This project aims to investigate (1) the behavioral and neural mechanisms of regulation of craving in Internet gamers; (2) effects of tDCS over the dorsal lateral prefrontal cortex (dlPFC) on craving and regulation of craving and aversive emotions in this population. (3) effects of tDCS over dlPFC on attentional bias towards gaming related cues.This project will be conducted in Beijing, China, based on a large sample of Internet gamers.
As with the experiment about tDCS effects on regulation of craving and aversive emotions, the experiment aims to test whether tDCS over dlPFC will enhance cognitive regulation of craving and aversive emotions. It is a within-subject, sham-controlled, double-blind design. Each participant receive both active and sham tDCS of dlPFC in a randomized order separated by one week. During both active and sham tDCS sessions, participants will perform regulation of craving (ROC) and emotion regulation (ER) tasks. In the ROC task, participants will be asked to downregulate and upregulate craving elicited by gaming pictures using cognitive reappraisal. In the ER task, participants will be asked to downregulate and upregulate aversive feelings elicited by negative pictures using cognitive reappraisal. During these tasks, self-report ratings and skin conductance responses (SCRs) will be recorded. The cognitive regulation ability is indexed by rating and SCRs differences between the up- and downregulation conditions. As with the experiment about tDCS effects on attentional bias, the experiment aims to test whether tDCS over dlPFC will enhance inhibitory control of attentional bias towards gaming related cues. The inhibitory control of attentional bias will be measured by a cognitive task in which participants will perform a number classification task with gaming pictures and non-gaming pictures being distractors. The experiment is a within-subject, sham-controlled, double-blind design. Each participant will receive both active and sham tDCS of dlPFC in a randomized order separated by one week. After each tDCS session, participants will complete the cognitive task assessing inhibitory control of attentional bias. During the task, reaction times (RTs) wil be recorded. The attentional bias is indexed by RTs differences between trials with gaming pictures and trials with non-gaming pictures.
Study Type
INTERVENTIONAL
Allocation
RANDOMIZED
Purpose
BASIC_SCIENCE
Masking
DOUBLE
Enrollment
20
During active tDCS session, participants will perform the regulation of craving (ROC) and emotion regulation (ER) tasks. In the ROC task, participants will downregulate and upregulate craving elicited by gaming pictures using cognitive reappraisal. In the ER task, participants will downregulate and upregulate aversive feelings by negative pictures using cognitive reappraisal. After the active tDCS session, participants will complete a cognitive task assessing inhibitory control of attentional bias, in which participants will perform a number classification task with gaming pictures and non-gaming pictures being distractors. During the task, reaction times (RTs) wil be recorded.
During the sham tDCS session, participants will perform the regulation of craving (ROC) and emotion regulation (ER) tasks. In the ROC task, participants will downregulate and upregulate craving elicited by gaming pictures using cognitive reappraisal. In the ER task, participants will downregulate and upregulate aversive feelings by negative pictures using cognitive reappraisal. After the sham tDCS session, participants will complete a cognitive task assessing inhibitory control of attentional bias, in which participants will perform a number classification task with gaming pictures and non-gaming pictures being distractors. During the task, reaction times (RTs) wil be recorded.
State Key Laboratory of Cognitive Neuroscience and Learning, Beijing Normal University
Beijing, Beijing Municipality, China
Craving in the regulation of craving (ROC) task after the initiation of active and sham tDCS
Using the Visual Analog Scale (from 1 = 'not at all' to 9 = 'very much'), craving is assessed in the ROC task. This task lasts 12-13 minutes. Craving in the downregulation condition will be compared between the active and sham tDCS. Craving in the upregulation condition will also be compared between the active and sham tDCS.
Time frame: 4 minutes after the initiation of active and sham tDCS for half of the participants
Aversive feeling in the emotion regulation (ER) task after the initiation of active and sham tDCS
Using the Visual Analog Scale (from 1 = 'not at all' to 9 = 'very much'), aversive feeling is assessed in the ER task. This task lasts 12-13 minutes. Aversive feeling in the downregulation condition will be compared between the active and sham tDCS. Aversive feeling in the upregulation condition will also be compared between the active and sham tDCS.
Time frame: 16-17 minutes after the initiation of active and sham tDCS
Reaction times (RTs) in the cognitive task assessing inhibition of attentional bias after the initiation of active and sham tDCS
Using the E-prime software, RTs are recorded in milliseconds in the cognitive task assessing inhibition of attentional bias. The cognitive task lasts 5-6 minutes. RTs difference between the trials including gaming pictures and those including gaming pictures will be calculated and such RTs difference will be compared between the active and sham tDCS.
Time frame: 45-47 minutes after the initiation of of active and sham tDCS
Skin conductance responses (SCRs) in the ROC task after the initiation of active and sham tDCS
Using a biosignal recorder, SCRs are recorded in μs in the ROC task. This task lasts 12-13 minutes. SCRs in the downregulation condition will be compared between the active and sham tDCS. SCRs in the upregulation condition will also be compared between the active and sham tDCS.
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Time frame: 4 minutes after the initiation of active and sham tDCS
Skin conductance responses (SCRs) in the ER task after the initiation of active and sham tDCS
Using a biosignal recorder, SCRs are recorded in μs in the ER task. This task lasts 12-13 minutes. SCRs in the downregulation condition will be compared between the active and sham tDCS. SCRs in the upregulation condition will also be compared between the active and sham tDCS.
Time frame: 16-17 minutes after the initiation of active and sham tDCS ham tDCS
Background craving before the initiation of active and sham tDCS
Using the Visual Analog Scale (from 1 = 'not at all' to 9 = 'very much'), background craving is assessed with a one-item questionaire (how much do you crave playing internet games now?). This assessment lasts approximately 1 minute. Background craving will be compared between the active and sham tDCS.
Time frame: Approximately 10 minutes before the initiation of active and sham tDCS
Cue-induced craving before the initiation of active and sham tDCS
Using the Visual Analog Scale (from 1 = 'not at all' to 9 = 'very much'), cue-induced craving is assessed in a cue-reactivity task. This assessment lasts 1-2 minutes. Cue-induced craving will be compared between the active and sham tDCS.
Time frame: Approximately 8 minutes before the initiation of active and sham tDCS
Background craving after the initiation of active and sham tDCS
Using the Visual Analog Scale (from 1 = 'not at all' to 9 = 'very much'), background craving is assessed with a one-item questionaire (how much do you crave playing internet games now?). This assessment lasts approximately 1 minute. Background craving will be compared between the active and sham tDCS.
Time frame: 38-40 minutes after the the initiation of active and sham tDCS
Cue-induced craving after the initiation of active and sham tDCS
Using the Visual Analog Scale (from 1 = 'not at all' to 9 = 'very much'), cue-induced craving is assessed in a cue-reactivity task. This assessment lasts 1-2 minutes. Cue-induced craving will be compared between the active and sham tDCS.
Time frame: 40-42 minutes after the the initiation of active and sham tDCS