TY - JOUR
T1 - Evaluation of sweetener synergy in humans by isobole analyses
AU - Michelle Reyes, M.
AU - Gravina, Stephen A.
AU - Hayes, John E.
N1 - Funding Information:
This work was supported in part by a Bunton–Waller scholarship from the Pennsylvania State University to M.M.R. and discretionary funds from the Pennsylvania State University controlled by J.E.H. Additional support was provided by a grant from the National Institutes of Health [R03DC010904] to J.E.H., and the United States Department of Agriculture and the National Institute of Food and Agriculture via Hatch Act Appropriations [Projects PEN04565 and PEN04332]. None of these organizations have had any role in study conception, design or interpretation, or the decision to publish these data.
Publisher Copyright:
© The Author(s) 2019. Published by Oxford University Press. All rights reserved.
PY - 2019/10/17
Y1 - 2019/10/17
N2 - The chemical senses and pharmaceuticals fundamentally depend on similar biological processes, but novel molecule discovery has classically been approached from vastly different vantage points. From the perspective of ingredient and flavor companies, there are countless ingredients that act via largely unknown mechanisms, whereas the pharmaceutical industry has numerous mechanisms in search of novel compounds. Mixtures of agonists can result in synergistic (superadditive) responses, which can be quantified via isobole analysis, a well-proven clinical approach in pharmacology. For the food and beverage industries, bulk (caloric) sweeteners like sugars are a key ingredient in sweetened foods and beverages, but consumers also desire products with fewer calories, which has led to the development of sweet enhancers and sweetener blends intended to achieve synergy or superadditivity. Synergistic mixtures are highly attractive targets commercially as they enable lower usage levels and enhanced efficacy. Although the psychophysical literature contains numerous prior reports of sweetener synergy, others have also noted that classical additive models fail to account for nonlinear dose-response functions. To address this shortcoming, here we systematically apply the isobole method from pharmacology to quantify the presence or absence of psychophysical synergy for binary pairs of sweeteners in a series of 15 separate experiments, each with ~100 adult volunteers (total n = 1576). Generally, these data support the hypothesis that structurally similar sweeteners acting as agonists will not synergize, whereas structurally dissimilar sweeteners binding to overlapping or distal sites can act as allosteric agonists or agonist-antagonists, respectively.
AB - The chemical senses and pharmaceuticals fundamentally depend on similar biological processes, but novel molecule discovery has classically been approached from vastly different vantage points. From the perspective of ingredient and flavor companies, there are countless ingredients that act via largely unknown mechanisms, whereas the pharmaceutical industry has numerous mechanisms in search of novel compounds. Mixtures of agonists can result in synergistic (superadditive) responses, which can be quantified via isobole analysis, a well-proven clinical approach in pharmacology. For the food and beverage industries, bulk (caloric) sweeteners like sugars are a key ingredient in sweetened foods and beverages, but consumers also desire products with fewer calories, which has led to the development of sweet enhancers and sweetener blends intended to achieve synergy or superadditivity. Synergistic mixtures are highly attractive targets commercially as they enable lower usage levels and enhanced efficacy. Although the psychophysical literature contains numerous prior reports of sweetener synergy, others have also noted that classical additive models fail to account for nonlinear dose-response functions. To address this shortcoming, here we systematically apply the isobole method from pharmacology to quantify the presence or absence of psychophysical synergy for binary pairs of sweeteners in a series of 15 separate experiments, each with ~100 adult volunteers (total n = 1576). Generally, these data support the hypothesis that structurally similar sweeteners acting as agonists will not synergize, whereas structurally dissimilar sweeteners binding to overlapping or distal sites can act as allosteric agonists or agonist-antagonists, respectively.
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U2 - 10.1093/chemse/bjz056
DO - 10.1093/chemse/bjz056
M3 - Article
C2 - 31424498
AN - SCOPUS:85073481827
SN - 0379-864X
VL - 44
SP - 571
EP - 582
JO - Chemical senses
JF - Chemical senses
IS - 8
ER -