SWA and slow oscillations are considered to play a key role in Enzalutamide synaptic down-scaling, because synchronized neuronal firing at this slow rate favours processes of synaptic depression rather than potentiation (Czarnecki et al., 2007). Indeed, a recent study (Van Der Werf et al., 2009) demonstrated that, in elderly individuals, selectively reducing SWA during nocturnal sleep by acoustic stimulation significantly impaired encoding of pictures on the next day. The decrement in learning performance was accompanied by a decrease in hippocampal activity during learning, and both observations
were shown to be specific for the encoding of pictures, as procedural learning on a serial reaction time task was not affected by prior suppression of SWA. This pattern, indicating a primary action of SWA on hippocampal encoding of memories, is remarkable, in as much as SWA-dependent synaptic
down-scaling is assumed to impact mainly on neocortical networks as the primary source of the slow oscillation (Timofeev et al., 2000; Murphy et al., 2009; Nir et al., 2011), whereas the hippocampus itself does not generate slow oscillations (Isomura et al., Autophagy Compound Library datasheet 2006). Rather than suppressing SWA, as in the study by Van Der Werf et al. (2009), here we aimed to demonstrate a role of SWA in the efficacy of encoding during wakefulness by enhancing SWA through electrical transcranial slow oscillation stimulation (tSOS). tSOS has
proven effective as a means to enhance SWA (Marshall et al., 2006; Kirov et al., 2009). During tSOS, an alternating electric current is applied to the scalp over frontolateral cortical sites with a frequency that matches the peak frequency of endogenous slow oscillations (~0.75 Hz) (Steriade et al., 1993; Mölle et al., 2002). The amplitude of the oscillating current stimulation (250 μA) is chosen such that the estimated Dichloromethane dehalogenase potential fields in underlying neocortical tissue are about the same size as those that occur naturally during endogenous slow oscillations (Steriade et al., 1996). tSOS applied during non-REM sleep in the first half of the night distinctly increased endogenous slow oscillations and SWA, and this was accompanied by increased frontocortical spindle activity and a significant enhancement in the sleep-dependent consolidation of hippocampus-dependent memory (Marshall et al., 2004, 2006). Animal studies have confirmed that cortical slow oscillation stimulation can effectively synchronize hippocampal activity (Ozen et al., 2010). Here, we hypothesized that applying tSOS during an afternoon nap improves the subsequent encoding of the declarative, i.e. hippocampus-dependent, tasks, with no effect on procedural learning. Fifteen subjects aged 23.4 ± 1.9 years (range, 19–27 years; seven women) participated in the experiments.