Activity-dependent codevelopment of the corticospinal system and target interneurons in the cervical spinal cord.
about
What are the Best Animal Models for Testing Early Intervention in Cerebral Palsy?Harnessing activity-dependent plasticity to repair the damaged corticospinal tract in an animal model of cerebral palsyGait training facilitates central drive to ankle dorsiflexors in children with cerebral palsy.Differential joint-specific corticospinal tract projections within the cervical enlargementInvestigating the mechanism(s) underlying switching between states in bipolar disorderFunctional organization of motor cortex of adult macaque monkeys is altered by sensory loss in infancy.Functional motor recovery from motoneuron axotomy is compromised in mice with defective corticospinal projectionsDipolar cortico-muscular electrical stimulation: a novel method that enhances motor function in both - normal and spinal cord injured miceEarly intervention to improve hand function in hemiplegic cerebral palsy.Postnatal refinement of proprioceptive afferents in the cat cervical spinal cord.Motor Cortex Activity Organizes the Developing Rubrospinal System.A Comparative Study of Three Interneuron Types in the Rat Spinal Cord.Using motor behavior during an early critical period to restore skilled limb movement after damage to the corticospinal system during development.Participatory design in the development of an early therapy intervention for perinatal stroke.Competition with Primary Sensory Afferents Drives Remodeling of Corticospinal Axons in Mature Spinal Motor Circuits.Cortical stimulation causes long-term changes in H-reflexes and spinal motoneuron GABA receptors.Rapid and persistent impairments of the forelimb motor representations following cervical deafferentation in rats.Postnatal maturation of the red nucleus motor map depends on rubrospinal connections with forelimb motor pools.EphA4-mediated ipsilateral corticospinal tract misprojections are necessary for bilateral voluntary movements but not bilateral stereotypic locomotion.Reserve pool neuron transmitter respecification: Novel neuroplasticityPathophysiological mechanisms of impaired limb use and repair strategies for motor systems after unilateral injury of the developing brain.Activity-Based Therapies for Repair of the Corticospinal System Injured during Development.Postnatal development of a segmental switch enables corticospinal tract transmission to spinal forelimb motor circuits.Skilled Bimanual Training Drives Motor Cortex Plasticity in Children With Unilateral Cerebral Palsy.Formation of descending pathways mediating cortical command to forelimb motoneurons in neonatally hemidecorticated rats.Early Intensive Leg Training to Enhance Walking in Children With Perinatal Stroke: Protocol for a Randomized Controlled Trial.Motor system plasticity after unilateral injury in the developing brain.Developmental changes in intralimb coordination during spontaneous movements of human infants from 2 to 3 months of age.Co-development of proprioceptive afferents and the corticospinal tract within the cervical spinal cordHigher primate-like direct corticomotoneuronal connections are transiently formed in a juvenile subprimate mammal
P2860
Q26829589-FC9C7312-3B0A-4312-87F7-34BDFD1AD27DQ26995250-91D8651E-FD04-4C0B-A806-3F6EA9EB7193Q27303884-54BAB542-2175-4F76-85F2-A960D2B3191BQ27306852-E6FD6523-F4A3-4C8F-B50F-1F2EA2207DF0Q28084519-F8B937AB-B4F9-4AA9-845F-C5B396CD0EDFQ33733808-E4453BD1-4135-4F8A-A5FC-04DFD37592CAQ33864370-AB72B5D5-BA0D-402B-8FFF-49F1DD64ADA4Q34173822-4FEC1453-E6AF-4F7E-9D73-D0A71A1D0D28Q34840225-304CF754-BDD2-45C8-B174-AC921DA2D20EQ34917118-254B339D-C093-4C4A-B536-69EED5091264Q36106848-FB3CFC72-5300-4AC8-BC74-DB5407B10B3DQ36141344-334FC5B7-4349-4F9E-BEAB-0E49B3B2A078Q36174503-0B0D4D50-7C19-4E83-9E51-06168B992D84Q36257877-2CE6844E-6636-4E73-A130-F89CF8B8CC92Q36431995-BB6CC1BA-59B5-4F20-A08D-A9E49D32FBB1Q36533004-93BF804B-9B18-45AB-84F4-3A4A55371C9EQ37405662-1232E3B2-F94E-4803-9FC7-2D8572A1CD61Q37650255-7375D082-EC3E-4638-8B7C-53100457E4B6Q37698162-2011F806-E820-436C-BB34-B0CCE453C382Q37877227-228FCA78-6F8C-4A5E-8D69-8998B4BB0ADBQ38163020-99C62173-B4EF-44D7-9665-B02352DC2CD1Q38287936-513D4F44-A7F5-4A14-A44F-0214DEA17BA4Q39764558-647D2F74-6CE5-4571-BD16-3C9BD981C201Q41654948-11AF4B85-E3AC-4FFF-8D0A-9C83915D18F5Q42957419-C6AEE1BC-9582-4FC7-9674-DCA3E11D0E28Q47301968-11B07A30-630C-46EA-B7F1-C1A4FD054DB6Q48035851-F895A887-1444-4BD6-9D29-35F9AC94F888Q48808089-4D8F2705-D0A4-4FA9-A45B-E5360680B8B1Q56329800-A40F9441-CBB3-4CC4-B4CD-C6E9499D4656Q58589792-E2140D13-AB57-49F3-8FAD-209C7BE454AD
P2860
Activity-dependent codevelopment of the corticospinal system and target interneurons in the cervical spinal cord.
description
article científic
@ca
article scientifique
@fr
articolo scientifico
@it
artigo científico
@pt
bilimsel makale
@tr
scientific article published on July 2009
@en
vedecký článok
@sk
vetenskaplig artikel
@sv
videnskabelig artikel
@da
vědecký článek
@cs
name
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en-gb
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@nl
type
label
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en-gb
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@nl
prefLabel
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en-gb
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@nl
P2860
P1476
Activity-dependent codevelopme ...... s in the cervical spinal cord.
@en
P2093
Brandon Shulman
John H Martin
P2860
P304
P356
10.1523/JNEUROSCI.0735-09.2009
P407
P577
2009-07-01T00:00:00Z