Detection and modulation of capsaicin perception in the human oral cavity.

Capsaicin causes a burning or spicy sensation when this vanilloid compound comes in contact with trigeminal neurons of the tongue. This compound has low solubility in water, which presents difficulties in examining the psychophysical properties of capsaicin by standard aqueous chemosensory tests. This report describes a new approach that utilizes edible strips for delivering precise amounts of capsaicin to the human oral cavity for examining threshold and suprathreshold amounts of this irritant. When incorporated into pullulan-based edible strips, recognition thresholds for capsaicin occurred over a narrow range, with a mean value near 1 nmol. When incorporated into edible strips at suprathreshold amounts, capsaicin yielded robust intensity values that were readily measured in our subject population. Maximal capsaicin intensity was observed 20 s after strips dissolved on the tongue surface, and then decreased in intensity. Suprathreshold studies showed that complete blockage of nasal airflow diminished capsaicin perception in the oral cavity. Oral rinses with vanillin-linoleic acid emulsions decreased mean intensity values for capsaicin by approximately 75%, but only modestly affected recognition threshold values. Also, oral rinses with isointense amounts of aqueous sucrose and sucralose solutions decreased mean intensity values for capsaicin by approximately 50%. In addition, this decrease in capsaicin intensity following an oral rinse with sucrose was partially reversed by the sweet taste inhibitor lactisole. These results suggest that blockage of nasal airflow, vanillin, sucrose, and sucralose modulate capsaicin perception in the human oral cavity. The results further suggest a chemosensory link between receptor cells that detect sweet taste stimuli and trigeminal neurons that detect capsaicin.

Integrating TRPV1 Receptor Function with Capsaicin Psychophysics.

Capsaicin is a naturally occurring vanilloid that causes a hot, pungent sensation in the human oral cavity. This trigeminal stimulus activates TRPV1 receptors and stimulates an influx of cations into sensory cells. TRPV1 receptors function as homotetramers that also respond to heat, proinflammatory substances, lipoxygenase products, resiniferatoxin, endocannabinoids, protons, and peptide toxins. Kinase-mediated phosphorylation of TRPV1 leads to increased sensitivity to both chemical and thermal stimuli. In contrast, desensitization occurs via a calcium-dependent mechanism that results in receptor dephosphorylation. Human psychophysical studies have shown that capsaicin is detected at nanomole amounts and causes desensitization in the oral cavity. Psychophysical studies further indicate that desensitization can be temporarily reversed in the oral cavity if stimulation with capsaicin is resumed at short interstimulus intervals. Pretreatment of lingual epithelium with capsaicin modulates the perception of several primary taste qualities. Also, sweet taste stimuli may decrease the intensity of capsaicin perception in the oral cavity. In addition, capsaicin perception and hedonic responses may be modified by diet. Psychophysical studies with capsaicin are consistent with recent findings that have identified TRPV1 channel modulation by phosphorylation and interactions with membrane inositol phospholipids. Future studies will further clarify the importance of capsaicin and its receptor in human health and nutrition.