0000000000154566

AUTHOR

Luca Angius

0000-0003-4606-4272

showing 2 related works from this author

Central alterations of neuromuscular function and feedback from group III-IV muscle afferents following exhaustive high-intensity one-leg dynamic exe…

2015

The aims of this investigation were to describe the central alterations of neuromuscular function induced by exhaustive high-intensity one-leg dynamic exercise (OLDE, study 1) and to indirectly quantify feedback from group III-IV muscle afferents via muscle occlusion (MO, study 2) in healthy adult male humans. We hypothesized that these central alterations and their recovery are associated with changes in afferent feedback. Both studies consisted of two time-to-exhaustion tests at 85% peak power output. In study 1, voluntary activation level (VAL), M-wave, cervicomedullary motor evoked potential (CMEP), motor evoked potential (MEP), and MEP cortical silent period (CSP) of the knee extensor…

MaleTime Factorscervicomedullary stimulationRefractory Period ElectrophysiologicalPhysiologynear-infrared spectroscopysilent periodmedicine.medical_treatmentendurance exerciseendurance performanceOcclusionMedicineEvoked potentialhumansquadriceps femorisFeedback PhysiologicalMotor CortexPain PerceptionAnatomyTranscranial Magnetic StimulationLower ExtremityAnesthesiamuscle fatiguecorticospinal excitabilitymedicine.symptomFemoral NerveperformanceMuscle contractionMuscle ContractionAdultPain ThresholdMean arterial pressurePainperipheral fatiguecomplex mixturesYoung AdultPhysiology (medical)Threshold of painskeletal-muscleNeurons AfferentMuscle SkeletalExerciseMuscle fatiguebusiness.industrycontractionEvoked Potentials MotorElectric Stimulationcentral fatigueTranscranial magnetic stimulation[ SDV.NEU ] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]Physical EnduranceSilent periodsport-sciencebusiness
researchProduct

Transcranial direct current stimulation improves isometric time to exhaustion of the knee extensors

2016

International audience; Transcranial direct current stimulation (tDCS) can increase cortical excitability of a targeted brain area, which may affect endurance exercise performance. However, optimal electrode placement for tDCS remains unclear. We tested the effect of two different tDCS electrode montages for improving exercise performance. Nine subjects underwent a control (CON), placebo (SHAM) and two different tDCS montage sessions in a randomized design. In one tDCS session, the anodal electrode was placed over the left motor cortex and the cathodal on contralateral forehead (HEAD), while for the other montage the anodal electrode was placed over the left motor cortex and cathodal electr…

Malemedicine.medical_treatmentIsometric exerciseFunctional LateralitytDCSRandom Allocation0302 clinical medicineHeart RateSingle-Blind Methodprefrontal cortexprimary motor cortexTranscranial direct-current stimulationexerciseGeneral NeuroscienceMotor Cortexvoluntary activationTranscranial Magnetic StimulationPeripheralmedicine.anatomical_structureMuscle FatiguePsychologyFemoral Nerveperformancemedicine.medical_specialtyShoulderintracortical inhibitionNeuroscience(all)B100brain stimulationPlacebo03 medical and health sciencesYoung AdultPhysical medicine and rehabilitationEndurance trainingIsometric ContractionHeart rateexcitabilitymedicineHumansneuromuscular functionMuscle Skeletalmagnetic stimulationhuman muscle fatigueLeg030229 sport sciencesEvoked Potentials MotorC600QPElectric Stimulationbody regionsBrain stimulation[ SDV.NEU ] Life Sciences [q-bio]/Neurons and Cognition [q-bio.NC]ForeheadPhysical therapyPerceptionsupraspinal factors030217 neurology & neurosurgery
researchProduct