Flavor Processing: Perceptual and Cognitive Factors in Multi-modal Integration

Abstract

The chemical senses may represent the most fundamental integrative sensory modalities. For example, flavor perception is widely considered to be an integrative process whereby two distinct neural systems (olfactory and gustatory) are activated peripherally to give rise to a unitary oral sensation of flavor. Benefits of multimodal sensory integration in other modalities include increased sensitivity and reaction times (Krushel and van der Kooy, 1988; Fowler and Dekle, 1991; Schifferstein and Verlegh, 1995). Investigations into the integration of multisensory information at a neural level in cats and primates have revealed that neurons of the superior colliculus are capable of integrating cues from three sensory modalities: vision, audition and somatosensation (Rolls and Baylis, 1994; Schul et al., 1996; Whalen, 1998). The close relationship between smell and taste along with the evidence of the existence of neurons particularly sensitive to multimodal inputs, led us to hypothesize that neural inputs for odor and taste can be integrative and exhibit perceptual additivity at subthreshold intensities such as that seen previously only with mixtures within a single modality. In the studies presented here, we evaluated the summation of odor and taste mixtures where each of the individual components were presented at sub-threshold levels. In the first study, multiple olfactory thresholds were measured within a group of 10 volunteers (five males and five females, ranging in age from 22 to 33 years) while holding an oral stimulus in the mouth (Dalton et al., 2000). One each day of testing, nasal detection thresholds for benzaldehyde and oral detection thresholds for saccharin were measured in counter-balanced order. A modified staircase method was employed for collecting detection thresholds using a five-reversal criterion. Subjects were given a 15 min break before a second nasal detection threshold for benzaldehyde was measured while holding a saccharin solution in the mouth. As single thresholds always preceded mixtures, a control procedure was incorporated where subjects were tested for single benzaldehyde thresholds followed by another single benzaldehyde threshold without taste stimuli. While holding the oral saccharin solution, sensitivity to benzaldehyde increased by an average of 28% over benzaldehyde threshold taken alone. This increase in sensitivity was significant (P = 0.01) with 9 of 10 subjects showing marked differences between benzaldehyde thresholds alone and in the cross-modal mixture. The incorporation of the control trials ruled out any effect of repeated testing since these trials resulted in a nonsignificant (P = 0.71) decrease in sensitivity. The effect did not appear to be due to concomitant somatosensory input from an oral stimulus or differences in breathing or airflow, as a second experiment found that filtered deionized water did not lower the threshold for benzaldehyde. However, there did appear to be an effect of stimulus congruency: when benzaldehyde was paired with an incongruent taste stimulus (L-glutamic acid monosodium salt or MSG) in the same protocol, thresholds for benzaldehyde were not significantly lower in the presence of MSG than when tested alone (P = 0.57).