1997; Calvert 2001; Lehmann et al. 2006; Pekkola et al. 2006), PI3K Inhibitor Library cost auditory and somatosensory cortices (Foxe et al. 2002; Schürmann et al. 2006), as well as visual and somatosensory cortices (Macaluso et al. 2000,

2002). However, a recent fMRI study investigated crossmodal effects on BOLD responses generated in the primary somatosensory cortex (SI) when both stimuli were relevant for guiding a motor response. Here, relevant unimodal (visual or tactile) and crossmodal stimuli (simultaneous Inhibitors,research,lifescience,medical visual + tactile) were presented and participants were required to summate both stimuli by squeezing a pressure-sensitive bulb. In order to ensure that stimulus associations were successfully learned prior to testing, participants completed a brief sensorimotor training session that required them to judge the amplitude of visual and vibrotactile stimuli and make a graded motor response representing the perceived amplitude of the stimuli. Inhibitors,research,lifescience,medical Results showed that the greatest BOLD responses were elicited in SI during crossmodal versus unimodal interactions suggesting that combining visual-tactile information relevant for behavior enhances modality-specific excitability in SI (Dionne et al. 2010). In a follow-up study, Dionne et al. (2013); used electroencephalography Inhibitors,research,lifescience,medical (EEG) and the same sensory-to-motor task to investigate the time course of crossmodal effects in SI. Results

showed that crossmodal interactions between vibrotactile and visual stimuli enhanced the amplitude of the somatosensory P50 component, generated in SI, at contralateral parietal electrode sites only when both stimuli were task-relevant. Inhibitors,research,lifescience,medical By contrast, the amplitude of the P100, likely generated in SII, increased bilaterally at parietal electrode sites during presentation of crossmodal stimuli but was not sensitive to the task-relevance of the stimuli. These Inhibitors,research,lifescience,medical findings suggest that crossmodal modulation occurs at very early stages in the somatosensory processing stream if both stimuli are relevant

for behavior (Dionne et al. 2013). Several other EEG studies support the finding that crossmodal stimuli can modulate neural excitability at very early stages of sensory processing. For example, Giard and Peronnet (1999); found that visual modulation for audio-visual stimuli, occurred Thymidine kinase as early as 40-msec post stimulus onset, while audio-tactile modulation has been found at 50 msec (Foxe et al. 2000; Molholm et al. 2002). Kennett et al. (2001); found modulation of visual event-related potentials (ERPs) by irrelevant but spatially aligned tactile stimuli at approximately 140-msec post visual onset, while McDonald et al. (2000); reported modulation of visual ERPs was possible with spatially aligned auditory stimuli. In summary, crossmodal interactions can improve behavioral performance and enhance neural excitability at early stages in modality-specific cortices to achieve goal-oriented behaviors (Dionne et al. 2010, 2013).