Cortical Low-Frequency Power and Progressive Phase Synchrony Precede Successful Memory Encoding

• Published in: The Journal of neuroscience Vol. 35; no. 40; pp. 13577 - 13586
• Main Authors: Haque, Rafi U, Wittig, Jr, John H, Damera, Srikanth R, Inati, Sara K, Zaghloul, Kareem A
• Format: Journal Article
• Language: English
• Published: United States Society for Neuroscience 07.10.2015
• Subjects: Adult; Biophysics; Brain Mapping; Brain Waves - physiology; Cerebral Cortex - physiology; Electric Stimulation; Electroencephalography Phase Synchronization - physiology; Epilepsy - physiopathology; Female; Humans; Image Processing, Computer-Assisted; Magnetic Resonance Imaging; Male; Memory - physiology; Nonlinear Dynamics; Spectrum Analysis; Time Factors; episodic memory; phase synchrony; attention
• ISSN: 0270-6474; 1529-2401
• DOI: 10.1523/JNEUROSCI.0687-15.2015

Neural activity preceding an event can influence subsequent memory formation, yet the precise cortical dynamics underlying this activity and the associated cognitive states remain unknown. We investigate these questions here by examining intracranial EEG recordings as 28 participants with electrodes placed for seizure monitoring participated in a verbal paired-associates memory task. We found that, preceding successfully remembered word pairs, an orientation cue triggered a low-frequency 2-4 Hz phase reset in the right temporoparietal junction with concurrent increases in low-frequency power across cortical regions that included the prefrontal cortex and left temporal lobe. Regions that exhibited a significant increase in 2-4 Hz power were functionally bound together through progressive low-frequency 2-4 Hz phase synchrony. Our data suggest that the interaction between power and phase synchrony reflects the engagement of attentional networks that in large part determine the extent to which memories are successfully encoded. Here we investigate the spatiotemporal cortical dynamics that precede successful memory encoding. Using intracranial EEG, we observed significant changes in oscillatory power, intertrial phase consistency, and pairwise phase synchrony that predict successful encoding. Our data suggest that the interaction between power and phase synchrony reflects the engagement of attentional networks that in large part determine the extent to which memories are successfully encoded.