This project optimizes high-resolution tACS to improve memory in healthy older adults, advancing drug-free approaches for ADRD. We test stimulation schedules and develop an adaptive, brain-guided tACS system to strengthen memory-supporting networks.
Cognitive decline, especially in memory and executive control, poses an escalating public health challenge as the population ages, contributing to loss of independence, reduced quality of life, and increased healthcare costs associated with Alzheimer's disease and related dementias (ADRD). Despite decades of research, there are few effective, non-pharmacological interventions capable of slowing or reversing these cognitive losses. Transcranial alternating current stimulation (tACS) has recently emerged as a promising, safe, and non-invasive technique for modulating neural rhythms that support memory. However, existing approaches remain limited by one-size-fits-all stimulation schedules that fail to account for individual brain connectivity patterns or dynamic fluctuations in cognitive state. This project aims to advance precision neuromodulation for cognitive aging by optimizing and personalizing high-resolution tACS protocols to enhance memory in older adults. Building on strong pilot data demonstrating the feasibility of personalized and adaptive stimulation, we will use multimodal imaging (EEG and fMRI) to track changes in frontotemporal synchrony, specifically theta-gamma phase-amplitude coupling and theta phase synchronization, that are known to support memory formation and retrieval. Aim 1 will establish how stimulation pattern (patterned vs. continuous waveforms) and schedule (one, three, or five consecutive days) shape the durability of memory enhancement. By comparing six systematically varied dosing protocols, we will determine the optimal pattern and repetition schedule that maximize and sustain improvements in working memory capacity, interference control, and long-term memory recognition over one month. By integrating behavioral, electrophysiological, and neuroimaging measures with adaptive control algorithms, this research will identify reliable biomarkers of responsiveness, elucidate causal mechanisms linking neural synchrony to memory, and yield a new class of personalized, connectivity-guided interventions for cognitive decline. The findings will lay a foundation for scalable, non-invasive, and mechanism-driven treatments for ADRD and age-related memory loss, advancing the broader NIH mission of promoting healthy cognitive aging.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
DOUBLE
Enrollment
240
Device: High definition transcranial electrical current stimulation Low-intensity, noninvasive application of electrical current to the human scalp with the goal of modulating levels of neuronal excitability.
Device: High definition transcranial electrical current stimulation Low-intensity, noninvasive application of electrical current to the human scalp with the goal of modulating levels of neuronal excitability.
Device: High definition transcranial electrical current stimulation Low-intensity, noninvasive application of electrical current to the human scalp with the goal of modulating levels of neuronal excitability.
Visual working memory capacity measured behaviorally
Behavioral k-capacity estimate derived from the change-detection task
Time frame: Baseline, 1-week after intervention, 1-month after intervention
Interruption suppression measured behaviorally
Memory accuracy performance difference between interruption and control trials on the interruption working memory task
Time frame: Baseline, 1-week after intervention, 1-month after intervention
EEG phase locking value (PLV) during working memory retention
Phase locking value between frontotemporal EEG electrodes within the theta frequency band during the memory retention interval of the visual working memory task
Time frame: Baseline, 1-week after intervention, 1-month after intervention
EEG phase amplitude coupling (PAC) during working memory retention
Theta phase gamma amplitude cross-frequency coupling at temporal EEG electrodes during the memory retention interval of the visual working memory task
Time frame: Baseline, 1-week after intervention, 1-month after intervention
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Device: High definition transcranial electrical current stimulation Low-intensity, noninvasive application of electrical current to the human scalp with the goal of modulating levels of neuronal excitability.
Device: High definition transcranial electrical current stimulation Low-intensity, noninvasive application of electrical current to the human scalp with the goal of modulating levels of neuronal excitability.
Device: High definition transcranial electrical current stimulation Low-intensity, noninvasive application of electrical current to the human scalp with the goal of modulating levels of neuronal excitability.