about
Repetitive hops induce postactivation potentiation in triceps surae as well as an increase in the jump height of subsequent maximal drop jumps.A qualitative review of balance and strength performance in healthy older adults: impact for testing and training.Effects of conditioning hops on drop jump and sprint performance: a randomized crossover pilot study in elite athletesHigh-Intensity Jump Training Is Tolerated during 60 Days of Bed Rest and Is Very Effective in Preserving Leg Power and Lean Body Mass: An Overview of the Cologne RSL Study.Spinal and supraspinal adaptations associated with balance training and their functional relevance.Specificity of Balance Training in Healthy Individuals: A Systematic Review and Meta-Analysis.Intermittent Theta Burst Over M1 May Increase Peak Power of a Wingate Anaerobic Test and Prevent the Reduction of Voluntary Activation Measured with Transcranial Magnetic Stimulation.How to prevent the detrimental effects of two months of bed-rest on muscle, bone and cardiovascular system: an RCT.Leg stiffness can be maintained during reactive hopping despite modified acceleration conditions.Excitability at the motoneuron pool and motor cortex is specifically modulated in lengthening compared to isometric contractions.Balance training and ballistic strength training are associated with task-specific corticospinal adaptations.Task-specific changes in motor evoked potentials of lower limb muscles after different training interventions.Influence of falling height on the excitability of the soleus H-reflex during drop-jumps.Conditioning hops increase triceps surae muscle force and Achilles tendon strain energy in the stretch-shortening cycle.Cortical and spinal adaptations induced by balance training: correlation between stance stability and corticospinal activation.The effect of paired associative stimulation on fatigue resistance.Contribution of afferent feedback and descending drive to human hopping.Differential modulation of motor cortex plasticity in skill- and endurance-trained athletes.Neuroplasticity following short-term strength training occurs at supraspinal level and is specific for the trained task.Task-specificity of balance training.Robotic guidance induces long-lasting changes in the movement pattern of a novel sport-specific motor task.Training-specific adaptations of H- and stretch reflexes in human soleus muscle.Anodal and cathodal transcranial direct current stimulation can decrease force output of knee extensors during an intermittent MVC fatiguing task in young healthy male participants.Postactivation potentiation can counteract declines in force and power that occur after stretching.Plyometrics Can Preserve Peak Power During 2 Months of Physical Inactivity: An RCT Including a One-Year Follow-Up.Active recovery affects the recovery of the corticospinal system but not of muscle contractile properties.Additional Intra- or Inter-session Balance Tasks Do Not Interfere With the Learning of a Novel Balance TaskThree months of slackline training elicit only task-specific improvements in balance performanceHigh Intensity Jump Exercise Preserves Posture Control, Gait, and Functional Mobility During 60 Days of Bed-Rest: An RCT Including 90 Days of Follow-UpThe Importance of Impact Loading and the Stretch Shortening Cycle for Spaceflight CountermeasuresImpact of sensorimotor training on the rate of force development and neural activationSpecific adaptations of neuromuscular control and knee joint stiffness following sensorimotor trainingDirect corticospinal pathways contribute to neuromuscular control of perturbed stanceFunctional maximal strength training induces neural transfer to single-joint tasksFour weeks of training in a sledge jump system improved the jump pattern to almost natural reactive jumpsEMG activity during whole body vibration: motion artifacts or stretch reflexes?Effects of ankle fatigue on functional reflex activity during gait perturbations in young and elderly menResistance training and neuromuscular performance in seniorsEnhanced neural drive after maximal strength training in multiple sclerosis patientsShort-term pressure induced suppression of the short-latency response: a new methodology for investigating stretch reflexes
P50
Q35023349-5DA1509A-AB9E-426E-B6F4-555F72F2E682Q35725040-53809B4F-6731-4096-B1A8-36F812F733EDQ35911662-6766775C-9930-47C6-B595-28FE7C949ED3Q36247753-58CC8747-0D44-40AF-BE16-DC943A4B8B31Q37111983-0D3E49DA-58F4-46EB-93C5-2A2DBB711038Q38780819-BA128CB9-C105-490E-836A-7290EDAF2348Q42216681-E2EC84C0-FCBE-4B4D-8396-388100425C20Q42377194-101F3389-C698-48B8-8B88-3A0D6C297411Q45770676-DB631AD0-482D-43E6-9898-0BD2E630FA33Q46133303-A62043EA-D367-45FB-B545-B259908FAA1BQ46644701-633BFC24-3CE1-4D9B-857B-7EF1D495D179Q46986123-9259FB15-57E3-4DE2-9A15-C0FD101F98CBQ47263609-68B59A63-BC57-46CC-B334-46A7174E4BC2Q48045767-6BC1A77F-6B2B-4A8C-9AFC-FCE577EE05CEQ48293275-5205044B-ED82-490D-BCDC-8351C6480A41Q48340286-38E7CABB-4651-4A57-8B5D-42EE7538CCBCQ48349002-6B52661D-68AF-47AB-95C8-EEAC06BA3CDEQ48394815-484F8330-6432-47F6-84F1-A5D72F13C950Q49965219-FF707E3F-F6B5-4A52-A5DD-41864F448C13Q50568729-A7BDA4B1-D185-4F3E-B880-6575ACC4C802Q50633631-977CC9B6-0D77-4116-97F4-DAB3B1A73116Q51996186-2663FA79-F52B-436D-884F-C7BC4B81AA92Q52562219-4893A170-C845-4B42-B17F-89A62DDF6A04Q53762010-C7EAF7A4-3E93-446A-A65A-E54A60AD30B4Q55211257-02F0E1B3-A751-4029-9722-F8B561581FD1Q55318023-50FC3E3E-BD5B-427D-8E2A-51059DEE1A22Q57072947-8DFFCCE8-4A30-436E-A1C6-08790E18EB2EQ59811501-EA85C0BC-162E-495C-BDB2-E84B498A44DDQ60047636-7C7D61B3-1240-476C-B48C-1E6D43F0115FQ64061696-A32A0DD1-FE16-4742-BFEB-8421B3764A8AQ79783294-45BC67CC-A154-421A-85F7-411A8CECDF7DQ80015383-E354FD86-FDE1-48C6-BD8A-15E4559364C7Q83118359-98CE4189-E334-4983-AE78-B1CC25212C8CQ84018288-68587C0A-726A-475A-A263-16E964FC98AEQ84040786-87CA8E3E-2276-4088-8E79-DD5800EE8B9BQ84110078-5217BF68-46B3-4829-9D7D-98B00882056DQ84141093-92512583-5FC4-4B77-98AD-46BE44A67D1FQ84150675-C3CBD326-9069-43F9-8912-5FE4BC137972Q84330178-06558FE6-5192-4D0C-9A15-B73F47B2CB8FQ84441552-CA9B6A19-5819-4FBD-B4E8-38CF5A0C3549
P50
description
investigador
@es
researcher
@en
wetenschapper
@nl
name
Markus Gruber
@en
Markus Gruber
@nl
type
label
Markus Gruber
@en
Markus Gruber
@nl
altLabel
Gruber M
@en
prefLabel
Markus Gruber
@en
Markus Gruber
@nl
P31
P496
0000-0002-0233-3912