Reactivating ordinal position information from auditory sequence memory in human brains

Author:

Fan Ying123,Luo Huan423

Affiliation:

1. Peking University School of Psychological and Cognitive Sciences, , Haidian District, 100871, Beijing, China

2. IDG/McGovern Institute for Brain Research, Peking University , Haidian District, 100871, Beijing , China

3. Beijing Key Laboratory of Behavior and Mental Health, Peking University , Haidian District, 100871, Beijing , China

4. Peking University School of Psychological and Cognitive Sciences, , Haidian District, 100871, Beijing , China

Abstract

Abstract Retaining a sequence of events in their order is a core ability of many cognitive functions, such as speech recognition, movement control, and episodic memory. Although content representations have been widely studied in working memory (WM), little is known about how ordinal position information of an auditory sequence is retained in the human brain as well as its coding characteristics. In fact, there is still a lack of an efficient approach to directly accessing the stored ordinal position code during WM retention. Here, 31 participants performed an auditory sequence WM task with their brain activities recorded using electroencephalography (EEG). We developed new triggering events that could successfully reactivate neural representations of ordinal position during the delay period. Importantly, the ordinal position reactivation is further related to recognition behavior, confirming its indexing of WM storage. Furthermore, the ordinal position code displays an intriguing “stable-dynamic” format, i.e. undergoing the same dynamic neutral trajectory in the multivariate neural space during both encoding and retention (whenever reactivated). Overall, our results provide an effective approach to accessing the behaviorally-relevant ordinal position information in auditory sequence WM and reveal its new temporal characteristics.

Funder

National Natural Science Foundation of China

National Science and Technology Development Agency

Publisher

Oxford University Press (OUP)

Subject

Cellular and Molecular Neuroscience,Cognitive Neuroscience

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