Brain functions are supported by multiple cell types, including neuronal and non-neuronal cells that are connected into complex networks. When the connectivity between those cells is altered or disrupted, the functioning of the brain is impaired. In stroke, the interruption of blood supply to the neural circuits results in connectivity damage and permanent disabilities. Experimental evidence suggests that some types of brain state, including sleep, can protect brain tissue from stroke and "repair" the damaged circuits. This project will investigate the neuronal mechanism underlying the protective effect of sleep on brain connectivity and network activity. To this end, the investigators will use a collection of state-of-the-art technologies including high-density electroencephalography (hd-EEG), transcranial magnetic stimulation (TMS) and transcranial alternating current stimulation (tACS). Perspectives include a better understanding of the causes and consequences of the perturbed electrical activity of the brain during sleep in stroke patients.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
SINGLE
Enrollment
21
The investigators recently showed that the repeated application of the so-called continuous theta burst protocol (cTBS) over the contralesional hemisphere resulted in a long-standing improvement of visual hemineglect (Cazzoli et al., 2012). The cTBS protocol was developed by Huang et al. (Huang et al., 2005) and modified by the investigators' group (Nyffeler et al., 2006). TBS protocol consists of a burst of 3 pulses at a frequency of 30 Hz, repeated at 6 Hz. One continuous train includes 801 pulses, the duration of one cTBS train is 44 seconds.
TACS stimulation involves two electrodes placed on either side of the desired site of cortical stimulation. The mode of stimulation used in this experiment is identical to previous studies using tACS in sleep ( Marshall et al., 2006; Prehn-Kristensen et al., 2014 ). Stimulation follows a sinusoidal pattern from 0 to 260 μA. This pattern is delivered at 0.75 Hz and is repeated for 225 cycles; a total of 5 minutes of stimulation. This 5 minute pattern is again repeated 5 times, with a minute of no stimulation between each; thus for a total of 30 minutes.
Sham coil will be used to exclude possible nonspecific effects of the TMS. The sham coil is shielded i.e., the magnetic field output is weakened and therefore insufficiently powerful to stimulate the cortex.
Sham stimulation will be used to exclude possible nonspecific effects of the tACS. Sham tACS stimulation will involve actual stimulation for the first 30 seconds of the ramp-up period (stimulation power is gradually increased until its final level), and then immediately gradually decreased until zero (without the intermediate 4 minutes of actual stimulation). This procedure will be repeated 5 times every 6 minutes and shall induce similar cutaneous sensations as real stimulation.
Department of Neurology, Inselspital, Bern University Hospital
Bern, Switzerland
Change from baseline in visual exploration and sleep parameters and the effect of cTBS
Relationship of visual exploration (mean cumulative fixation duration) to sleep parameters (slow wave activity and spindles) from the baseline to post-cTBS sleep.
Time frame: Day 3
Change from baseline in the effect of tACS on visual exploration
Group comparison of visual exploration task (mean cumulative fixation duration) between real and sham tACS.
Time frame: Day 2
The effect of cTBS on sleep
Relationship between baseline sleep parameters (slow wave activity and spindles) and effectiveness of cTBS.
Time frame: Day 1 to 3
The effect of tACS on sleep
Change in sleep architecture (REM and NREM sleep) between tACS and sham stimulation.
Time frame: Day 1 to 2
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