Transcranial Magnetic Brain Stimulation to Reduce Cannabis Use in Heavy Cannabis Users (iCURE)

The expanding legalization of cannabis across the U.S. is associated with increases in cannabis use and, accordingly, an increase in the number of individuals with cannabis use disorder (CUD). One key predictor of relapse is elevated attentional bias to drug cues, coupled with attenuated cognitive control in the presence of those cues. Attentional bias to drug cues is associated with increased activity in the Salience Network (SN), including the anterior cingulate cortex and bilateral anterior insula, as well as reduced activity in the dorsolateral prefrontal cortex (DLPFC) and broader cognitive control circuitry during exposure to cannabis cues.

Our prior data demonstrate that neural responses to drug cues can be reduced by attenuating ventromedial prefrontal cortex (VMPFC) and reward circuitry using inhibitory repetitive transcranial magnetic stimulation (rTMS) (Strategy 1). An alternative approach, however, may be to enhance activity in the DLPFC and cognitive control circuitry, which may also reduce neural reactivity to drug cues by inversely regulating SN cue hyper-reactivity (Strategy 2, the focus of this K01). Through the research and training plan outlined in this K01 proposal, I seek to evaluate the ability of left DLPFC-targeted rTMS to attenuate SN drug cue reactivity and attentional bias, and to reduce cannabis use. This will be accomplished by applying accelerated intermittent theta burst stimulation (aiTBS), a novel patterned excitatory form of rTMS, to the L DLPFC in heavy cannabis users.

GOAL. The primary objectives of this K01 research project are to:

1. determine whether L DLPFC aiTBS decreases cannabis use using real-time data collected in the natural environment;
2. determine whether aiTBS-induced changes in cannabis use are associated with changes in Salience Network drug cue reactivity; and
3. assess whether L DLPFC aiTBS is feasible, tolerable, and safe relative to sham stimulation.

DESIGN. Fifty (50) treatment-seeking, heavy (near-daily) cannabis users will be randomized to receive either active or sham aiTBS targeting the L DLPFC. Participants will complete a total of 25 treatment sessions, delivered as five sessions per day (50-min inter-session interval) across five treatment days, with visits flexibly scheduled over a two-week period. Cannabis use data will be collected throughout the study, and functional magnetic resonance imaging (fMRI) data will be collected before and after aiTBS treatment, as well as following a 4-week follow-up period.

Cannabis use in the natural environment will be assessed using Ecological Momentary Assessment (EMA) during a two-week baseline (pre-treatment) period, a two-week treatment period, and a four-week follow-up period. Frequency of use (days per week) and quantity of use (average grams per use day) will be captured via EMA and corroborated during the four follow-up visits using Timeline Followback (TLFB) interviews and urine toxicology to assess cannabis and other substance use and to monitor for adverse events.

We will test the hypotheses that active aiTBS will reduce neural reactivity to cannabis cues (Aim 2), reduce cannabis use frequency and/or quantity (Aim 1), and demonstrate non-inferior feasibility, tolerability, and safety compared to sham stimulation (Safety Aim).

Over the two-year recruitment period, this project will generate a critical dataset to advance brain stimulation treatment development for CUD. In addition, these data will support a subsequent R01 application aimed at extending this line of treatment development research. Finally, this project will provide essential training in human behavioral pharmacology and clinical trial research design and analysis, supporting my progression toward independence as an interdisciplinary addiction neuroscientist.