Abstract
BackgroundAn experienced car mechanic can often deduce what's wrong with a car by carefully listening to the sound of the ailing engine, despite the presence of multiple sources of noise. Indeed, the ability to select task-relevant sounds for awareness, whilst ignoring irrelevant ones, constitutes one of the most fundamental of human faculties, but the underlying neural mechanisms have remained elusive. While most of the literature explains the neural basis of selective attention by means of an increase in neural gain, a number of papers propose enhancement in neural selectivity as an alternative or a complementary mechanism.Methodology/Principal FindingsHere, to address the question whether pure gain increase alone can explain auditory selective attention in humans, we quantified the auditory cortex frequency selectivity in 20 healthy subjects by masking 1000-Hz tones by continuous noise masker with parametrically varying frequency notches around the tone frequency (i.e., a notched-noise masker). The task of the subjects was, in different conditions, to selectively attend to either occasionally occurring slight increments in tone frequency (1020 Hz), tones of slightly longer duration, or ignore the sounds. In line with previous studies, in the ignore condition, the global field power (GFP) of event-related brain responses at 100 ms from the stimulus onset to the 1000-Hz tones was suppressed as a function of the narrowing of the notch width. During the selective attention conditions, the suppressant effect of the noise notch width on GFP was decreased, but as a function significantly different from a multiplicative one expected on the basis of simple gain model of selective attention.Conclusions/SignificanceOur results suggest that auditory selective attention in humans cannot be explained by a gain model, where only the neural activity level is increased, but rather that selective attention additionally enhances auditory cortex frequency selectivity.
Highlights
The neural basis of selective attention constitutes one of the most fundamental questions in cognitive neuroscience and psychology
Increase in activity level has been reported in functional Magnetic Resonance Imaging [7,11,15,16], positron emission tomography (PET) [9,10,12,13], electroencephalography (EEG) [1,2,4,6], and magnetoencephalography (MEG) [3,5,8,14] studies in humans, but the issue of whether there is a ‘bias’ mechanism in addition to the attentional gain control has been only recently raised [20]
To further assess this effect, the observed global field power (GFP) peak amplitudes were pairwise compared to the predicted ones
Summary
The neural basis of selective attention constitutes one of the most fundamental questions in cognitive neuroscience and psychology. Based on previous studies in sensory systems, two alternative neural mechanisms, multiplicative increase in neural gain [1,2,3,4,5,6,7,8,9,10,11,12,13,14,15,16] vs enhanced feature selectivity of the neurons in sensory cortices [17,18,19,20,21], have been suggested to underlie selective attention. During the selective attention conditions, the suppressant effect of the noise notch width on GFP was decreased, but as a function significantly different from a multiplicative one expected on the basis of simple gain model of selective attention. Our results suggest that auditory selective attention in humans cannot be explained by a gain model, where only the neural activity level is increased, but rather that selective attention enhances auditory cortex frequency selectivity
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