Effects of retro-nasal aroma release on satiation

It is suggested that the brain response of a food odour sensed retro-nasally is related to satiation. The extent of retro-nasal aroma release during consumption depends on the physical structure of a food, i.e. solid foods generate a longer, more pronounced retro-nasal aroma release than liquid foods. The aim of this study was to investigate if a beverage becomes more satiating when the retro-nasal aroma release profile coincides with the profile of a (soft) solid food. In a double-blind placebo-controlled randomised cross-over full factorial design, twenty-seven healthy subjects (fourteen males and thirteen females; aged 16-65 years; BMI 19-37 kg/m(2) were administered aroma profiles by a computer-controlled stimulator based on air dilution olfactometry. Profile A consisted of a profile that is obtained during consumption of normal beverages. Profile B is normally observed during consumption of (soft) solids. The two profiles were produced with strawberry aroma and administered in a retro-nasal fashion, while the subjects consumed a sweetened milk drink. Before, during and after the sensory stimulation, appetite profile measurements were performed. Subjects felt significantly more satiated if they were aroma stimulated with profile B (P = 0.04). After stimulation with sweet strawberry aroma, there was a significant decrease in desire to eat sweet products (P = 0.0001). In conclusion, perceived satiation was increased by altering the extent of retro-nasal aroma release

Retronasal Aroma Release and Satiation: a Review

In view of the epidemic of obesity, one of the aims of the food industry is to develop good-tasting food products that may induce an increased level of satiation, preventing consumers from overeating. This review focuses on the possibility of using aroma as a trigger for inducing or increasing satiation. Using a novel approach of atmospheric pressure chemical ionization-mass spectrometry (APcl-MS) in combination with olfactometry, the relative importance of different aroma concepts for satiation was studied, from both consumer and food product points of view. The extent of retronasal aroma release appears to be a physiological feature that characterizes a person. Although the extent of retronasal aroma release appears to be subject specific, food product properties can be tailored in such a way that these can lead to a higher quality and/or quantity of retronasal aroma stimulation. This in turn provokes enhanced feelings of satiation and ultimately may contribute to a decrease in food intake

Real-Time Flavor Release from French Fries Using Atmospheric Pressure Chemical Ionization-Mass Spectrometry

Flavor release from French fries was measured with atmospheric pressure chemical ionization-mass spectrometry (APCI-MS) using both assessors (in vivo) and a mouth model system (in vitro). Several volatiles measured with APCI were identified with MS-MS. The effect of frying time, salt addition, and an alternative process using superheated steam was determined on Imax (maximum intensity of compounds) and on tmax (time of maximum intensity). In vitro a "chewing" frequency of 0.60 Hz caused an increased tmax for low molecular weight compounds compared to the other frequencies tested. Above 0.93 Hz further increase in the frequency did not affect tmax. Trends observed with in vivo experiments could be verified with in vitro experiments. Imax correlated well with frying time. Addition of salt resulted in a decreased tmax, suggesting a salting-out effect. The alternative process caused a layer of oil on the surface, and this resulted in a higher tmax, but no effect on Imax was found. This phenomenon may be critical for the sensory quality and would not have been observed with static volatile measurements, demonstrating the value of flavor release measurement

Flavor Release from French Fries

Flavor release from French fries was measured with the MS-NOSE using both panelists and a mouth-model system. The identity of several volatiles measured with the MS-NOSE was verified with MS-MS. The effect of frying time and the effect of adding salt on I-max (maximum intensity of compounds) and on (time of maximum intensity of compounds) were determined. I-max of the formation of all compounds correlated with frying time. Addition of salt resulted in a lower t(max), but no significant effect on I-max was found. In vivo measurements with panelists showed that all components reached t(max) within 10 seconds, while in vitro measurements with the mouth model system showed that low molecular compounds reached t(max) within 50 seconds, while higher molecular compounds reached t(max) after 3-5 minutes

Acute Effects of Complexity in Aroma Composition on Satiation and Food Intake

Compared to placebo, subjects felt significantly more satiated during aroma stimulation with the multicomponent strawberry aroma in the olfactometer-aided setting. Additionally, perceived satiation was significantly increased 10-15 min after consumption of the multicomponent strawberry-aromatized sweetened yogurt product in the ad libitum eating setting. There was no effect on the amount of strawberry-aromatized sweetened yogurt product consumed ad libitum. Apart from the differences in timing of the appetite-regulating effects, both experimental settings demonstrated that the multicomponent strawberry aroma, which was perceived as being more complex, yet of similar aroma quality, intensity, and pleasantness compared with the single-component strawberry aroma, was able to enhance perceived satiation. The methodology of the olfactometer-aided aroma stimulation proved to be representative of a real-life setting with regard to aroma exposure and satiation. Food products, which are perceived as being more complex, have been suggested to delay the development of sensory satiation as a result of implicitly cueing for variation. The present results may be explained by increased sensory stimulation, due to concurrent exposure to multiple aroma components cueing for sensorily similar strawberry perceptio

Effect of whey protein on the In Vivo Release of Aldehydes.

Retention of aldehydes by whey proteins in solutions buffered at a range of pH values was studied under static and dynamic headspace conditions and in vivo in exhaled air. Static headspace measurements showed a clear increase in retention in the presence of whey proteins for aldehydes with longer carbon chains and for buff er solutions with higher pH values. For in vivo aldehyde release measurements, these effects were much less pronounced. The presence of saliva or the binding of aldehydes to the surface of the oral cavity was not responsible for this effect. This difference can be explained by the highly dynamic conditions of in vivo aroma release of liquid products, due to the relatively large flow of air during exhalation. After swallowing, a thin film of aldehyde solution remains in the pharynx; subsequent exhalation will release both the free aldehydes present in this film and those reversibly bound to the whey protein