Time course of the induction of homeostatic plasticity generated by repeated transcranial direct current stimulation of the human motor cortex.

Several mechanisms have been proposed that control the amount of plasticity in neuronal circuits and guarantee dynamic stability of neuronal networks. Homeostatic plasticity suggests that the ease with which a synaptic connection is facilitated/suppressed depends on the previous amount of network activity. We describe how such homeostatic-like interactions depend on the time interval between two conditioning protocols and on the duration of the preconditioning protocol. We used transcranial direct current stimulation (tDCS) to produce short-lasting plasticity in the motor cortex of healthy humans. In the main experiment, we compared the aftereffect of a single 5-min session of anodal or cathodal tDCS with the effect of a 5-min tDCS session preceded by an identical 5-min conditioning session administered 30, 3, or 0 min beforehand. Five-minute anodal tDCS increases excitability for about 5 min. The same duration of cathodal tDCS reduces excitability. Increasing the duration of tDCS to 10 min prolongs the duration of the effects. If two 5-min periods of tDCS are applied with a 30-min break between them, the effect of the second period of tDCS is identical to that of 5-min stimulation alone. If the break is only 3 min, then the second session has the opposite effect to 5-min tDCS given alone. Control experiments show that these shifts in the direction of plasticity evolve during the 10 min after the first tDCS session and depend on the duration of the first tDCS but not on intracortical inhibition and facilitation. The results are compatible with a time-dependent "homeostatic-like" rule governing the response of the human motor cortex to plasticity probing protocols.

Covert word reading induces a late response in the hand motor system of the language dominant hemisphere.

Recent work has demonstrated that overt reading influences the excitability of the language-dominant hand motor cortex. However, this effect was related to speech output, whereas results on silent reading have been inconsistent, and have not allowed for systematic investigation of the different stages of word recognition. To investigate a possible modulation of the cortical excitability mediating hand movements through different stages of covert reading, motor evoked potentials (MEP) from hand muscles in right-handed subjects were recorded. We showed a significant increase of the excitability of the hand motor cortex of the dominant hemisphere during late stages of covert word reading, whereas processing of abstract shapes had no effect and covert articulation induced a decrease in hand motor cortex excitability. There was no significant change of MEP amplitudes during earlier stages of covert reading in the dominant hemisphere or in the non-dominant hemisphere. Our results demonstrate a functional connection between cortical networks mediating linguistic processing and hand movements without concurrent activation of the motor cortex through overt articulation at late stages of word reading, which have been shown to involve converging activation of classic left frontal language regions. We speculate that the effect reported here is related to a cortical network mediating gestures which are a part of verbal communication. This supports recent theories on language evolution which postulate that language emerged through manual gestures.