Clinical Trial Details
— Status: Completed
Administrative data
| NCT number |
NCT03907917 |
| Other study ID # |
1412015006_b |
| Secondary ID |
1K23MH111977 |
| Status |
Completed |
| Phase |
N/A
|
| First received |
|
| Last updated |
|
| Start date |
April 9, 2019 |
| Est. completion date |
June 1, 2023 |
Study information
| Verified date |
August 2023 |
| Source |
University of Kentucky |
| Contact |
n/a |
| Is FDA regulated |
No |
| Health authority |
|
| Study type |
Interventional
|
Clinical Trial Summary
Psychiatric disorders characterized by pathological fear and anxiety are common and often
disabling. Despite their limitations, exposure therapies are among the most efficacious
treatments for these disorders. Extinction learning is thought to be a core mechanism of
therapeutic exposure. Extinction learning is mediated by a well-defined circuit encompassing
the medial prefrontal cortex (mPFC), amygdala, and hippocampus. This raises the exciting
possibility that direct engagement of this circuitry might enhance the response to
therapeutic exposure. Transcranial direct current stimulation (tDCS) is a neuromodulation
technology that can augment brain plasticity, learning, and memory. The proposed study will
evaluate whether tDCS can engage extinction circuitry, and improve extinction learning and
memory.
This study will enroll psychiatrically healthy volunteers to test whether tDCS applied to the
mPFC can augment spontaneous mPFC activity, engagement of extinction circuitry during
extinction learning and recall, and classically-conditioned extinction learning and memory.
Healthy volunteers will complete a standardized, three-day fear conditioning and extinction
learning and memory task. On day 1, participants will complete a fear conditioning task. On
day 2, participants will receive sham (placebo) or active tDCS prior to completing a fear
extinction learning task. On day 3, participants will complete an extinction recall task.
Electrodermal activity and heart rate will be continuously monitored during the conditioning
and extinction procedures to assess autonomic arousal. All procedures will be completed in a
magnetic resonance imaging (MRI) scanner; imaging data will be collected before and after
tDCS and during all conditioning and extinction procedures.
Description:
Most effective behavioral treatments of disordered anxiety involve repeated exposure to
feared stimuli, which often results in systematic reductions in fearful responding to said
stimuli. It is believed that this process results from successful fear extinction, a
well-characterized learning process that is mediated by fear extinction brain circuitry.
Namely, fear extinction is an inhibitory learning process that requires activation and
plasticity within a variety of brain regions, including the medial prefrontal cortex (mPFC),
which can exert inhibitory control over fearful responding and parts of the brain that drive
said responding. Behavioral treatments of disordered anxiety, while effective, have serious
limitations; many patients fail to respond at all or only partially respond to exposure-based
treatments. One candidate reason for this is deficits in fear extinction learning or memory
processes. The proposed study aims to examine the effects of non-invasive neuromodulation -
namely, multifocal transcranial direct current stimulation (tDCS) targeting the mPFC - on
spontaneous mPFC activity (Aim 1), functional activation of fear extinction circuitry (Aim
2), and fear extinction learning and memory (Aim 3).
This study will randomize 64 psychiatrically healthy volunteers at the Yale (proposed n = 32)
and the University of Kentucky (proposed n = 32) for Aims 1-3. Following the completion of
proper diagnostic and safety screening and Institutional Review Board (IRB) approved informed
consent, healthy volunteers will complete a 3-day experimental procedure. Subjects will be
conditioned to fear a previously neutral stimulus on Day 1. Subjects will be randomized (1:1,
double-blind) to receive Active or Sham tDCS prior to fear extinction training on Day 2.
Allocation will be done by independent research staff at Yale, who is experienced with such
allocation, using block randomization (blocks of 8), stratified by sex. Subjects and
investigators will be blind to allocation. Lastly, the strength of extinction recall will be
tested on Day 3. Functional magnetic resonance imaging (fMRI) and psychophysiological
measures (electrodermal activity and heart rate) will be acquired during all fear
conditioning, extinction, and recall procedures and prior to and after tDCS.
tDCS will be delivered using an 8-channel Starstim transcranial electric stimulator from
Neuroelectrics. To target the mPFC, the anodal electrode will be placed over the frontal pole
(Fpz, 10-20 EEG landmarks) and will be surrounded by five return (cathodal) electrodes in a
circumferential array (AF7, AF8, F3, Fz, and F4). Subjects in the Active tDCS condition will
receive 20 minutes of direct current stimulation for 20 minutes; current will be ramped in
and out for 30 seconds at the beginning and end of the 20-minute period. Subjects in the Sham
tDCS condition will receive the same electrode placement and ramping procedures, but no
current will be delivered between ramping.
All healthy volunteers will complete state-of-the-art Human Connectome Project Style
(HCP-Style) accelerated multiband acquisition sequences. Scan sequences will be identical
across sites. Scans will include a mixture of structural, resting state, and functional fMRI
sequences. All scans will be completed on Siemens Prisma 3T scanners using 64-channel head
coils. Psychophysiological measures will include electrodermal activity (EDA) and heart rate.
All psychophysiological data will be collected with MRI-compatible Biopac systems.
Study 1 is well-powered for both planned and exploratory analyses; proposed methods help to
improve signal-to-noise-ratio (SCR) and our proposed sample size of 64 will adequately power
all a priori analyses, planned contrasts, and exploratory analyses. Power analysis suggested
a sample of 42 would be adequate for the proposed primary hypothesis tests. We propose to
recruit 70 participants to allow for approximately 10% attrition or data failures (e.g., head
movement or null skin conductance response [SCR]). Our statistical approach and statistical
power were developed in collaboration with statistical consultants of the PI and the primary
mentor.
The proposed study will provide important preliminary data to examine the potential for
medial prefrontal tDCS to augment and enhance fear extinction processes across multiple
levels of analyses: the effects of tDCS on extinction circuitry and classically-conditioned
extinction learning and memory.
