Comparative study on the volatile compounds and sensory characteristics of some locally produced potato chips

Document Type : Original Article

Authors

1 Food Science and Technology Department, Faculty of Agriculture, Al-Azhar University, Cairo, Egypt

2 National Research Center, Flavour and Aromatic Chemistry Department, Dokki, Giza, Egypt

Abstract

This study was carried out to evaluate the volatile compounds in the headspace of two types of fried potato chips (A and B), flavoured with salt only. The impact of seasoning addition (tomato, onion and cheese) that are highly preferred by consumers on the flavour quality of these two potato snacks was investigated. A comparative study concerning fat contents, headspace volatiles and sensory characteristics was carried out between the two brand types of tested potato chips. The results indicated that the lipid content of the two brand types of potato chips ranged from 28.65 to 33.41% in all tested traditional potato chips. The gas chromatography-mass spectrometric (GC-MS) analysis of the headspace volatiles of all samples revealed the presence of 86 volatile compounds with total higher content in all brand B varieties than brand A. The identified compounds included different chemical groups such as; sugar and Maillard degradation products, lipid degradation products, sulfur containing compounds, terpenes and miscellanies compounds. The total amount of lipid degradation products in samples A and B was lower than that of Maillard reaction, sugar degradation, or both products. The results revealed that sample As showed higher scores for all investigated attributes compared to sample Bs. The odour intensity and onion flavour scored higher values in sample Aco than sample Bco. Whereas, the taste attribute and cheese flavour showed the opposite trend. Concerning the tomato seasoned potato chips, sample Bt showed higher scores for all investigated sensory attributes compared to sample At.

Keywords


Comparative study on the volatile compounds and sensory characteristics of some locally produced potato chips

M. A. Mohamed 1, M. I. Mohamed 1, H. H. Fadel 2 and S. M. Ghanem 1*

1 Food Science and Technology Department, Faculty of Agriculture, Al-Azhar University, Cairo, Egypt

2 National Research Center, Flavour and Aromatic Chemistry Department, Dokki, Giza, Egypt

* Corresponding author E-mail: sameh.ghanem@azhar.edu.eg (S. Ghanem)

ABSTRACT

This study was carried out to evaluate the volatile compounds in the headspace of two types of fried potato chips (A and B), flavoured with salt only. The impact of seasoning addition (tomato, onion and cheese) that are highly preferred by consumers on the flavour quality of these two potato snacks was investigated. A comparative study concerning fat contents, headspace volatiles and sensory characteristics was carried out between the two brand types of tested potato chips. The results indicated that the lipid content of the two brand types of potato chips ranged from 28.65 to 33.41% in all tested traditional potato chips. The gas chromatography-mass spectrometric (GC-MS) analysis of the headspace volatiles of all samples revealed the presence of 86 volatile compounds with total higher content in all brand B varieties than brand A. The identified compounds included different chemical groups such as; sugar and Maillard degradation products, lipid degradation products, sulfur containing compounds, terpenes and miscellanies compounds. The total amount of lipid degradation products in samples A and B was lower than that of Maillard reaction, sugar degradation, or both products. The results revealed that sample As showed higher scores for all investigated attributes compared to sample Bs. The odour intensity and onion flavour scored higher values in sample Aco than sample Bco. Whereas, the taste attribute and cheese flavour showed the opposite trend. Concerning the tomato seasoned potato chips, sample Bt showed higher scores for all investigated sensory attributes compared to sample At.

Keywords:Potato chips, potato chips with salt, cheese and onion, tomato flavour, odour intensity.

 

INTRODUCTION

Potato (Solanum tuberosum L.) is one of the most important vegetable crops grown in Egypt. It is the fourth most important world crop after rice, wheat and maize. It is a major source of inexpensive energy. Moreover, potato is used in many industries, such as French fries, chips, starch and alcohol production (Elhakim et al., 2016).

In Egypt, potato chips are considered one of the most important products of food industry and they are the top choice for between-meal munching for adults and children (Allshouse et al., 2002). Potato crisp is a fragile but firm slice of potato that has been cooked by deep-frying in vegetable oil and to which edible salt (powder or brine) or permitted food grade spices, colour and flavour may have been added (Surkan et al., 2009; Godswill et al., 2018).

The potato chip or crisp is considered one of the most popular snacks globally (Dhital et al., 2018). Some authors define a snack as a portion of food, smaller than a regular meal, generally eaten between meals. Snack food manufacturers produce mainly two kinds of potato crisps: the traditional crisps from fresh potatoes, which are produced from thinly slicing and deep frying of them, and the typical restructured potato crisps from potato dough, which are molded into desired shapes by extruding or pressing before frying, such as Pringles (Pedreschi et al., 2018).

Traditionally, potato crisps are produced by oil frying to a temperature well above the boiling point of water (180°C), causing evaporation of water inside the product, and the formation of a crust. Besides cooking foods very quickly, this unit operation also provides unique sensorial attributes attractive to the consumer, such as colours, aromas, flavours and textures that improve the overall palatability (Pedreschi et al., 2018).

Consumer’s acceptance of food stuffs is closely related to their flavours. Volatiles from potato snacks are usually classified based on the mechanism of formation (Whitfield and Last, 1991; Comandini et al., 2011; Raigond et al., 2015). These volatiles are lipid oxidation products, Maillard, sugar degradation or all such products and small amounts of endogenous flavour compounds (Loon et al., 2005)

Chips flavour is affected by many factors including potato tuber composition, frying oil composition and temperature and the time of frying (Martin and Ames 2001).  Studies on the volatile compounds of potato chips have been reviewed by Jansky (2010).  More than 500 volatile compounds were identified in the volatiles of French fries and potato chips showing a similar aroma (Comandini et al, 2011). Among the 150 volatile compounds identified in the volatiles of potato chips, 60 compounds are lipid degradation products, with the polyunsaturated fatty acids of the frying oil likely to be their main precursors (Warner et al., 1997). 

Flavour stability in seasoned snack food, such as potato chips, is of great importance because of its relationship with the quality and acceptability of foods over the shelf life but is often difficult to control. Cheese and onion seasoning helps in slowing the lipid oxidation in deep-fried potato crisps and consequently controls both the shelf-life stability of seasoning and seasoned products (Agarwal et al., 2018). Cheese flavour is one of the most important criteria determining consumer choice and acceptance (Avsar et al., 2004). Cheese flavouring agent, because of its rich flavours, convenient application, lower cost and long shelf life, is used in a variety of products including, by way of example only, breads, salad dressings, cheese spreads, pizza toppings, sauces and snack foods (El-Shayeb et al., 2017).

Tomato seasoned potato chips are very popular among consumers, however, no studies could be found regarding the impact of tomato flavour on the odour profile of potato chips. Flavour and aroma are essential parameters of quality in tomatoes. Characteristic tomato flavour results from taste components, aromatic volatiles and a complex interaction between them (Yilmaz 2001). Among over 400 volatile compounds determined in tomatoes, only a limited number is considered essential to the aromatic component of tomato flavour. Volatiles in fresh tomatoes and leaves are formed from lipids, carotenoids, amino acids, terpenoids (C10 and C15), lignin and other sources. The pleasant sweet-sour taste of tomatoes is mainly due to their sugars (primarily the reducing sugars, glucose and fructose) and organic acids (citric and malic acids) are the major organic acids content (Tandon et al., 2000).

Flavour analysis using a variety of methods has been conducted for many years to help the development of new products, to understand the nature of existing products, to study shelf-life, and to maintain quality of foods, beverages, products for oral care, and other products such as oral pharmaceuticals and tobacco (Meilgaard et al., 2006; Lawless and Heymann, 2010).

Flavour evaluation is usually carried out by sensory and/or instrumental analysis. Sensory descriptive tests involve the detection and description of both qualitative and quantitative sensory components of a product by trained panels. Descriptive tests can establish a relationship between sensory and instrumental results (Comandini et al., 2011). An important factor affecting consumer preferences of a fried food is its flavour which is defined as the combined perception of aroma, taste and mouthfeel sensation (Montaser et al., 2017). However, sensory methods are sometimes expensive to implement, may be time-consuming when used properly, and sometimes cannot be implemented “on-line” for immediate feedback.

Instrumental methods for examining flavour have also been developed to provide feedback about the individual compounds associated with flavours. Those methods take many forms, but all are based on separation, identification, and quantification of compounds either in headspace or the actual product matrix (Maarse, 1991).  The analysis of volatile compounds in food is commonly performed using gas chromatographic (GC) techniques, employing very sensitive technologies capable of detecting trace levels of volatile compounds. It is fundamental that GC detection has high efficiency, especially for volatile compounds, present at trace levels, can be easily perceived during sensory analysis (low perception threshold) and can contribute significantly to the flavour profile of cheese (Hummel et al., 1997).

The aim of the present work is to compare the volatile profile of two potato chip brands that are highly popular locally among Egyptian consumers, especially for children. The study was extended to evaluate the impact of seasoning addition (tomato, onion and cheese) on the headspace volatiles and sensory qualities of these two potato snacks. The oil content of each sample was determined, due to its effect on the overall quality of potato chips flavour.

MATERIALS AND METHODS

Materials

Potato chips samples

The manufactured potato chips samples (which represent of the most common brands distributed in the Egyptian local markets) were collected from the most frequently consumed brands (different producers, A and B); for each brand, three varieties of potato chips were chosen (unseasoned, seasoned with cheese & onion and tomato). These potato chips represent a major portion of the potato chip products processed in the Arab Republic of Egypt.

All potato chips samples (manufactured at same date) were purchased from local market. The samples, packed in plastic bags, were transported to the laboratory until analyses. The code number of each tested potato chips sample was shown in Table (1).

Ingredients of tested potato chips

The basic composition of the investigated samples is fresh potato, vegetable oil and food additive such as some flavouring agents.

Authentic compounds and standard n- paraffin (C8-C20) were purchased from Sigma-Aldrich CO. (St. Louis, MN, USA) and Merck (Darmstadt, Germany), respectively. All other chemicals were analytical grade.

Methods

Preparation of tested samples

The different potato chips samples were crushed in a mill cup blender and made homogeneous, then subjected to oil extraction, sensory analysis, isolation and identification of headspace volatiles.

Determination of lipid content (%)

Fat content was determined by extracting a weighed sample of 10g with petroleum ether (boiling point 60 - 80°C) in a Soxhlet apparatus for 16 h. The extract containing lipid and petroleum ether was evaporated over steam bath and dried in an oven at low temperature (50 °C), weighed and lipid percent was calculated according to the method described by AOAC (2011).

Analysis of volatile compounds by Gas chromatography / mass spectrometry

Extraction of volatile compounds

About 100g of tested potato chips samples were placed in a conical flask containing 500 ml distilled water. The mixture solution was stirred using teflon-coated magnetic bar at 60 ºC. The volatiles were purged with purified nitrogen (grade of N2 > 99.99%), at flow rate 100ml/min for 5h to three cooling traps at low temperature (ice – water/ice – acetone/dry ice – acetone).   Volatile chemicals collected in each trap were recovered with diethyl ether – pentane (1:1, v/v). The solvents containing volatiles were dried over anhydrous sodium sulphate for 12 h and concentrated with a Vigreux column (25 cm) to final volume of 100 µl. (Fadel et al., 2006). 

Characterization of volatile compounds by GC/ MS analysis

The analysis was carried out by using a coupled gas chromatography Hewllet-Packard (5890)/ mass spectrometry Hewllet-Packard (5890), (Bremen, Germany). A fused silica capillary column DB5 (60 m × 0.32 mm i.d.) was used. The oven temperature was maintained initially at 50 ºC for 5 min, then programmed from 50 to 250 ºC at a rate of 4 ºC/min. Helium was used as the carrier gas at a flow rate of 1.1 ml/min. The injector and detector temperatures were 220 and 250 ºC, respectively. The mass spectrometry was operated in electron impact mode (EI) 70.ev, mass range m/z 39-400 amu. The retention indices (Kovats index) of the separated volatile components were calculated with hydrocarbon (C8-C20, Aldrich Chemical CO.) as references. The isolated peaks were identified by matching with data from the library of mass spectra (NIST) (version 2.0) and comparison with those of authentic compounds and published data (Adams, 1995).The amount of each individual compound was expressed as total ion chromatogram (TIC).

Sensory analysis of tested potato chips

Sensory analysis was aimed to monitor the differences in sensory attributes between the investigated potato chips A and B regarding each type (Table 1). Sensory evaluation was carried out according to Majcher and Jeleń (2005) with some modifications. In the present study, each type of potato chips brand A was compared to the same type of brand B, such as: As compared with Bs, Aco compared with Bco and At compared with Bt. Ten panelists were drawn from the Chemistry of Flavour and Aroma Department, National Research Center and Food Science and Technology Department, Faculty of Agriculture, Al-Azhar University. All were requested to evaluate the sensory attributes to determine the acceptability of the samples regarding odour, taste, seasoning perception such as salt, cheese & onion, tomato and overall acceptability. The individual panelists separately scored each attribute on a category scale 0.0 (not perceptible) to 10.0 (strongly perceptible). The analysis was carried out in triplicate.

 

Statistical analysis

The data were statistically analyzed by using the Statistical Package for Social Science (SPSS) computer program software; (version 20.0 produced by IBM Software, Inc., Chicago, USA) of a completely randomized design as described by Gomez and Gomez (1984). All obtained results are expressed as mean ± standard error (SE). The statistical analysis was performed using a one-way analysis of variance (ANOVA) followed by Duncan's multiple range tests according to the procedure of Armitage (1971).

RESULTS AND DISCUSSION

Fat content is one of the most important parameters checked during the quality control processes. It affects the product’s texture. The factors that influence fat uptake include: the quality of the raw material, the type of oil fraction and the technological process, with temperature and frying time being the two main parameters (Mazurek et al., 2016).

The lipid content of the two brand types of tested potato chips is listed in Table (2). The lipid content ranged from 28.65 to 33.41% in all tested potato chips with and without different flavouring agents. However, in the two brands, the seasoned samples showed higher oil content compared with the unseasoned samples.

The present results revealed that for all tested samples the oil content was lower than the recommended value (within the permissible values ≥ 42%), reported by the Egyptian Standard Specifications (2005), of potato chips. On the other side, the lipid content in tested potato chips brand B with salt only and also with cheese and tomato flavours was more than that found in tested potato chips brand A. Furthermore, the lipid content in both tested samples brands A (28.65%) and B (31.70%) with salt was lower than those obtained in flavoured tested samples, which recorded 30.45 and 31.92 % of tested samples of brand A, 33.28 and 33.41% of tested samples brand of B with cheese and tomato flavours; respectively. These results are consistent with the findings ofMinihane and Harland (2007), Pedreschi et al. (2012), Mazurek et al. (2016), kalnina et al. (2017) and Caetano et al. (2018) who reported that the fried potato chips contain rather high amounts of fat (35-40%). These results may be due to the moisture loss during deep-fat frying that results in oil uptake, which may amount to as much as 40% of total product weight (Pedreschi et al., 2012).

Volatile compounds identified in fried potato chips seasoned with salt only

As shown in Table (3), the total amount of volatile compounds in sample B were 2.72 folds higher than in sample A. The increase in the total amount of the volatile compounds in sample B compared with sample A may be due to several factors; (i) the higher oil content in B than A (Table 2); (ii) the sinuous surface of sample B may increase the amount of loaded volatile compounds; (iii) different frying condition and different potato varieties.

A total of 57 volatile compounds were identified in the two samples (As and Bs) (Table 3). These compounds were classified into five main chemical groups; lipid degradation products, sugar degradation and/or Maillard reaction products (not involving sulfur-containing amino acids), sulfur-containing compounds, terpenes and miscellanies flavour compounds. Most of the identified compounds have been reported previously as volatiles from fried potato chips (Loon et al., 2005; Comandini et al., 2011).

Sugardegradation and Maillard reactionproducts

The aroma compounds produced by Maillard reaction and/or sugar degradation products included: Strecker aldehydes (4), diketones (2), pyrazines (6), furans (4), acetic acid and ethyl pyrrole (Table 3).

The total ion chromatograms (TIC) of these chemical classes were 26.57×106 and 69.36×106 in the two samples As and Bs, respectively. Approximately 85.6 % of the aroma compounds identified in head space volatiles of French-fried potato chips were generated from sugar degradation and/or Maillard reaction, not involving sulfur-containing compounds (Loon et al., 2005; Cha et al., 2019).

The di ketones 2,3- butandione (1) and 2,3- pentandione (10) are sugar degradation products and contribute to caramel and buttery note. They were identified among the active compounds from French fries (Loon et al., 2005).

2-Methyl butanal (6), 3-methyl butanal (7), phenylacetaldehyde (46) and benzaldehyde (33) are strecker aldehydes of the amino acids; isoleucine, leucine and phenylalanine, respectively (Martin and Ames, 2001a). Their major formation pathway seems to be oxidative deamination-decarboxylation of the corresponding amino acids via strecker degradation (Sanches-Silva et al., 2005). Whereas, benzaldehyde (33) is produced by interaction of sugar with phenylalanine (Fong and Yaylayan 2008).

Compared to the previous studies, the total yield of 2- methyl butanal and 3-methyl butanal showed a relatively lower level (3.13 × 106 and 16. 44× 106) in sample A and B; respectively. These two compounds were the predominant compounds in the volatiles of fried potatoes (Loon et al., 2005) and accounted for 81% of the total volatiles. Their low presentation in this study may be attributed to their oxidation to 2-methyl butanoic acid (25) and 3- methyl butanoic acid (26), respectively (Loon et al., 2005), which were represented at high content (7.92×106 and 15.56×106) in the volatile of sample A and B, respectively. Compounds (25 and 26) do not seem to give a distinct note but may influence the perceived aroma as a whole.

The seven identified pyrazines were: 2- methyl pyrazine (20), 2,5- dimethyl pyrazine (29), 2,3- dimethyl pyrazine (30), vinyl pyrazine (31), 2- ethyl-3-methyl pyrazine (40), 2- vinyl -6-pyrazine methyl (41) and 3-ethyl -2,5 –dimethyl pyrazine (47) (Table 3).   Pyrazines are typical products of Maillard reaction (Corrales et al., 2017; Yu et al., 2019). Generally, they are associated with positive sensory perception in deep-fried potato crisps such as nutty, brown, roasted and baked, but also associated with a negative sensory perception such as raw and musty (Agarwal et al., 2018). Pyrazines are mainly formed from glutamine and asparagine, the most abundant amino acids in potatoes (Dresow and Böhm, 2009; Krishnakumar and Visvanathan, 2014).

2- Methyl pyrazine (20) was the major identified compound in sample As (6.94×106) and it showed approximately similar amount (6.88×106) in sample Bs. 2,5-dimethyl pyrazine (29) and 2- ethyl-3-methyl pyrazine (40) comprised 5.77×106 and 5.42×106 in sample Bs, respectively whereas, they showed less amounts (1.87 × 106 and 1.60 × 106) in samples As. These compounds were the predominant pyrazines identified in the volatiles of potato chips fried in palmolein (Martin and Ames, 2001).

 The five furans identified in the present study were vinyl furan (11), dihydro-2-methyl (2H)-furanone (18), 2-furfural (21) 5- methyl -2-furfural (35) and 4- hydro -3,5-dimethyl -3(2H)- furanone (48), with total amounts of 1.98×106 and 6.64×106 in sample A and B, respectively (Table 3). 2-Furfural (21) is a typical sugar degradation product, and it possesses a pungent sweet note. 4-Hydro-3-5-dimethyl -3 (2H)- furanone (furaneol) (48) is formed via Maillard reaction from 2- hydroxyl propanal, and its oxidation product is 2- oxopropanal (Belitz et al., 2004).

Lipid degradation products

During frying, the hydroperoxides are formed as primary products of lipid oxidation. These products are unstable and decompose to secondary oxidation products. Deep fat frying causes evaporation of water, which moves away from food into the surrounding oil that replaces some of the lost water. This process leads to a product with extremely high-fat content (Moreira et al., 1995; Nayak et al., 2016).

However, as shown in Table (3), the total amounts of lipid degradation products in samples A and B (15.70×106 and 47.48×106 respectively) were lower than that of Maillard reaction and/or sugar degradation products (26.57×106 and 69. 36×106). This finding may be attributed to that the heat transfer from oil to the products is more favorable for sugar degradation and/or Maillard reaction than for lipid oxidation (Loon et al., 2005). At the same time, the melanodines formed from Maillard reactions are known to have an anti-oxidative effect (Morales and Jiménez-Pérez, 2001) and subsequently affect lipid oxidation.

 The lipid-derived volatile compounds are corresponding to different chemical classes, aldehydes (9), ketone (2), alcohols (3), carboxylic acid (3), esters (3), furans (3) and hydrocarbons (2) (Table 3). These compounds are considered as secondary oxidation markers for lipid oxidation.

Among the nine aldehydes, hexanal (15) was the abundant compound in sample B (15.76×106) whereas; it showed much less amount (2.00 × 106) in sample A. It is a typical oxidation product of lineoleic acid and used as a marker of lipid oxidation (Sanches- Silva et al., 2005 and Comandini et al., 2011).

The amount of nonanal (52) in sample B (1.12 × 106) was three and half fold higher than its amount in sample A (0.31× 106). Hexanal and nonanal were detected at high concentrations in the volatiles of French fried potatoes (Loon et al., 2005). The first compound is the predominant degradation product of 2,4- decadienal (E, Z) (62) which is formed from linoleic acid (Hammond, 1993 and Diaz et al., 2015).

 Loon et al. (2005) confirmed the fact that 2,4- decadienal (E,Z) (62), 2,4- decadienal (E,E) (63) and 2,4 (E,E) nonadienal (57) contribute to the deep–fried note. These compounds were identified as the main volatile compounds in palmolein fried potato chips (Comandini et al., 2011).

 The two identified ketones, 3-heptanone (24) and octenal (39) are oxidative degradation products of unsaturated fatty acids (Careri et al., 1994). They were identified among the volatiles of potato crisps (Sanches-silva et al., 2005).

Three alcohols, 1-octen -3-ol (36), dodecanol (76) and tetradecanol (84) are shown in Table (3), with total amount 2.30 × 106   and 1.94 x 106 in samples A and B, respectively. They have a minor significant role in flavour of fried potatoes. The three identified carboxylic acids are hexanoic acid (37), decanoic acid (68) and dodecanoic acid (81). They are formed by lipid oxidation or by deamination of amino acids during the frying process. Therefore, their high presentation indicates the advanced lipid oxidation state (Sanches- Silva et al., 2005).

 The three identified esters, ethyl decanoate (69), methyl dodecanoate (78) and ethyl dodecanoate (82), accounted for 0.82 × 106 and 0.52 × 106 in sample A and B, respectively. These compounds are esterification products of carboxylic acid and alcohols (Guillén et al., 2004).

The lipid degradation furans reported in Table (3) are methyl furan (2), tetrahydrofuran (3), 2- ethyl furan (9) and pentyl furan (38). 1-octen- 3-ol and 2-pentyl furan are degradation products of linoleic acid and are responsible for fatty and fruity notes (Neff et al., 2000).

Sulfur-containing compounds

The total yield of the three identified sulfur compounds, 1,2 dimethyl disulfide (12), methional (28) and dimethyltrisulfide (34), showed low representation in both samples A and B (0.97×106 and2.95×106, respectively). These compounds are Maillard reaction products and characterized as sulfuryl and onion flavour (Loon et al., 2005). These compounds comprised low amount of the total volatiles of French fries (Loon et al., 2005). Methional, a strecker aldehyde of methionine, is a potent odorant of French fries flavour (Wagner and Grosch, 1997; Majcher and Jeleń, 2005). The low amount of methional might be due to its masking by 2,5 - di methyl pyrazine (Oruna-Concha et al., 2001).

Miscellanies compounds

Styrene (27) is a benzene derivative that contributes to the sweet and balsamic aroma note (Zhang et al., 2020 and Corrales et al., 2017). It is naturally synthesized by several plant species (Fernandez et al., 2005) and significantly increased at high temperatures. It was found in the headspace volatiles of fried potatoes (Loon et al., 2005). Limonene (42) was detected in the volatiles of French fries (Loon et al., 2005). 2-Isobutyl-2-methoxy pyrazine (54) was detected in the volatiles of raw and boiled potato. β- damascenone (E) (70) was reported as a degradation product of carotenoids (Majcher and Jeleń, 2005). It is present in raw foods, and its amount increases during different heat processing.

Volatile compounds identified in headspace of fried potato chips seasoned with cheese and onion

A total of 55 volatile compounds were classified into five main chemical groups; Maillard reaction and sugar degradation products, lipid degradation products, sulfur-containing compounds, terpenes and miscellanies compounds.

As shown for potato chips seasoned with salt only (Table 3), the total volatiles in sample Bs (124.48×106) were higher than in sample As (47.74×106). Most of the identified compounds were previously identified in headspace of potato chips seasoned with salt only (Table 3). Some of the volatile compounds reported in Table (3) are specific aroma compounds of onion and cheese. Butandione (1) was represented by 1.16 × 106   and 1.20 × 106   TIC in sample Aco and Bco, respectively. This compound possesses buttery note (Avsar et al., 2004) and reported as an active aroma compound in cheddar and Swiss cheeses (Castada et al., 2019).

The identified acids; acetic acid (5), butanoic acid (16), 3- methyl butanoic acid (26), haxanoic acid (37), dedcanoic acid (68) and dodecanoic acid (81) were found in the volatiles of different cheese types (Avsar et al., 2004 and Hayaloglu and Karabulut, 2013).  Acetic acid and butanoic acid are produced by lipolysis or by fermentation of lactose or lactic acids whereas, 3- methyl butanoic acid is produced by metabolism of leucien (Curioni et al., 2002). Compounds 16 and 37 are the principal acids in Turkish cheese (Hayaloglu and Karabulut, 2013). Their importance is due to their low perception thresholds as well as the fact that they are precursors for the formation of methyl ketones, alcohols, lactones and esters (Pinho et al., 2004).

As shown in Table (3), 3-methyl butanoic acid (26) was the major compound identified in headspace of the two samples A and B (10.86×106 and 20.82×106,respectively). This compound is produced from the oxidation of 3- methyl butanal (McSweeney and Sousa 2000; Castada et al., 2015). The aldehydes reported in Table (3) are produced by catabolism of fatty acids or amino acids via decarboxylation or deamination (McSweeney and Sousa 2000).

Hexanal (15), a lipid degradation product, was the predominant aldehyde in sample Aco and Bco (5.36 and 8.22 × 106, respectively). 2-Methylbutanal (6) and 3-methylbutanal (7), strecker aldehydes of isoleucine and leucine, accounted for 0.0 and 2.80 × 106   in sample Aco and 0.80 and 2.28 × 106,respectivelyin sample Bco. These compounds contribute to nutty flavour in aged cheddar cheese (Avsar et al., 2004; Whetstine et al., 2006). 3-Methylbutanal (6), hexanal (15) and pentanal (14) were the predominant aldehydes identified in Turkish cheese (Hayaloglu and Karabulut, 2013). Aldehydes are transitory compounds and do not accumulate significantly in cheese as they rapidly transform into alcohols and corresponding acids (Bovolenta et al., 2014). A strong negative correlation was found between 3- methyl butanoic acid and 3- methyl butanal (McSweeney and Sousa 2000; Castada et al., 2015).

Six sulphides were identified and reported in Table (3) such as methional (28), methyl-1- propenyl disulfide (32), dimethyl trisulfide (34), iso propely propyl disulfide (44), dipropyl disulfide (51) and dipropyl trisulfide (76), with total amount of 7.45× 106 and 15.80 × 106   in sample Aco and Bco, respectively. Among these compounds, 32, 44, 51 and 67 are generally associated with onion sensory perception (Villière et al., 2015).

Limonene (42), the only terpene identified in the present study, comprised 0.40 and 1.79 × 106   in sample Aco and Bco, respectively (Table 3). This compound was the most abundant terpene identified in Turkish cheese and it is associated with citrus like note (Nogueira et al., 2005). Limonene, dipropyl disulfide, dimethyl trisulfide, methyl-1-propenyl disulfide, isopropyl propyl disulfide and 3-methylbutanal were identified with cheese and onion seasoned potato crisps as specific compounds (Agarwal et al., 2018).

Volatile compounds identified in headspace of tomato seasoned potato chips

A total of 41 volatile compounds were identified in headspace of the two potato chips samples (At and Bt) seasoned with tomato flavour. The identified compounds were classified into five main chemical classes; sugar degradation and Maillard reaction products, lipid degradation products, sulfur containing compounds, terpenes and miscellanies compounds.

Among the identified compounds, several compounds are considered as key odorants of tomato aroma. As previously mentioned, the total volatiles of sample B were higher than that in sample A (Table 3). 3ـ-Methyl butanal (7), hexanal (15), hexanol (23), hexanoic acid (37), nonanoic acid (58), 2-decanal (59), (E,Z) 2,4 decadienal (62), (E, E)-2,4-decadienal (63), dedcanoic acid (68), dodecanoic acid (81), methional (28), limonene (42), isobutyl thiazole (45), guaiacol (49), 2- phenyl alcohol (50), methyl salicylate (55) α-terpineol (56), geranial (60), geraneol (61), eugenol (64), geranyl acetone (73)  and β-Ionone (77) were reported as important tomato aroma compounds (Alonso et al., 2009; Güler and Şekerli, 2013; Selli et al., 2014). Isobutyl thiazole accounted for 3.86×106 and 4.85×106 in samples A and B, respectively and it was described as tomato leaves-like aroma (Alonso et al., 2009).

Cis-3- Hexanal (tomato leaf-like fresh, cut grass) is considered one of the most contributors to tomato aromas (Selli et al., 2014). The absence of this compound in the present study may be correlated to the extraction technique of volatile compounds. In a previous study (Alonso et al., 2009), cis-3- hexanal was found in simultaneous steam distillation extraction (SDE) and hydrodistillation (HD) of tomato flavour, but wasn’t in solid phase micro-extraction (SPME). Hexanal accounted on 2.53× 106 and 10.46×106 of the total volatiles of samples A and B, respectively (Table 3). It was the main compound in traditional tomatoes with abundance percentage in head space of around 40% of total volatiles (Alonso et al., 2009).

The peak area of 2ـ phenyl ethanol (floral) was found in quantities of 0.23 and 1.27×106   in the volatiles of samples A and B, respectively. It was previously detected by Tandon et al. (2001) as potent odorants in red-ripe stage tomatoes. Geranyl acetone (Lavender, fruity, and rose sweet aroma) (Alonso et al., 2009) is the main volatile compound from lycopene degradation in tomatoes (Krumbein et al., 2004).

β-Ionone is consistently present in tomato at all stages of ripening. It is oxidative breakdown product of β-carotene. Methyl salicylate was predominant volatile compound in green tomato (Güler and Sekerli, 2013).

Sensory analysis of tested potato chips samples

The Fig. (1 a, b and c) shows the results of sensory analysis of the potato chips samples A and B seasoned with salt only, cheese and onion and tomato flavour. As illustrated in the obtained results in Fig. (1 a), it is obvious that the salt seasoned potato chips brand A showed higher scores for all investigated sensory attributes compared to brand B.

Regarding cheese and onion seasoned potato chips (Fig. b), the low score of the overall acceptability of sample Bco compared with sample Aco, may be correlated to the unacceptable oily flavour detected by the panelists. The odour intensity and onion flavour scored higher in sample Aco than sample Bco. Whereas, the taste attribute and cheese flavour showed the opposite trend. Concerning the tomato seasoned potato chips, sample Bt showed higher scores for all of the investigated attributes compared to sample At (Fig. c).

CONCLUSION

In the present study two potato chips brands A and B which are the most acceptable to the Egyptian consumers were chosen and subjected to a comparative study concerning their flavour qualities.  Three similar varieties of each brand were selected in this study such as unseasoned potato chips (salt only), cheese and onion seasoned potato chips and tomato seasoned potato chips. In general, the total content of the headspace volatiles of all sample varieties of potato chips B was higher than their similar varieties of potato chips A. A total of 86 volatile compounds were identified in the present study with higher concentration in B than A, especially for the most contributors to the characteristic aroma of each variety. The sensory evaluation revealed that the overall acceptability of potato chips A flavoured with salt As and cheese and onion Aco scored higher values than potato chips Bs and Bco. While tomato seasoned potato chips scored higher for all investigated sensory attributes.  These differences between the two potato chips brands may be correlated to the different oil content, potato tubers, and time and temperature of frying.

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Table 1. The code numbers of tested potato chips samples.

Brand code

Cod. No.

Sample collected with different flavour

(Cod. Name)

 

A

As

Salt

Aco

Seasoned cheese &onion flavour

At

Tomato flavour

B

 

Bs

Salt

Bco

Seasoned cheese &onion flavour

Bt

Tomato flavour

         

Brand A and B: fried potato chips locally produced by two companies. As:Potato chips flavoured with salt (brand A); Bs:Potato chips flavoured with salt (brand B); Aco:Potato chips flavoured with cheese and onion (brand A) Bco:Potato chips flavoured with cheese and onion (brand B); At:Potato chips flavoured with tomato (brand A); Bt:Potato chips flavoured with tomato (brand B).

Table 2. lipid content (%) of tested potato chips (Means ± SE).

Potato chips samples

Lipid content (%)

brand A

Salt

28.65±0.07c

Seasoned cheese

30.45±0.11b

Tomato

31.92±0.15ab

brand B

Salt

31.70±0.04ab

Seasoned cheese

33.28±0.08a

Tomato

33.41±0.11a

a,b,c Means in the same column with different superscripts are different significantly (p < 0.05)

 

 

 

 

 

 

 

 

 

 

 

 

 

Table 3. Volatile compounds identified in headspace of different types of flavoured potato chips.

 

Peak

No.

(K.I.)

Compounds

TIC (values ×106 )

As

Bs

Aco

Bco

At

Bt

Sugar degradation and Maillard reaction products (not involving sulfur containing amino acids)

1

610

2,3- Butandione

0.46

4.84

1.16

1.20

0.27

1.09

5

650

Acetic acid

0.15

1.73

0.28

0.80

0.26

1.07

6

654

2-Methylbutanal

1.52

3.68

ــــــ

0.80

ــــــ

ــــــ

7

664

3-Methylbutanal

1.61

12.76

2.80

2.28

1.66

5.39

10

697

2,3Pentandione

0.51

1.54

ــــــ

ــــــ

ــــــ

ــــــ

11

713

Vinyl furan

ــــــ

0.40

ــــــ

ــــــ

ــــــ

ــــــ

17

820

1- Ethyl pyrrole

0.40

2.11

0.93

3.74

ــــــ

ــــــ

18

822

Dihydro-2-methyl(2H)-furanone

1.06

1.26

ــــــ

2.31

ــــــ

ــــــ

20

831

2-Methylpyrazine

6.94

6.88

1.02

1.63

0.42

1.44

21

834

2-Furfural

0. 39

3.90

ــــــ

0.11

ــــــ

ــــــ

25

884

2-Methyl butanioc acid

2.99

ــــــ

4.27

4.44

ــــــ

ــــــ

26

888

3-Methyl butanioc acid

4.93

15..56

10.86

20.82

5.45

27.24

29

911

2,5- Dimethyl-pyrazine

1.87

5.77

4.06

8.09

2.25

9.94

30

923

2,3- Dimethyl-pyrazine

ــــــ

0.31

ــــــ

0.36

ــــــ

ــــــ

31

943

Vinyl pyrazine

0.36

1.26

0.74

1.30

0.37

1.39

33

969

Benzaldehyde

0.21

0.88

0.54

1.00

0.29

0.83

35

978

5-Methyl-2- furfural

0.19

1.08

0.85

0.93

0.48

0.85

40

1005

2-Ethyl-3-methyl-pyrazine

1.60

5.42

4.34

7.66

2.70

10.06

41

1027

2-Vinyl-6-methyl-pyrazine

ــــــ

0.34

0.30

0.54

ــــــ

0.67

46

1048

Phenylacetaldehyde

0.81

ــــــ

1.25

1.68

0.72

ــــــ

47

1073

3-Ethyl-2,5- dimethyl-pyrazine

0.23

ــــــ

ــــــ

0.60

ــــــ

0.53

48

1095

4-Hydro-3,5-dimethyl-3-(2H)-furanone

0.34

ــــــ

0.42

ــــــ

ــــــ

ــــــ

Total

26.57

69. 36

33.82

60.29

14.87

60.50

 

 

 

 

 

 

 

 

 

 

Table 3. Continued…..

Peak

No.

(K.I.)

Compounds

TIC (values ×106 )

As

Bs

Aco

Bco

At

Bt

Lipid degradation products

2

621

2-Methyl furan

0.18

3.28

ــــــ

ــــــ

ــــــ

0.77

3

634

Tetrahydrofuran

0.68

3.74

1.22

1.39

ــــــــ

ـــــــــ

4

635

1-Butonol

ــــــــ

ـــــــــ

0.48

1.40

ــــــــ

ـــــــــ

8

670

Pentanal

0.18

0.92

ــــــــ

ـــــــــ

ــــــــ

ـــــــــ

9

681

2-Ethylfuran

3.81

11.27

ــــــ

8.29

ــــــــ

ـــــــــ

13

747

2- Methyl-2-butanal

ــــــــ

0.49

ــــــــ

0.75

ــــــــ

ـــــــــ

14

767

1-Pentanal

ــــــــ

0.14

ــــــــ

0.26

ــــــــ

ـــــــــ

15

799

Hexanal

2.00

15.76

5.36

8.22

2.53

10.46

16

809

Butanoic acid

ــــــــ

ــــــــ

ـــــــــــــ

0.69

ــــــــ

ـــــــــ

19

826

(E) 2- Ethyl-2-butanal

0.59

0.52

ــــــــ

ـــــــــ

1.95

3.28

22

851

2-Hexanal (E)

ــــــــ

ـــــ

ــــــــ

0.63

ــــــــ

ـــــــــ

23

881

Hexanol

ــــــــ

ـــــ

ــــــــ

ــــــــ

2.83

5.83

24

882

3-Heptanone

ــــــــ

0.32

ـــــــــ

ـــــــ

ــــــــ

ـــــــــ

36

984

1- Octen-3- ol

ــــــــ

0.36

ـــــــ

0.64

--------

11.17

37

988

Haxanoic acid

1.63

1.69

3.04

3.50

2.07

9.13

38

993

2- Pentyl furan

0.15

0.70

0.50

0.68

0.27

1.05

39

999

Octenal

ـــــــ

ـــــــ

ـــــ

0.26

ــــــــ

ـــــــــ

43

1038

Benzyl alcohol

0.83

1.98

ـــــ

ــــــ

ــــــــ

4.85

52

1108

Nonanal

0.31

1.12

0.32

0. 63

1.25

1.16

53

1192

Decanal

ـــــــ

ـــــــ

ـــــ

ـــــ

ــــــ

1.06

57

1235

2,4 (E,E)Nonadienal

0.26

ــــــ

ـــــــ

0.61

ـــــ

ـــــ

58

1259

Nonanoic acid

ـــــــ

ـــــــ

ـــــ

ـــــ

ــــــ

0.54

59

1263

2-Decenal

ـــــ

ــــــ

0.21

ـــــ

ـــــ

ــــــ

62

1299

2,4 Decadienal (E,Z)

0.67

0.40

1.67

1.83

ـــــ

1.00

63

1306

2,4 Decadienal (E,E)

0.29

ـــــ

0.75

1.36

0.55

1.09

65

1358

Octadecanal

0.18

ـــــ

0.39

ـــــ

0.32

0.90

68

1370

Dedcanoic acid

0.20

ـــــ

0.41

0.41

0.53

1.48

69

1385

Ethyl decanoate

0.27

0.52

ـــــ

ـــــ

ـــــ

ـــــ

72

1407

Dodecanal

ـــــ

1.51

ـــــ

ـــــ

ـــــ

ـــــ

76

1470

Dodecanol

0.16

0.55

0.32

0.76

0.44

1.18

78

1528

Methyl decanoate

0.27

ـــــ

ـــــ

ـــــ

0.82

1.48

79

1529

α- Decalactone

ـــــ

ـــــ

1.25

0.88

ـــــ

ـــــ

80

1547

β- Decalactone

ـــــ

ـــــ

0.33

0.46

ـــــ

ـــــ

 

 

Table .3 Continued…

Peak

No.

(K.I.)

Compounds

TIC (values ×106 )

As

Bs

Aco

Bco

At

Bt

Lipid degradation products

81

1563

Dodecanoic acid

0.28

ـــــ

0.28

ـــــ

ـــــ

1.61

82

1592

Ethyl dodecanoate

0.28

ـــــ

0.51

0.93

0.33

1.62

83

1599

Hexadecane

0.10

0.64

ـــــ

ـــــ

1.52

4.85

84

1680

Tetradecanol

2.14

1.03

ـــــ

ـــــ

3.93

4.80

85

1685

α-Dodecalactone

ـــــ

ـــــ

1.83

7.29

ـــــ

ـــــ

86

1700

Heptadecane

0.24

0.54

ـــــ

ـــــ

0.55

2.43

Total

15.70

47.48

18.87

41.87

19.89

71.74

Sulfur compounds

12

742

1,2-Dimethyl disulfide

0.32

0.41

ـــــــ

ـــــــ

ـــــــ

ـــــــ

28

896

Methional

0.31

0.23

0.51

1.29

ـــــــ

1.03

34

971

Dimethyltrisulfide

0.34

2.31

1.98

2.67

1.44

4.59

32

951

Methyl-1- propenyl disulfide

ـــــــ

ـــــــ

0.26

0.31

ـــــــ

ـــــــ

44

1039

Iso propely propyl disulfide

ـــــــ

ـــــــ

3.32

8.86

ـــــــ

ـــــــ

45

1040

Isobutylthiazole

ـــــــ

ـــــــ

ـــــــ

ـــــــ

3.86

4.85

51

1106

Dipropyl disulfide

ـــــــ

ـــــــ

0.84

1.71

ـــــــ

ـــــــ

67

1363

Dipropyl trisulfide

ـــــــ

ـــــــ

0.54

0.96

ـــــــ

ـــــــ

Total

0.97

2.95

7.45

15.80

5.30

10.47

Trepenes

42

1033

Limonene

0.27

0.73

0.40

1.79

ـــــــ

0.46

50

1101

Phenyl alcohol

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.23

1.27

56

1200

α-Terpineol

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.55

1.78

60

1264

Geranial

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.20

0.74

61

1271

Geraneol

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.80

0.59

64

1351

Eugenol

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.42

1.26

71

1400

Methyl eugenol

ـــــــ

ـــــــ

ـــــــ

ـــــــ

2.68

5.63

73

1453

Geranylacetone

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.43

1.77

74

1459

β-(E)farnesene

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.43

1.04

75

1464

Ethyl cinnamate

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.56

1.43

77

1500

β-Ionone

ـــــــ

ـــــــ

ـــــــ

ـــــــ

1.63

4.15

Total

0.27

0.73

0.40

1.79

7.93

20.12

 

 

 

 

 

Table 3. Continued….

Peak

No.

(K.I.)

Compounds

TIC (values ×106 )

As

Bs

Aco

Bco

At

Bt

Miscellanens compounds

27

893

Styrene

0.41

0.72

0.41

0.72

ـــــــ

ـــــــ

49

1096

Guaiacol

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.53

2.35

54

1193

2-Isobutyl-3-methoxy pyrazine

2.68

2.95

0.77

0.43

ـــــــ

ـــــــ

55

1194

Methyl salicylate

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.32

1.01

66

1359

β-Damascenone (z)

ـــــــ

ـــــــ

ـــــــ

ـــــــ

0.49

1.25

70

1399

β-demascenone (E)

1.14

0.29

2.68

2.95

0.41

1.07

Total

4.23

3.96

3.86

4.10

1.75

5.68

Total of all volatiles:

47.74

124.48

64.40

123.85

49.74

168.51

TIC: Total ion chromatogram; KI: Kovats Index

As:Potato chips flavoured with salt (brand A); Bs:Potato chips flavoured with salt (brand B); Aco:Potato chips flavoured with cheese and onion (brand A)

Bco:Potato chips flavoured with cheese and onion (brand B); At:Potato chips flavoured with tomato (brand A); Bt:Potato chips flavoured with tomato (brand B).

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure1. Sensory characteristics of flavoured potato chips with salt. For each sensory attribute the

values followed by different superscript low case letters are significantly different.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure2. Sensory characteristics of cheese and onion seasoned potato chips. For each sensory attribute, the values followed by different superscript low case letters are significantly different.

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

 

Figure3. Sensory characteristics of tomato seasoned potato chips. For each sensory attribute, the values followed by different superscript low case letters are significantly different.

 

 


 

 

دراسة مقارنة على المرکبات الطيارة والخصائص الحسية لبعض رقائق البطاطس المنتجة محلياً

مصطفى ابو الفضل محمد 1 ،محمد ابراهيم محمد 1، هدى هانم محمد فاضل 2، سامح محمد صلاح غانم 1،*

1 قسم علوم وتکنولوجيا الأغذية، کلية الزراعة، جامعة الازهر بالقاهرة، مصر

2 قسم مکسبات الطعم والرائحة، المرکز القومى للبحوث، الدقي، الجيزة، مصر

* البريد الاليکترونى للباحث الرئيسي: sameh.ghanem@azhar.edu.eg

الملخص العربي

تم إجراء هذه الدراسة لتقييم المرکبات المتطايرة فى نوعين من البطاطس المقلية (أ ،ب) المنکهة بالملح فقط بإلاضافة إلى دراسة تأثيرإضافة النکهات التي يفضلها المستهلکون بشدة (الطماطم والجبنة المتبلة) على جودة نکهة العينات محل الدراسة. کما شملت الدراسة أيضا مقارنة بين الخصائص الحسية والمرکبات المتطايرة لنوعي رقائق البطاطس محل الدراسة. وقد أظهرت النتائج أن نسبة الدهون في العينات المختبرة تراوحت من 28.65 إلى 33.41٪ وأظهرت نتائج التحليل الکروماتوغرافي الغازي لجميع العينات وجود 86 مرکبًا متطايرًا بمحتوى أعلى في جميع نکهات العينة (ب) مقارنة بالعينة (أ). وقد شملت المرکبات المحددة مجموعات کيميائية مختلفة مثل نواتج تفاعل ميلارد، ونواتج تحلل الدهون، والمرکبات المحتوية على الکبريت، والتربينات ومرکبات أخرى. وقد کان المحتوى الکلي لنواتج تحلل الدهون في العينات أ و ب أقل من نواتج تفاعل ميلارد. کما أظهرت نتائج التقييم الحسي أن العينة (أ بنکهة الملح) أظهرت درجة أعلى لجميع الصفات التي تم تقييمها مقارنة بالعينة )ب) کما کانت کثافة الرائحة ونکهة البصل فى العينات المنکهة بالجبنة المتبلة أعلى في عينة (أ) عن العينة (ب) في حين أظهرت صفة الطعم ونکهة الجبن اتجاهًا معاکسًاً. أما بالنسبة لرقائق البطاطس المنکهة بالطماطم أظهرت العينة (ب) درجة أعلى لجميع الصفات الحسية مقارنة بالعينة (أ).

الکلمات الاسترشادية: رقائق البطاطس، رقائق البطاطس بطعم الملح، الجبنة والبصل، نکهة الطماطم، کثافة الرائحة.