Individual differences in attributional style but not in interoceptive sensitivity, predict subjective estimates of action intention

The debate on the existence of free will is on-going. Seminal findings by Libet et al. (1983) demonstrate that subjective awareness of a voluntary urge to act (the W-judgment) occurs before action execution. Libet's paradigm requires participants to perform voluntary actions while watching a clock hand rotate. On response trials, participants make a retrospective judgment related to awareness of their urge to act.This research investigates the relationship between individual differences in performance on the Libet task and self-awareness. We examined the relationship between W-judgment, attributional style (AS; a measure of perceived control) and interoceptive sensitivity (IS; awareness of stimuli originating from one's body; e.g., heartbeats). Thirty participants completed the AS questionnaire (ASQ), a heartbeat estimation task (IS), and the Libet paradigm. The ASQ score significantly predicted performance on the Libet task, while IS did not - more negative ASQ scores indicated larger latency between W-judgment and action execution. A significant correlation was also observed between ASQ score and IS. This is the first research to report a relationship between W-judgment and AS and should inform the future use of electroencephalography (EEG) to investigate the relationship between AS, W-judgment and RP onset. Our findings raise questions surrounding the importance of one's perceived control in determining the point of conscious intention to act. Furthermore, we demonstrate possible negative implications associated with a longer period between conscious awareness and action execution. © 2014 Penton, Thierry and Davis

Effects of force–load on cortical activity preceding voluntary finger movement: Whole-scalp magnetoencephalography of the Bereitschaftsfeld

Neural activity preceding force-loaded voluntary finger movement (the Bereitschaftsfeld) was recorded using 143-channel whole-scalp magnetoencephalography (MEG) in order to determine how the level of force produced during voluntary finger movement is represented in activity over different premovement time intervals localized to different cortical areas. Eighteen healthy subjects performed voluntary right index-finger extension movements against an inertial load of either 0, 100, or 200 g. Results showed that the earliest component of premovement activity, beginning between 1.5 and 1.0 s prior to movement and localized to the central midline around the region of supplementary/cingulate motor areas, was not modulated by the level of force required for movement. However, later premovement activity, occurring between 500 and 200 ms prior to movement onset, was significantly greater for the highest force movements compared with both intermediate (p < 0.05) and no weight-load conditions (p < 0.01). This component was localized to primary sensorimotor cortical areas, with greater source strength on the left side contralateral to movement. Results indicate that, although early premovement activity of the supplementary/cingulate motor areas does not appear to encode movement force, later premovement activity of the primary motor cortex is significantly greater for movements made with more force, not only during movement execution but also up to 500 ms prior in readiness for intended movements of greater force

Experiments in Movement Using DC-EEG, MEG, SPECT and FMRI

Our volitional self-initiated acts are preceded by the Bereitschaftspotential (BP) or readiness potential [34,35]. The BP has an early component (BP1) and a late component (BP2, see Fig. 1). The early component BP1 lasts from the very beginning of the BP (1-2 s or more prior to movement onset depending on the complexity of the movement) to app. ½ s prior to movement onset and the late component BP2 lasts from ½ s before to the onset of movement itself (s 0 in Fig. 1). BP1 is symmetrical even for unilateral movement, while BP2 is larger over the contralateral hemisphere