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Long-chain fatty acids elicit a bitterness-masking effect on quinine and other nitrogenous bitter substances by formation of insoluble binary complexes Kayako Ogi, Haruyuki Yamashita, Tohru Terada, Ryousuke Homma, Akiko Shimizu Ibuka, Etsuro Yoshimura, Yoshiro Ishimaru, Keiko Abe, and Tomiko Asakura J. Agric. Food Chem., Just Accepted Manuscript • DOI: 10.1021/acs.jafc.5b03193 • Publication Date (Web): 12 Sep 2015 Downloaded from http://pubs.acs.org on September 18, 2015

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Journal of Agricultural and Food Chemistry

TITLE: Long-Chain Fatty Acids Elicit a Bitterness-Masking Effect on Quinine and Other Nitrogenous Bitter substances by Formation of Insoluble Binary Complexes

AUTHOR INFORMATUON Kayako Ogi,†,‡ Haruyuki Yamashita,†,‡ Tohru Terada,† Ryousuke Homma,† Akiko Shimizu-Ibuka,§ Etsuro Yoshimura,



Yoshiro Ishimaru,



Keiko Abe,† and Tomiko

Asakura*,†



Department of Applied Biological Chemistry, Graduate School of Agricultural and Life

Sciences, The University of Tokyo, 1-1-1, Yayoi, Bunkyo-ku, Tokyo 113-8657, Japan, and §

Faculty of Applied Life Sciences, Niigata University of Pharmacy and Applied Life

Sciences, 265-1 Higashijima, Akiha-ku, Niigata 956-8603, Japan.

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ABSTRACT: We have previously found that fatty acids can mask the bitterness of certain

2

nitrogenous substances through direct molecular interactions. Using isothermal titration

3

calorimetry, we investigated the interactions between sodium oleate and 22 bitter

4

substances. The hydrochloride salts of quinine, promethazine and propranolol interacted

5

strongly with fatty acids containing 12 or more carbon atoms. The 1H-NMR spectra of

6

these substances obtained in the presence of the sodium salts of the fatty acids in dimethyl

7

sulfoxide, revealed the formation of hydrogen bonds between the nitrogen atoms of the

8

bitter substances and the carboxyl groups of the fatty acids. When sodium laurate and the

9

hydrochloride salt of quinine were mixed in water, an equimolar complex was formed as

10

insoluble heterogeneous needle-like crystals. These results suggested that fatty acids

11

interact directly with bitter substances through hydrogen bonds and hydrophobic

12

interactions to form insoluble binary complexes, which mask bitterness.

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KEYWORDS: fatty acids, bitter substances, bitterness-masking, binary complex, quinine

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INTRODUCTION

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Taste comprises of five basic modalities: sweetness, sourness, bitterness, saltiness,

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and umami. Bitter and sour tastes are generally undesirable1 and in particular, bitter tastes

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are instinctively avoided because toxic substances often taste bitter.2 However, some

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physiologically beneficial species such as flavonoids, polyphenols, and pharmaceutical

21

agents often taste bitter.2 In food processing, bitter tastes can also be generated during

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fermentation and heating.3,4 Therefore, Bitterness-masking needs to be considered in food

23

preparation and pharmaceutical manufacturing.

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Several bitterness-masking methods have been developed such as adding other

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tastants and flavors to suppress bitter tastes.5-7 Bitterness can also be masked by applying

26

antagonists for the bitter taste receptors, T2Rs.8-11 Coating and encapsulating are often used

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in the pharmaceutical industry to mask the bitterness of drugs.12-20 Cyclodextrin can

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incorporate various substances to form an inclusion complex.21-23 Amino acid derivatives

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are one example of low molecular weight bitterness-masking compounds.24 Zinc can also

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mask the bitterness of quinine, tetralone, and denatonium benzoate.25 In many cases,

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however, the masking mechanisms of these compounds have not been elucidated. For food

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processing, these compounds must be harmless so identifying safe bitterness-masking

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agents, originating from foods, is a desirable objective.

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In a previous study,26 we found that certain cheeses contained bitterness-masking

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substances. Their masking effect was attributed to the presence of fatty acids which could

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mask the bitterness of some substances through direct interactions. However, there was

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some specificity in the observed effects; for example, the bitterness of quinine was

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suppressed, while the bitterness of caffeine was not.

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We would investigate the bitterness-masking mechanism of fatty acids by defining

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the interactions between the sodium salts of fatty acids and bitter substances using

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isothermal titration calorimetry (ITC) and nuclear magnetic resonance (NMR)

42

spectroscopy. Initially, we will use ITC to screen various bitter substances to determine

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which of them interact with the sodium salts of fatty acids. Sodium oleate will be used for

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the screening because it has been shown to have the strongest bitterness-masking activity

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against quinine hydrochloride (QHCl) in the sensory test. 26 We will then determine the

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strength and mode of interactions between various sodium salts of fatty acids and the

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screened bitter substances using ITC. Finally, the 1H-NMR spectra of the bitter substances

48

will be obtained in the absence and presence of the sodium salts of fatty acids to elucidate

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the interactions with the bitter substances.

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The aim of this study is to elucidate which substructures of fatty acids and bitter

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substances interact with each other, as well as their state after the interaction. These

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findings will lead to clarification of the bitterness-masking mechanism on a molecular

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basis. From this information, molecular models composed of fatty acids and bitter 4

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substances can be constructed to elucidate the mode of interaction.

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MATERIALS AND METHODS

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Chemicals. These were obtained from commercial sources. The fatty acids, hexanoic,

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octanoic, decanoic, linoleic, linolenic acids, sodium thiocyanate, taurine, acesulfame K,

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saccharin sodium dehydrate, caffeine, thiamine hydrochloride, and amygdalin were

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obtained from Wako Pure Chemical Industries Ltd. (Osaka, Japan); lauric acid,

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N-phenylthiocarbamide, salicin, berberine hydrochloride monohydrate and quinine

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hydrochloride dihydrate were obtained from Nacalai Tesque Inc. (Kyoto, Japan). The fatty

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acids,

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(±)-propranolol hydrochloride, promethazine hydrochloride, chloramphenicol, yohimbine

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hydrochloride, colchicine, cromolyn disodium salt, limonin, and ouabain octahydrate were

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obtained from Sigma-Aldrich Co. (Tokyo, Japan). Methyltryptophan and naringin were

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obtained from Tokyo Chemical Industry Co., Ltd. (Tokyo, Japan). Acetic acid and

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antipyrine were obtained from Kanto Chemical Co. Inc. (Tokyo, Japan), and glycerol

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monolaurate was obtained from Chem-Implex International Inc. (Wood Dale, IL, USA).

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Screening of Bitter Substances. ITC was performed using a MicroCal iTC200 instrument

71

(Malvern Instruments Japan Corp., Kobe, Japan). The fatty acids were neutralized and

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solubilized by adding of an equimolar amount of sodium hydroxide. The interactions

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between 22 bitter substances whose structures are shown in Supplemental Figure S1-1 and

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sodium oleate were measured. The concentrations of the bitter substances and sodium

myristoleic,

palmitoleic,

oleic,

arachidonic

acids,

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glycerol

monooleate,

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oleate were 1.5 mM and 0.5 mM, respectively. The compounds were dissolved in 5 mM

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phosphate buffer (pH 7.0). The reference cell was filled with Milli-Q water (Millipore

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Corp., Billerica, MA, USA). The bitter substances in buffer solutions were titrated into

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sodium oleate dissolved in 5 mM phosphate buffer (pH 7.0) at a stirring rate of 1,000 rpm

79

and at 25 °C. Each titration was carried out with an initial injection volume of 0.4 µL

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followed by 18 main injections of 2 µL each at 120 s intervals. The first titration (0.4 µL)

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was excluded from the analysis. The data corresponding to the dilution of the ligand in the

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buffer was subtracted from the titration data.

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Measurement of Interactions between Fatty Acids and Bitter Substances. The

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interactions between five bitter substances, QHCl, promethazine hydrochloride (PHCl),

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propranolol hydrochloride (PrHCl), berberine hydrochloride (BHCl) and yohimbine

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hydrochloride (YHCl), and 8 sodium salts of fatty acids (sodium hexanoate, sodium

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octanoate, sodium decanoate, sodium laurate, sodium myristoleate, sodium oleate, sodium

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linoleate, and sodium linolenate) and 2 monoacylglycerides (glycerol monolaurate and

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glycerol monooleate) were measured. The concentrations of the fatty acids were 0.5 mM

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and those of the bitter substances are given in Supplemental Table S1. The samples were

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dissolved in 5 mM phosphate buffer (pH 7.0). Titrations were conducted as described

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above.

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The data were analyzed according to the “one set of sites” model provided in Origin 7

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7.0 software for MicroCal iTC200. The binding constant (K) and enthalpy change (∆H) of

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binding were obtained from the fitted curve. The entropy change (∆S) and free energy

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change (∆G) of binding were obtained using the following equation:

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∆G = ∆H − T∆S = −RT ln K, where R is the gas constant and T is the thermodynamic temperature.

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Preparation of Crystals. QHCl (3 mmol, 1.08 g) was dissolved in 3 L of Milli-Q water. A

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solution of sodium laurate (3 mmol, 0.67 g) in Milli-Q water (50 mL) was added to the

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QHCl solution and was thoroughly stirred. The mixture was allowed to stand overnight at

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room temperature. The precipitated crystals were filtered No. 5A (Toyo Rishi Kaisha Ltd.

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Tokyo, Japan), rinsed with water and air-dried. Differential scanning calorimetry (DSC)

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measurements were performed using a Shimazu DSC-60 (Kyoto, Japan) in the temperature

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range from 5 to 60 °C at a heating rate of 5 °C/min under a nitrogen atmosphere.

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NMR Spectroscopy. All NMR experiments except for solid-state NMR were conducted

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on a Varian Inova 500 NMR spectrometer (500 MHz) at 25 °C (Varian Inc, Palo Alto, CA,

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USA). The bitter substances (32 µmol; QHCl, PHCl, and PrHCl) were measured in the

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absence and presence of sodium laurate. The samples were dissolved in 600 µL of

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DMSO-d6. The 1H-NMR measurement conditions were as follows: number of data points:

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16384; acquisition time: 1.75 s; delay time: 5 s; number of scans: 16. The NOESY (nuclear

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Overhauser enhancement spectroscopy) measurement conditions were as follows: number 8

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of data points: 512 and 1024 for F1 and F2, respectively; digital resolutions of F1 and F2:

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5.50 Hz and 8.79 Hz, respectively; delay time: 1.5 s; mixing time: 1.0 s; number of scans:

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16. Solid-state NMR was conducted using an ECA 500 (500MHz) (JEOL, Tokyo, Japan) at

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0 °C to stop the crystals from melting, using 4 mm of CP/MAS (Cross Polarization/ Magic

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Angle Spinning) probe at 10,000 rpm. The measurement was as follows: number of data

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points: 1024; digital resolution: 49.2 Hz; delay time: 5.0 s; number of scans: 2048.

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Molecular Modeling. Initial models of conformations that were consistent with the

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NOESY data of the 3 bitter substances in the absence and presence of sodium laurate were

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manually constructed using GaussView 5.0 (Gaussian Inc. Wallingford, CT, USA). The

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geometries were optimized in vacuo at the B3LYP/6-31G (d) level of theory, then, the

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geometries were optimized in DMSO at the same level of theory. The polarizable

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continuum model (PCM) was used to calculate solvent effects in DMSO. All calculations

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were performed using the Gaussian 09 software package.27

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RESULTS

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ITC Measurements. The interactions between 22 bitter substances and sodium oleate

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were studied using ITC (Supplemental Figure S1-2). Five bitter substances, QHCl, PHCl,

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PrHCl, BHCl, and YHCl were found to interact with sodium oleate. Notably, each of these

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substances bears a nitrogen atom (Figure 1). The interactions between these five substances

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and six fatty acids were then studied (Table 1). The change in Gibbs free energy (∆G) was

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negative for all the interactions detected, meaning that these interactions occurred

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spontaneously. The change in enthalpy (∆H) contributed to ∆G in all cases and the change

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in entropy (∆S) contributed in some cases (Table 1). In these cases, the titrated solutions

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became turbid upon injecting the bitter substances, indicating that insoluble complexes had

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been formed between the fatty acids and the bitter substances. Of the five bitter substances

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examined, BHCl and YHCl exhibited relatively weak interactions with the fatty acids

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(Table 2). Therefore, only the three which had strong interactions with the fatty acids,

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QHCl, PHCl, and PrHCl, were examined.

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No interactions were detected between fatty acids with 10 or fewer carbon atoms

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and the three bitter substances. All these three substances showed the greatest binding

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constants, upon binding with sodium oleate, which increased as the number of carbon

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atoms in the alkyl chain of the fatty acids increased. The binding constant also decreased as

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the number of double bonds in the fatty acids increased (Table 2). These results suggested

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that the carbon chain length and the number of double bonds in the fatty acids affected

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these interactions.

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To examine the effect of the carboxyl group in the fatty acids, the interactions

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between the bitter substances and glycerol monolaurate and glycerol monooleate were also

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measured. However, no interactions between the bitter substances and these glycerol esters

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were detected (Table 2).

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Overall, carbon chains of a certain length and the presence of carboxyl groups in the

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fatty acids were necessary to induce interactions with the bitter substances.

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NMR Measurements. ITC measurements proved that fatty acids interacted directly with

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some bitter substances. To examine the mechanism of these interactions, the 1H-NMR

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spectra of three bitter substances (QHCl, PHCl, and PrHCl) were measured in the absence

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and presence of an equimolar amount of sodium laurate. As these bitter substances are

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insoluble in water when sodium laurate is added, DMSO-d6 was used as the solvent

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instead.

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The three bitter substances contained a nitrogen atom (Figure 1). The signals of the

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protons on the hydrogen atoms located near the nitrogen atoms was shifted upfield in the

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presence of sodium laurate (H2, H6, and H8 of QHCl; H9, H10, H11, H12, and H13 of

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PHCl; H1″ and H3 of PrHCl) (Figure 2). The changes in the chemical shift (∆δ) of these

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protons were more than 0.3 ppm for QHCl and PHCl and more than 0.2 ppm for PrHCl 11

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(Supplemental Table S2). In the presence of glycerol monolaurate, no significant changes

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were observed ( ∆δ < 0.02 ppm) (Supplemental Table S3).

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The 1H-NMR spectra of QHCl were also measured in the presence of sodium

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decanoate (10:0), sodium octanoate (8:0) and sodium hexanoate (6:0) which caused the

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signals corresponding to H2, H6, and H8 of QHCl (Supplemental Table S4) to be shifted

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upfield (∆δ > 0.3 ppm). These results suggested that the hydrogen bond between the

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nitrogen atom of the bitter substances and the carboxyl group of the fatty acid was formed

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in DMSO.

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In addition, the 1H-NMR spectra were measured after changing the molar ratio of

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sodium laurate to QHCl (0, 0.2, 0.5 and 0.8). The changes in the chemical shifts of H2, H6,

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and H8 (∆δ) were plotted as a function of the molar ratio of sodium laurate (Figure 3). As

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the chemical shifts depended on the molar ratio of sodium laurate, the exchange between

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the free and complexed states was faster than the chemical shift difference between the two

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states.

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ITC measurements revealed that the length of the carbon chain and the number of

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double bonds in the fatty acids affected the binding constants, which suggested that the

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alkyl chains contributed to the interactions. To examine where the hydrophobic interactions

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occurred, the NOESY spectra of the bitter substances were measured in the absence and

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presence of sodium laurate (Figure 4). 12

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In the present study, there were three possible locations for hydrophobic interactions:

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the first was between the fatty acids and bitter substances; the second between different

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molecules of the bitter substances; and the third between different molecules of the fatty

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acids. Although no cross-peaks were observed between sodium laurate and QHCl, some

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were observed between H2′ and H8′ of QHCl in the presence of sodium laurate (Figure 4).

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Because these protons cannot interact with each other within a single molecule of QHCl,

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intermolecular hydrophobic interactions between two molecules of QHCl occurred in the

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presence of sodium laurate. However, in the case of PHCl and PrHCl, no interactions

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between bitter substances and fatty acids and between different molecules of bitter

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substances were observed (Supplemental Figure S3 and Table S5). Detailed analysis of the

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cross-peaks between carbon chains was impossible because many signals overlapped.

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However, because the length of the carbon chain affected the strength of the interactions in

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the ITC experiment, we concluded that hydrophobic interactions existed primarily between

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the carbon chains in an aqueous environment. Based on the NOESY results, we

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constructed molecular models of the binary complexes formed between the bitter

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substances and sodium laurate in DMSO (Figure 5).

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Crystal Analysis of Sodium Laurate and QHCl. Needle-like crystals were observed

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upon mixing an aqueous solution of sodium laurate and QHCl (Figure 6a). These crystals

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were composed of an equimolar amount of laurate and quinine, as indicated by 1H-NMR. 13

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The DSC curve of the crystal revealed a wide exothermic peak (Figure 6b). From CP/MAS

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NMR spectra, it appeared that C2, C6 and C8 in QHCl resonated at chemical shifts of 62.3,

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56.9 and 66.3 ppm, respectively, whereas each of the signals split into three peaks, with a

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broadened peak width when the crystal was formed with lauric acid (Supplemental Figure

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S2). This indicates that at least three states were involved in the crystal. In addition, peak

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broadening of the methyl and methylene carbon atoms in lauric acid upon formation of

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crystal demonstrated an incoherent microcrystalline structure. X-ray diffraction analysis

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was applied to the ground crystal samples using the radial distribution function 4πr2ρ (r) to

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obtain structural information. The sum of the data for QHCl and lauric acid, measured

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independently, was different from the data for the ground crystal sample, implying that

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specific interactions had been formed in the complex. The crystal seems to be in an

214

intermediate state regarding its amorphosity and crystal style (data not shown). These

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results suggested that the crystal was composed of various conformations. The bitterness of

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the crystal was significantly less than that of QHCl alone using sensory testing (data not

217

shown).

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DISCUSSION

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In a previous report,26 it was shown that sodium oleate suppressed the bitterness of

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QHCl. Exothermic interactions were observed when QHCl was added to the fatty acid,

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associated with masking the bitterness of QHCl by direct interaction with the fatty acids.

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However, the detailed mechanism of the bitterness-masking reaction has not been

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elucidated. In the present study, we found that two types of interaction, hydrogen bonds

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and hydrophobic interactions were necessary to mask the bitterness of some compounds.

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Specifically, NMR revealed that hydrogen bonding occurred between the nitrogen atom of

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the bitter substances (N1 of QHCl, N11 of PHCl, and N4 of PrHCl) and the carboxyl group

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of the fatty acids in DMSO (Figure 2). In addition, the ITC experiments in water indicated

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that the strength of the interaction between the bitter substance and the fatty acid depended

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on the length of the carbon chain of the fatty acid, demonstrating the involvement of

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hydrophobic interactions.

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In aqueous solutions, the bitter substances and fatty acids dissociated as weak bases

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and acids, respectively.28 In neutral pH solutions, the dissociation equilibrium of the

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long-chain fatty acids (RCOOH) shifted to the left of the equilibrium reaction presented in

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Equation (I), given that the pKa values of oleic acid, linoleic acid, and linolenic acid are

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9.85, 9.24, and 8.28, respectively.28

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,

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However, the dissociation equilibrium of nitrogenous bitter substances (BN) such as

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quinine, promethazine, and propranolol shifted to the left side of Equation (II) given that

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the pKa values of quinine,29 promethazine30 and propranolol31 are 8.3, 8.6 and 9.2,

241

respectively.

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BNH+

BN +

H+

(II) ,

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The ∆H values for the interactions between the fatty acids and bitter substances were

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in the range of 10 to 40 kJ/mol for in all cases (Table 1). These results suggested that

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hydrogen bonds existed between the fatty acids and bitter substances. Two possible

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mechanisms of hydrogen bond formation are proposed: one involves interaction between

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RCOOH and BN that comprise a unit of the binary complex; and the other occurs between

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BH+ and RCOO−. The former hypothesis can explain the observation that long-chain fatty

249

acids interact with the bitter substances whereas short-chain fatty acids do not. The latter

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hypothesis can account for the ionic attraction between oppositely charged species.

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Of the twenty two bitter substances examined, those that exhibited strong

252

interactions with the fatty acids contained secondary or tertiary amino groups. Although

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some bitter substances that did not interact with the fatty acid also had nitrogen atoms,

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most of these nitrogen atoms were present in amide groups or in conjugated systems. The

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rest were present in primary amino groups which might be unsuitable for forming 16

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hydrophobic interactions with the carbon chain of the fatty acids.

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Regarding hydrophobic interactions, the contribution of the carbon chains was

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obvious because the length of the carbon chain and the number of double bonds affected

259

the binding constants (Table 2). The NOESY data indicated the possibility of a stacking

260

effect between the aromatic rings of QHCl. However, the T∆S values varied widely and

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were not correlated with ∆G, especially with sodium linoleate (Table 1). This phenomenon

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was perhaps due to the conformational variation of the fatty acids or the decreased

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solubility of the mixture of hydrochloride salts of the bitter substances and the sodium salts

264

of the fatty acids.

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Based on these results, we propose that the bitterness of substances can be masked

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with fatty acids by the formation of a binary complex between these species through a

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hydrogen bond and a hydrophobic interaction (Figure 7). Specifically, the aggregation of a

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unit of binary complex of fatty acids and bitter substances generated large insoluble

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complexes. The formation of these complexes made it more difficult for the bitter

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substances to interact with the bitter taste receptors, thereby masking the bitterness.

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Particularly in the case of QHCl and sodium laurate, both substances aggregated because

272

of hydrophobic interactions between the carbon chains, forming needle-like crystals

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(Figure 7). As suggested by DSC, the crystal was probably composed of quinine laurate in

274

various conformations with stacking interactions between the aromatic rings of QHCl. 17

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In the present study, fatty acids have been found to interact directly with bitter

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substances through hydrogen bonds and hydrophobic interactions. Moreover, both types of

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interaction played important roles in masking bitterness. This study has been described

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how direct interactions between bitterness-masking substances and bitter substances can

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suppress bitterness. The results of this study should lead to the development of new method

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for masking bitterness, which may be directly applicable to food processing. More research

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would be needed to investigate the taste and acceptability of food containing fatty acids

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and nitrogen-containing bitter compounds.

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From this study, we can propose that a possible mechanism of how fatty acids can

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mask the bitterness of bitter substances. Both hydrogen bonds and hydrophobic

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interactions are essential for forming the insoluble binary complexes composed of bitter

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substances and fatty acids. Nitrogen atoms in the bitter substances and fatty acids with

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chain lengths of 12 carbon atoms or more are necessary for forming the binary complexes.

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ASSOCIATED CONTENT

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Supporting Information The supporting information is available for free of charge from the journal

291 292

website at http://pubs.acs.org.

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The structures of screened substances and the isothermal titration profiles, solid-state

294

NMR spectra of crystal, lauric acid and QHCl, 1H-NMR assignments of QHCl, PHCl and

295

PrHCl in the absence and presence of sodium laurate, 1H-NMR assignments of QHCl,

296

PHCl and PrHCl in the absence and presence of glycerol monolaurate, 1H-NMR

297

assignments of QHCl in the absence and presence of sodium decanoate, sodium octanoate

298

and sodium hexanoate, NOESY assignments of QHCl, PHCl and PrHCl in the absence and

299

presence of sodium laurate, NOESY spectra of PHCl and PrHCl in the presence of sodium

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laurate.

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AUTHER INFORMATION

302

Corresponding Author *

303 304

Phone/Fax: +81-3-5841-1879; E-mail: [email protected]

Author Contributions ‡

305 306 307

These authors contributed equally to this work.

Notes The Authors declare no competing financial interest. 19

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ACKNOWLEDGEMENTS

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This work was supported by a Grant-in-Aid for Scientific Research 20259013 to T.A

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from the Ministry of Education, Culture, Sports, Science and Technology of Japan. This

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work was supported by the Council for Science, Technology and Innovation

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(CSTI), Cross-Ministerial Strategic Innovation Promotion Program (SIP),

313

“Technologies for creating next-generation agriculture, forestry and fisheries”

314

ABBREVATIONS USED

315

ITC, isothermal titration calorimetry; 1H-NMR, proton nuclear magnetic resonance;

316

NOESY, nuclear Overhauser enhancement spectroscopy; DMSO, dimethyl sulfoxide;

317

T2Rs, taste receptors type 2; K, binding constant; ΔH, enthalpy change of binding; ΔS,

318

entropy change of binding; ΔG, free energy change of binding; R, the gas constant; T, the

319

thermodynamic temperature; QHCl, quinine hydrochloride; PHCl, promethazine

320

hydrochloride; PrHCl, propranolol hydrochloride; BHCl, berberine hydrochloride; YHCl,

321

yohimbine hydrochloride; CP/MAS, Cross Polarization/ Magic Angle Spinning; DSC,

322

differential scanning calorimetry; PCM, polarizable continuum model

323 324

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REFERENCES

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1. Chandrashekar, J.; Hoon, M. A.; Ryba, N. J. P.; Zuker, C. S. The receptors and cells for

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mammalian taste. Nature 2006, 444, 288–294.

2. Drewnowski, A.; Gomez-Carneros, C. Bitter taste, phytonutrients, and the consumer: a review. Am. J. Clin. Nutr. 2000, 72, 1424–1435.

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Uchida, T. The effect of various substances on the suppression of the bitterness of

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quinine-human gustatory sensation, binding, and taste sensor studies. Chem.

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7. Squier, C. A.; Mantz, M. J.; Wertz, P. W. Effect of menthol on the penetration of

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12. Bora, D.; Borude, P.; Bhise, K. Taste masking by spray-drying technique. AAPS PharmSciTech. 2008, 9, 1159–1164.

13. Joshi, S.; Petereit, H. Film coatings for taste masking and moisture protection. Int. J. Pharm. 2013, 457, 395–406.

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taste-masked donepezil hydrochloride orally disintegrating tablets. Biol. Pharm.

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15. Khan, S.; Kataria, P.; Nakhat, P.; Yeole, P. Taste masking of ondansetron

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16. Li, S. P.; Martellucci, S. A.; Bruce, R. D.; Kinyon, A. C.; Hay, M. B.; Higgins III, J. D.

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Evaluation of the film-coating properties of a hydroxyethyl cellulose/hydroxypropyl

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17. Elder, D. Pharmaceutical applications of ion-exchange resins. J. Chem. Educ. 2005, 82, 575.

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18. Samprasit, W.; Akkaramongkolporn, P.; Ngawhirunpat, T.; Rojanarata, T.; Opanasopit,

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Chlorpheniramine maleate using ion-exchange resins. Pharm. Dev. Technol. 2013,

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tablets containing Sumatriptan succinate. Int. J. Pharm. Investig. 2012, 2, 162–168.

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21. Binello, A.; Cravotto, G.; Nano, G.; Spagliardi, P. Synthesis of chitosan-cyclodextrin

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adducts and evaluation of their bitter-masking properties. Flavour Fragr. J. 2004,

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22. Izutani, Y.; Kanaori, K.; Imoto, T.; Oda, M. Interaction of gymnemic acid with

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cyclodextrins analyzed by isothermal titration calorimetry, NMR and dynamic

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light scattering. FEBS J. 2005, 272, 6154–6160.

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23. Szejtli, J.; Szente, L. Elimination of bitter, disgusting tastes of drugs and foods by cyclodextrins. Eur. J. Pharm. Biopharm. 2005, 61, 115–125.

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24. Tokuyama, E.; Shibasaki, T.; Kwabe, H.; Mukai, J.; Okada, S.; Uchida, T. Bitterness

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suppression of BCAA solutions by L-ornithine. Chem. Pharm. Bull. 2006, 54,

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1288–1292.

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25. Keast, R. S. J.; Breslin, P. A. S Bitterness suppression with zinc sulfate and

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Na-cyclamate: a model of combined peripheral and central neural approaches to

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flavor modification. Pharm. Res. 2005, 22, 1970–1977.

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26. Homma, R.; Yamashita, H.; Funaki, J.; Ueda, R.; Sakurai, T.; Ishimaru, Y.; Abe, K.;

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Asakura, T. Identification of bitterness-masking compounds from cheese. J. Agric.

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Food Chem. 2012, 60, 4492–4499.

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27. Frisch, M. J.; Trucks, G. W.; Schlegel, H. B.; Scuseria, G. E.; Robb, M. A.; Cheeseman,

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M.; Li, X.; Hratchian, H. P.; Izmaylov, A. F.; Bloino, J.; Zheng, G.; Sonnenberg, J. L.;

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Hada, M.; Ehara, M.; Toyota, K.; Fukuda, R.; Hasegawa, J.; Ishida, M.; Nakajima, T.;

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Honda, Y.; Kitao, O.; Nakai, H.; Vreven, T.; Montgomery, J. A. Jr.; Peralta, J. E.;

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Ogliaro, F.; Bearpark, M.; Heyd, J. J.; Brothers, E.; Kudin, K. N.; Staroverov, V. N.;

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Keith, T.; Kobayashi, R.; Normand, J.; Raghavachari, K.; Rendell, A.; Burant, J. C.;

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Iyengar, S. S.; Tomasi, J.; Cossi, M.; Rega, N.; Millam, J. M.; Klene, M.; Knox, J. E.;

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Cross, J. B.; Bakken, V.; Adamo, C.; Jaramillo, J.; Gomperts, R.; Stratmann, R. E.;

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Yazyev, O. ; Austin, A. J.; Cammi, R.; Pomelli, C.; Ochterski, J. W.; Martin, R. L.;

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Morokuma, K.; Zakrzewski, V. G.; Voth, G. A.; Salvador, P.; Dannenberg, J. J.; Dapprich,

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S.; Daniels, A. D.; Farkas, O.; Foresman, J. B.; Ortiz, J. V.; Cioslowski, J.; Fox, D. J.;

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Gaussian, Inc., Wallingford CT, USA, 2013.

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28. Kanicky, J. R.; Shah, D. O. Effect of degree, type, and position of unsaturation on the pKa of long-chain fatty acids. J. Colloid Interface Sci, 2002, 256, 201-207.

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29. Geiser, L.; Henchoz, Y.; Galland, A.; Carrupt, P.; Veuthey, J. Determination of pKa

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values by capillary zone electrophoresis with a dynamic coating procedure. J. Sep.

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Sci. 2005, 28, 2374–2380.

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30. Magnussen, M. P. The effect of ethanol on the gastrointestinal absorption of drugs in the rat. Acta Pharmacol. Toxicol. 1968, 26, 130–144.

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31. Krämer, S. D.; Braun, A.; Jakits-Deiser, C.; Wunderli-Allenspach, H. Towards the

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predictability of drug-lipid membrane interactions: the pH-dependent affinity of

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propranolol to phosphatidylinositol containing liposomes. Pharm. Res. 1998, 15,

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739–744.

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FIGURE CAPTIONS

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Figure 1. Chemical structures of five bitter substances showing exothermic interactions

428

with sodium oleate.

429

Figure 2. 1H-NMR spectra of (1) QHCl, (2) PHCl, and (3) PrHCl. a) Spectra of bitter

430

substances in the presence of sodium laurate; b) spectra of bitter substances alone; c)

431

spectra of bitter substances in the presence of glycerol monolaurate. Characteristic protons

432

are indicated by arrows. The broadening of the OH and perturbation of H9 in QHCl and

433

the broadening of OH and NH in PrHCl resulted from the exchange of OH or NH protons

434

with those in the carboxyl moiety in sodium laurate. *Signals of sodium laurate,

435

of glycerol monolaurate.

436

Figure 3. Titration curve corresponding to QHCl (H6, H8, and H2) upon addition of

437

sodium laurate. The change in the chemical shift (∆δ) in 32 µmol of QHCl is plotted as a

438

function of the molar ratio of sodium laurate (0, 0.2, 0.5, and 0.8).

439

Figure 4. NOESY spectra of QHCl in the presence of sodium laurate. 1H-NMR spectra of

440

QHCl/sodium laurate is displayed on X–Y axis. Characteristic cross-peaks are indicated by

441

red circles. *Signals of sodium laurate;

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Figure 5. Structures of three bitter substances and their laurates



signals of aromatic protons in QHCl.

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443

Carbon atoms are presented in gray, oxygen in red, sulfur in yellow, nitrogen in blue, and

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chloride in light green.

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Figure 6. (a) Needle-like crystals formed between sodium laurate and QHCl. (b) DSC

446

thermal curve of the crystal.

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Figure 7. Possible mechanism of interaction between sodium laurate and QHCl. Sodium

448

laurate and QHCl interact weakly via step 1; dissociation equilibrium of QHCl as weak

449

bases and sodium laurate as weak acids. Hydrogen bonding and insoluble binary

450

complexes occur via step 2; For fatty acids with a chain length of 12 or more carbon atoms,

451

hydrogen bond formation between quinine and laurate. The complex model is presented in

452

the lower image. QHCl molecules are colored blue, and sodium laurate is shown in orange.

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The binary complexes are connected to each other by hydrophobic interactions, and grow

454

in a single direction, forming of the needle-like crystals.

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TABLES

Table 1. Thermodynamic parameters for association between five bitter substances and sodium salts of fatty acids. QHCl a

Lauric acid (12:1) Myristoleic acid (14:1) Palmitoleic acid (16:1) Oleic acid (18:1) Linoleic acid (18:2) Linolenic acid (18:3)

∆H d

b

PHCl

PrHCl

BHCl

YHCl

e

−25.5±3.5

−20.3±2.6

−16.7±2.3

-

-

−3.5±3.5

0.7±2.6

1.3±2.5

-

-

c

∆G

−22.0±0.1

−21.0±0.0

−18.0±0.1

-

-

∆H

−10.8±1.4

−12.6±0.7

-

-

-

T∆S

13.7±1.9

11.0±0.6

-

-

-

∆G

−24.5±0.5

−23.6±0.1

-

-

-

∆H

−28.0±2.6

−21.8±2.5

−24.4±1.4

-

-

T∆S

−0.3±2.8

5.2±3.0

1.3±1.5

-

-

∆G

−27.6±0.3

−27±0.6

−25.7±0.1

-

-

∆H

−17.7±0.4

−10.7±0.2

−6.4±0.1

−11.5±0.2

−10.0±0.5

T∆S

11.5±0.4

18.3±0.3

22.0±0.1

15.7±0.2

14.6±0.4

∆G

−29.2±0.0

−29.0±0.3

−28.4±0.3

−27.2±0.0

−24.6±0.2

∆H

−27.3±3.1

−21.0±2.3

−28±1.7

-

-

T∆S

1.3±3.1

7.5±2.4

−2.1±1.8

-

-

∆G

−28.6±0.1

−28.6±0.1

−25.8±0.1

-

-

∆H

−42.3±2.5

−30.4±3.2

−28.2±3.8

−34.5±0.8

−7.8±1.5

T∆S

−15.1±2.5

−2.6±3.2

−2.6±4.0

8.8±8.2

−17.4±1.7

∆G

−27.2±0.0

−27.8±0.0

−25.6±0.2

−25.6±0.1

−25.1±0.3

T ∆S

a

Enthalpy change ∆H (kJ/mol), bentropy change ∆S (kJ/mol・K), cGibbs free energy ∆G (kJ/mol), and dT thermodynamic temperature (K). e“-” means not determined by

calculation according to “one set of site” model using the titration curve. Mean and standard deviation values from the fitted data of three independent experiments.

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Table 2. Binding constant K (× ×103・M−1) derived from ITC profiles for the association between five bitter substances and nine sodium salts of fatty acids and two glycerol esters.

QHCl

PHCl

PrHCl

BHCl

YHCl

a

Octanoic acid (8:0)

-

-

-

-

-

Decanoic acid (10:0)

-

-

-

-

-

Lauric acid (12:0)

7.2±0.2

4.9±0.0

1.4±0.1

Myristoleic acid (14:1)

19.9±4.0

13.7±0.3

-

-

-

Palmitoleic acid (16:1)

69.2±6.9

54.8±14.0

32.2±2.2

-

-

Oleic acid (18:1)

129±1.2

123.0±14.3

94.8±9.1

59.5±4.8

20.4±1.5

Linoleic acid (18:2)

101.1±3.4

100.7±4.9

33.4±0.8

-

-

Linolenic acid (18:3)

60.4±0.7

74.2±0.5

31.2±2.2

31.1±1.0

25.8±3.6

Glycerol monolaurate

-

-

-

-

-

Glycerol monooleate

-

-

-

-

-

Hexanoic acid (6:0)

a

“-” means not determined by calculation according to the “one set of site” model using the

titration curve. Mean and standard deviation values obtained from the fitted data of three independent experiments

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FIGURE GRAPHICS

Figure 1.

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Figure 2.

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Figure 3.

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Figure 4.

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Figure 5.

QHCl

Quinine Laurate

PHCl

Promethazine Laurate

PrHCl

Propranolol Laurate

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Figure 6.

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Figure 7.

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GRAPHICS FOR TABLE OF CONTENTS

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