Whole limb kinematics are preferentially conserved over individual joint kinematics after peripheral nerve injury
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Don't break a leg: running birds from quail to ostrich prioritise leg safety and economy on uneven terrain.High-speed X-ray video demonstrates significant skin movement errors with standard optical kinematics during rat locomotion.Effect of slope and sciatic nerve injury on ankle muscle recruitment and hindlimb kinematics during walking in the rat.Misdirection of regenerating axons and functional recovery following sciatic nerve injury in rats.Rules to limp by: joint compensation conserves limb function after peripheral nerve injuryMotor adaptation to prosthetic cycling in people with trans-tibial amputation.Stabilization of cat paw trajectory during locomotionPerspectives on human-human sensorimotor interactions for the design of rehabilitation robotsEffects of a foot placement constraint on use of motor equivalence during human hopping.Effect of axon misdirection on recovery of electromyographic activity and kinematics after peripheral nerve injuryShort-term motor compensations to denervation of feline soleus and lateral gastrocnemius result in preservation of ankle mechanical output during locomotionShort-term effects of muscular denervation and fasciotomy on global limb variables during locomotion in the decerebrate cat.Locomotor control of limb force switches from minimal intervention principle in early adaptation to noise reduction in late adaptationPermanent central synaptic disconnection of proprioceptors after nerve injury and regeneration. II. Loss of functional connectivity with motoneurons.Short-term effect of crural fasciotomy on kinematic variability and propulsion during level locomotionUnexpected Fascicle Length Changes In Denervated Feline Soleus Muscle During Stance Phase Of Walking.Effects of treadmill training on functional recovery following peripheral nerve injury in rats.Increased intensity and reduced frequency of EMG signals from feline self-reinnervated ankle extensors during walking do not normalize excessive lengtheningChondroitinase ABC reduces time to muscle reinnervation and improves functional recovery after sciatic nerve transection in rats.Humans robustly adhere to dynamic walking principles by harnessing motor abundance to control forces.Locomotor impact of beneficial or nonbeneficial H-reflex conditioning after spinal cord injury.Self-reinnervated muscles lose autogenic length feedback, but intermuscular feedback can recover functional connectivity.Upslope treadmill exercise enhances motor axon regeneration but not functional recovery following peripheral nerve injuryThe nociceptive withdrawal reflex does not adapt to joint position change and short-term motor practiceTime course of functional recovery during first three months after surgical transection and repair of nerves to feline soleus and lateral gastrocnemius muscles.A decerebrate adult mouse model for examining the sensorimotor control of locomotion.Why New Spinal Cord Plasticity Does Not Disrupt Old Motor Behaviors.VGLUT1 synapses and P-boutons on regenerating motoneurons after nerve crush.Effects of gradual versus sudden training on the cognitive demand required while learning a novel locomotor task.The negotiated equilibrium model of spinal cord function.Adaptation after vastus lateralis denervation in rats demonstrates neural regulation of joint stresses and strainsProgressive adaptation of whole-limb kinematics after peripheral nerve injury
P2860
Q28654211-A442C9DA-59E1-4F00-88A4-053B807E86E0Q30492971-55EC7190-592B-4EEF-A9C9-C6133BA3F6BCQ30498231-1ACB5645-4502-42CC-AFA0-4C961E345569Q30541219-5E91C1CA-EF84-46F2-BF6A-31D2C494B9A4Q30575154-599497E7-F1A9-4D5C-B95C-FA7F799E9524Q33825222-B4B11B33-BBC8-42C5-9737-F36CD546EE3AQ34063209-7F704A26-27EC-419C-B8BC-F6AE371D72B9Q34340074-9B86DFEE-E338-4B41-9E1E-B1A43BAE2918Q34920051-F240416B-B99D-4432-BCA5-8EF196AD5972Q35082244-28BAC3E8-0EEF-43F7-8898-338C39AD57EAQ35082247-B3D5FF6D-DF5F-4394-9546-C7CEA691329BQ35082250-23595D1D-B029-4BA9-B44A-41966822DBC7Q35138429-C9807EC6-8B95-438B-9FBA-26DBEF6CBEF1Q35543907-E72BA0D6-A7A9-47D4-B821-7BF44180096BQ35641358-4AC76416-D925-46D8-9811-1CE0CFB69DD9Q36346175-D5E4ABFA-97C3-48BB-9FF0-1638895DB04FQ36924073-6C2AA086-C465-4351-A2F5-693A168D6ABBQ37041625-26BC49C3-D381-4955-B17E-836C75C53DB6Q37175978-A256AAE1-BB76-4B4E-B59F-F9DDA53B9578Q37435540-4759F145-83E7-45F9-89E1-3E67DED4C978Q37629754-8B506ACF-52BA-4769-99FD-9F21722946CEQ39680701-4F6AC1B9-61AA-4CBF-936F-876D49AF9E9CQ41207501-C288C9CC-F734-421B-AC7F-EC03E452ABE2Q41862531-F84BBFF3-1084-4AB0-BB7E-FA417367CD7AQ46092791-F00E024B-642D-4A55-970F-C75591B4537AQ46652282-BE2D9D6F-5137-4DAE-B271-BAA207838679Q47687117-B0579278-144F-4400-B3F8-F977B579D83FQ48096901-2A306F6B-0515-49EE-86ED-4E016B05FD4FQ50729627-57FA29DE-8DF7-4BCB-8B3C-7926AC5AF42EQ52583911-5519D3CE-179F-4B16-B726-5F43F853E515Q58766690-684D3688-AA31-4AD4-825B-4BAF1B8BB392Q58776205-5B6DC5D1-1405-4238-A528-81B75B7DCCBF
P2860
Whole limb kinematics are preferentially conserved over individual joint kinematics after peripheral nerve injury
description
2009 nî lūn-bûn
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2009年の論文
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2009年学术文章
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2009年学术文章
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2009年学术文章
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2009年学术文章
@zh-my
2009年学术文章
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name
Whole limb kinematics are pref ...... after peripheral nerve injury
@en
Whole limb kinematics are pref ...... after peripheral nerve injury.
@nl
type
label
Whole limb kinematics are pref ...... after peripheral nerve injury
@en
Whole limb kinematics are pref ...... after peripheral nerve injury.
@nl
prefLabel
Whole limb kinematics are pref ...... after peripheral nerve injury
@en
Whole limb kinematics are pref ...... after peripheral nerve injury.
@nl
P2093
P2860
P356
P1476
Whole limb kinematics are pref ...... after peripheral nerve injury
@en
P2093
Arick G Auyang
John P Scholz
T Richard Nichols
Young-Hui Chang
P2860
P304
P356
10.1242/JEB.033886
P577
2009-11-01T00:00:00Z