6). We found that constancy in stimulus onset (i.e. temporal regularity) facilitates higher-order sensory predictions based on deviant repetition probability, in rapid tone sequences (Sussman & Winkler, 2001; Todd & Robinson, 2010). Neural response attenuation to highly find protocol probable and therefore predictable deviant repetitions thus reflects the contribution of both formal and temporal regularities in input. As the stimuli were presented outside the focus of attention, the build up of higher-order sensory predictions can be deemed automatic to a certain degree. Conversely,

no significant MMN attenuation was found to less probable deviant repetitions in isochronous sequences, as well as no MMN attenuation regardless of deviant repetition probability

in anisochronous sequences, suggesting similar surprise levels for both deviant events (Yaron et al., 2012). The absence of a main effect of temporal regularity in fast sequences excludes any artifactual low-pass filter effect that might derive from averaging jittered single-trial peak latencies (Spencer, 2005). Taken together, our findings corroborate and at the same time advance the sensory expectancy account of repetition suppression (Summerfield et al., 2008, 2011; Todorovic et al., 2011) by highlighting the relevance of temporal information for higher-order predictive processes. We also found that temporal information Ruxolitinib concentration is not required to elicit a prediction error response, i.e. the error response to a first-order prediction represented by standard repetition. We demonstrated this with both fast and slow stimulation sequences, confirming other studies using slow oddball sequences with a large onset time jitter (Schwartze et al., 2011). First-order prediction error appears to rely simply on stimulus feature mismatch. This makes sense from an ecological point of view, as conditioning the detection

of feature changes upon the regularity of stimulus presentation would severely limit the adaptive efficiency of the deviance detection system in complex natural environments. In a recent work, Schwartze et al. (2013) reported on an impact of temporal regularity on the N1 deflection. In our control study, the N1 was Mannose-binding protein-associated serine protease not influenced by temporal regularity. This difference may stem from high-pass filter settings sensibly affecting the slow ERP components contributing to N1 deflection (for a discussion, see Widmann & Schröger, 2012). We opted for a conservative 0.5-Hz high-pass filter, as opposed to 5 Hz in Schwartze et al. (2013). Interestingly, in our control experiment temporal regularity appears to shift ERPs in the MMN/N2 latency range to more negative values, similarly to the effects of attention to sounds (negative difference, Näätänen, 1990; Alho et al., 1994). Speculatively, it could be argued that both temporal regularity and attention translate into sharpened neuronal responses (Neelon et al., 2011).