion repair after spinal cord injury |
| Q37718924 | Progesterone reduces secondary damage, preserves white matter, and improves locomotor outcome after spinal cord contusion |
| Q34916082 | Progranulin expression is upregulated after spinal contusion in mice. |
| Q28071816 | Rat models of spinal cord injury: from pathology to potential therapies |
| Q73497607 | Rats and mice exhibit distinct inflammatory reactions after spinal cord injury |
| Q37443479 | Re-expression of locomotor function after partial spinal cord injury. |
| Q28248202 | Reactive astrocytes protect tissue and preserve function after spinal cord injury |
| Q36481046 | Regeneration following spinal cord injury, from experimental models to humans: where are we? |
| Q33839440 | Regional heterogeneity in astrocyte responses following contusive spinal cord injury in mice |
| Q33773505 | Rescuing vasculature with intravenous angiopoietin-1 and alpha v beta 3 integrin peptide is protective after spinal cord injury |
| Q36965296 | Robust axonal growth and a blunted macrophage response are associated with impaired functional recovery after spinal cord injury in the MRL/MpJ mouse |
| Q36243960 | Role of IL-6 in spinal cord injury in a mouse model |
| Q36974841 | STAT3 is a critical regulator of astrogliosis and scar formation after spinal cord injury |
| Q36858361 | Schwann cell coculture improves the therapeutic effect of bone marrow stromal cells on recovery in spinal cord-injured mice. |
| Q81073902 | Semiquantitative assessment of hindlimb movement recovery without intervention in adult paraplegic mice |
| Q34147877 | Sensory stimulation prior to spinal cord injury induces post-injury dysesthesia in mice. |
| Q44216018 | Sexual dimorphism in the spontaneous recovery from spinal cord injury: a gender gap in beneficial autoimmunity? |
| Q48648817 | Spinal cord repair in neonatal rats: a correlation between axonal regeneration and functional recovery |
| Q51787596 | Spontaneous recovery of hindlimb movement in completely spinal cord transected mice: a comparison of assessment methods and conditions. |
| Q36893915 | Stem cell-based cell therapy for spinal cord injury |
| Q42961203 | Suppression of fibrotic scar formation promotes axonal regeneration without disturbing blood-brain barrier repair and withdrawal of leukocytes after traumatic brain injury |
| Q33956900 | TGF-alpha increases astrocyte invasion and promotes axonal growth into the lesion following spinal cord injury in mice. |
| Q33464903 | Tests to assess motor phenotype in mice: a user's guide |
| Q36862975 | The Ryk receptor is expressed in glial and fibronectin-expressing cells after spinal cord injury |
| Q37239354 | The impact of myelination on axon sparing and locomotor function recovery in spinal cord injury assessed using diffusion tensor imaging |
| Q44250286 | The increase of reactive oxygen species and their inhibition in an isolated guinea pig spinal cord compression model |
| Q44570605 | The use of flow cytometry to assess neutrophil infiltration in the injured murine spinal cord |
| Q57090611 | Toll-Like Receptor Signaling Is Critical for Wallerian Degeneration and Functional Recovery after Peripheral Nerve Injury |
| Q89619662 | Transcriptional Profiling of Non-injured Nociceptors After Spinal Cord Injury Reveals Diverse Molecular Changes |
| Q35635076 | Transgenic inhibition of Nogo-66 receptor function allows axonal sprouting and improved locomotion after spinal injury |
| Q27025285 | Translational spinal cord injury research: preclinical guidelines and challenges |
| Q64061191 | Traumatic Spinal Cord Injury: An Overview of Pathophysiology, Models and Acute Injury Mechanisms |
| Q59048171 | Treatment of a Spinal Cord Hemitransection Injury with Keratin Biomaterial Hydrogel Elicits Recovery and Tissue Repair |
| Q47828718 | Unique sensory and motor behavior in Thy1-GFP-M mice before and after spinal cord injury. |
| Q79080347 | Vaccination with dendritic cells pulsed with peptides of myelin basic protein promotes functional recovery from spinal cord injury |
| Q38170038 | Vascular Pathology as a Potential Therapeutic Target in SCI. |
| Q27863428 | p53 Regulates the neuronal intrinsic and extrinsic responses affecting the recovery of motor function following spinal cord injury. |