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Sweetness sucrose

The taste of aqueous quinine hydrochloride solution with and without sucrose was examined in four volunteers (males, aged 23 28). All considered 1 mM quinine hydrochloride quite bitter, ImM quinine hydrochloride and 100mM sucrose bitter-sweet, and 1 mM quinine hydrochloride and 500 mM sucrose sweet though bitter. Sucrose is thus shown to lessen the bitterness of quinine hydrochloride solution, as generally already known. Quinine hydrochloride and sucrose are bitter and sweet substances, respectively, and thus a sweet substance may alter oscillation, when a bitter substance is present, to that corresponding to a sweet substance. [Pg.722]

The taste profile of aspartame is similar to sucrose sweetness (Ripper et al., 1985). It is approximately 200 times as sweet as sucrose. It is synergistic with saccharin, cyclamate, stevioside, acesulfame K and many sugars, in particular fructose, but has little sweetness intensity synergy with sucralose. [Pg.76]

Typical five primary taste substances, HC1 (sour), NaCl (salty), quinine-HCl (bitter), sucrose (sweet) and MSG (umami) were studied [16]. In general, the response of each lipid membrane was nonspecific to various taste substances. [Pg.384]

Influence of Sweeteners on Bitterness. In model system studies, natural fruit juice sugars were observed to raise the limonin threshold (24). An expanded study of natural and artificial sweeteners (26) demonstrated that sucrose, neohesperidin dihydro-chalcone (NHD), hesperetin dihydrochalcone glucoside (HDG) and aspartylphenylalanine methyl ester (AP) all raise the limonin threshold. At low sweetness levels HDG was the most effective followed by AP and NHD. Sucrose was without effect up to the 2% level. At sweetness levels equivalent to 1% sucrose, HDG, AP and NHD raised the limonin threshold in water from 1.0 ppm to 3.2, 2.5 and 1.3 ppm, respectively. Because of its high sweetness intensity, the concentration of NHD (16 ppm) was considerably lower than HDG (80 ppm) and AP (90 ppm). At 3-10% sucrose sweetness equivalency, the effectiveness of NHD increased substantially, sucrose moderately and HDG slightly, while that of AP decreased. Therefore, the sweeteners HDG, AP and NHD can effectively suppress limonin bitterness at low concentrations. [Pg.75]

Sucrose Sweet taste but hygroscopic, may be diluted with lactose... [Pg.989]

Flavouring substances that cause only taste impressions are defined as substances that are usually non-volatile at room temperature. Therefore, they are only perceived by the taste receptors [7]. Examples are sucrose (sweet) or caffeine (bitter). Flavouring substances causing odour impressions are volatiles that are perceived by the odour receptors [7]. Examples are ethyl butyrate or dimethyl sulfide. Some flavouring substances are perceived by taste and odour receptors (e.g. acetic acid, butyric acid). [Pg.140]

It is also well known that sweet and bitter tastes interact. It is the case for the inhibition of sucrose sweet taste by inhibitors like lactisol or methyl-4, 6-dichloro-4,6-dideoxy-galactopyranoside which was attributed to their hydrophobic character and their bitterness (Mathlouthi et al., 1993). Bitter taste was foimd to be suppressed by sweeteners such as sucrose (Bartoshuk, 1975). The masking of unpleasant taste by pleasant (sweet) stimuli is greatly sought after in pharmaceuticals. For example, cyclodextrins were described to have the ability of masking the bitterness of drugs like propantheline... [Pg.583]

In a mixture of sugars, if the sweetness values of the components are calculated in terms of dextrose sweetness, the values become additive rather than supplemental as they appear to be when calculated in terms of sucrose sweetness as the standard (3). The sugar and corn products industries, through the nature of their products, have given the confectioner a flexibility and a challenge to his creative abilities for producing new candy. [Pg.61]

PRO-PL - for pregnant and lactating Sucrose, sweet dairy whey, soy protein 30 g 294mcg/100 g... [Pg.736]

For example, D-fructose solutions are sweeter than sucrose solutions, but in pastries and hot coffee both sugars show the same sweetness. The sweetest form is P-D-fructopyranose, which has about 180% of sucrose sweetness, but as a result of mutarota-tion, the sweetness of solutions decreases to about 150% of the sucrose sweetness because the individual anomers each have a... [Pg.634]

It is found in lichens and in some algae. It has m.p. 120 C, is very soluble in water and is about twice as sweet as sucrose. It is a reference compound upon which the erythro nomenclature is based. [Pg.162]

Ordinary glucose is ct-glucopyranose monohydrate m.p. 80-85°C and [ajp 4-113-4 . In solution it gives a mixture with the form with [alo 4-52-5 . It is manufactured from starch by hydrolysis with mineral acids, purification and crystallization, and is widely used in the confectionery and other food industries. It is about 70% as sweet as sucrose. [Pg.191]

Sucralose has the structure most similar to su crose Galactose replaces the glucose unit of sucrose and chlorines replace three of the hydroxyl groups Sucralose is the newest artificial sweetener having been approved by the U S Food and Drug Adminis tration in 1998 The three chlorine substituents do not dimmish sweetness but do interfere with the ability of the body to metabolize sucralose It there fore has no food value and IS noncaloric... [Pg.1051]

Sensory perception is both quaUtative and quantitative. The taste of sucrose and the smell of linalool are two different kinds of sensory perceptions and each of these sensations can have different intensities. Sweet, bitter, salty, fmity, floral, etc, are different flavor quaUties produced by different chemical compounds the intensity of a particular sensory quaUty is deterrnined by the amount of the stimulus present. The saltiness of a sodium chloride solution becomes more intense if more of the salt is added, but its quaUty does not change. However, if hydrochloric acid is substituted for sodium chloride, the flavor quahty is sour not salty. For this reason, quaUty is substitutive, and quantity, intensity, or magnitude is additive (13). The sensory properties of food are generally compHcated, consisting of many different flavor quaUties at different intensities. The first task of sensory analysis is to identify the component quahties and then to determine their various intensities. [Pg.1]

A persistent idea is that there is a very small number of flavor quaUties or characteristics, called primaries, each detected by a different kind of receptor site in the sensory organ. It is thought that each of these primary sites can be excited independently but that some chemicals can react with more than one site producing the perception of several flavor quaUties simultaneously (12). Sweet, sour, salty, bitter, and umami quaUties are generally accepted as five of the primaries for taste sucrose, hydrochloric acid, sodium chloride, quinine, and glutamate, respectively, are compounds that have these primary tastes. Sucrose is only sweet, quinine is only bitter, etc saccharin, however, is slightly bitter as well as sweet and its Stevens law exponent is 0.8, between that for purely sweet (1.5) and purely bitter (0.6) compounds (34). There is evidence that all compounds with the same primary taste characteristic have the same psychophysical exponent even though they may have different threshold values (24). The flavor of a complex food can be described as a combination of a smaller number of flavor primaries, each with an associated intensity. A flavor may be described as a vector in which the primaries make up the coordinates of the flavor space. [Pg.3]

Texture also influences the evaluation of taste. Sweetness in a Hquid is associated with body or viscosity. An artificially sweetened beverage that lacks body, therefore, may be rated quaUtatively lower than one equally sweet but containing sucrose. [Pg.10]

Ammonium glycyrrhizinate [53956-04-0] (AG), C42H N02g, is a flavor enhancer derived from Hcorice root. It is approximately 50 times sweeter than sucrose and is often used to enhance sweetness in a wide variety of food products (56). Maltol [118-71 -8] C H O, and ethyl maltol [4940-11-8], CyHgO, are used as flavor enhancers in products such as cake mixes, confections, cookies, ice cream, fmit juices, puddings, and beverages (57). [Pg.441]

Saccharin. Sacchatin [81-07-2] C H NO S, which is approximately 300 times as sweet as sucrose ia coaceatratioas up to the equivaleat of a 10% sucrose solutioa, has beea used commercially as a nonnutritive sweeteaer siace before 1900, predomiaanfly ia carboaated soft drioks, tabletop sweeteaers, and dietetic foods marketed primarily to diabetics. In 1977, the FDA proposed a ban on sacchatin because of its association with bladder cancer ia laboratory animals. At the time, it was the only commercially available nonnutritive sweetener, and pubflc outcry led to a delay of the ban, which was officially withdrawn ia 1991. Instead, the FDA required that warning labels be placed on all foods that contained the iagredient. Although sacchatin is heat stable, the pubflc debate over its safety, as well as the fact that approximately one-third of the population perceives it to have a bitter aftertaste, has limited its use. [Pg.442]

Acesulfame K. Acesulfame K [55589-62-3] C H NO S -K, is an oxathia2iae derivative approximately 200 times as sweet as sucrose at a 3% concentration ia solutioa (70). It is approved for use as a nonnutritive sweeteaer ia 25 couatties (71), and ia the United States has approval for use in chewing gum, confectionery products, dry mixes for beverages, puddings, gelatins, and dairy product analogues, and as a tabletop sweetener (72). [Pg.442]

Other Sweeteners. Two other sweeteners, sucralose and cyclamates, are approved for use outside of the United States. Sucralose, a chlorinated derivative of sucrose which is 500—600 times as sweet as sugar, has received limited approval in Canada, and petitions for its approval are pending in the United States and Europe (71). Cyclamate sweeteners, once available in the United States, but now baimed because they caused bladder cancer in animals, are stiU available in Canada and Europe. Table 7 gives several examples of nonnutritive sweeteners that have been developed. [Pg.442]

The sweet taste of sucrose is its most notable and important physical property and is regarded as the standard against which other sweeteners (qv) are rated. Sweetness is induenced by temperature, pH, sugar concentration, physical properties of the food system, and other factors (18—20). The sweetening powers of sucrose and other sweeteners are compared in Table 3. The sweetness threshold for dissolved sucrose is 0.2-0.5% and its sweetness intensity is highest at 32-38°C (19). [Pg.4]

Table 3. Relative Sweetness of Sucrose and Other Sweet Substances... Table 3. Relative Sweetness of Sucrose and Other Sweet Substances...
Fmctose is sweeter than sucrose at low temperatures (- S C) at higher temperatures, the reverse is tme. At 40°C, they have equal sweetness, the result of a temperature-induced shift in the percentages of a- and P-fmctose anomers. The taste of sucrose is synergistic with high intensity sweeteners (eg, sucralose and aspartame) and can be enhanced or prolonged by substances like glycerol monostearate, lecithin, and maltol (19). [Pg.4]

Food Applications. On the basis of intake, sucrose is the leading food additive (2). Its principal contribution to food is sweetness. However, it provides many other functionahties, eg, body, mouthfeel, texture, and moisture retention. Cereals and baked goods are the leading consumers of sucrose, followed closely by confectionery products (36). [Pg.5]


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