Abstract
BackgroundBehavioral studies in both human and animals generally converge to the dogma that multisensory integration improves reaction times (RTs) in comparison to unimodal stimulation. These multisensory effects depend on diverse conditions among which the most studied were the spatial and temporal congruences. Further, most of the studies are using relatively simple stimuli while in everyday life, we are confronted to a large variety of complex stimulations constantly changing our attentional focus over time, a modality switch that can impact on stimuli detection. In the present study, we examined the potential sources of the variability in reaction times and multisensory gains with respect to the intrinsic features of a large set of natural stimuli.Methodology/Principle findingsRhesus macaque monkeys and human subjects performed a simple audio-visual stimulus detection task in which a large collection of unimodal and bimodal natural stimuli with semantic specificities was presented at different saliencies. Although we were able to reproduce the well-established redundant signal effect, we failed to reveal a systematic violation of the race model which is considered to demonstrate multisensory integration. In both monkeys and human species, our study revealed a large range of multisensory gains, with negative and positive values. While modality switch has clear effects on reaction times, one of the main causes of the variability of multisensory gains appeared to be linked to the intrinsic physical parameters of the stimuli.Conclusion/SignificanceBased on the variability of multisensory benefits, our results suggest that the neuronal mechanisms responsible of the redundant effect (interactions vs. integration) are highly dependent on the stimulus complexity suggesting different implications of uni- and multisensory brain regions. Further, in a simple detection task, the semantic values of individual stimuli tend to have no significant impact on task performances, an effect which is probably present in more cognitive tasks.
Highlights
It is widely accepted that multisensory presentation of stimuli leads to a behavioural facilitation compared to unisensory presentation (A or V alone) [1]
Among many parameters that can be derived from the matrices, we focused on four of second-order parameters, which we computed across four different orientations (0 ̊, 90 ̊, 180 ̊ and 270 ̊)
As reported in previous studies, we found that, for both monkeys and for human subjects, the modality of the stimulus had a strong effect on reaction times (RT)
Summary
It is widely accepted that multisensory presentation of stimuli (e.g. an auditory stimulus A simultaneous with a visual stimulus V) leads to a behavioural facilitation compared to unisensory presentation (A or V alone) [1]. Cappe and collaborators [14] adapted such paradigms to the rhesus macaque monkey and showed that a simple manual detection task can reveal multisensory integration in this species, like in humans or other species [15,16,17]. Some recent studies combined some of these factors (i.e. spatial location and effectiveness) using simple stimuli and showed a strong interdependency between these factors in determining behavior and shaping perception [26,27] Behavioral studies in both human and animals generally converge to the dogma that multisensory integration improves reaction times (RTs) in comparison to unimodal stimulation. These multisensory effects depend on diverse conditions among which the most studied were the spatial and temporal congruences. We examined the potential sources of the variability in reaction times and multisensory gains with respect to the intrinsic features of a large set of natural stimuli
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