'Thermal taste' predicts higher responsiveness to chemical taste and flavor

Individual differences in taste perception have been explained in part by variations in peripheral innervation associated with the genetic ability to taste the bitter substances PTC and PROP. In the present study we report evidence of another source of individual differences that is independent of taste stimulus, taste quality, or gustatory nerve. Individuals who perceived taste from thermal stimulation alone (thermal taste) gave significantly higher taste ratings to chemical stimuli--often by a factor of >2:1--than did individuals who perceived no taste from thermal stimulation. This was true for all taste stimuli tested (sucrose, saccharin, sodium chloride, citric acid, quinine sulfate, MSG and PROP), for all three gustatory areas of the mouth (anterior tongue, posterior tongue and soft palate) and for whole-mouth stimulation. Moreover, the same individuals reported stronger sensations from the olfactory stimulus vanillin, particularly when it was sensed retronasally. The generality of the thermal-taster advantage and its extension to an olfactory stimulus suggests that it arises from individual differences in CNS processes that are involved in perception of both taste and flavor.     

Contributions of Smell and taste to overall intensity

The integration of olfaction and gustation in producing thesensation of flavor was studied using an almond extract stimuluspresented with the Two-Module Delivery System. Almond in themouth was found to influence the scaling of smell. The datasugest that this background effect is due to the diffusion ofairborne molecules from the oral cavity to the olfactory receptorsarea. At least under some stimulation conditons, almond vaporin the nose was shown to afect the scaling of taste. When scalingoverall intensity, subjects apparently added together the sensationsof smell and taste to produce the sensation of overall intensity.However, for all combinations of odorants and tastants, theestimate of overall intensity was less than the sum of the estimateof the smell and the estimate of the taste. The data furthersuggest that when estimating the overall intensity, the magnitudeassigned to the olfactory or gustatory sensations was less thanthat which have been assigned when estimating just smell ortaste.     

Evidence for human orosensory (taste?) sensitivity to free fatty acids

Accumulating evidence suggests dietary fatty acids (FAs) may be sensed in the oral cavity. However, the effective cues have not been characterized. In particular, influences from other sensory cues have hampered identification of an independent gustatory contribution. Experiment 1 examined techniques to minimize the formation of FA oxidation products and improve the homogeneity of water/lipid emulsions to be used as stimuli in Experiment 2, a psychophysical study to determine FA detection thresholds in humans. Through sonication of chilled samples held in polypropylene labware and the addition of 0.01% ethylenediaminetetraacetic acid, calcium disodium salt, homogenous emulsions of unoxidized linoleic and oleic FAs were obtained. Spectrophotometric analysis revealed no oxidation product formation over a 24-h period. Coupled with these techniques, a masking approach was used to minimize other sensory cues imparted from linoleic, oleic, and stearic FAs. Concentration ranges from 0.00028% to 5% (w/v) were prepared in mixtures with 5% mineral oil (w/v) and 5% gum acacia (w/v) to mask lubricity and viscosity effects, respectively. Testing was conducted under red light with nares blocked to eliminate visual and olfactory cues. Oral rinses with 20 ppm capsaicin were administered to desensitize participants to selected irritation effects prior to remeasuring linoleic acid detection thresholds. To determine if the effective stimulus was an oxidation product, oxidized linoleic acid was included among the test stimuli. Detection thresholds were obtained using a 3-alternative, forced-choice ascending-concentration presentation procedure. The mean detection threshold for linoleic acid pre-desensitization was 0.034 +/- 0.008%, for linoleic acid post-desensitization was 0.032 +/- 0.007%, for oleic 0.022 +/- 0.003%, for stearic 0.032 +/- 0.005%, and oxidized linoleic 0.025 +/- 0.005%. The results suggest that linoleic, oleic, stearic, and oxidized linoleic acids are detectable in the oral cavity of humans with minimal input from the olfactory, capsaicin, and viscosity-assessing tactile systems.     

The independence and integration of olfaction and taste

To study the influences of smell on the scaling of taste, andvice versa, an unobtrusive device was developed which permitsthe independent varying of the olfactory and gustatory componentsof a flavor compound. With instant coffee and the method ofmagnitude estimation, the slopes of the olfactory, taste, andflavor curves produced by this device were similar to thoseproduced by more traditional delivery systems. To study theinteraction of taste on smell and vice versa, subjects scaledolfactory stimuli against different taste backgrounds and tastestimuli against different odorant backgrounds. Taste backgroundsdid not significantly alter the scaling of olfaction. Similarly,olfactory backgrounds did not significantly alter the scalingof taste. Finally, subjects scaled overall intensity (flavor)when presented with all combinations of four concentrationsof odorants and tastants. Smell and taste were shown to contributeindependently to the estimation of overall intensity.     

The role of desensitization to capsaicin in chili pepper ingestion and preference

It has been suggested that part of the widespread preferencefor chih pepper can be explained as a desensitization of thechemical irritant receptors in the mouth, produced by continuedexposure to chili pepper. To evaluate this possibility, we measuredetection thresholds and salivary response of subjects who varyin liking for chili pepper and amount of exposure to it. Thestimuli used are aqueous solutions of capsaicin, the purifiedpiquant agent in chili peppers. We find very small but reliableand significant decreases in sensitivity to capsaicin for bothmeasures by chili likers or users. We conclude that there isa slight desensitization effect, but also that it cannot bea major factor in explaining the acquisition of chili preference.There is too much overlap between groups, and chili likers claimto like chili because of its chemical irritant ("mouth burn")effect, not in spite of it.     

Sensory irritation and taste produced by NaCl and citric acid: effects of capsaicin desensitization

Three experiments were conducted to measure the sensory irritationproduced by two prototypical gustatory stimuli: citric acidand NaCl. The stimuli were applied to the tip of the tongueon filter paper disks. The first experiment revealed that solutionsof NaCl and citric acid that produced approximately equal tastesensations also produced similar amounts of irritation; thatthe psychophysical functions for irritation were approximatelytwice as steep as the functions for taste; and that irritationgrew over time for NaCl but not for citric acid. When viewedas a percentage of the taste sensation at 25 s, NaCl irritationaveraged 23% at the lowest concentration and 70% at the highestconcentration; citric acid irritation averaged 44% at the lowestconcentration and 98% at the highest concentration. The secondexperiment investigated whether the irritation produced by thesetwo stimuli was mediated via capsaicin-sensitive (CS) fibers.The experiment included a pre-test, an irritation treatmentwith either capsaicin (a desensitizing agent) or zingerone (anon-desensitizing agent), a 15 min rest period and a post-test.Reductions in irritation and taste occurred following treatmentwith both capsaicin and zingerone. A third experiment demonstratedthat the majority of the effect of zingerone on taste and irritationwas due to a perceptual context effect. After the context effectwas taken into account, capsaicin desensitization remained significantfor both salt taste and salt irritation at the highest concentration.A similar pattern of results for citric acid suggests that bothcitric acid and NaCl produce irritation in part via CS fibers.The results are discussed in terms of the ability of subjectsto discriminate the gustatory and chemesthetic components oforal sensations and the role of salt and acid irritation inflavor perception.     

Phenylalanine ammonia-lyase activity and capsaicin-precursor compounds in p-fluorophenylalanine-resistant and -sensitive variant cells of chili pepper (Capsicum annuum)

Cell suspension cultures of chili pepper ( Capsicum annuum L. cv. Tampiqueño 74) displaying differences in their resistance to p -fluorophenylalanine (PFP) and in their contents of capsaicin (the compound which is responsible for the hot taste of chili pepper fruits) were characterized in relation to the activity of phenylalanine ammonia-lyase (PAL; EC 4.3.1.5), the levels of free l -phenylalanine, phenolics and the phenylpropanoid acids involved in capsaicin biosynthesis. A nonselected cell line, a sensitive line (CA-02), a moderately resistant cell line (CA-29) and two resistant cell lines (CA-04 and CA-16) were studied. Higher PAL activities and higher levels of phenylalanine and phenolics were found in the PFP-resistant cells even after a minimum of 9 subcultures (15 days each) in the absence of the analog, indicating that the selected trait was stable. PFP-resistant chili pepper cells accumulated higher amounts of capsaicin precursors (cinnamic, caffeic and ferulic acids) than either the nonselected cells or the sensitive cell line. p -Coumaric acid was not detected at significant levels in any of the cell cultures. Overall, accumulation of free phenyl-alanine correlated well with PAL activity, phenolics, phenylpropanoids and capsaicin levels, suggesting an active flow through the phenylpropanoid pathway in PFP-resistant cells of chili pepper.     

Capsaicin as a cutaneous stimulus: sensitivity and sensory qualities on hairy skin

An experiment was conducted to investigate the sensitivity ofthe skin to capsaicin. Whereas most previous work on capsaicin'scutaneous (extra-oral) effects have focused on its ability tosensitize or desensitize the skin to subsequent stimulation,the present study measured the absolute sensitivity to, andthe sensations produced by, transient exposures to capsaicin.A wide range of concentrations of capsaicin was presented tothe volar forearm under conditions that prevented significantevaporation for the first 10 min of exposure, and subjects reportedthe sensations they experienced over a 20-min period. The resultsshowed that capsaicin produced a variety of sensations (includingitch, stinging/pricking and burning) that varied in time andfrequency of appearance. Missing from the subjective reportswas a significant thermal component to the sensation; capsaicinapparently failed to stimulate warm fibers either strongly orreliably. Overall, however, the variety of sensations inducedby capsaicin reflects the multi-modal nature of the chemicalsensitivity of the skin.     

fMRI activation in response to odorants orally delivered in aqueous solutions

During food intake flavor perception results from simultaneous stimulation of the gustatory, olfactory and trigeminal systems. Olfactory stimulation occurs mainly through the retronasal pathway and the resulting perception is often interpreted as a taste perception, thus leading to the well-known sensory confusion between taste and olfaction. The present experiment was designed to study, with functional magnetic resonance imaging (fMRI), the cortical representation of olfactory perception in humans in response to retronasal stimulation by odorants delivered in aqueous solution. Psychophysical evaluation confirmed that the stimuli acted as pure olfactory stimuli through the retronasal pathway and did not present any taste component. Results showed activation in all brain regions previously described with neuroimaging techniques using olfactory stimulation with an odorized air flow. Piriform and orbitofrontal cortex were found activated as well as the hippocampal region, the amygdala, the insular lobe, the cingulate gyrus and the cerebellum. These results demonstrate the feasibility of efficiently stimulating the olfactory system in an fMRI scanner through the retronasal pathway with liquids delivered to the oral cavity. The presentation of olfactory stimuli in liquids to the mouth is a realistic model for the study of food-related flavor perception. This stimulation protocol furthermore allows presenting taste and olfactory stimuli separately or combined, thus allowing for direct comparisons between single modality representation, taste or olfaction, and representation of multi-modality mixtures.     

Response of Drosophila to wasabi is mediated by painless, the fly homolog of mammalian TRPA1/ANKTM1

A number of repellent compounds produced by plants elicit a spicy or pungent sensation in mammals . In several cases, this has been found to occur through activation of ion channels in the transient receptor potential (TRP) family . We report that isothiocyanate (ITC), the pungent ingredient of wasabi, is a repellent to the insect Drosophila melanogaster, and that the painless gene, previously known to be required for larval nociception, is required for this avoidance behavior. A painless reporter gene is expressed in gustatory receptor neurons of the labial palpus, tarsus, and wing anterior margin, but not in olfactory receptor neurons, suggesting a gustatory role. Indeed, painless expression overlaps with a variety of gustatory-receptor gene reporters. Some, such as Gr66a, are known to be expressed in neurons that mediate gustatory repulsion . painless mutants are not taste blind; they show normal aversive gustatory behavior with salt and quinine and attractive responses to sugars and capsaicin. The painless gene is an evolutionary homolog of the mammalian "wasabi receptor" TRPA1/ANKTM1 , also thought to be involved in nociception. Our results suggest that the stinging sensation of isothiocyanate is caused by activation of an evolutionarily conserved molecular pathway that is also used for nociception.     

Taste suppression following lingual capsaicin pre-treatment in humans

The effect of oral capsaicin on taste sensations in humans was reinvestigated with attention to methodological issues raised in previous studies, including the mode of presentation and temperature of the tastant stimulus, as well as the sensitizing and desensitizing properties of capsaicin. One-half of the dorsal anterior tongue was pre-treated with capsaicin, followed by bilateral tastant application (sucrose, NaCl, quinine, monosodium glutamate and citric acid). Subjects indicated on which side the taste intensity was greater in a two-alternative, forced-choice procedure and also rated taste intensity independently on each side of the tongue. Each of the five tastants was tested sequentially, with reapplication of capsaicin between trials in order to maintain a constant level of burn. Four experiments were conducted: (i) a high concentration (33 p.p.m.) (109 microM) capsaicin effect on taste intensity elicited by high tastant concentrations; (ii) a high concentration capsaicin effect on taste intensity elicited by low tastant concentrations; (iii) a low concentration (1.5 p.p.m.) (4.9 microM) capsaicin effect on taste intensity elicited by low tastant concentrations; and (iv) validation of the method for localizing taste by pre-treating one side of the tongue with Gymnema sylvestre, followed by bilateral application of sucrose. In the first experiment, a significant proportion of the subjects chose the non-treated side in the two-alternative, forced-choice procedure and assigned significantly higher ratings to that side for sucrose-induced sweetness, quinine-induced bitterness and glutamate-induced umami sensations. Salty and sour sensations were not different between sides. A 15 min break was imposed in order to allow the capsaicin burn to disappear and desensitization to set in, followed by reapplication of the tastant test solutions. There were no bilateral differences in the intensity of the sensations elicited by any of the five tastants. Similar results were obtained in experiments 2 and 3. In the fourth experiment, all 15 subjects tested chose the side not treated with Gymnema sylvestre as having a stronger sweet taste and assigned significantly higher ratings to that side, thereby validating the method for taste localization. These results indicate that oral capsaicin reduces certain but not all taste sensations and are discussed in terms of possible physiological and cognitive interactions.     

Measurement of sensitivity to olfactory flavor: application in a study of aging and dentures

Olfaction involves a dual sensory process for perceiving odors orthonasally (through the nostrils) and retronasally (through the mouth). This investigation entailed developing a measure of sensitivity to an odor delivered in an orally sampled food (orange flavoring in a sucrose-sweetened gelatin) and examining sensitivity in the elderly. In experiment 1, olfactory flavor sensitivity was 49 times lower in elderly (n = 21) than in young (n = 28) subjects. In experiment 2, with 73 elderly women, higher olfactory flavor sensitivity correlated significantly with higher orthonasal perception (Connecticut Chemosensory Clinical Research Center test). Some women, however, exhibited low olfactory flavor sensitivity despite high orthonasal perception; none had high olfactory flavor sensitivity and low orthonasal perception. Those who wore complete or palatal covering dentures had lower olfactory flavor sensitivity than those who were dentate or wore dentures that did not cover the palate. Through multiple regression analysis, orthonasal perception and denture status were found to be independent contributors to predicting olfactory flavor sensitivity. In summary, elderly subjects showed depressed olfactory flavor sensitivity (i.e. retronasal sensitivity) that related to poor orthonasal olfactory perception and denture characteristic. Thus, while good orthonasal olfaction may be necessary for good olfactory flavor sensitivity, it is not sufficient. Other factors, some associated with oral conditions, may impede release and retronasal transport of odors from the mouth to the olfactory receptors.     

一些蜘蛛类群味觉毛的形态、数量和分布

化学通讯是蜘蛛最基础和最普遍的种内及种间通讯方式之一,蜘蛛体表的味觉毛能够接触性地或者近距离地感知环境中的化学物质,但味觉毛的相关研究仅在少数几种蜘蛛中有过报道。我们通过扫描电镜分别对幽灵蛛科(Pholcidae)、弱蛛科(Leptonetidae)、泰莱蛛科(Telemidae)、蟹蛛科(Thomisidae)和球蛛科(Theridiidae)共5科32种蜘蛛味觉毛的形态、数量及分布进行了观察。结果显示:蜘蛛味觉毛一般呈"S"形或弧形;毛根部与体表形成较大角度,末端开口。一般分布在步足的跗节和后跗节,一些种类在步足胫节亦有味觉毛分布。所观察的蜘蛛中绝大部分种类在触肢上未发现味觉毛,仅有2种蟹蛛即角红蟹蛛(Thomisus labefactus)和膨胀微蟹蛛(Lysiteles inflatus)以及1种球蛛即鼬形微姬蛛(Phycosomamustelinum)在触肢上有味觉毛。味觉毛的数量在不同蜘蛛种类中有较大差异,从十几根到上百根不等。蜘蛛味觉毛的形态、数量和分布等特征除了与遗传相关外,亦有可能与其生境和生活方式等有关。     

Topological and functional characterization of an insect gustatory receptor

Insect gustatory receptors are predicted to have a seven-transmembrane structure and are distantly related to insect olfactory receptors, which have an inverted topology compared with G-protein coupled receptors, including mammalian olfactory receptors. In contrast, the topology of insect gustatory receptors remains unknown. Except for a few examples from Drosophila, the specificity of individual insect gustatory receptors is also unknown. In this study, the total number of identified gustatory receptors in Bombyx mori was expanded from 65 to 69. BmGr8, a silkmoth gustatory receptor from the sugar receptor subfamily, was expressed in insect cells. Membrane topology studies on BmGr8 indicate that, like insect olfactory receptors, it has an inverted topology relative to G protein-coupled receptors. An orphan GR from the bitter receptor family, BmGr53, yielded similar results. We infer, from the finding that two distantly related BmGrs have an intracellular N-terminus and an odd number of transmembrane spans, that this is likely to be a general topology for all insect gustatory receptors. We also show that BmGr8 functions independently in Sf9 cells and responds in a concentration-dependent manner to the polyalcohols myo-inositol and epi-inositol but not to a range of mono- and di-saccharides. BmGr8 is the first chemoreceptor shown to respond specifically to inositol, an important or essential nutrient for some Lepidoptera. The selectivity of BmGr8 responses is consistent with the known responses of one of the gustatory receptor neurons in the lateral styloconic sensilla of B. mori, which responds to myo-inositol and epi-inositol but not to allo-inositol.     

The psychophysical relationship between bitter taste and burning sensation: evidence of qualitative similarity

Although it has long been studied as a pure sensory irritant, the ability of capsaicin to evoke, mask, and desensitize bitter taste suggests that burning sensations and bitter taste might be closely related perceptually. The current study investigated the psychophysical relationship between bitterness and burning using 2 different approaches. In Experiment 1, spatial discrimination of 4 taste stimuli was measured in the presence or absence of capsaicin. The subjects' task was to report which of 3 swabs, spaced 1 cm apart and presented to the tongue tip, contained a taste stimulus when 1) water was presented on the other 2 swabs or 2) when 10 muM capsaicin was presented on all 3 swabs. The presence of capsaicin did not change performance on the 3 alternative forced-choice (3-AFC) task for sweet, sour, and salty stimuli, while the localization error for 1.8 mM quinine sulfate (QSO(4)) increased significantly. In Experiment 2, the perceptual similarity/dissimilarity of taste stimuli and capsaicin was measured directly using pairs of stimuli applied to opposite sides of the tongue tip on swabs separated by 2 cm. Multidimensional scaling analyses showed that capsaicin fell nearer to QSO(4) than to any other taste stimulus. Cluster analysis corroborated this finding: capsaicin was closely linked with QSO(4) and the capsaicin-QSO(4) group was separated from the other taste stimuli. The latter result indicated that bitterness was more similar to burning than to the other tastes. These findings imply that despite being mediated by different sensory modalities, bitterness and burn are qualitatively similar. We speculate that this similarity reflects a common function of these 2 sensations as sensory signals of potentially harmful stimuli.     

A study of gustatory and olfactory function in patients with craniofacial anomalies.

Olfactory and gustatory function can be reiably studied in patients with craniofacial anomalies over the age of 7 years. In our unoperated patients with orbital hypertelorism or craniofacial dysostosis, preoperative evaluation of the olfactory and gustatory functions showed normal values. The same techniques were employed to study any changes in these modalities following reconstructive craniofacial surgery, and the results are presented.     

TRPV6 mediates capsaicin-induced apoptosis in gastric cancer cells--Mechanisms behind a possible new "hot" cancer treatment

Capsaicin is an organic compound in chili peppers which are consumed by over one quarter of the world's population daily. Studies have shown that capsaicin can induce apoptosis in some cancer cells by unknown mechanisms. In this study, both gastric cancer and normal epithelial cells were treated with capsaicin and examined for apoptosis by Annexin V binding. Our results showed that capsaicin induces apoptosis in both cells, although cancer cells are more susceptible. This susceptibility is dependent on the availability of TRPV6, a calcium-selective channel protein, as overexpression of TRPV6 in normal cells increased capsaicin-induced apoptosis and knockdown of TRPV6 in cancer cells suppressed this action. Our results further demonstrated that capsaicin increases mitochondrial permeability through activation of Bax and p53 in a JNK-dependent manner. Conclusions: (1) TRPV6, rather than TRPV1 (the well-known capsaicin receptor), mediates capsaicin-induced apoptosis in gastric cells; (2) abundance of TRPV6 in gastric cells determines their live or death under capsaicin treatment; and (3) capsaicin induces apoptosis by stabilization of p53 through JNK activation. Together, our data suggest that capsaicin may be a promising dietary candidate for cancer chemoprevention.     

NEUROPHYSIOLOGY AND HUMAN TASTE SENSATIONS

Taste sensations are of primary importance in food flavor. Any attempt to synthesize chemically the flavor of a natural food involves mainly taste active compounds. Many distinct taste sensations can be identified as associated with food compounds. Thirteen different taste sensations are discussed herein. These different taste sensations are differentiated on the basis of stimulus chemistry and peripheral nerve conveying the taste information. Neurophysiological examination of the peripheral nerves involved in taste reveals that the sensory neurons can, in any species, be subdivided into distinct neural groups. These different neural groups respond to distinct classes of chemicals and often display different neurophysiological characteristics. Altogether in four different species, nine functional neural taste groups can be distinguished. In many cases, these neural groups can be taken as analogs for the neural groups assumed to underly human taste sensations. Distinct human taste sensations can be considered to arise from the excitation or inhibition of different neural groups. For certain human taste sensations there are no animal neural analog groups; and for certain neural groups there are no analog human sensations.     

Ghrelin, leptin and adiponectin as possible predictors of the hedonic value of odors

Several lines of evidence point to a close relationship between the hormones of energy homeostasis and the olfactory system. Examples are the localization of leptin and adiponectin receptors in the olfactory system or increased activation of brain regions related to the palatability and the hedonic value of food in response to food pictures after application of ghrelin. In this preliminary study, we tested in 31 subjects (17 male and 14 female) if and to what extent the peripheral blood concentrations of "satiety" hormones, such as leptin, adiponectin, and ghrelin (acyl and total), are correlated with the self-ratings of odor pleasantness and with the objective olfactory and gustatory ability. The hedonic values of some odors were found to be differently rated between donors depending on gender and body weight. The concentrations of leptin, adiponectin and total ghrelin were significantly associated with the hedonic value of pepper black oil, but failed to show significant correlations for 5 other odors tested. Except for a significant association between leptin and odor identification, hormone concentrations were not linked to the abilities of smell and taste. Peripheral adipokines and gut hormones may alter the perception and pleasantness of specific odors, presumably either directly through their receptors in the olfactory system or indirectly through central interfaces between the regulation systems of olfaction, appetite control, memory and motivation.