The Quality Characteristics of Different Fruit Juice Brands Consumed in Oman

Fruit juices are widely consumed beverages worldwide due to their refreshing taste, nutritional benefits, and convenience. They contain several important health-promoting bioactive that may reduce the risk of various non-communicable diseases. Fruit juices are rich in antioxidants, vitamins C and E, and possess pleasant taste and aroma [1]. The demand for fruit juices has increased rapidly in recent years, leading to the development of numerous commercialized fruit juice products with different formulations and flavour characteristics. The quality of fruit juices is defined by their physical properties, enzymatic, microbiological, and sensory characteristics as well as stability [2]. Evaluation of the physicochemical and sensory properties of these products is important in terms of quality, safety, and consumer acceptance [3]. The fruit juice industry has shown an increased interest in producing healthy, high-quality, minimally processed, and natural products [4], as consumers demand. Therefore, several non-thermal food processing technologies, such as sonication, pulsed electric field, and high-pressure homogenization, have gained considerable attention due to their capacities to keep original freshness and nutritional contents in foods, with minor energy utilization and high sensory acceptability, compared to the conventional heat treatments [1; 4; 5]. Heat treatments can degrade sensitive nutrients and enzymes in juices, leading to a loss of nutritional value and flavour. Non-thermal methods minimize nutrient loss by avoiding the high temperatures associated with traditional pasteurization. This retention of nutrients can result in juices with better taste, colour, and nutritional content [1]. 

The physicochemical evaluation of fruit juice products involves analysing chemical and physical properties, such as acidity, pH, Total Soluble Solids (TSS), colour, and viscosity. These parameters provide information about the composition, stability, and shelf-life of the products [6]. The acidity of fruit juice is a crucial parameter that determines its taste, microbial stability, and nutritional value [7]. The pH of fruit juice affects its stability and enzymatic reactions, while TSS represents the total amount of dissolved solids in the juice and influences its sweetness and texture [8]. The colour and viscosity of fruit juice products are important sensory attributes that influence consumer acceptance [9]. 

In addition to the physicochemical properties, the sensory evaluation of fruit juice products involves assessing their taste, aroma, appearance, texture, and overall acceptability [10]. Sensory evaluation is crucial for determining the product's marketability, consumer preference, and final quality [11]. The taste of fruit juice products is affected by their sweetness, sourness, bitterness, and astringency, while the aroma is influenced by their volatile compounds present in the juice [12]. The appearance of fruit juice products, such as colour and clarity, also affects their sensory characteristics. The texture of fruit juice products, such as viscosity and mouthfeel, is important for their sensory characteristics and consumer acceptance [13]. 

Commercialized fruit juice products are produced using various processing techniques, such as pasteurization, sterilization, and concentration [14]. These techniques affect the physicochemical and sensory characteristics of the final product [15]. Nowadays, consumers are increasingly demanding, giving preference to natural, healthier, innovative, and tastier products with sustainable characteristics and with a minimum amount of chemical preservatives and/or ultra-processing technologies [16]. 

The quality and safety of fruit juice products are determined by their compliance with regulatory standards set by national and international regulatory authorities, such as the General Standard for Fruit Juices, Fruit Drink, and Nectars [17], and Labelling of Fruit Juices, Nectars, and Fruit Drinks [18]. These standards specify the minimum and maximum levels of various physical, chemical, and microbiological parameters. 

The objectives of this study were to evaluate the physicochemical and sensory characteristics of the different fruit juice brands (such as orange, mango, and apple) consumed in Oman and to investigate the consumer acceptability and international conformity standards of these brands.

Samples 

Five commercial juice brands (Mazoon, A’Safwah, Marie, Nada, and Rawabi) including three fruit juices types (such as orange, mango, and apple) were purchased randomly from various shops and supermarkets in Muscat, Oman. To maintain anonymity, the samples were accurately coded, such as the brand name, location of purchase, collection time, and date were recorded. All collected samples (15 samples in total) were then stored at a cold temperature (5°C) until the completion of analyses. The brands were labelled as (D, E, F, L, and J for orange juices; N, B, I, H, and O for mango juices; and M, C, K, A, and G for apple juices). 

Physicochemical Analyses 

The physicochemical analyses of fruit juices were conducted according to the official methods of AOAC 2007 [19], moisture content (method 934.06), pH value (method 981.12), total acidity (method 942.15), Brix value, Brix/acidity ratio, and total solids (method 920.151). 

Labelling Requirement 

The mandatory labelling requirements of fruit juice products were evaluated according to the Labelling of Fruit Juices, Nectars, and Fruit Drinks Standard [18]. Five clauses from the standard were evaluated which are; 4.2 represents the type of product (Drink, Nectar or Juice), 4.2.1 represents whether juice is made from fresh or concentrated juice, 4.2.5 if sugar added, 4.3.1 availability of nutritional data and 4.4.2 when no added sugar it shall mention its natural. 

Descriptive Sensory Analysis 

Six panellists from the Natural and Medical Sciences Research Centre, University of Nizwa (four males, and two females, aged between 30 and 50 years old), were recruited and trained according to the sensory practices and their reliability was assessed in three sessions [20]. The panellists conducted the sensory evaluation for colour, flavour, acidity, sweetness, and overall acceptability attributes for orange, mango, and apple juices. Each panellist received samples labelled with code numbers to evaluate using a 5-point test scale [21]. The average value of each sensory attribute was analysed using statistical analysis software. 

Consumer Preference Analysis

The consumers were recruited (53 graduate and post-graduate students; 13 females and 41 males; and aged between 23 and 50 years old) from the Natural and Medical Sciences Research Center, University of Nizwa. The participation was based on voluntary and no monetary compensation was given. Each group consisting of 5 panellists was taken to the panel booths (where room temperature was 23 to 25°C and relative humidity 67 to 75%) in the Food Science and Technology Laboratory. Each panellist evaluated 3 types of juices from five different brands. Each juice was served (20mL) in a 50mL clear plastic cup at room temperature (23 to 25°C). Overall acceptability was rated on a 5-point category scale using the Consumer Preference Questionnaire (supplementary data) according to Wunwisa and Kamolnate [22]. 

Data Analysis 

The physicochemical results were expressed as mean of triplicate determinations ± standard deviation on a wet weight basis. Microsoft Excel and Originlab Software were used to draw column and radar charts. The data from the physicochemical and sensory analyses were evaluated statistically using Microsoft Excel for the mean value. The analysis of variance (ANOVA) was used to determine the level of significance (p < 0.05).

Physicochemical Characteristics of Orange Juice Products 

In this study, we analysed the physicochemical characteristics, including moisture content, total solids, pH value, Brix value, total acidity, Brix/acidity ratio, and label compliance of various fruit juice brands consumed in Oman. Table 1 presents the average values resulting from triplicate analyses of orange juice products from different brands labelled as D, E, F, L, and J. The moisture content analysis revealed slight variability among the brands, with brand E having the highest moisture content of 90.9%, while brand J presented the lowest moisture content (88.9%). On average, the moisture content in various juice brands was reported as 90.1%. Previous literature suggests that high moisture content is inversely related to the shelf-life stability of juice products [23].

Table 1: Physicochemical characteristics of different orange juice brands. 

Note: Letters D, E, F, L, and J are the codes for orange juice brands. The values are average of triplicate analysis ±SD followed by the same letter, within a row, are not significantly different (P>0.05). C and NC are compliant and non-compliant to the “Labelling of fruit juices nectars and fruit drinks Standard”, GSO 2577:2021. 

Similarly, in the total solid content of various orange juice types, brand J presented the highest total solid content of 11.1%, whereas brand E revealed the lowest total solid content of 9.1%. Statistical analysis observed significant differences among the total solid values of various fruit juice brands. The total solid contents of brands D, F, and L of orange juices were 9.9, 9.9, and 10.2%, respectively. The average total solid content in orange juice from various brands was 10.2%, which is consistent with recommended amounts [24]. The total solids contents reported in this study are similar to those of orange juice samples studied by Ndife et al. [25]. Variations from other reported studies could be attributed to differences in drying methods used for studying solid contents. The Federal Institute of Industrial Research, Oshodi (FIIRO) reported that differences in production processes may explain most differences observed in juice composition and quality [26]. 

The pH of fruit juice is primarily determined by the stage of ripeness and maturity of the fruits used for production [27]. In the physicochemical analysis of orange juice conducted in the current study, a pH range of 3.42-4.12 was observed. These results fall within the typical range of 2-5 for fruit and vegetable juices [28], indicating the acidic nature of orange juice. The brand L exhibited the most acidic pH (3.42), while brand J had the least acidic pH (4.12). These findings are consistent with those reported by Tiencheu et al. [26], who observed similar pH values for orange juices. Additionally, Ndife et al. [26], reported pH values ranging from 3.23 to 4.08 for different brands of fruit juices, aligning with our results. The low pH of fruit juices is generally attributed to the presence of rich organic acids, with lemon and orange being particularly high in citric acid [28]. 

The Brix values for orange juice brands (D, E, and J) were reported as 11.3, whereas the values were 11.6 for brands F and L. According to the mandatory “General Standard for Fruit Juices, Fruit Drink, and Nectars” [17], the Brix value of orange juice must fall within the range of 11.2-11.8, indicating that all investigated brands complied with the Brix requirement. The consistent Brix values suggest uniform sugar content in the products [29]. 

In terms of total acidity, the highest value (0.78%) was reported for brand F, followed by brands E, L, and D, with values of 0.73, 0.62, and 0.58%, respectively. Conversely, the lowest total acidity value (0.53%) was reported for Brand J, which could be considered more favourable than others [30]. An increase in total acidity corresponds to a decrease in pH; titratable acidity determines the acidic taste in the juice, while pH determines its susceptibility to microbial spoilage [28]. 

The Brix/acidity ratio varied significantly among the brands, indicating the balance between sweetness and acidity of the product. Brand J displayed the highest ratio (21.3), indicating a sweeter taste relative to acidity, while Brand F had the lowest ratio of 14.9. The Brix/acidity ratios of brands D, E, and L were recorded as 19.5, 15.5, and 18.7, respectively. These findings align with a previous study by Jayasena and Cameron [31], indicating that taste preferences rely on this balance. 

Product labelling is one of the most important aspects of food products, and it should adhere to national and international quality standards [32]. In the current study, we analysed the labelling information of different brands of orange juices, all of which were found to be Non-Compliant (NC) with the labelling requirements specified by GSO 2577 [18]. Non-compliance with orange juice labels includes failure to provide information about the type of juice (Drink, Nectar, or Juice), the source of juice (fresh or concentrated), and when a free sugar statement is used, it must specify that it is natural. This regards a clear violation of mandatory labelling standards, which requires the removal of the product from the market until the labelling requirements are corrected. 

Physicochemical Characteristics of Mango Juice products 

Table 2 represents the values resulting from the triplicate analysis of all parameters and compliance status of the mango juice brands namely N, B, I, H, and O. Moisture content exhibited subtle variations among the brands, with brand O displaying the highest moisture content of 91.8%. Brands B and I have a value of 90.1%, followed by brand H (85.5%), and brand N with the lowest moisture content of 84.8%. It can be concluded from such high moisture content that the mango juice products from all brands have reduced shelf stability. 

Table 2: Physicochemical characteristics of different mango juice brands. 

Note: Letters N, B, I, H, and O are the codes for mango juice brands. The values are average of triplicate analysis ±SD followed by the same letter, within a row, are not significantly different (P>0.05). C and NC are compliant and non-compliant to the “Labelling of fruit juices nectars and fruit drinks Standard”, GSO 2577:2021. 

Brand N showed the highest total solid content of 15.2% followed by brand H. The total solid content value was 9.9% for brands B and I, while brand O had the lowest total solid content of 8.2%. These results agree with the previous study of Mahajan [33], who reported high solid content in juice products stored for long periods. 

In terms of pH, brand H exhibited the highest pH of 4.27, whereas brand N had the lowest pH of 3.9. The total acidity varied slightly among the brands, with brand I having the highest total acidity (0.27%) and brand H having the lowest total acidity (0.18%). Again, the results of pH and total acidity make perfect sense as brand I had the lowest pH and highest acidity and brand H had the highest pH value and lowest total acidity. The acidity of juice products indicates the storage period of the products. The acidity of the products increases with a longer storage period [34]. 

The Brix values ranged from 11.6 for brand B to 15.1 for brand N. According to the General Standard for Fruit Juices, Fruit Drink, and Nectars, GSO 1820 [17], the Brix value of mango juice must be not less than 13.5, which leaves brands B and O non-compliant with the Brix requirement. 

The Brix/acidity ratio exhibited significant variation across the brands. The brand H exhibited the highest ratio of 81.7, followed by brands N, B, and I with ratios of 71.9, 52.7, and 49.6, and brand O with the lowest ratio of 49.2. Such significant variation in the Brix/acidity ratios highlights the critical value of sweetness and acidity equilibrium in flavour perception. 

Similar to that of orange juice products, all the brands of mango juice products were categorized as “non-compliant” (NC) to the “Labelling of Fruit Juices Nectars and Fruit Drinks Standard”, GSO 2577 [18]. The non-compliance in mango juice labels include; provide information about type of juice (Drink, Nectar or Juice), source of juice (fresh or concentrated), mention when sugar added and when free sugar statement used it must mention its natural. Therefore, these non-compliant products should be removed from the market until they correct their Brix values and labels to the standard requirement. 

Physicochemical Characteristics of Apple Juice Products 

Table 3 outlines the average values obtained from the triplicate analysis describing the physicochemical parameters and compliance status of brands M, C, K, A, and G of the apple juice products. The moisture content ranged from 89.8% for brand G to 91.9% for brand C, with brands M, K, and A having moisture content of 90.5, 89.9, and 91.3% respectively. Again, the high moisture content indicates reduced shelf stability. 

Table 3: Physicochemical characteristics of different apple juice brands. 

Note: Letters M, C, K, A, and G are the codes for apple juice brands. The values are average of triplicate analysis ±SD followed by the same letter, within a row, are not significantly different (P>0.05). C and NC are compliant and non-compliant to the “Labelling of fruit juices nectars and fruit drinks Standard”, GSO 2577:2021. 

In terms of total solid content, brand K showed the highest total solid content of 10.0%, followed by brand G (10.3%), M (9.5%), and A (8.7%), while brand C exhibited the lowest total solid content of 8.1%. Such high solid contents indicate the longer storage period of the products [23]. 

The pH varied slightly among the brands, with brands M and A being the most acidic (3.73) and brand C the least acidic (3.96). Brands K and G had a pH of 3.79. Brand A had the highest total acidity of 0.45%, followed by K (0.42%), G (0.39%), and C (0.37%). Conversely, brand M showed the lowest total acidity of 0.28%. These pH and acidity values fall within the accepted range of pH 3-5 for fruit and vegetable juice products [28]. 

The Brix value of brand G (13.4) was the highest among the brands, suggesting its elevating sugar content. Brands M, C, and A had the Brix values of 11.2, 11.7, and 11. 5 respectively. Brand K exhibited the lowest Brix value of 10.8, indicating that brand K juice product had the lowest sugar content. According to the General Standard for Fruit Juices, Fruit Drink, and Nectars, GSO 1820 [17], the Brix value of apple juice must be not less than 11.5, which leaves brands M and K non-compliant with the Brix requirement. 

All apple juice product brands were categorized as “non-compliant” (NC) indicating that none of the brands meet the GSO 2577 [18], labelling standards. The non-compliance in apple juice labels includes; providing information about the type of juice (Drink, Nectar, or Juice), source of juice (fresh or concentrated), and when the free sugar statement is used it must mention it’s natural. All apple juice samples were non-compliant with the standard either from Brix and label requirements, therefore, they should be removed from the market until they correct their Brix values and label requirements. 

The Compliance to Label Standards 

This study investigated the compliance of fruit juice products to the mandatory label requirements imposed by the standard “Labelling of Fruit Juices Nectars and Fruit Drinks Standard”, GSO 2577 [18]. The standard defines the food product label as “Any label, mark, brand, image, or other descriptive data written, printed, stamped, placed, engraved, or prominent on the food packaging in a way that is not removable”. Five clauses from the standard were evaluated which are 4.2, 4.2.1, 4.2.5, 4.3.1, and 4.4.2. These clauses have been selected as they present: type of product (Drink, Nectar, or Juice), if it is made from fresh or concentrated juice, if sugar is added, availability of nutritional data, and when no added sugar it shall mention it’s natural figure 1 presents the compliance of the investigated fruit juice samples to the label standard. None of the products managed to fulfill the standard’s requirements for labels, the only requirement achieved by all samples is the availability of nutrition data. Therefore, all these samples are regarded as non-compliance samples according to the label standard and they should be removed from the market. These requirements demand that consumers should be aware of the contents of the food through the label and most importantly, be warned about unsafe, unhealthy food, in a manner that is intelligible to everyone, so that they make an informed choice and stay away from unhealthy food. 

 Figure 1: The compliance of product labels to standards requirements. 

Note: Clause 4.2: Types of the product (Drink, Nectar or Juice), 4.2.1: Made from concentrated juice, 4.2.5: When sugar added, 4.3.1: Nutritional data, and 4.4.2: when free sugar, shall be mentioned it's natural. 

Descriptive Sensory Characteristics of Orange Juice Products

Figure 2 represents the descriptive sensory analysis data of orange juices from different brands namely D, E, F, L, and J for the attributes of colour, flavour, acidity, sweetness, and an overall acceptability. The colour scores varied among the brands with brand E having the highest colour score of 3.83 and brand D having the lowest colour score of 2.5. The high colour scores of brands E and F imply that the juice had a vibrant and appealing colour due to the presence of high levels of beta-carotenoids and terpenes which are responsible for the vivid colour of fruits [35]. While less intense colour is indicated by the low colour scores of brands D, L, and J. 

 Figure 2: Descriptive sensory attribute scores of different fruit juice brands (n=6). 

Concerning flavour, brand J had the highest flavour score (3.83), followed by brand F (3.5), and E (2.83). Brands D and L exhibited the lowest flavour scores (2.5). The high flavour scores of brands J and F indicated that orange juice of both these brands had strong flavouring profiles due the presence of abundant citric acid. This correlation is supported by their acidity scores. 

The acidity scores of brands D and L were 2.33 and 2.87, suggesting that fewer organic acids were present compared to brands F and J with acidity scores of 3.5 each. Also, brands D and L had the lowest sweetness scores of 2.5 each compared to brands F and J, having the highest sweetness scores of 3.8 each. The sweetness score of brand E was 3, indicating the moderate sweetness of brand E juice product. The sweetness did not appear to be influenced by colour. Results in this study are in agreement with those reported by Fernández-Vázquez et al. [36], related to colour variation in orange juice does not effect on sweetness. 

Brands F and J received the highest overall acceptability score of 3.7 due to their appealing colours, strong flavouring profiles, balanced acidities, and notable sweetness. Brands E and L had with overall acceptability score of 3.0 and 2.8, respectively. While brand D had the lowest acceptability score of 2.3 due to its subdued colour, weak flavouring profile, elevated acidity, and reduced sweetness. These descriptive sensory attributes can assist in formulating a juice product according to consumer liking. 

Descriptive Sensory Characteristics of Mango Juice Products

Figure 2 also represents the descriptive sensory analysis of mango juices from different brands namely N, B, I, H, and O based on colour, flavour, acidity, sweetness, and overall acceptability. Brand N exhibited the highest overall acceptability score of 4.3 due to its consistently high scores across all attributes. Brand N exhibited 4.3 scores for colour, flavour, and acidity and a slightly elevated score of 4.7 for sweetness. Brand N was followed by brand B with an overall acceptability score of 4.0. The colour and flavour scores of brand B were 3.8 each, while the score of 4 was consistent for the acidity and sweetness of brand B. The high sensory scores of brands N and B suggest that juices from brands N and B were most appealing in colour with strong flavour profiles indicating the presence of excess vitamin A, citric acid, and malic acids, appropriate acidity and sweetness compared to brands O and H with moderate overall acceptability scores of 3.2 and 2.2 respectively. This indicate that all the attributes of brands O and H juices were moderate. In contrast, brand I exhibited the lowest overall acceptability score of 1.5 indicating its weak colour intensity (1.7), indicating low levels of carotenes and organic acids. The flavour, acidity, and sweetness score of brand I were consistent at 1.5, making the mango juice product of brand I least favourable suggesting that not fully ripened mangoes were used with low levels of mango specific aromatic compounds such as hexanal and isobutyl acetate [37]. 

The Descriptive Sensory Characteristics of Apple Juice Products 

The data obtained from the descriptive sensory analysis of apple juices from different brands namely M, C, K, A, and G is presented in figure 2. Brand G exhibited a 4.2 score for colour, 3.8 for flavour, 3.7 for acidity, and 3.5 scores for sweetness, which lead to the highest score in acceptability among brands (3.8). The high sensory scores of brand G colour may be attributed to browning, which can be categorized into enzymatic and non-enzymatic browning. Similarly, polyphenols, including flavonoids, are known to be responsible for the colour profiles of apple fruit. However, brand M scored lower than brand G in the rest of the attributes with an overall acceptability score of 3.5, followed by brand K (3.3). In contrast, brand C had the lowest scores in colour (1.3), flavour (1.3), acidity (1.3), and sweetness (1.7), and therefore exhibited the lowest overall acceptability score of 1.3. Such low scores of brand C indicated an unappealing colour due to the low levels of anthocyanins and carotenoids, undesirable taste profile due to insufficient flavour intensity suggesting the low levels of polyphenols including flavonoids, and imbalanced sweetness-to-acidity ratio due to the imbalance between organic acids and sugars. These results agree with the previous study of Rosa-Martínez et al. [38], who reported desired acidity and sweetness profiles due to a balanced organic acids-to-sugars ratio. 

Consumer Preferences of Orange, Mango, and Apple Juices 

Consumer preference sometimes referred to as public or market preference is an important aspect of market and product development. The average preference scores provide a general overview of public perception and reflect the collective opinion of a group of consumers about a product. It is determined based on reviews and factors such as quality, price, brand reputations, and social and cultural influences. The average consumer preference scores for orange, mango, and apple juices of all brands are provided in figure 3. For orange juice, brand L received the highest average preference score of 3.6 among the fifty-three consumers surveyed, suggesting that consumers prefer this brand most for orange juices, followed by brand J with a preference score of 3.5. The preference scores of E and F were 2.9 and 2.6, respectively. Brand D showed the lowest preference score of 2.2, suggesting that brand D was the least preferred brand among the orange juices. The total average preference score for orange juice is 2.96. 

 Figure 3: The average of consumer preference score (n=53). 

Note: The values followed by the same letter are not significantly different (P>0.05). 

The preference scores for mango juices varied among different brands. Brand B exhibited the highest preference score of 3.7, indicating that consumers preferred brand B for mango juice over other brands. The preference scores of brands O, I, and H were 3.3, 3.0, and 2.6, respectively. Brand N showed the lowest preference score of 2.5, suggesting that brand N was the least preferred brand among mango juices. 

For apple juices, the highest preference score was exhibited by brand G (3.4). This indicates that brand G was the most preferred and brand C with a 2.4 preference score was the least preferred brand among apple juices. These perfectly align with the descriptive sensory results of apple juices. Brand G had the highest colour, flavour, acidity, and overall assessment scores, while brand C had the lowest scores in all sensory attributes. The preference scores of brands M, A, and K were 3.3, 3.2, and 2.8, respectively, making the average preference score of apple juice for all the brands 3.02, which is similar to other juices. 

The correlation coefficient of each type of juice product varied considerably when compared between the overall preference values by descriptive and consumer analyses (the data not included). For orange and mango juices, the correlation was weakly positive (0.37 and 0.22, respectively), while it was strongly positive for apple juice (0.90). Also, the overall preference of the descriptive panel (45.7) was slightly higher than that of the consumer panel (44.9). This is similar to the result of Okayasu and Naito [39], who reported that trained judges tended to find larger differences in liking among apple juice than an untrained panel.

This study focused on the physicochemical characteristics, sensory quality, and consumer perception of orange, mango, and apple juice brands consumed in Oman. The analysis of physicochemical characteristics revealed non-compliance with Brix requirements in mango and apple juices. Additionally, all evaluated juice brands were found to be non-compliant with label requirements, potentially misleading consumers and constituting a clear violation of mandatory juice and label standards. Therefore, such products need to be recalled or withdrawn from the market until they meet quality standards. 

Descriptive sensory analysis and consumer preference scores showed significant differences in overall acceptability among different juice brands, highlighting consumer preferences. This study provides valuable insights into fruit juice quality, aiding consumers in making informed choices. Furthermore, it underscores the importance of improving legislation for fruit juice brands by incorporating quality parameters such as acidity and sensory preferences. Implementing such legislation will contribute to maintaining a sustainable fruit juice industry.

The authors gratefully acknowledge the financial support of the Natural & Medical Sciences Research Center, University of Nizwa, Oman.

Al-Farsi: Conceptualization, Investigation, Supervise Analysis and Writing original draft.

Sana Ullah: Methodology, Investigation.

Al-Omairi, Al-Amri, Al-Jassasi & Al-Yaqoobi: Methodology & Analysis.

Cesarettin Alasalvar: Review & Editing.

The authors declare no conflict of interest. The authors declare that they have no known competing financial interests or personal relationships that could have appeared to influence the work reported in this paper.

Ethic approval was not required for this study. Ethical approval for sensory evaluation of juice products is not required in Oman. However, the proper verbal consent of the taste panellists was obtained for sensory evaluation. All participants were aware of the juice formulation being evaluated, and the evaluation used the proper protocols for the juice product.

The data that support the findings of this study are available from the corresponding author upon reasonable request.

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