Visual working memory (VWM) is a capacity-limited system to temporarily maintain visual information. Attending to information in VWM conveys a benefit, as revealed by the retro-cue effect. For example, when the location of one memory item is retro-cued during VWM maintenance, memory accuracy for that item improves. Attentional selection in VWM can also be feature-based: One feature (e.g., shape) may serve as a retrieval cue for another feature (e.g., color) of the same item. Here, we assessed the scope of feature retro-cue benefits with continuous report of colors and orientations.Across six experiments, we observed robust feature retro-cue benefits with manipulations of the cued and recalled feature dimensions, as well as against different baselines controlling for temporal and interference effects. Furthermore, we replicated with continuous report the hallmark of external feature-based attentionconcurrent selection of multiple items. Mixture modelling indicated that feature retro-cue benefits increased recall probability and sometimes precision, paralleling findings on spatial attention.Importantly, cueing multiple items did not produce costs, indicating that concurrently attended items did not interfere with each other. Lastly, manipulation constraining spatial location to a single position suggested that feature retro-cue benefits persist even when spatial context is not singular, but take longer to emerge.
Absolute pitch (AP) refers to the ability to effortlessly identify given pitches without any reference. Correlative evidence suggests that the left posterior dorsolateral prefrontal cortex (DLPFC) is responsible for the process underlying pitch labeling in AP. Here, we measured the sight-reading performance of right-handed AP possessors and matched controls under cathodal and sham transcranial direct current stimulation of the left DLPFC. The participants were instructed to report notations as accurately and as fast as possible by playing with their right hand on a piano. The notations were simultaneously presented with distracting auditory stimuli that either matched or mismatched them in different semitone degrees. Unlike the controls, AP possessors revealed an interference effect in that they responded slower in mismatching conditions than in the matching one. Under cathodal stimulation, this interference effect disappeared. These findings confirm that the pitch-labeling process underlying AP occurs automatically and is largely nonsuppressible when triggered by tone exposure. The improvement of the AP possessors' sight-reading performances in response to the suppression of the left DLPFC using cathodal stimulation confirms a causal relationship between this brain structure and pitch labeling.
We have no conflict of interest to disclose. This research was supported by a grant from the Velux Foundation to A. S. Souza (project n° 1053). This research was presented on the Virtual Working Memory Symposium 2020, as a poster at the virtual 61 st Annual Meeting of the Psychonomic Society, and is shared as a poster on ResearchGate.
BackgroundAbsolute pitch (AP) refers to the ability of effortlessly identifying given pitches without the reliance on any reference pitch. Correlative evidence suggests that the left posterior dorsolateral prefrontal cortex (DLPFC) is responsible for the process underlying pitch labeling in AP.ObjectiveHere, we aimed at investigating the causal relationship between the DLPFC and the pitch-labeling process underlying AP.MethodsTo address this, we measured sight-reading performance of right-handed AP possessors and matched control musicians (N =18 per sample) under cathodal and sham transcranial direct current stimulation of the left DLPFC. The participants were instructed to report visually presenting notations as accurately and fast as possible by playing with their right hand on a piano. The notations were simultaneously presented with distracting auditory stimuli that either matched or mismatched them in different semitone degrees.ResultsUnlike the control participants, the AP possessors revealed an interference effect in that they responded slower in mismatching conditions than in the matching one. Under cathodal stimulation, half of the time discrepancies between matching and mismatching conditions vanished; specifically, the ones with small up to moderate deviations.ConclusionsThese findings confirm that the pitch-labeling process underlying AP occurs automatically and is largely non-suppressible when triggered by tone exposure. The improvement of the AP possessors’ sight-reading performance in response to the suppression of the left DLPFC using cathodal stimulation confirms a causal relationship between this brain structure and pitch labeling.
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