TY - JOUR
T1 - Distributed networks for auditory memory contribute differentially to recall precision
AU - Lim, Sung-Joo
AU - Thiel, Christiane
AU - Sehm, Bernhard
AU - Deserno, Lorenz
AU - Lepsien, Jöran
AU - Obleser, Jonas
PY - 2021/1
Y1 - 2021/1
N2 - The representations held in working memory are inherently noisy, but attention directed to relevant objects can effectively enhance their fidelity. While recent working memory models suggest that memory representations are distributed across sensory and cognitive-control brain regions, it remains unknown how multiple brain networks generate this attentional gain in fidelity. Here, we investigated the contributions of the distinct brain networks in maintaining and enhancing memory representations using psychophysical modeling and fMRI. Human listeners performed an auditory syllable pitch-discrimination task, in which they received valid (vs. neutral) retro-active cues to selectively attend to one of the two syllable categories maintained in memory. Valid (vs. neutral) retro-cues facilitated task performance, eliciting faster recall and enhanced recall precision of syllables in memory. Valid retro-cues also led to increased neural activation in fronto-parietal and cingulo-opercular networks, but not in sensory-specific superior temporal cortex. Multivariate pattern analysis as a proxy for representational fidelity in memory revealed that attended syllable objects were maintained in distributed areas across superior temporal, frontal, parietal, and sensorimotor brain areas. However, neural fidelity in left superior temporal sulcus and its enhancement through attention-to-memory best predicted the ensuing individual gain in recall precision of auditory objects from memory. These results demonstrate that maintaining versus attentionally enhancing auditory memory representations are functionally separable mechanisms across distributed brain regions.Significance Statement Working memory is distributed across sensory and cognitive-control brain regions. But how do these brain networks enhance working memory precision when attention is re-directed to memory? We here investigate the contributions of distinct brain networks in maintaining and enhancing auditory memory representations through attention-to-memory using fMRI. We demonstrate that re-directing attention to the relevant auditory memory objects mainly recruits higher-order cognitive-control networks. Among the multiple brain regions retaining memory representations, however, attentional enhancement of the neural fidelity in superior temporal sulcus best predicts the individual gain in recall precision of auditory objects from memory. This study provides evidence of the interplay among the discrete, functionally specialized brain regions in maintaining and attentionally enhancing working memory representations.Competing Interest StatementThe authors have declared no competing interest.
AB - The representations held in working memory are inherently noisy, but attention directed to relevant objects can effectively enhance their fidelity. While recent working memory models suggest that memory representations are distributed across sensory and cognitive-control brain regions, it remains unknown how multiple brain networks generate this attentional gain in fidelity. Here, we investigated the contributions of the distinct brain networks in maintaining and enhancing memory representations using psychophysical modeling and fMRI. Human listeners performed an auditory syllable pitch-discrimination task, in which they received valid (vs. neutral) retro-active cues to selectively attend to one of the two syllable categories maintained in memory. Valid (vs. neutral) retro-cues facilitated task performance, eliciting faster recall and enhanced recall precision of syllables in memory. Valid retro-cues also led to increased neural activation in fronto-parietal and cingulo-opercular networks, but not in sensory-specific superior temporal cortex. Multivariate pattern analysis as a proxy for representational fidelity in memory revealed that attended syllable objects were maintained in distributed areas across superior temporal, frontal, parietal, and sensorimotor brain areas. However, neural fidelity in left superior temporal sulcus and its enhancement through attention-to-memory best predicted the ensuing individual gain in recall precision of auditory objects from memory. These results demonstrate that maintaining versus attentionally enhancing auditory memory representations are functionally separable mechanisms across distributed brain regions.Significance Statement Working memory is distributed across sensory and cognitive-control brain regions. But how do these brain networks enhance working memory precision when attention is re-directed to memory? We here investigate the contributions of distinct brain networks in maintaining and enhancing auditory memory representations through attention-to-memory using fMRI. We demonstrate that re-directing attention to the relevant auditory memory objects mainly recruits higher-order cognitive-control networks. Among the multiple brain regions retaining memory representations, however, attentional enhancement of the neural fidelity in superior temporal sulcus best predicts the individual gain in recall precision of auditory objects from memory. This study provides evidence of the interplay among the discrete, functionally specialized brain regions in maintaining and attentionally enhancing working memory representations.Competing Interest StatementThe authors have declared no competing interest.
UR - https://www.researchgate.net/publication/348599379_Distributed_networks_for_auditory_memory_contribute_differentially_to_recall_precision
U2 - 10.1101/2021.01.18.427143
DO - 10.1101/2021.01.18.427143
M3 - Journal articles
JO - biorxiv
JF - biorxiv
ER -