Strength training reduces intracortical inhibition. - Wikidata - awgldk - TriplyDB

Strength training reduces intracortical inhibition.

Strength training reduces intracortical inhibition.

http://www.wikidata.org/entity/Q48490830

about

Tendon neuroplastic training: changing the way we think about tendon rehabilitation: a narrative review.Differences in supraspinal and spinal excitability during various force outputs of the biceps brachii in chronic- and non-resistance trained individuals The power of the mind: the cortex as a critical determinant of muscle strength/weakness Age-related weakness of proximal muscle studied with motor cortical mapping: a TMS study The effects of a protein enriched diet with lean red meat combined with a multi-modal exercise program on muscle and cognitive health and function in older adults: study protocol for a randomised controlled trial.Concurrent neuromechanical and functional gains following upper-extremity power training post-stroke.Short-interval intracortical inhibition is not affected by varying visual feedback in an isometric task in biceps brachii muscle.Weaker Seniors Exhibit Motor Cortex Hypoexcitability and Impairments in Voluntary Activation Neurophysiological correlates of aging-related muscle weakness.Enhanced Corticospinal Excitability and Volitional Drive in Response to Shortening and Lengthening Strength Training and Changes Following Detraining.Tibialis Anterior muscle coherence during controlled voluntary activation in patients with spinal cord injury: diagnostic potential for muscle strength, gait and spasticity.Resting and active motor thresholds versus stimulus-response curves to determine transcranial magnetic stimulation intensity in quadriceps femoris.Isometric exercise induces analgesia and reduces inhibition in patellar tendinopathy.Corticomotor Excitability is Increased Following an Acute Bout of Blood Flow Restriction Resistance Exercise.The neuromechanical adaptations to Achilles tendinosis.Corticospinal responses following strength training: a systematic review and meta-analysis.Elevated corticospinal excitability in patellar tendinopathy compared with other anterior knee pain or no pain.Heavy-resistance exercise-induced increases in jump performance are not explained by changes in neuromuscular function.Eight weeks of local vibration training increases dorsiflexor muscle cortical voluntary activation.Resistance Exercise Reduces Seizure Occurrence, Attenuates Memory Deficits and Restores BDNF Signaling in Rats with Chronic Epilepsy.Emerging evidence that exercise-induced improvements in muscular strength are partly due to adaptations in the brain.The corticospinal responses of metronome-paced, but not self-paced strength training are similar to motor skill training.Effects of vitamin D supplementation on neuroplasticity in older adults: a double-blinded, placebo-controlled randomised trial.Anodal-tDCS applied during unilateral strength training increases strength and corticospinal excitability in the untrained homologous muscle.The Time-Course of Acute Changes in Corticospinal Excitability, Intra-Cortical Inhibition and Facilitation Following a Single-Session Heavy Strength Training of the Biceps Brachii.Adaptations in corticospinal excitability and inhibition are not spatially confined to the agonist muscle following strength training.

P2860

Q27320080-87E904C9-D274-4490-BAED-A01C2DDED9BE Q28539185-E3D21DA7-D62B-41C5-B891-4FD611FC23DA Q34726965-59324765-4397-4D30-B0DC-FC88CA7B07E5 Q35107157-F942998A-BEFC-4603-B6FB-765F2D6DDBE1 Q35930203-105A723C-AECD-4D19-B053-1AEBA61ECFBA Q36581461-1EA99B4F-6E23-40AC-8691-A802C7AEF00A Q36666728-AC4B3702-B0EA-4DB4-B5A0-86970726E163 Q36885331-369F7E1C-1451-456C-9081-6A649F9F35EA Q37441246-0C2F76E7-305C-4A1A-AE4C-B6B13FFED05B Q37627125-C9480DAA-D156-433A-8FB0-649E918FE28C Q37681546-166DD7C9-6DAE-4DD5-AA5C-73E172C7C03E Q38619752-2CB9D416-0434-48C8-AEBD-B29448044BAC Q39189213-B0942EC7-D570-4CCF-B7F5-B510FF888F13 Q42265668-9F062AA2-4A6D-4004-8B61-B93FACAF9281 Q46808151-7E3B02F7-3713-4934-AE9F-6FB481C8DAD3 Q47881366-CF507056-E069-4D6B-BA45-68720E23C756 Q48007893-35E1EE35-6311-4F9D-97D1-CD80694DA602 Q48044830-ABCCA11E-5D44-4781-BFD5-130259391980 Q48309779-AE09439C-FD64-49F7-ABA1-C358FC38FA86 Q48361638-A68F18AD-79C4-4A61-B5B8-E3579877B6F2 Q48390414-A0DB5140-32BF-45B6-9F9B-348F7C231F0D Q48525378-04E90E59-5488-4F58-8964-3C6C4F53A5F9 Q48595978-1BD31CBC-8950-40D6-8A95-15A82E41E43C Q48709116-0C81740A-E258-4FF5-9271-B678E46BEEF6 Q51003510-B7C43E0F-4C51-4496-93BF-D6DBD4A40AE9 Q52874999-B6D3DE6A-3CB8-4807-BD20-D8FB21BCA9AC

P2860

Strength training reduces intracortical inhibition.

http://www.wikidata.org/entity/Q48490830

description

2012 nî lūn-bûn

@nan

2012年の論文

@ja

2012年学术文章

@wuu

2012年学术文章

@zh

2012年学术文章

@zh-cn

2012年学术文章

@zh-hans

2012年学术文章

@zh-my

2012年学术文章

@zh-sg

2012年學術文章

@yue

2012年學術文章

@zh-hant

name

Strength training reduces intracortical inhibition.

@en

Strength training reduces intracortical inhibition.

@nl

type

label

Strength training reduces intracortical inhibition.

@en

Strength training reduces intracortical inhibition.

@nl

prefLabel

Strength training reduces intracortical inhibition.

@en

Strength training reduces intracortical inhibition.

@nl

P1433

Q48490830-DE98EC8E-5D6C-489F-B90E-1B377899C561

P1476

Q48490830-12049F24-25B9-49C7-9EDC-299381478991

P2093

Q48490830-5BB406C5-A352-48A6-A534-421E7FFFFC71

Q48490830-ABAC6226-ECB8-42F8-8C0B-D9DA581CFAD5

Q48490830-E83D1DB2-B4A7-4280-AC63-A14C70338F9F

P2860

Q48490830-06F00FD2-8F18-4D0E-8747-452EDE0B1A0F

Q48490830-0C5964F4-CC50-44A0-A976-1CD4B43C76C1

Q48490830-0E7593BC-1365-4907-BB13-68C48A4AAB4F

Q48490830-183CE139-0B3C-4A8B-B04B-2C8ECA6E5298

Q48490830-29D929B4-D2F2-4833-A958-D74F0FD8A9A7

Q48490830-2EE57D60-8B84-4F10-A912-9777F20237D9

Q48490830-3A22E2D2-DCA1-4B2E-8A80-4C4C02FBE14E

Q48490830-40AE5F72-5958-40A9-B57E-1D1702E95ADC

Q48490830-4C388856-0143-4D0B-98F7-0DC07997270A

Q48490830-4F67EF78-CFA0-4CC1-B521-B7B0864678F6

P304

Q48490830-01590B88-3839-4C63-9588-8F490F9BA8DE

P31

Q48490830-56D756B1-FF50-4057-BCCC-DFC6880B0A74

P356

Q48490830-219BCF59-20B1-409B-AA9E-D184960B1631

P433

Q48490830-0FED7487-FF7C-4605-805E-4D46089D1B2D

P478

Q48490830-6CFB0C47-7928-4A01-87C1-09E1289E0ED8

P577

Q48490830-50DBDAEB-7FC3-4505-87B7-66DC1ADBBEF5

P5875

Q48490830-DA0C2E9C-B122-4001-9DED-99D8D8F36141

P698

Q48490830-CD7B9516-8499-46EE-9D3C-54948E4A7EEF

P356

J.1748-1716.2012.02454.X

P1433

Acta Physiologica

P1476

Strength training reduces intracortical inhibition.

@en

P2093

A J Pearce

http://www.w3.org/2001/XMLSchema#string

A T Weier

http://www.w3.org/2001/XMLSchema#string

D J Kidgell

http://www.w3.org/2001/XMLSchema#string

P2860

Corticocortical inhibition in human motor cortex

Neural adaptations to strength training: moving beyond transcranial magnetic stimulation and reflex studies.

Transcranial magnetic stimulation and the human brain.

Neural adaptation to resistance training: changes in evoked V-wave and H-reflex responses.

The sites of neural adaptation induced by resistance training in humans.

Combinations of muscle synergies in the construction of a natural motor behavior.

Neural adaptations to resistance training: implications for movement control.

Neural adaptations to resistive exercise: mechanisms and recommendations for training practices.

Mechanisms of use-dependent plasticity in the human motor cortex

Training principles: evaluation of modes and methods of resistance training--a coaching perspective.

P304

109-119

http://www.w3.org/2001/XMLSchema#string

P31

scholarly article

P356

10.1111/J.1748-1716.2012.02454.X

http://www.w3.org/2001/XMLSchema#string

P433

2

http://www.w3.org/2001/XMLSchema#string

P478

206

http://www.w3.org/2001/XMLSchema#string

P577

2012-06-23T00:00:00Z

http://www.w3.org/2001/XMLSchema#dateTime

P5875

225072150

http://www.w3.org/2001/XMLSchema#string

P698

22642686

http://www.w3.org/2001/XMLSchema#string