about
Physiological types and histochemical profiles in motor units of the cat gastrocnemiusTwo-step, predictive, isometric force model tested on data from human and rat muscles.Novel patterns of functional electrical stimulation have an immediate effect on dorsiflexor muscle function during gait for people poststroke.Extra forces evoked during electrical stimulation of the muscle or its nerve are generated and modulated by a length-dependent intrinsic property of muscle in humans and catsMuscular, skeletal, and neural adaptations following spinal cord injury.Neuromuscular fatigue is not different between constant and variable frequency stimulation.The tetanic depression in fast motor units of mammalian skeletal muscle can be evoked by lengthening of one initial interpulse interval.Single-motor-unit discharge characteristics in human lumbar multifidus muscle.Predicting muscle forces of individuals with hemiparesis following strokeActivation properties of trigeminal motoneurons in participants with and without bruxism.Quadriceps rate of force development affects gait and function in people with knee osteoarthritis.Microstimulation of single human motor axons in the toe extensors: force production during long-lasting trains of irregular and regular stimuli.Fast oscillations during gasping and other non-eupneic respiratory behaviors: Clues to central pattern generation.Towards physics of neural processes and behavior.Interaction of posttetanic potentiation and the catchlike property in mouse skeletal muscle.The Effects of K(+) Channel Blockade on Eccentric and Isotonic Twitch and Fatiguing Contractions in situDoublet stimulation increases Ca2+ binding to troponin C to ensure rapid force development in skeletal muscle.ET-1 receptor gene expression and distribution in L1 and L2 cells from hypertensive sheep pulmonary artery.Improvement of diaphragm and limb muscle isotonic contractile performance by K+ channel blockade.Metabolic costs of force generation for constant-frequency and catchlike-inducing electrical stimulation in human tibialis anterior muscle.Respiratory muscle injury, fatigue and serum skeletal troponin I in rat.Oscillations in motor unit discharge are reflected in the low-frequency component of rectified surface EMG and the rate of change in force.Contribution of central vs. peripheral factors to the force loss induced by passive stretch of the human plantar flexors.Doublet potentiation in the triceps surae is limited by series compliance and dynamic fascicle behavior.Fuzzy FES controller using cycle-to-cycle control for repetitive movement training in motor rehabilitation. Experimental tests with wireless system.Role of calcium conductances on spike afterpotentials in rat trigeminal motoneurons.Comparison of the ballistic contractile responses generated during microstimulation of single human motor axons with brief irregular and regular stimuli.Selective loss of high-frequency oscillations in phrenic and hypoglossal activity in the decerebrate rat during gasping.Interleaved neuromuscular electrical stimulation: Motor unit recruitment overlap.Effects of electrical stimulation pattern on quadriceps force production and fatigue.The afterhyperpolarization conductance exerts the same control over the gain and variability of motoneurone firing in anaesthetized cats.The neuromuscular transform: the dynamic, nonlinear link between motor neuron firing patterns and muscle contraction in rhythmic behaviors.Associations between force and fatigue in fast-twitch motor units of a cat hindlimb muscle.
P2860
Q24538978-952DB30D-586A-4A4A-926B-865AF8E355E2Q31960213-688AC722-55C7-4D5E-817D-0266193B9487Q33576195-90AD0032-E3AD-4752-934B-8590A9066DE0Q33970427-635C6E6B-93DD-4210-B6E6-24ABD46E9602Q34524823-EA71BE85-E05F-41CB-A96D-DC0107797F6AQ35083468-845FA2E8-0DBD-4E71-807D-7833A1B53F48Q35205860-73DF9FF0-C5EC-40DE-8885-0895EB81464CQ36496947-DF45B276-571F-4D99-ABA1-A8D5424CB89FQ36539286-25EED516-8213-41F3-BE34-E486FFB37131Q37441454-10790047-341B-465F-A876-C0B6A32E3401Q37588559-85080438-9266-4C66-B93A-603AD247E791Q37670226-823B1200-D381-4EBD-8071-C5298C7A4678Q38094820-19F41256-3D5E-4BD6-8BA5-8AE54DC28CDBQ38920618-183CAEF7-CC87-42C5-90BD-3C5CDFAB1B0AQ40070476-D2DB86C8-F5DE-4C75-903E-BE5A9B15B600Q41820595-9504F4A9-7D6A-48BB-B713-BB0C7EFC50E5Q42027727-746C5316-D5A0-4B9D-BE3E-91A379919F7DQ42522263-A20D9E6B-A909-4107-B9EF-B1B73DD5D3D6Q42917344-4EAA104A-A63B-425D-B276-C157C03AFA28Q43900150-1C3C372C-0F74-4C72-8BC8-277212869705Q44691691-11D8DEE2-1033-49E2-9D6C-277BADC46991Q46139044-01F0D0A2-072D-457D-8ECE-F505F1EEC16EQ46917500-BFAB4C6E-0F89-47B7-94E1-DB5664A01680Q48149067-964C2C9E-9D0F-41F8-A26D-D881AE2FC9FEQ48628326-030D0065-416F-4A4C-8D7B-CB73317E33B6Q48692909-E466CD27-46C0-422D-A56D-1A67A0E71B22Q51097955-E102C728-A477-4800-8BD4-04049606AE25Q51167560-8BE74FD7-1860-4AB2-B576-9252C9E6F790Q51246830-148D28C1-78DA-439A-AA4F-AC6D1441FFC2Q51747835-850491BC-D722-4582-891A-E44D2D525846Q51934618-9E137648-ADD2-4843-8DB5-9D3D82E6FE7AQ52893645-9674FB68-FC85-40D2-A3B1-C38DDE17DF4EQ53880809-0502B76B-E05E-4F64-9671-A241E31061CE
P2860
description
1970 nî lūn-bûn
@nan
1970年の論文
@ja
1970年学术文章
@wuu
1970年学术文章
@zh
1970年学术文章
@zh-cn
1970年学术文章
@zh-hans
1970年学术文章
@zh-my
1970年学术文章
@zh-sg
1970年學術文章
@yue
1970年學術文章
@zh-hant
name
Catch property in single mammalian motor units.
@en
Catch property in single mammalian motor units.
@nl
type
label
Catch property in single mammalian motor units.
@en
Catch property in single mammalian motor units.
@nl
prefLabel
Catch property in single mammalian motor units.
@en
Catch property in single mammalian motor units.
@nl
P2093
P1433
P1476
Catch property in single mammalian motor units.
@en
P2093
P304
P356
10.1126/SCIENCE.168.3927.122
P407
P577
1970-04-01T00:00:00Z