Evaluation of Initial Flavor Fade in Fresh Roasted Peanuts using Gas Chromatography-Flame Ionization Detection, Gas Chromatography-Olfactometry, Sensory Analysis, and Chemosensory Techniques

Powell, Jodi

17 November 2004

Preventing flavor fade requires an understanding of the relationship between carbonyl amine and lipid oxidation reactions. The polyunsaturated fatty acid content of lipids in peanuts makes them more susceptible to lipid oxidation. The major by-products of the oxidation reaction are nonanal, hexanal, octanal, and decanal. These chemicals are associated with cardboardy, painty, and oxidized flavors associated with flavor fade. The carbonyl-amine reaction yields a variety of pyrazines with positive flavor attributes. Initial flavor notes were explored through sensory work, Gas Chromatography-Olfactometry, and chemical analysis. The fresh roasted volatiles produced from roasted peanuts and the aldehydes resulting from oxidation were also evaluated using GC-FID to quantify and identify the pyrazines and hexanal over a 21 day storage period. Electronic Nose was used to determine differences between storage periods. Gas chromatography-Olfactometry identified potent pyrazines contributing to fresh roasted peanutty aroma in fresh peanuts. Using GC-FID a significant decrease (p<.05) in 2-ethylpyrazine and 2,3-diethylpyrazine concentration was found over a 21-day period. No significant difference (p>0.05) was noted in the other pyrazines evaluated. A significant increase (p<0.05) was noted in the hexanal concentration over a 21-day period. The peroxide values and sensory analysis correlated directly with the GC-FID results with a significant increase (p<0.05) in peroxide value at Day 14 and Day 21, and a significant decrease (p<0.05) in fresh roasted peanuty flavor from days 0-21 and a significant increase (p<.05) in painty, cardboardy and bitter from days 7-21. The electronic nose successfully separated Day 0 and Day 21 samples from Day 7 and 14, which were also separated, but with minimal overlap. / Ph. D.

solid phase microextraction

gas chromatography-olfactometry

roasted peanuts

Pyrazines

Formation of Key Aroma Compounds Generated in Condensed Wood Smoke for the Flavoring of Foods

Vazquez, Timothy D.

11 August 2022

No description available.

Food Science

Aplicación de la cromatografía de gases-olfatometría en la caracterización del aroma del vinagre de vino, de los pistachos y del aceite de oliva.

Aceña Muñoz, Laura

04 March 2011

En esta Tesis Doctoral se aplica la cromatografía de gases con detector olfatométrico (la nariz humana) en el análisis de los compuestos volátiles aromáticos de distintos alimentos: el vinagre de vino con Denominación de Origen Protegida “Vinagre de Jerez”, los pistachos tostados y el aceite de oliva. Los distintos métodos de preparación de muestra (la microextracción en fase sólida sobre el espacio de cabeza, o HS-SPME, y la extracción directa con disolvente, o DSE) han proporcionado extractos representativos del aroma de estos productos, y gracias a la técnica olfatométrica empleada (Aroma Extract Dilution Analysis o AEDA) se han identificado los odorantes más potentes. Así se ha logrado caracterizar el aroma de dichos alimentos, recogiéndose los resultados de las investigaciones realizadas en distintos artículos publicados en varias revistas internacionales. / In this Doctoral Thesis, the gas chromatography with olfactometry detector (the human nose) has been applied to analyse the volatile aromatic compounds from different foodstuffs: the wine vinegar produced under Protective Denomination of Origen “Vinagre de Jerez”, the roasted pistachios and the olive oil. The different sample pre-treatment methods employed (the headspace solid-phase microextraction, or HS-SPME, and the direct solvent extraction, or DSE) have provided representative aroma extracts from these products. Furthermore, and thanks to the olfactometric technique used (the Aroma Extract Dilution Analysis or AEDA), the most potent odorants have been identified. Thus, the aroma of all these foodstuffs has been characterized. All the results obtained from the research developed have been published in different international journals.

Análisis cromatográfico

Chromatographic analysis

Gas chromatography-olfactometry (GCO)

Aroma

fragrancy

compuestos volátiles

volatile compounds

Caracterización

Characterization

517

543

663/664

Préservation de l'arôme dans un jambon cuit non nitrité / Preservation of aroma in a nitrite-free cooked ham

Thomas, Caroline

10 December 2014

Le nitrite est un ingrédient essentiel à la fabrication du jambon cuit, pourtant les risques sanitaires dont il est accusé remettent en question son utilisation. L’emploi de cet unique additif permet de remplir de nombreuses fonctions comme la protection antioxydante et antimicrobienne mais aussi le développement de la couleur et de l’arôme. C’est sur cette dernière fonction que ce travail de thèse s’est focalisé avec pour objectif la suppression du nitrite dans la fabrication du jambon cuit. La mise en œuvre de plusieurs techniques complémentaires de chromatographie en phase gazeuse couplées à l’olfactométrie a permis dans une première partie d’identifier le 2-methyl-3-furanthiol, 2-methyl-3-(methyldithio)furan, et le bis(2-methyl-3-furyl)disulfide comme les molécules soufrées responsables de l’arôme du jambon cuit. Il est apparu qu’en l’absence de nitrite et par conséquent en absence de protection antioxydante, les composés odorants issus de l’oxydation sont produits massivement et ont tendance à perturber l’arôme global du jambon cuit. Afin de restaurer l’arôme en l’absence de nitrite, l’étude a été organisée selon 2 axes : le premier visant à favoriser la production des molécules soufrées clés de l’arôme et le second visant à limiter la formation des composés d’oxydation perturbateurs de l’arôme grâce à l’utilisation d’antioxydants naturels. Les recherches ont été conduites sur des mini-jambons cuits modèles. La thiamine a été identifiée comme précurseur majoritaire du 2-methyl-3-furanthiol, du 2-methyl-3-(methyldithio)furan, et du bis(2-methyl-3-furyl)disulfide dans les conditions de fabrication du jambon cuit et des extraits d’acérola, de canneberge, d’oignon et de thé ont été sélectionnés pour leurs propriétés antioxydantes. L’évaluation en parallèle de l’oxydation et de l’arôme a montré que ces quatre extraits utilisés en mélange permettaient, non seulement d’égaler les performances antioxydantes du nitrite, mais aussi de rehausser la note aromatique « jambon cuit » par rapport à la formulation non nitritée de référence. L’association de la thiamine et des extraits végétaux a finalement permis de réaliser des jambons non nitrités qui, en termes d’arôme et d’oxydation, se rapprochent fortement d’un jambon nitrité. Les formulations réalisées constituent donc une première piste satisfaisante pour répondre à la problématique de la suppression du nitrite dans le jambon cuit. La protection antimicrobienne des nouvelles formulations doit être validée et la restauration de la couleur rose du jambon demeure une problématique organoleptique. / Sodium nitrite is an essential ingredient in the cooked ham production process, yet its use is under challenge due to food safety concerns. Sodium nitrite is a multifunctional additive used for its ability to act on several fronts—from inhibiting oxidation and preventing microbial growth to giving desirable colour and aroma. This study focused on the aroma function under a wider objective to reduce nitrite use in cooked ham processing. Using several complementary methods with gas chromatography–olfactometry, we first identified 2- methyl-3-furanthiol, 2-methyl-3-(methyldithio)furan and bis(2-methyl-3-furyl)disulfide as the odour- active sulphur-compounds responsible for cooked ham flavour. It emerged that in the absence of nitrite—and therefore the absence of inhibited oxidation—the massive formation of an array of odour-active compounds produced by oxidative breakdown tended to disrupt the overall aroma of the final cooked ham. Next, in an effort to restore this aroma in the absence of nitrite, the study was organized into two strands, where the first strand aimed to promote the production of key aroma-active sulphur-compounds while the second strand aimed to minimize the formation of aroma-disruptive oxidation compounds by using natural antioxidants. This research was led on model cooked mini-hams. We identified thiamine as the major precursor of 2-methyl-3-furanthiol, 2-methyl-3-(methyldithio)furan and bis(2-methyl-3-furyl)disulfide under cooked ham production conditions, and we selected acerola, cranberry, onion and tea extracts as natural antioxidants. The coupled evaluations of oxidation and aroma showed that the formulated mixture of these four extracts not only equalled the antioxidant performances of added sodium nitrite but also lifted the “cooked ham” head note compared to the reference no-added-nitrite formulation. The association of thiamine and vegetal extracts ultimately made it possible to produce no-added-nitrite hams that, in terms of aroma and oxidation levels, proved almost identical to nitrite-added ham. The engineered formulations thus offer a good research track to suppress the sodium nitrite in cooked ham. The problem of how to restore the distinctive pink colour of cooked ham is an issue that remains to be resolved, and the ability of these new formulations to inhibit microbial growth needs to be validated.

Jambon cuit

Nitrite

Composés odorants clés

Chromatographie en phase gazeuse

Olfactométrie

Composés soufrés

Précurseurs d’arôme

Oxydation

Antioxydants

Analyse sensorielle

Cooked ham

Nitrite

Key odorants

Chromatography olfactometry

Sulphur compounds

Aroma precursors

Oxidation

Antioxidants

Sensory analysis