Abstract
The brain’s fascinating ability to adapt its internal neural dynamics to the temporal structure of the sensory environment is becoming increasingly clear. It is thought to be metabolically beneficial to align ongoing oscillatory activity to the relevant inputs in a predictable stream, so that they will enter at optimal processing phases of the spontaneously occurring rhythmic excitability fluctuations. However, some contexts have a more predictable temporal structure than others. Here, we tested the hypothesis that the processing of rhythmic sounds is more efficient than the processing of irregularly timed sounds. To do this, we simultaneously measured functional magnetic resonance imaging (fMRI) and electro-encephalograms (EEG) while participants detected oddball target sounds in alternating blocks of rhythmic (e.g., with equal inter-stimulus intervals) or random (e.g., with randomly varied inter-stimulus intervals) tone sequences. Behaviorally, participants detected target sounds faster and more accurately when embedded in rhythmic streams. The fMRI response in the auditory cortex was stronger during random compared to random tone sequence processing. Simultaneously recorded N1 responses showed larger peak amplitudes and longer latencies for tones in the random (vs. the rhythmic) streams. These results reveal complementary evidence for more efficient neural and perceptual processing during temporally predictable sensory contexts.
Highlights
The temporal dynamics of environmental sounds can be predictable, such as approaching footsteps, or unpredictable and novel, such as a tire screech or a notification of a text message
We explored the proposition that the brain flexibly switches between vigilant and rhythmic processing modes depending on the temporal context, and that both behaviorally and at the neural level, detecting target sounds in a rhythmic context is more efficient
Our behavioral results show more accurate and faster detection of targets embedded in rhythmic streams compared to those occurring randomly in time, supporting the improved behavioral efficiency of rhythmic mode processing (Schroeder and Lakatos, 2009)
Summary
The temporal dynamics of environmental sounds can be predictable, such as approaching footsteps, or unpredictable and novel, such as a tire screech or a notification of a text message. It has been shown that ongoing oscillatory brain activity in the macaque auditory and visual cortices can be entrained by rhythmic, task-relevant event streams, such that the cortical representation of the events in that stream is enhanced Oscillatory entrainment is thought to be metabolically efficient (Buzsáki and Draguhn, 2004) and is sometimes referred to as a rhythmic mode of processing (Schroeder and Lakatos, 2009). As many environmental stimuli such as biological motion are inherently rhythmic, characterized by slow rates of 1–5 Hz, this “rhythmic” mode is thought to be beneficial for processing such natural stimuli by enhancing and resetting low-frequency (delta and theta-band) spontaneous oscillations (Schroeder and Lakatos, 2009)
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