Disinhibition oder Fazilitation nach repetitivem Handtraining?

 

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Zusammenfassung

Einleitung Aufgabenspezifische Veränderungen der intrakortikalen Inhibition und Fazilitation sind bekannt. In dieser Studie wurde der Mechanismus, der kurz nach den jeweiligen Einzelbewegungen während einer repetitiven physiotherapeutischen Trainingsaufgabe wirksam ist, mittels der transkraniellen magnetischen Doppelstimulation untersucht. Methodik Das repetitive Training bestand aus Handextensionen mit Wiederholungen alle 6 s, wobei jede Handextension von einem magnetischen Einzel- oder Doppelstimulus über dem motorkortikalen Handareal gefolgt war. Doppelstimuli wurden mit einem Interstimulusintervall (ISI) von 2 ms (Inhibition; 15 gesunde Versuchspersonen) bzw. 8 ms (Fazilitation; 12 gesunde Versuchspersonen) appliziert. Motorisch evozierte Potenziale (MEP) wurden von den Handextensoren (ECR, Agonist) bzw. Handflexoren (FCU, Antagonist) 1 s nach Beendigung von Einzelbewegungen abgeleitet und mit der Ruhebedingung bzw. mit Einzelstimuli verglichen. Ergebnisse Inhibitorische Effekte wurden bei ISI von 2 ms in beiden Muskeln beobachtet. Lediglich in den Agonisten nach aktiven Bewegungen waren die MEP-Amplituden signifikant höher als bei Ruhe und passiven Bewegungen. Die MEP-Amplitudendifferenzen (Einzelstimuli - Doppelstimuli 2 ms) ergaben jedoch nahezu identische Werte für Ruhe, passive oder aktive Bewegungen, sodass eine Disinhibition durch aktives Training nicht nachweisbar war. Die MEP-Amplitudendifferenzen (Doppelstimuli 8 ms - Einzelstimuli) hingegen zeigten eine zusätzliche MEP-Amplitudenerhöhung für aktive Bewegungen im ECR, die für eine Fazilitation spricht. Diskussion Als Ursache für den zusätzlichen MEP-Amplitudenanstieg nach aktiven Bewegungen des Agonisten wird nicht eine Disinhibition, sondern eine die intrakortikale Fazilitation verstärkende trainingsinduzierte Fazilitation angenommen. Diese Ergebnisse könnten auch Implikationen für die Auswahl von physiotherapeutischen Trainingsmethoden oder Zielmuskeln haben.

Abstract

Introduction Task-related changes of intracortical inhibition and facilitation have been reported. In this study, transcranial magnetic paired pulse stimulation was used to investigate the mechanism operating shortly after movements of a repetitive training task which is used as a physiotherapeutic procedure in central weakness. Methods and subjects Repetitive training consisted of hand extensions recurring every 6 s. Each hand movement was followed by a (single or paired) magnetic stimulus. Single and paired stimuli with inter-stimulus intervals (ISI) of 2 ms (inhibition; 15 healthy subjects) and 8 ms (facilitation; 12 healthy subjects) were applied to the cortical motor hand area. Motor evoked potentials (MEP) from hand extensors (ECR, agonist) and flexors (FCU, antagonist) were recorded 1 s after active or passive hand extensions and compared with rest or single stimuli. Results Inhibitory effects were observed using paired stimuli of ISI = 2 ms in both muscles. Significantly larger MEP were detected in agonists after active training only. MEP amplitude differences (single - paired stimuli 2 ms), however, were nearly equal for rest, passive or active movements indicating that active movements did not produce disinhibition. MEP amplitude differences (paired 8 ms - single stimuli) showed an additional MEP increase after active movements of the agonist muscle indicating facilitation. Discussion The additional MEP increase produced shortly after active movements in agonist muscles suggests that after training intracortical facilitation is enhanced by post-movement facilitation. Disinhibition was not detected. The finding may also have implications for the choice of training methods or target muscles in physiotherapy.

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Priv.-Doz. Dr. Margot Schubert

NRZ Neurological Rehabilitation Center Leipzig

Muldentalweg 1

04828 Bennewitz

Email: Schubert@sachsenklinik.de