Local Targeted Memory Reactivation in Human Sleep

Ella Bar; Amit Marmelshtein; Anat Arzi; Ofer Perl; Ethan Livne; Eyal Hizmi; Rony Paz; Noam Sobel; Yadin Dudai; Yuval Nir

doi:10.1016/j.cub.2020.01.091

Local Targeted Memory Reactivation in Human Sleep

Ella Bar, Amit Marmelshtein, Anat Arzi, Ofer Perl, Ethan Livne, Eyal Hizmi, Rony Paz, Noam Sobel, Yadin Dudai, Yuval Nir^*

^*Corresponding author for this work

Department of Brain Sciences

Research output: Contribution to journal › Article › peer-review

35 Citations (Scopus)

Abstract

Memory consolidation can be promoted via targeted memory reactivation (TMR) that re-presents training cues or context during sleep. Whether TMR acts locally or globally on cortical sleep oscillations remains unknown. Here, we exploit the unique functional neuroanatomy of olfaction with its ipsilateral stimulus processing to perform local TMR in one brain hemisphere. Participants learned associations between words and locations in left or right visual fields with contextual odor throughout. We found lateralized event-related potentials during task training that indicate unihemispheric memory processes. During post-learning naps, odors were presented to one nostril in non-rapid eye movement (NREM) sleep. Memory for specific words processed in the cued hemisphere (ipsilateral to stimulated nostril) was improved after local TMR during sleep. Unilateral odor cues locally modulated slow-wave (SW) power such that regional SW power increase was lower in the cued hemisphere relative to the uncued hemisphere and negatively correlated with select memories for cued words. Moreover, local TMR improved phase-amplitude coupling (PAC) between slow oscillations and sleep spindles specifically in the cued hemisphere. The effects on memory performance and cortical sleep oscillations were not observed when unilateral olfactory stimulation during sleep followed learning without contextual odor. Thus, TMR in human sleep transcends global action by selectively promoting specific memories associated with local sleep oscillations.

Original language	English
Pages (from-to)	1435-1446
Number of pages	12
Journal	Current Biology
Volume	30
Issue number	8
Early online date	5 Mar 2020
DOIs	https://doi.org/10.1016/j.cub.2020.01.091
Publication status	Published - 20 Apr 2020

Funding

We thank Aharon Weissbrod, Danielle Honigstein, and Abebe Medhanie for their work on designing and building the nasal masks and olfactory stimulation setup; Dr. Motti Ratmansky from Loewenstein Rehabilitation Hospital; Dr. Noa Bar-Ilan Regev for administrative support; and members of Sobel/Nir/Paz labs and Dudai lab alumni for discussions and suggestions. This work was supported by the Israel Science Foundation (ISF) grant 51/11 (I-CORE cognitive sciences; Y.D. and Y.N.) and US-Israel Binational Science Foundation (BSF) grant no. 2017628 (Y.N.). R.P. and E.B. are supported by a Joy-Ventures grant. Research in the Sobel lab is supported by the Rob and Cheryl McEwen Fund for Brain Research. E.B. conceived and designed experiments with supervision from Y.D. and N.S.; E.B. E.L. and N.S. designed and built the experimental setup; E.B. and E.H. collected data; E.B. analyzed data with the help of A.A. A.M. and O.P. and supervision from Y.N.; E.B. and Y.N. wrote the manuscript; R.P. supervised the control experiment; and all authors provided ongoing critical review of results and commented on the manuscript. The authors declare no competing interests.

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title = "Local Targeted Memory Reactivation in Human Sleep",

abstract = "Memory consolidation can be promoted via targeted memory reactivation (TMR) that re-presents training cues or context during sleep. Whether TMR acts locally or globally on cortical sleep oscillations remains unknown. Here, we exploit the unique functional neuroanatomy of olfaction with its ipsilateral stimulus processing to perform local TMR in one brain hemisphere. Participants learned associations between words and locations in left or right visual fields with contextual odor throughout. We found lateralized event-related potentials during task training that indicate unihemispheric memory processes. During post-learning naps, odors were presented to one nostril in non-rapid eye movement (NREM) sleep. Memory for specific words processed in the cued hemisphere (ipsilateral to stimulated nostril) was improved after local TMR during sleep. Unilateral odor cues locally modulated slow-wave (SW) power such that regional SW power increase was lower in the cued hemisphere relative to the uncued hemisphere and negatively correlated with select memories for cued words. Moreover, local TMR improved phase-amplitude coupling (PAC) between slow oscillations and sleep spindles specifically in the cued hemisphere. The effects on memory performance and cortical sleep oscillations were not observed when unilateral olfactory stimulation during sleep followed learning without contextual odor. Thus, TMR in human sleep transcends global action by selectively promoting specific memories associated with local sleep oscillations.",

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AU - Marmelshtein, Amit

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AU - Paz, Rony

AU - Sobel, Noam

AU - Dudai, Yadin

AU - Nir, Yuval

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N2 - Memory consolidation can be promoted via targeted memory reactivation (TMR) that re-presents training cues or context during sleep. Whether TMR acts locally or globally on cortical sleep oscillations remains unknown. Here, we exploit the unique functional neuroanatomy of olfaction with its ipsilateral stimulus processing to perform local TMR in one brain hemisphere. Participants learned associations between words and locations in left or right visual fields with contextual odor throughout. We found lateralized event-related potentials during task training that indicate unihemispheric memory processes. During post-learning naps, odors were presented to one nostril in non-rapid eye movement (NREM) sleep. Memory for specific words processed in the cued hemisphere (ipsilateral to stimulated nostril) was improved after local TMR during sleep. Unilateral odor cues locally modulated slow-wave (SW) power such that regional SW power increase was lower in the cued hemisphere relative to the uncued hemisphere and negatively correlated with select memories for cued words. Moreover, local TMR improved phase-amplitude coupling (PAC) between slow oscillations and sleep spindles specifically in the cued hemisphere. The effects on memory performance and cortical sleep oscillations were not observed when unilateral olfactory stimulation during sleep followed learning without contextual odor. Thus, TMR in human sleep transcends global action by selectively promoting specific memories associated with local sleep oscillations.

AB - Memory consolidation can be promoted via targeted memory reactivation (TMR) that re-presents training cues or context during sleep. Whether TMR acts locally or globally on cortical sleep oscillations remains unknown. Here, we exploit the unique functional neuroanatomy of olfaction with its ipsilateral stimulus processing to perform local TMR in one brain hemisphere. Participants learned associations between words and locations in left or right visual fields with contextual odor throughout. We found lateralized event-related potentials during task training that indicate unihemispheric memory processes. During post-learning naps, odors were presented to one nostril in non-rapid eye movement (NREM) sleep. Memory for specific words processed in the cued hemisphere (ipsilateral to stimulated nostril) was improved after local TMR during sleep. Unilateral odor cues locally modulated slow-wave (SW) power such that regional SW power increase was lower in the cued hemisphere relative to the uncued hemisphere and negatively correlated with select memories for cued words. Moreover, local TMR improved phase-amplitude coupling (PAC) between slow oscillations and sleep spindles specifically in the cued hemisphere. The effects on memory performance and cortical sleep oscillations were not observed when unilateral olfactory stimulation during sleep followed learning without contextual odor. Thus, TMR in human sleep transcends global action by selectively promoting specific memories associated with local sleep oscillations.

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Local Targeted Memory Reactivation in Human Sleep

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