Dynamic Causal Modeling of Neuromodulation of Action Speed Via Targeted TMS-EEG

Summary

Stroke is a major cause of long-term disability, with cognitive and motor deficits-especially action slowing and executive dysfunction-being strong predictors of poor recovery outcomes. Recent advances in network neuroscience suggest that action speed is governed by interactions between specific prefrontal and premotor regions. However, the precise neural mechanisms underlying action slowing in stroke remain unclear, limiting the efficacy of current rehabilitation approaches. This study integrates high-density EEG, fNIRS and dynamic causal modeling (DCM), and rTMS to map and modulate the neural circuits involved in action speed. In the first phase, we will assess the role of seven key brain regions in action speed modulation by applying virtual lesions using single-pulse TMS in 60 healthy individuals. In the second phase, we will apply offline intermittent theta burst stimulation (iTBS) to the most relevant regions and evaluate its impact on action speed. Finally, in the clinical phase, we will administer individualized iTBS to 20 stroke patients to enhance action speed. Patients will be assessed at baseline, immediately post-treatment, and after one and three months to track improvements in action speed using DCM and behavioral tests. Changes in connectivity and action speed performance will be compared to healthy controls to refine treatment parameters. Secondary outcomes include executive function and daily life motor performance. Longitudinal follow-up will determine the persistence of improvements, informing future personalized rehabilitation strategies. By characterizing effective connectivity changes post-stroke, we aim to refine neuromodulation strategies and develop a personalized rTMS approach. Our hypothesis is that targeting specific regions identified through integration of EEG, fNIRS and DCM can enhance action speed, ultimately improving functional recovery. This personalized approach could lead to more effective rehabilitation protocols, tailored to individual brain damage patterns.

Conditions

• Temporal Perturbation
• Virtual Lesion
• EEG
• fNIRS
• TMS
• Stroke Lesions
• Action Slowing
• Stroke

Interventions

OTHER

Phase 1 functional MRI (fMRI)

3D T1-weighted imaging (T1w) and (10 min) resting-state functional MRI (fMRI) will be acquired for each healthy subject to identify target regions for TMS interventions. Phase 1 aims to assess the impact of temporary disruption (caused by virtual lesions (VL)) on action speed, measured by reaction time (RT) using a simple reaction time (SRT) task in healthy subjects

OTHER

Phase 2 functional MRI (fMRI)

Phase 2 will assess the effects of intermittent theta burst stimulation (iTBS) on improving action speed in healthy individuals.

OTHER

Phase 3 functional MRI (fMRI)

Phase 3 administers iTBS to enhance action speed in stroke patients within the first six months post-stroke, leveraging individualized action speed models to tailor interventions.

Sponsors & Collaborators

• CHRU LILLE

  collaborator UNKNOWN

• Centre Hospitalier Universitaire, Amiens

  lead OTHER

Study Design

Allocation

NON_RANDOMIZED

Purpose

OTHER

Masking

NONE

Model

PARALLEL

Eligibility

Min Age

18 Years

Sex

ALL

Healthy Volunteers

Yes

Timeline & Regulatory

Start

2026-01-06

Primary Completion

2028-12-31

Completion

2028-12-31

Countries

• France

Study Locations