@article{bfea443bbe6640158e7d7961f3228f56,
title = "Somatosensory Targeted Memory Reactivation Modulates Oscillatory Brain Activity but not Motor Memory Consolidation",
abstract = "Previous research has shown that targeted memory reactivation (TMR) protocols using acoustic or olfactory stimuli can boost motor memory consolidation. While somatosensory information is crucial for motor control and learning, the effects of somatosensory TMR on motor memory consolidation remain elusive. Here, healthy young adults (n = 28) were trained on a sequential serial reaction time task and received, during the offline consolidation period that followed, sequential electrical stimulation of the fingers involved in the task. This somatosensory TMR procedure was applied during either a 90-minute diurnal sleep (NAP) or wake (NONAP) interval that was monitored with electroencephalography. Consolidation was assessed with a retest following the NAP/NONAP episode. Behavioral results revealed no effect of TMR on motor performance in either of the groups. At the brain level, somatosensory stimulation elicited changes in oscillatory activity in both groups. Specifically, TMR induced an increase in power in the mu band in the NONAP group and in the beta band in both the NAP and NONAP groups. Additionally, TMR elicited an increase in sigma power and a decrease in delta oscillations in the NAP group. None of these TMR-induced modulations of oscillatory activity, however, were correlated with measures of motor memory consolidation. The present results collectively suggest that while somatosensory TMR modulates oscillatory brain activity during post-learning sleep and wakefulness, it does not influence motor performance in an immediate retest.",
keywords = "electrical stimulation, motor learning, retention, sleep, targeted memory reactivation",
author = "Veldman, \{Menno P.\} and Nina Dolfen and Gann, \{Mareike A.\} and Julie Carrier and King, \{Bradley R.\} and Genevi{\`e}ve Albouy",
note = "Funding Information: This work was supported by the Belgian Research Foundation Flanders (FWO; G099516N) and internal funds from KU Leuven. GA also received support from FWO (G0D7918N G0B1419N and 1524218N) and Excellence of Science (EOS, 30446199, MEMODYN). MPV, ND and MAG received salary support from these grants. MAG is funded by a predoctoral fellowship from FWO (1141320N). Financial support for BRK was provided by the European Union's Horizon 2020 research and innovation program under the Marie Sk{\l}odowska-Curie grant agreement (703490) and a postdoctoral fellowship from FWO (132635). We wish to thank Fabien Huaranca Ilaquita for his assistance with data collection and Sonia Frenette for sleep scoring. Funding Information: This work was supported by the Belgian Research Foundation Flanders (FWO; G099516N ) and internal funds from KU Leuven . GA also received support from FWO ( G0D7918N G0B1419N and 1524218N ) and Excellence of Science (EOS, 30446199, MEMODYN). MPV, ND and MAG received salary support from these grants. MAG is funded by a predoctoral fellowship from FWO ( 1141320N ). Financial support for BRK was provided by the European Union{\textquoteright}s Horizon 2020 research and innovation program under the Marie Sk{\l}odowska-Curie grant agreement ( 703490 ) and a postdoctoral fellowship from FWO ( 132635 ). We wish to thank Fabien Huaranca Ilaquita for his assistance with data collection and Sonia Frenette for sleep scoring. Publisher Copyright: {\textcopyright} 2021 IBRO",
year = "2021",
month = jun,
day = "15",
doi = "10.1016/j.neuroscience.2021.03.027",
language = "English",
volume = "465",
pages = "203--218",
journal = "Neuroscience",
issn = "0306-4522",
publisher = "PERGAMON-ELSEVIER SCIENCE LTD",
}