Trials / Unknown

UnknownNCT05263414

Neuromodulation of Inhibitory Control in Tic Disorders

Modulation of Neurocognitive Mechanisms Involved in Inhibitory Control in Tic Disorders

Status: Unknown
Phase: N/A
Study type: Interventional
Enrollment: 26 (estimated)

Sponsor: IRCCS Eugenio Medea · Academic / Other
Sex: All
Age: 18 Years – 50 Years
Healthy volunteers: Accepted

Summary

The present study aims to assess the effects of non invasive electrical stimulation of the vagus nerve via transcutaneous vagus nerve stimulation (tVNS) on cognitive functions, inhibitory and tic control in patients with tic disorders. Taking into account the role that GABA plays in inhibitory control, the presence of alteration of GABA neurotransmission in Tic disorders and the possibility to increase GABA release with tVNS, the investigators hypothesized that tVNS might improve behavioral control in Tic disorders. Moreover, as suggested by previous studies investigating the effects of tVNS in other patient populations, the investigators expected that tVNS will be safe and well tolerated. Such results would encourage the use of tVNS in Tic disorders.

Detailed description

The investigators planned a single centre, randomized, double-blind, sham- controlled, crossover (within subject) design. Adults with Tic Disorders will be recruited and randomly assigned to two different groups: the active-tVNS group and the sham-tVNS group. Each group will undergo a two-sessions intervention during which active tVNS followed by sham tVNS or sham tVNS followed by active tVNS will be delivered in the active and sham tVNS group, respectively. The stimulation will be delivered during the execution of an inhibitory task and an attentional task. For the inhibitory task a Contextual Go No-Go paradigm will be used. During this task, participants will be presented with visual stimuli representing everyday actions embedded within congruent or incongruent context. For example, stimuli could consist in precision or grasping actions suggesting the intention to eat or to move the object in another place. For each stimulus, there will be a kinematic component consisting in the movement performed by the model and a contextual component, consisting in the embedding scenario of the action (a breakfast scenario, or a cleaning scenario). Participants will be instructed to press a button when a specific intention (go) will be suggested by the video and not to press a button for the opposite intention (no go), either according to the kinematics or to the context, depending on the experimental block. This way, it will be possible to assess inhibitory control at response level. Crucially, kinematics and context of the visual stimuli could point toward the same (congruent) or opposite (incongruent) intentions, thus allowing to assess inhibitory control at the stimulus level. For the attentional task, the attentional network test (ANT; Fan et al.,2002) will be used. The task is a modified version of a Flanker task and it allows measuring orienting, alerting and executive control components. To assess the clinical, neuropsychological and behavioural profiles, the Yale Global Tic Severity Rating Scale (YGTSS), the EuroQol quality of life questionnaire, the Raven Matrix, the Autism Quotient, the Barratt Impulsiveness scale and the Navon Task will be used. The effects of tVNS on patients' behavioural control (as assessed through the Contextual Go No-Go task and the ANT) will be related to clinical, neuropsychological and behavioural profile, for identifying best the features tVNS responder patients. Side effects will be tested after each session. The protocol will allow testing the efficiency of tVNS in: * enhancing inhibition at response level (response selection) in Tic disorders; * enhancing inhibition at stimulus level (response inhibition) in Tic disorders; * improving alerting, orienting or executive control in Tic disorders; * improving patients' quality of life and Tic control; * further investigating the safety and tolerability of tVNS.

Conditions

Tic Disorders

Interventions

Type	Name	Description
DEVICE	tVNS	tVNS allows the non-invasive activation of the Vagus Nerve by delivering electrical pulses to the sensory afferent fibers of the auricular, thick-myelinated, branch of the vagus nerve in the outer ear. TVNS seems to engage the same neural pathways of invasive VNS methods and may provide a novel, bottom-up NIBS method to promote GABA release. tVNS will be performed by using a CE marked tVNS device. It consists in a programmable stimulation unit connected to two titan ear electrodes that are mounted on a gel frame, allowing to generate and transfer electric impulses from the stimulation unit to the surface of the skin, where the electrodes are applied.

Timeline

Start date: 2022-06-01
Primary completion: 2023-03-31
Completion: 2023-04-30
First posted: 2022-03-02
Last updated: 2022-03-02

Locations

1 site across 1 country: Italy

Source: ClinicalTrials.gov record NCT05263414. Inclusion in this directory is not an endorsement.