IntroductionThe sense of taste is t

Introduction
The sense of taste is the gatekeeper to ingestion. From an evolutionary perspective, taste played a critical role in the survival of species by informing about nutrients or toxins in potential foods (Cordain et al. 2005). In the modern environ- ment, our sense of taste does not play such a central role for survival but may still have a significant role in dietary choice (Connors et al. 2001; Duffy, 2004; Glanz et al. 1998). Taste sensors are located in papillae throughout the oral cavity. The- se papillae house taste receptor cells (TRCs), which are stim- ulated when nonvolatile chemicals enter the mouth. TRCs synapse onto afferent fibers that project to cortical regions of the brain; with sufficient stimulation, the impulse is decoded, and we perceive a taste (Bachmanov and Beauchamp 2007). There is large interindividual variation in taste perception (see review by Hayes et al. 2013), where such variation may arise from differences in human physiology or the cognitive pro- cessing of taste signals. There is no single method to assess global taste function; indeed, five distinct methods are com- monly employed by researchers studying chemosensation or ingestive behavior. Detection and recognition thresholds pro- vide estimates of the lowest chemical concentration that can be perceived by an individual. For example, a solution may contain a substance at a concentration undetectable to the gen- eral population, but as the concentration is increased, a detec- tion threshold (DT) is attained such that the solution can be discriminated from pure solvent in a forced choice task. As the concentration is further increased, a recognition threshold (RT) is attained, and this is the point where the substance is both perceived and identifiable as having a specific perceptual quality (Keast and Roper 2007).
It is widely accepted that individuals with lower DT and RT are more sensitive to a particular chemical than those with a higher DT and RT. In contrast, suprathreshold intensity refersto the perceived intensity (magnitude) of a substance at con- centration above threshold. As the stimulus concentration in- creases, it is expected that the perceived intensity will also increase, eventually reaching to a terminal threshold for the stimulus and quality. Suprathreshold intensity of prototypical tastants is a third means to quantify taste function. These tests occur at concentrations between the recognition threshold and the terminal threshold, and intensity of the same stimulus can vary widely across individuals (e.g., Allen et al. 2013). The fourth measure often used is propylthiouracil (PROP) bitter- ness; PROP is extremely bitter for some, while others will perceive little or no bitterness (Bartoshuk et al. 1994; Tepper et al. 2009). PROP has been previously used to identify indi- viduals, known as supertasters, who find this chemical to be intensely bitter. Subsequently, this term has also been applied to individuals who show heightened taste response across multiple qualities, not just PROP bitterness (Hayes et al. 2008). More recently, it was suggested that the terminology supertaster can be confusing, as it may refer to a narrow trait relating to PROP, or the broad trait of heightened taste re- sponse to a broad range of stimuli (Hayes and Keast 2011). The fifth measure commonly used is the quantification of fungiform papillae (FP) anatomy. FP contain taste buds, and it is due to their abundance and location on the anterior tongue that they are chosen for quantification when compared to fo- liate and circumvallate papillae (Huguley 1990). FP are small, mushroom-shaped structures, and the densities of these struc- tures have been shown to vary largely between individuals. Presumably, the more FP an individual has, a stronger signal is sent centrally from the FP, resulting in a more intense taste perception (Essick et al. 2003; Miller and Reedy 1990; Zhang et al. 2009; Hayes and Duffy 2007; Hayes et al. 2010), al- though not all studies support this contention (Garneau et al. 2014; Feeney and Hayes 2014; Fischer et al. 2013).
The aim of the present study is to investigate how these five distinct measures commonly used to assess taste function re- late to each other.
Materials and Methods
Study Design
This study comprised five methods of taste assessment rou- tinely used in chemosensory research measured over two ses- sions on separate days: (1) detection threshold (DT), (2) rec- ognition threshold (RT), (3) suprathreshold intensity of the five prototypical tastes, (4) suprathreshold bitterness of propylthiouracil (PROP), and (5) fungiform papillae quantifi- cation. Demographic information was also collected, includ- ing gender, age, height, and weight. Body mass index (BMI, kg/m2) was calculated from the height and weight measure- ments. DT, RT, and suprathreshold intensity procedures were
conducted in computerized, partitioned sensory booths in the Centre for Advanced Sensory Science using Compusense Five Software Version 5.2 (Compusense Inc., Ontario, Canada). Fungiform papillae photography (Haryono et al. 2014) and PROP testing (Zhao et al. 2003) were also conducted within this laboratory using standard methods.