Determining Some Quality Characteristics of Vegan Tarhana Added with Red Beet (Beta Vulgaris Var. Cruenta) Powder

Soğuksulu, Sena; Külcü, Duygu Balpetek

doi:10.1590/1678-4324-2023220844

Abstract

The present study aims to increase the number of tarhana versions, which have traditionally had a place in our culture, in order to increase the range of vegan products. In the present study, it was aimed to diversify the versions of tarhana, which has had a place in our traditional culture. For this purpose sauced and sauce-free vegan tarhana (yogurt-free) samples added with red beet (Beta vulgaris var. Cruenta) powder at different concentrations (control, 0.5%, 1%, 1.5%, 2%, 2.5%, 3%) samples were produced. Several physicochemical, microbiological, and sensorial properties of tarhanas produced were examined. Vegan tarhana with tomato sauce with 1.0% red beet powder had the highest score for consistency, taste, aroma and general acceptability. The highest score of color and odor properties was determined in vegan tarhana with tomato sauce added with 2.0% red beet powder. Ash, total acidity, protein, water-holding capacity, total dietary fiber, total phenolic content, and antioxidant capacity increased in parallel with red beet powder concentration. It was found that microbiological characteristics met the standards for tarhana, that the total number of mesophilic aerobic bacteria was higher than that of total yeast-mold. Staphylococcus aureus and coliform-group bacteria could not be detected in vegan tarhanas with red beet powder. In conclusion, it can be stated that all the vegan tarhanas with red beet powder samples had equivalent physicochemical and bioactive characteristics in comparison to the tarhana samples examined in the literature.

Keywords:
functional product; red beet powder; tarhana; vegan diet.

HIGHLIGHTS

• The 'vegan tarhana' produced without yogurt can be consumed as a functional food.

• Addition of red beet powder to vegan tarhana increased antioxidant capacity.

• Vegan tarhana can be consumed as an alternative to traditional tarhana.

INTRODUCTION

Traditional tarhana is a traditional product, which is prepared by pulping onion, tomato, pepper, yogurt, and various spices with wheat products and fermented for 1-7 days. Having a sour and acidic aroma, tarhana is generally consumed as soup. Since it is rich in protein and vitamin content, it plays an important role in the diets of elderly people and children [¹1 Daglioǧlu O. Tarhana as a traditional Turkish fermented cereal food. Its recipe, production and composition. Food/Nahrung. 2000 Mar 1;44(2):85-8. https://doi.org/10.1002/(sici)1521-3803(20000301)44:2<85::aid-food85>3.0.co;2-h
https://doi.org/10.1002/(sici)1521-3803(... ]. Although traditional tarhana production is common in Turkey, industrial production increased [²2 İbanoğlu Ş, Maskan M. Effect of cooking on the drying behaviour of tarhana dough, a wheat flour-yoghurt mixture. Journal of Food Engineering. 2002 Sep 1;54(2):119-23. https://doi.org/10.1016/s0260-8774(01)00192-3
https://doi.org/10.1016/s0260-8774(01)00... ]. Low moisture (6-9%) and pH (3.8-4.2) protect tarhana from pathogens and other microorganisms. Moreover, thanks to its low moisture content, tarhana can be stored for 2-3 years [³3 İbanoǧlu Ş, İbanoǧlu E, Ainsworth P. Effect of different ingredients on the fermentation activity in tarhana. Food Chem. 1999 Jan 1;64(1):103-6. https://doi.org/10.1016/s0308-8146(98)00071-5
https://doi.org/10.1016/s0308-8146(98)00... ]. The combination of vegetable and animal protein contents within tarhana and its fermented structure significantly improve its bioavailability and digestibility [⁴4 Çevik A. Tarhananın besinsel zenginleştirilmesinde kinoa, karabuğday ve lüpen unlarının kullanımı [Utilization of quinoa, buckwheat and lupin flour in Tarhana for nutritional enrichment] [master's thesis].Turkey, Konya. Necmettin Erbakan University, Graduate School of Natural and Applied Sciences, Department of Food Engineering; 2016. 113 p. https://acikerisim.erbakan.edu.tr/xmlui/handle/20.500.12452/7457
https://acikerisim.erbakan.edu.tr/xmlui/... ]. Red beet (Beta vulgaris var. Cruenta) growing in the Mediterranean region and it is grown in Asia, America, and Europe because of the demand from consumers. Moreover, red beet is used as a natural coloring agent for foods such as processed meat, ice cream, wine, jam, bakery products, candies, and yogurt [⁵5 Akan S, Horzum Ö, Tuna-Güneş N. Fonksiyonel gıda kaynağı ‘Kırmızı Pancar’. [‘Red Beetroot’ as a Functional Food Source] Proceedings book of 5th International Eurasian Congress on Natural Nutrition, Healthy life & Sport, Ankara-Turkey. 2019.]. Red beet’s unique red color arises from betalain pigments including betanin and beta-cyanine. Thanks to its phenolic compound and betalain contents, Red beet is a very good antiradical and antioxidant source [⁶6 Clifford T, Howatson G, West DJ, Stevenson EJ. The potential benefits of red beetroot supplementation in health and disease. Nutrients. 2015 Apr;7(4):2801-22. https://doi.org/10.3390/nu7042801
https://doi.org/10.3390/nu7042801... ]. In the vegan diet, the important point is to ignore all animal-origin products [⁷7 Altaş A. Vegetarianism and veganism: Current situation in Turkey in the light of examples in the world. https://doi.org/10.21325/jotags.2017.157
https://doi.org/10.21325/jotags.2017.157... ]. The main reason for individuals to choose the vegan lifestyle is their concerns about the health, environmental, and economic problems that a diet having high animal-origin food would cause [⁸8 Appleby PN, Key TJ. The long-term health of vegetarians and vegans. Proceedings of the Nutrition Society. 2016 Aug;75(3):287-93.https://doi.org/10.1017/S0029665115004334
https://doi.org/10.1017/S002966511500433... ]. In comparison to the non-vegan population, it was reported that vegan individuals had a lower incidence of cardiovascular diseases, obesity, diabetes mellitus, arteriosclerosis, and hypertension, as well as a lower level of blood cholesterol [⁹9 Tunçay GY. Sağlık yönüyle vegan/vejetaryenlik. [Health-wise vegan/vegetarianism]. Avrasya Sağlık Bilimleri Dergisi. 2018 Jun 6;1(1):25-9.].

In the present study, producing vegan tarhanas (without yogurt) with red beet powder (RP) additive at 0% (control), 0.5%, 1.0%, 1.5%, 2.0%, 2.5%, and 3.0% concentrations, several characteristics of vegan tarhanas were examined. Given the literature review, although there are versions of tarhana containing different contents, no study on vegan tarhana could be found and it was aimed to carry out a new study on the vegan tarhana.

MATERIAL AND METHOD

Material

The raw materials used in tarhana production; wheat flour (Söke Flour), yeast (Saccharomyces cerevisiae, Pakmaya) and tomato sauce (Tat tomato sauce) were obtained from local markets while onion, red pepper, green pepper, red beet, and salt were procured from local open air markets.

Method

Production of Red Beet Powder

Red beets were washed, their leaves and stems were cut, and root parts were peeled. Using the slicing apparatus of a food processor, they were thinly sliced and then dried in a tray oven at 60° C for 11 hours. The dried red beets were ground and processed into red beet powder (RP) [¹⁰10 Turp G, Kazan H, Ünübol H. [The usage of red beet powder as natural colorant and antioxidant in sausage production]. CBUJS. 2016 Aug 8;12(2). https://doi.org/10.18466/cbujos.76228
https://doi.org/10.18466/cbujos.76228... ].

Production of Vegan Tarhana with Red Beet Powder and Sauce

Different formulations for vegan tarhana with red beet powder and sauce (RPSVT) were revised and the contents were wheat flour (56-59%), tomato sauce (9%), onion (16%), red pepper (7%), green pepper (7%), yeast (1%), salt (1%), and RP (0-3%) [¹¹11 Ekıncı R. The effect of fermentation and drying on the water-soluble vitamin content of tarhana, a traditional Turkish cereal food. Food Chem. 2005 Mar 1;90(1-2):127-32. https://doi.org/10.1016/j.foodchem.2004.03.036
https://doi.org/10.1016/j.foodchem.2004.... ,¹²12 Erkan H, Çelik S, Bilgi B, Köksel H. A new approach for the utilization of barley in food products: Barley tarhana. Food Chemistry. 2006 Jul 1;97(1):12-8. https://doi.org/10.1016/j.foodchem.2005.03.018
https://doi.org/10.1016/j.foodchem.2005.... ,¹³13 Işık Fatma. [Use of paste waste materials in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2013. 178 p.]. The mixture was homogeneously kneaded for 5 minutes. The doughs obtained were left for fermentation at 30-35°C for 1-5 days. pH values of doughs left for fermentation were measured using a pH-meter and the fermentation was then ceased when pH reached 3.8-4.2 [¹⁴14 Gamze ÜÇ, Cankurtaran T, Demir MK. [Use of paste waste materials in tarhana production]. Harran Tarım ve Gıda Bilimleri Dergisi. 2019 Mar 3;23(1):22-30. https://doi:10.29050/harranziraat.402350
https://doi:10.29050/harranziraat.402350... ]. After the fermentation, the RPSVT samples were dried using a domestic drier at 40 °C for 48 hours under control and then powdered by grinding [¹⁵15 Erol NI. [A research on tarhana with carob] [master's thesis]. Afyonkarahisar, Turkey. Afyon Kocatepe University, Institute of Science, Department of Food Engineering; 2010. https://acikerisim.aku.edu.tr/xmlui/bitstream/handle/11630/6370/369690.pdf?sequence=1&isAllowed=y
https://acikerisim.aku.edu.tr/xmlui/bits... ].

Production of Sauce-free Vegan Tarhana with Red Beet Powder

In the production of sauce-free vegan tarhana with red beet powder (RPVT), different formulations were revised and the contents were wheat flour (65-68%), onion (16%), red pepper (7%), green pepper (7%), yeast (1%), salt (1%), and RP (0-3%) [¹¹11 Ekıncı R. The effect of fermentation and drying on the water-soluble vitamin content of tarhana, a traditional Turkish cereal food. Food Chem. 2005 Mar 1;90(1-2):127-32. https://doi.org/10.1016/j.foodchem.2004.03.036
https://doi.org/10.1016/j.foodchem.2004.... ,¹²12 Erkan H, Çelik S, Bilgi B, Köksel H. A new approach for the utilization of barley in food products: Barley tarhana. Food Chemistry. 2006 Jul 1;97(1):12-8. https://doi.org/10.1016/j.foodchem.2005.03.018
https://doi.org/10.1016/j.foodchem.2005.... ,¹³13 Işık Fatma. [Use of paste waste materials in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2013. 178 p.]. The mixture was homogeneously kneaded for 5 minutes. The doughs obtained were left for fermentation at 30-35°C for 1-5 days. pH values of doughs left for fermentation were measured using a pH-meter and the fermentation was then ceased when pH reached 3.8-4.2 [¹⁴14 Gamze ÜÇ, Cankurtaran T, Demir MK. [Use of paste waste materials in tarhana production]. Harran Tarım ve Gıda Bilimleri Dergisi. 2019 Mar 3;23(1):22-30. https://doi:10.29050/harranziraat.402350
https://doi:10.29050/harranziraat.402350... ]. After the fermentation, the RPVT samples were dried using a domestic drier at 40 °C for 48 hours under control and then powdered by grinding [¹⁵15 Erol NI. [A research on tarhana with carob] [master's thesis]. Afyonkarahisar, Turkey. Afyon Kocatepe University, Institute of Science, Department of Food Engineering; 2010. https://acikerisim.aku.edu.tr/xmlui/bitstream/handle/11630/6370/369690.pdf?sequence=1&isAllowed=y
https://acikerisim.aku.edu.tr/xmlui/bits... ].

Physicochemical Analyses

Physicochemical analyses conducted for all vegan tarhana samples include dry matter and moisture [¹⁶16 AOAC. Official Methods of Analysis, (15th Ed.), Association of Official Analytical Chemists, Washington, DC.1990.], ash [¹⁷17 ICC. Standard Methods of International Association for Cereal Science and Technology (ICC). Vienna, Austria. 2002.], salt [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.], fat [¹⁹19 AOCS. Official methods and recommended practices of the American Oil Chemists Society. Champaign, IL (USA), AOCS Press. 2003.], total acidity [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.], water-holding capacity, and foaming capacity [²⁰20 Tarakci Z, Anil M, Koca I, Islam A. Effects of adding cherry laurel (Laurocerasus officinalis) on some physicochemical and functional properties and sensorial quality of tarhana. Quality Assurance and Safety of Crops & Foods. 2013 Dec 1;5(4):347-55. https://doi.org/10.3920/QAS2012.0155
https://doi.org/10.3920/QAS2012.0155... ]. Water activity (a_w) was analyzed using a water activity tester (Aqualab 4TE Meter Group, Inc., USA) [²¹21 Demiray Engin. [Dehydration of carrot and red pepper by different drying techniques, modeling of drying characteristics and changes in some quality properties] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2010.263 p.]. Protein detection was performed using the Kjeldahl method (AACC 46-12) [²²22 AACC. American Association of Cereal Chemists, Approved Methods of the AACC The Association: St. Paul, MN. 2000.]. pH analyses of tarhana samples were conducted using a pH meter (Mettler-Toledo International Inc., Switzerland). Color determination of all vegan tarhana samples was performed using a color tester (Hunterlab MiniScan EZ 4000L, USA) and the results were presented as L* (dark-bright (0-100)), a* (green-red (-60-60)), and b* (blue-yellow (-60-60)) values [²³23 Cueva O, Aryana KJ. Quality attributes of a heart healthy yogurt. LWT-Food Science and Technology. 2008 Apr 1;41(3):537-44.https://doi.org/10.1016/j.lwt.2007.04.002
https://doi.org/10.1016/j.lwt.2007.04.00... ]. Total dietary fiber content was determined using the gravimetric analysis method [²⁴24 AOAC Official Method 985.29. Total dietary fiber in foods, first action 1985 and final action 1986].

Determination of Total Phenolic Content

Total phenolic content of vegan tarhanas were conducted using the Folin-Ciocaltaeu method. Obtained using 70% ethanol, 0.5 mL red beet powder (RP) and all vegan tarhana samples were mixed with 2.5 mL Folin-Ciocalteu reactive (10% (v/v) (Sigma) and 2 mL sodium carbonate solution (7.5% (w/v)) (Sigma)and then kept in a dark place at the room temperature for 1 hour. The sample’s blind absorbance was determined using UV-Visible Spectrophotometer (Hach DR6000, Lange GmbH, 189 Germany) at 725 nm. Using the calibration curve prepared with gallic acid, the total phenolic contents of the samples were expressed as mg gallic acid equivalent (GAE) per gram of dry weight (dw) [²⁵25 Waterhouse AL. Determination of total phenolics. Current protocols in food analytical chemistry. 2002 Nov;6(1):I1-1. https://doi.org/10.1002/0471142913.fai0101s06
https://doi.org/10.1002/0471142913.fai01... ].

Determination of Antioxidant Activity

Antioxidant activities of all tarhana samples were determined using ABTS radical. To be used in analyses, ABTS [2,2’-azino-bis(3-ethylbenzothiazoline-6-sulfonic acid)] (Sigma-Aldrich) solution was diluted by 1:10 using 96% ethanol (Sigma-Aldrich). Put into test tubes, x ml sample extract, (4-x) ml ethanol, and 1 mL ABTS solution were mixed. The mixture was kept at room temperature for 6 minutes and then the absorbance values were measured using a spectrophotometer (Hach DR6000, Lange GmbH. 189 Germany) at 734 nm. Similarly, 4 ml ethanol and 1 ml ABTS were mixed and, at the end of the 6 minutes, the absorbance value was measured as a witness test. Making use of the calibration curve prepared using the Trolox standard, the total antioxidant capacities of all vegan tarhana samples were calculated as µmol TE/100 g dry matter [²⁶26 Vitali D, Dragojević IV, Šebečić B. Effects of incorporation of integral raw materials and dietary fibre on the selected nutritional and functional properties of biscuits. Food chemistry. 2009 Jun 15;114(4):1462-9. https://doi.org/10.1016/j.foodchem.2008.11.032
https://doi.org/10.1016/j.foodchem.2008.... ].

Microbiological Analyses

Plate Count Agar (Merck 105463, PCA) medium [²⁷27 Korkmaz BO, Aydin A, Kiliç N. [Investigation of enteral nutrition products for Mesophilic Aerobic Bacteria and Cronobacter sakazakii contamination]. Food and Health. 2020 Nov 25;7(1):39-44. https://doi.org/10.3153/FH21005
https://doi.org/10.3153/FH21005... ] was used for total mesophilic aerobic bacteria (TMAB) count (24 hours at 37ºC), Potato Dextrose Agar (Merck 110130, PDA) medium [²⁸28 Temiz, A. [General Microbiology Application Techniques]. 5th Edition, Hatiboğlu Publishing House, Ankara,Turkey. 2010; 63 p.] for total yeast-mold (TYM) count (5 days at 25 ºC), Fluorocult Violet Red Bile Agar (Merck 101406, VRB) medium [²⁹29 FDA. Bacteriolological Analytical Manual. Food and Drug Administration 1995;16.] for total coliform group bacteria (24 hours at 37ºC), and Baird Parker Agar (Merck 105406, BPA) medium added with egg yolk (Egg yolk tellurite emulsion, Merck 103785, Germany) for Staphylococcus aureus count (24 hours at 37ºC) [³⁰30 Kalkan S. Predicting the antimicrobial effect of probiotic lactic acid bacteria against Staphylococcus aureus in white cheeses, using Fourier series modeling method. J Food Saf. 2020 Feb;40(1):e12724. https://doi.org/10.1111/jfs.127244
https://doi.org/10.1111/jfs.127244... ].

Scanning Electron Microscope

Surface morphologies of RP and all vegan tarhanas were imaged using a scanning electron microscope (SEM). To have them show conductive characteristics, the samples were sprinkled on a carbon plate and coated with gold-palladium (80:20/w:w) (SPI-MODULE Sputter Coater) at room temperature. Images of samples were taken using SEM (ZEISS, EVO/LS 10, Germany). Micrographs were obtained at X250 magnification [³¹31 Goencue A, Celik I. Investigation of some properties of gluten-free tarhanas produced by red, green and yellow lentil whole flour. Food Sci Technol. 2020 Jun 12;40:574-81. https://doi.org/10.1590/fst.34919
https://doi.org/10.1590/fst.34919... ].

Sensorial Analysis

Sensorial analyses of the all vegan tarhana soups were performed by a 10-person panelist group(Giresun University consists of faculty members) who were informed prior. Using a 5-point hedonic scale (1: very poor, 2: poor, 3: moderate, 4: good, and 5: very good), the consumer test was conducted on the panelists considering the color, odor, taste, consistency, and general appreciation criteria for all vegan tarhana [³²32 Durmuş Y. [Effects of using hydrocolloids on quality of gluten free tarhana production] [master's thesis]. Ordu, Turkey. Ordu University, Institute of Science and Technology, Department of Food Engineering; 2015. 120 p. http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/1124
http://earsiv.odu.edu.tr:8080/xmlui/hand... ].

Statistical Analysis

The data obtained were analyzed using IBM SPSS Statistics 20 package software (SPSS, CHICAGO, IL, USA). The significance of differences between mean values of groups was tested using One-Way ANOVA, whereas where there were remarkable significant differences between the groups was determined using Duncan’s multiple comparison test. Statistical significance was set at the confidence level of p≤0.05.

RESULTS

Raw Material Analysis Results

The analysis results of RP used in the experiments are presented in Table 1. Given the results presented, it was determined that RP used in vegan tarhana production contained high amounts of protein, ash, and dietary fiber. Besides that, it was also found to be rich in antioxidant capacity and total phenolic content.

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Table 1
Physicochemical analysis findings of RP

**Analysis Results of Vegan Tarhana Added with Red Beet (Beta Vulgaris Var. Cruenta) Powder Additive**

Obtained from the color measurements of sauced and sauce-free vegan tarhana samples with and without RP (0%) additive, L* (brightness), a* (redness), and b* (yellowness) values are presented in Table 2. The color values of all vegan tarhana samples were found to be statistically significant in relationship with the RP additive concentration (p≤0.05).

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Table 2
Color values of vegan tarhana samples

The results for water holding and foaming of all vegan tarhana samples produced in the present study are presented in Table 3. Water holding and foaming capacities of all vegan tarhana samples were found to be statistically significant in relation to additive concentration (p≤0.05).

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Table 3
Water holding and foaming capacity values of vegan tarhanas

RP -added sauced and sauce-free vegan tarhana samples’ dry matter, moisture, and ash results are presented in Table 4. The differences in dry matter and moisture values of RPSVT by additive concentration were found to be statistically significant (p≤0.05). This difference can be explained by the fact that the heat applied during the drying process was not homogeneously distributed and that they might vary depending on the characteristics of raw materials used. Moreover, the moisture content of the seeds of tomato, which is the main content in the sauce, was found to be high in previous studies [¹³13 Işık Fatma. [Use of paste waste materials in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2013. 178 p.]. Thus, it was found that the difference between dry matter ratios of RPSVT was statistically significant. No statistically significant difference was found in dry matter and moisture contents of RPVT by the additive concentration (p≥0.05). The difference in ash contents of sauced and sauce-free vegan tarhanas by the additive concentration was found to be statistically significant (p≤0.05) (Table 4).

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Table 4
Dry matter, moisture and ash values of vegan tarhanas

The statistical results for a_w, pH, and total acidity values of all vegan tarhana samples produced are presented in Table 5. The differences in a_w, pH, and total acidity values of sauced and sauce-free vegan tarhanas by the additive concentration were found to be statistically significant (p≤0.05).

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Table 5
a_w, pH and total acidity values of vegan tarhanas

The statistical results for protein, fat, and salt content of all RP added vegan tarhana samples produced here are presented in Table 6. The differences in protein, fat, and salt contents of sauced and sauce-free vegan tarhana samples by additive concentration were found to be statistically significant (p≤0.05).

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Table 6
Protein, fat and salt values of vegan tarhanas

SEM images of RP, RPSVT, and RPVT samples under X250 magnification are presented in Figures 1 and 2.

Figure 1
SEM images of RP and all vegan tarhanas (250x). A: RP, B: Control, C: D: E: F: G: H: 0.5%, 1, 1.5, 2, 2.5, 3 RPSVT

Figure 2
SEM images of RBP and all vegan tarhanas (250x). A: RP, B: Control, C: D: E: F: G: H: 0.5%, 1, 1.5, 2, 2.5, 3 RPVT

Statistical analysis results of total phenolic content (TPC), antioxidant capacity, and total dietary fiber content values of sauced and sauce-free RP-added vegan tarhana samples are presented in Table 7. Of vegan tarhanas added with RP at different concentrations, TPC values ranged between 17.25 and 41.3 mg GAE/100 g, antioxidant capacity between 1.46 and 2.28 µM TE/g TA, and total dietary fiber content between 1.47 and 5.01%. The difference in sauced and sauce-free vegan tarhanas’ TPC, antioxidant capacity, and total dietary fiber content values by additive concentration was found to be statistically significant (p≤0.05).

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Table 7
TPC, antioxidant capacity and total dietary fiber values of vegan tarhanas

Statistical results of microbiological characteristics of RP added vegan tarhana samples are presented in Table 8. For vegan tarhanas added with different concentrations of RP, TMAB count was found to be 3.82-4.19 log CFU/g and TYM count to be 3.48 - 3.97 log CFU/g. No coliform or S.aureus could be found in either group. The difference in TMAB and TYM counts and coliform and S. aureus values of sauced and sauce-free vegan tarhanas was found to be statistically significant (p≤0.05).

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Table 8
Microbiological properties of vegan tarhana samples (log CFU/g)

Sensorial Analysis Results

During the sensorial panels of soups prepared using RP added vegan tarhanas, the products were presented to the panelists by randomly coding with 3-digit numbers [³³33 Bratcher CL. Trained Sensory Panels. Sci Meat Quality, 2013;207-13. https://doi.org/10.1002/9781118530726
https://doi.org/10.1002/9781118530726... ]. Sensorial analysis diagrams of RPSVT and RPVT are presented in Figures 3 and 4.

Figure 3
Sensory data graph of RPSVT vegan tarhana

Figure 4
Sensory data graph of RPVT vegan tarhanas

DISCUSSION

Given the results obtained, it was determined that, as a result of RP addition, RPSVT and RPVT vegan tarhana samples’ L* and a* values decreased, RPVT’ b* values increased, and RPSVT’ b* values decreased. In previous studies, it was reported that L* value and protein characteristics were related to each other and L* value might decrease with increasing protein concentration [³⁴34 Chevallier, S., Colonna, P., Della-Valle, G., Lourdin, D. Contribution of major ingredients during baking of biscuit dough systems. 2000;31(3):241-52. https://doi.org/10.1006/jcrs.2000.0308
https://doi.org/10.1006/jcrs.2000.0308... ]. In many studies, it was found that there were differences between color values and L* values ranged between 58 and 80 [³⁵35 Ertaş N, Sert D, Demir MK, Elguen A. Effect of whey concentrate addition on the chemical, nutritional and sensory properties of tarhana (A Turkish fermented cereal-based food). Food Sci Technol Res. 2009;15(1):51-8. https://doi.org/10.3136/fstr.15.51
https://doi.org/10.3136/fstr.15.51... ,³⁶36 Çelik I, Işik F, Şimşek Ö, Gürsoy O. The effects of the addition of baker's yeast on the functional properties and quality of tarhana, a traditional fermented food. Czech J Food Sci. 2005. https://doi.org/10.17221/3390-cjfs
https://doi.org/10.17221/3390-cjfs... ]. The results were similar to the L* values (73.04 - 87.44) reported for homemade tarhana samples collected by Ovando- Martinez and coauthors [³⁷37 Ovando-Martinez M, Daglioglu O, Gecgel U, Simsek S. Analysis of the fatty acids and phenolic compounds in a cereal-based fermented food (Tarhana). Food Nutr Sci. 2014 Jul 9;2014. http://dx.doi.org/10.4236/fns.2014.513128
http://dx.doi.org/10.4236/fns.2014.51312... ] from different cities.

The results obtained from the analyses were found to be lower than a* (19.4 - 20.7) values found by Gül [³⁸38 Gül T. [Using of stale bread in tarhana production] [master's thesis]. Kayseri, Turkey. Erciyes University, Institute of Science and Technology, Department of Food Engineering; 2010.91 p. https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=JaiuMmgcFhjGsvDtmUXL6Q&no=TTbnLINfqv914D8QOS0iRA
https://tez.yok.gov.tr/UlusalTezMerkezi/... ]. The low a* value found in sauced and sauce-free vegan tarhana samples might be explained by the oxidation reaction, which occurs due to the exposure of carotenoids to the factors such as temperature, oxygen, and light during the drying process [³⁹39 Dayısoylu KS, Gezginç Y, İnanç AL. [A view of Kahramanmaraş tarhana in terms of nutritional functionality]. 3. Gıda Mühendisliği Kongresi. 2003:511-23.]. Similarly, in another study carried out using wheat flour, b* value of tarhana was found to be 20.12 [¹²12 Erkan H, Çelik S, Bilgi B, Köksel H. A new approach for the utilization of barley in food products: Barley tarhana. Food Chemistry. 2006 Jul 1;97(1):12-8. https://doi.org/10.1016/j.foodchem.2005.03.018
https://doi.org/10.1016/j.foodchem.2005.... ].

It was determined that the water-holding capacity of sauced and sauce-free vegan tarhana samples increased with increasing RP additive concentration. This increase can be explained by the difference between starch molecules and protein structures in the tarhana composition [³⁶36 Çelik I, Işik F, Şimşek Ö, Gürsoy O. The effects of the addition of baker's yeast on the functional properties and quality of tarhana, a traditional fermented food. Czech J Food Sci. 2005. https://doi.org/10.17221/3390-cjfs
https://doi.org/10.17221/3390-cjfs... ]. The results achieved here are similar to the water-holding capacity results (1.07-1.46 ml/g) reported by Durmuş [³²32 Durmuş Y. [Effects of using hydrocolloids on quality of gluten free tarhana production] [master's thesis]. Ordu, Turkey. Ordu University, Institute of Science and Technology, Department of Food Engineering; 2015. 120 p. http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/1124
http://earsiv.odu.edu.tr:8080/xmlui/hand... ] for the tarhanas added with corn flour by using 3 different hydrocolloids.

It was observed that the foaming capacity of sauced and sauce-free vegan tarhanas decreased with the increasing concentration of RP additive. These decreases in foaming capacities of control and RP added tarhana samples are thought to originate from the protein concentration increasing with RP. In a previous study carried out by Kıtan [⁴⁰40 Kıtan S. [Use of quinoa (Chenopodium quinoa) in gluten-free tarhana production] [master's thesis]. Samsun, Turkiye. Ondokuz Mayıs University, Institute of Science and Technology, Department of Food Engineering; 2017, 100 p. https://www.researchgate.net/publication/374290926_TC_GLUTENSIZ_TARHANA_URETIMINDE_KINOA_Chenopodium_quinoa_KULLANIMI_SAMSUN_2017_ONDOKUZ_MAYIS_UNIVERSITESI_FEN_BILIMLERI_ENSTITUSU_YUKSEK_LISANS_TEZI_SEBIHA_KITAN_GIDA_MUHENDISLIGI_ANABILIM_DALI
https://www.researchgate.net/publication... ], foaming capacity values of tarhanas added with quinoa flour (0.04-0.08 mL/mL) were similar to the results achieved here (sauced 0.13-0.03 mL/mL and sauce-free 0.15-0.09 mL/mL).

Given the tarhana standard, the moisture content should be 10% at the maximum [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.]. Given the results achieved, it can be stated that the dry matter and moisture content of all vegan tarhanas met the standards. Besides that, it was also determined that the ash content of sauced and sauce-free vegan tarhanas increased with the increasing concentration of RP additive. The results (8.82-6.21% for RPSVT and 5.66-5.88% for RPVT) achieved here were higher than those reported by Demir [⁴¹41 Demir MK. [Use of whole wheat flour in traditional tarhana production]. Akademik Gıda. 2018;16(2):148-55. https://dx.doi.org/10.24323/akademik-gida.449606
https://dx.doi.org/10.24323/akademik-gid... ] for tarhana added with whole wheat flour (4.37-4.55%) and it can be stated that this difference might arise from the differences in drying methods and characteristics of raw materials used.

In a study carried out by Şemşioğlu [⁴²42 Şemşimoğlu E. [A study on tarhana production with the addition of various grape fruits]. Afyonkarahisar, Turkey. Afyon Kocatepe University, Institute of Science and Technology, Department of Food Engineering; 2019, 117 p.], the ash contents of tarhanas added with various berry-like fruits (1.89-5.02%) were different in comparison to the present results (2.55-4.25% for sauced and 2.58-3.61% for sauce-free) and it can be stated that this difference might be related with the varieties and amounts of raw materials used.

Total acidity values of RP added vegan tarhanas were generally related to the pH levels. pH values of RPVT were found to be higher than those of RPSVT. This difference might arise from the increase in acidity because of tomato sauce. It was found that the total acidity values of all RP added vegan tarhana samples (10.83-17.00 and 10.50-13.67) met the tarhana standards (between 10 and 35) [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.]. Total acidity of tarhanas produced was in a similar range to the total acidity (10.2-28.4) of tarhanas produced in a study carried out by Esimek [⁴³43 Esimek H. [Determination of total dietary fiber content and antioxidative properties of tarhana] [master's thesis]. Malatya, Turkey. İnönü University, Institute of Science and Technology, Department of Food Engineering; 2010. 68 p. http://abakus.inonu.edu.tr/xmlui/handle/11616/9685?show=full , https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=J5p6WF9QQ5YFUIbR452uyg&no=PJzBWJqxqI3W_hWSBJGSHg
http://abakus.inonu.edu.tr/xmlui/handle/... ].

Comparing the previous studies to the present results, differences were observed in aw values [⁴⁴44 Önçirak Z. [Use of different pre-treated legume flours as a raw material in tarhana production] [master's thesis]. Samsun, Turkey. Ondokuz Mayıs University, Institute of Science and Technology, Department of Food Engineering; 2019, 107 p. https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=DYYcaFUg1I0XqWPqRRmXOQ&no=aC0Mb3YmDoFA7E9pOOk5gg
https://tez.yok.gov.tr/UlusalTezMerkezi/... ]. These differences can be explained by the drying methods and water contents of raw materials used. pH values of tarhanas produced (5.68-5.45 and 5.95-5.56) were found to be higher than those reported by Esimek [⁴³43 Esimek H. [Determination of total dietary fiber content and antioxidative properties of tarhana] [master's thesis]. Malatya, Turkey. İnönü University, Institute of Science and Technology, Department of Food Engineering; 2010. 68 p. http://abakus.inonu.edu.tr/xmlui/handle/11616/9685?show=full , https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=J5p6WF9QQ5YFUIbR452uyg&no=PJzBWJqxqI3W_hWSBJGSHg
http://abakus.inonu.edu.tr/xmlui/handle/... ] (3.62 and 4.75). In general, the reason for these higher pH values might be the absence of LAB, which is found in yogurt, in vegan tarhana.

It can be seen that the high protein content of RP (8.75%) influenced the RP added vegan tarhanas [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.]. In all samples, protein contents of control samples and those added with 0.5%, 1.0%, and 1.5% RP (9.68%, 11.21%, 11.78%, and 11.96%, respectively) were lower than the values specified in tarhana standards (min. 12%) and the protein contents of RPSVT added with 2.0%, 2.5%, and 3.0% RP (12.86%, 13.05%, and 13.18%, respectively) were found to be higher. For RPVT samples, the protein contents of control samples and those added with 0.5%, 1.0%, 1.5%, 2.0%, and 2.5% RP (10.38%, 10.51%, 11.46%, 11.62%, 11.71%, and 11.83%, respectively) were lower than the values specified in tarhana standards (min. 12%) but only the protein content of 3.0% RPVT (12.48%) was higher than the standard. Comparing the present results to the protein contents (2.73%-15.37%) reported by Şemşioğlu [⁴²42 Şemşimoğlu E. [A study on tarhana production with the addition of various grape fruits]. Afyonkarahisar, Turkey. Afyon Kocatepe University, Institute of Science and Technology, Department of Food Engineering; 2019, 117 p.], it was determined that there were differences. This difference might be explained by the active role of vegetable foods in the protein content of vegan tarhana rather than animal foods (such as yogurt).

The decrease in fat content of RP added vegan tarhanas (4.23-0.13% for RPSVT and 2.40-0.38% for RPVT) together with increasing additive concentration might be explained by the low fat content of RP (0.99%) as seen in Table 1. Similarly, in a previous study carried out by Tamer and coauthors [⁴⁵45 Tamer CE, Kumral AY, Aşan M, Şahin İ. Chemical compositions of traditional tarhana having different formulations. J Food Process Preserv. 2007 Feb;31(1):116-26. https://doi.org/10.1111/j.1745-4549.2007.00113.xx
https://doi.org/10.1111/j.1745-4549.2007... ], it was reported that fat content of homemade tarhanas was generally lower than 5.10%. Given the tarhana standards [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.] (maximum salt content 10%), it can be seen that all the RP added vegan tarhana samples met the standards in terms of salt content (2.31-3.34% for RPSVT and 2.24-1.35% for RPVT). It was found that the salt content of RPSVT samples increased with increasing RP additive concentration, whereas the salt content of RPVT samples decreased. The insufficient acidity in sauce-free vegan tarhanas might have negatively affected the salt content. The present results were compared to those reported in a previous study and similar salt content values (increased from 1.74% to 3.08% in the first 8 days) were determined [⁴⁶46 Soyuçok A, Yurt MN, Altunbas O, Ozalp VC, Sudagidan M. Metagenomic and chemical analysis of Tarhana during traditional fermentation process. Food Bioscience. 2021 Feb 1;39:100824. https://doi.org/10.1016/j.fbio.2020.100824
https://doi.org/10.1016/j.fbio.2020.1008... ].

In Figure 1 and 2, there are the micrographs of RP, all vegan tarhanas added with different concentrations of RP (control 0%, 0.5%, 1%, 1.5%, 2%, and 3%) taken under x250 magnification by using a SEM. Particle distributions can be seen. While control tarhana and RP-added tarhanas had similar appearances consisting of large and small particles from the volumetric aspect, particle density increased with increasing additive concentration. In all tarhana versions, small (100 µm) particles were observed to be irregular. The present study results were similar to those reported by Göncü [⁴⁷47 Göncü Ali. [Investigation of possibilities of different lentil flour and boza usage in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2020. 182 p.].

Industrially produced tarhanas’ TPC (1.27-28.18 μg GAE/g) and homemade tarhanas’ TPC (0.55-42.67 μg GAE/g) reported in a previous study carried out by Çağındı and coauthors [⁴⁸48 Cagindi O, Aksoylu Z, Savlak NY, Kose E. Comparison of physicochemical and functional properties of domestic and commercial tarhana in Turkey. Bulg J Agric Sci. 2016;22(2):324-30.] were different in comparison to the present results (30.41-41.30 for RPSVT and 17.25-32.23 for RPVT samples). It was observed that RP addition at different concentrations slightly increased TPC values of vegan tarhana samples. It might be because RP addition concentrations were low or phenolic compounds disintegrated during the fermentation of vegan tarhana. Antioxidant capacity results of tarhanas added with hazelnut pulp reported in a study carried out by Oğurlu [⁴⁹49 Oğurlu MN. [The effects of different proportions of reduced-fat hazelnut pulp on the organoleptic and physico-chemical properties of tarhana] [master's thesis]. Ordu, Turkey. Ordu University, Institute of Science and Technology, Department of Food Engineering; 2019. 86 p. http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/659
http://earsiv.odu.edu.tr:8080/xmlui/hand... ] (0.15-0.42 mMol Trolox /g) were higher than the present results (1.46-2.04 for sauced samples and 1.59-2.28 for sauce-free samples). It was observed that RP addition at different concentrations slightly increased antioxidant capacity values of vegan tarhana samples. It might be because RP addition concentrations were low or radical compounds disintegrated during the fermentation of vegan tarhana. Total dietary fiber content of vegan tarhanas (1.96-5.01 for RPSVT samples and 1.47-3.42 for RPVT samples) increased with increasing concentration of RP addition. However, a higher level of increase was observed in RPVT samples in comparison to RPSVT. This difference suggests the fibrous structure of tomatoes. These results are similar to the total dietary fiber values of tarhana samples (3.0-4.2%) examined by O’Callaghan and coauthors [⁵⁰50 O'Callaghan YC, Shevade AV, Guinee TP, O'Connor TP, O'Brien NM. Comparison of the nutritional composition of experimental fermented milk: Wheat bulgur blends and commercially available kishk and tarhana products. Food Chem. 2019 Apr 25;278:110-8. https://doi.org/10.1016/j.foodchem.2018.11.026
https://doi.org/10.1016/j.foodchem.2018.... ] .

According to the tarhana standards, TMAB count in tarhana sample should be 1x10⁴ CFU/g and TYM count should be 1x10³ CFU/g [¹⁸18 TSE. TS 2282 Tarhana Standard. Turkish Standards Institute, Ankara, Turkey. 5. 2004.]. In a study carried out by Işık [¹³13 Işık Fatma. [Use of paste waste materials in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2013. 178 p.] by using wastes of sauce production, TMAB count of tarhanas (3.13-6.79 log CFU/g) was higher than the values found in the present study (4.18-3.94 log CFU/g for sauced samples and 4.01-3.82 log CFU/g for sauce-free samples) and they were higher than the lower threshold and lower than the upper threshold. Lower TMAB count of RP added vegan tarhana samples in comparison to the previous studies might be because of the lower pH value. TYM counts found in the present study (3.97-3.79 log CFU/g for sauced samples and 3.85-3.61 log CFU/g for sauce-free samples) were lower than TYM values (4.72-5.53 log CFU/g) reported by Göncü and Çelik [³¹31 Goencue A, Celik I. Investigation of some properties of gluten-free tarhanas produced by red, green and yellow lentil whole flour. Food Sci Technol. 2020 Jun 12;40:574-81. https://doi.org/10.1590/fst.34919
https://doi.org/10.1590/fst.34919... ] examining tarhanas added with red, yellow, and green lentil flour. Lower TYM count of RP added vegan tarhana samples in comparison to the previous studies might be because of the lower pH value.

The general acceptability values of all vegan tarhana samples produced in the study as a result of the sensory evaluation ranged between 3.00±0.67-4.10±0.74. The general acceptability values of the RPSVT samples were determined to be between 3.80±0.79-4.10±0.74. The general acceptability values of the RPVT samples were found to be between 3.00±0.67-3.80±0.79. While RPSVT vegan tarhana sample with 1% had the highest general acceptability values with 4.10±0.74, it was seen that 3% RPVT vegan tarhana sample had the lowest values of general acceptability characteristics with 3.00±0.67. In general, when the sensory evaluation scores of all vegan tarhanas are taken into account, it is seen that 3% RPVT vegan tarhana received the lowest scores in terms of color, smell, taste, consistency, aroma and general acceptability. It can be stated that 1% RPSVT vegan tarhanas got the highest score as a result of the evaluation of consistency, color, aroma and general acceptability.

CONCLUSION

In the present study, by using red beet (Beta vulgaris var. Cruenta) powder at different concentrations (control, 0.5%, 1%, 1.5%, 2%, 2.5%, 3%), it was aimed to diversify the versions of tarhana, which has had a place in our traditional culture, in order to increase the diversity of vegan products and the physicochemical, microbiological, textural, bioactive, and sensorial characteristics of the products were examined.

It was determined that ash, total acidity, protein, water holding capacity, total dietary fiber, total phenolic content and antioxidant capacity increased in proportion to the red beet powder concentration in all tarhanas. It was determined that the highest score in terms of sensory properties (consistency, taste, aroma and general acceptability) was given to vegan tarhana with 1.0% red beet powder and tomato sauce. In terms of color and odor characteristics, it was determined that the highest score was in vegan tarhana with tomato sauce with 2.0% red beet powder added. The microbiological properties of vegan tarhana were found to be in accordance with the standards. Staphylococcus aureus and coliform group bacteria could not be detected in any of the vegan tarhana. When all vegan tarhanas are compared with the studies in the literature, it can be said that they have similar physicochemical and bioactive properties.

In conclusion, although many characteristics of all red beet powder added vegan tarhana were similar to those of traditional tarhana, it is an alternative to the traditional tarhana for vegan individuals.

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» https://www.researchgate.net/publication/374290926_TC_GLUTENSIZ_TARHANA_URETIMINDE_KINOA_Chenopodium_quinoa_KULLANIMI_SAMSUN_2017_ONDOKUZ_MAYIS_UNIVERSITESI_FEN_BILIMLERI_ENSTITUSU_YUKSEK_LISANS_TEZI_SEBIHA_KITAN_GIDA_MUHENDISLIGI_ANABILIM_DALI
⁴¹
Demir MK. [Use of whole wheat flour in traditional tarhana production]. Akademik Gıda. 2018;16(2):148-55. https://dx.doi.org/10.24323/akademik-gida.449606
» https://dx.doi.org/10.24323/akademik-gida.449606
⁴²
Şemşimoğlu E. [A study on tarhana production with the addition of various grape fruits]. Afyonkarahisar, Turkey. Afyon Kocatepe University, Institute of Science and Technology, Department of Food Engineering; 2019, 117 p.
⁴³
Esimek H. [Determination of total dietary fiber content and antioxidative properties of tarhana] [master's thesis]. Malatya, Turkey. İnönü University, Institute of Science and Technology, Department of Food Engineering; 2010. 68 p. http://abakus.inonu.edu.tr/xmlui/handle/11616/9685?show=full , https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=J5p6WF9QQ5YFUIbR452uyg&no=PJzBWJqxqI3W_hWSBJGSHg
» http://abakus.inonu.edu.tr/xmlui/handle/11616/9685?show=full , https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=J5p6WF9QQ5YFUIbR452uyg&no=PJzBWJqxqI3W_hWSBJGSHg
⁴⁴
Önçirak Z. [Use of different pre-treated legume flours as a raw material in tarhana production] [master's thesis]. Samsun, Turkey. Ondokuz Mayıs University, Institute of Science and Technology, Department of Food Engineering; 2019, 107 p. https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=DYYcaFUg1I0XqWPqRRmXOQ&no=aC0Mb3YmDoFA7E9pOOk5gg
» https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=DYYcaFUg1I0XqWPqRRmXOQ&no=aC0Mb3YmDoFA7E9pOOk5gg
⁴⁵
Tamer CE, Kumral AY, Aşan M, Şahin İ. Chemical compositions of traditional tarhana having different formulations. J Food Process Preserv. 2007 Feb;31(1):116-26. https://doi.org/10.1111/j.1745-4549.2007.00113.xx
» https://doi.org/10.1111/j.1745-4549.2007.00113.xx
⁴⁶
Soyuçok A, Yurt MN, Altunbas O, Ozalp VC, Sudagidan M. Metagenomic and chemical analysis of Tarhana during traditional fermentation process. Food Bioscience. 2021 Feb 1;39:100824. https://doi.org/10.1016/j.fbio.2020.100824
» https://doi.org/10.1016/j.fbio.2020.100824
⁴⁷
Göncü Ali. [Investigation of possibilities of different lentil flour and boza usage in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2020. 182 p.
⁴⁸
Cagindi O, Aksoylu Z, Savlak NY, Kose E. Comparison of physicochemical and functional properties of domestic and commercial tarhana in Turkey. Bulg J Agric Sci. 2016;22(2):324-30.
⁴⁹
Oğurlu MN. [The effects of different proportions of reduced-fat hazelnut pulp on the organoleptic and physico-chemical properties of tarhana] [master's thesis]. Ordu, Turkey. Ordu University, Institute of Science and Technology, Department of Food Engineering; 2019. 86 p. http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/659
» http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/659
⁵⁰
O'Callaghan YC, Shevade AV, Guinee TP, O'Connor TP, O'Brien NM. Comparison of the nutritional composition of experimental fermented milk: Wheat bulgur blends and commercially available kishk and tarhana products. Food Chem. 2019 Apr 25;278:110-8. https://doi.org/10.1016/j.foodchem.2018.11.026
» https://doi.org/10.1016/j.foodchem.2018.11.026

Funding:

This research received no external funding

Edited by

Editor-in-Chief:

Bill Jorge Costa

Associate Editor:

Bill Jorge Costa

Publication Dates

Publication in this collection
30 Oct 2023
Date of issue
2023

History

Received
27 Oct 2022
Accepted
31 July 2023

This is an open-access article distributed under the terms of the Creative Commons Attribution License

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» https://dx.doi.org/10.24323/akademik-gida.449606

[42] ⁴²
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[43] ⁴³
Esimek H. [Determination of total dietary fiber content and antioxidative properties of tarhana] [master's thesis]. Malatya, Turkey. İnönü University, Institute of Science and Technology, Department of Food Engineering; 2010. 68 p. http://abakus.inonu.edu.tr/xmlui/handle/11616/9685?show=full , https://tez.yok.gov.tr/UlusalTezMerkezi/tezDetay.jsp?id=J5p6WF9QQ5YFUIbR452uyg&no=PJzBWJqxqI3W_hWSBJGSHg
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Tamer CE, Kumral AY, Aşan M, Şahin İ. Chemical compositions of traditional tarhana having different formulations. J Food Process Preserv. 2007 Feb;31(1):116-26. https://doi.org/10.1111/j.1745-4549.2007.00113.xx
» https://doi.org/10.1111/j.1745-4549.2007.00113.xx

[46] ⁴⁶
Soyuçok A, Yurt MN, Altunbas O, Ozalp VC, Sudagidan M. Metagenomic and chemical analysis of Tarhana during traditional fermentation process. Food Bioscience. 2021 Feb 1;39:100824. https://doi.org/10.1016/j.fbio.2020.100824
» https://doi.org/10.1016/j.fbio.2020.100824

[47] ⁴⁷
Göncü Ali. [Investigation of possibilities of different lentil flour and boza usage in tarhana production] [dissertation]. Denizli, Turkey. Pamukkale University, Institute of Science and Technology, Department of Food Engineering; 2020. 182 p.

[48] ⁴⁸
Cagindi O, Aksoylu Z, Savlak NY, Kose E. Comparison of physicochemical and functional properties of domestic and commercial tarhana in Turkey. Bulg J Agric Sci. 2016;22(2):324-30.

[49] ⁴⁹
Oğurlu MN. [The effects of different proportions of reduced-fat hazelnut pulp on the organoleptic and physico-chemical properties of tarhana] [master's thesis]. Ordu, Turkey. Ordu University, Institute of Science and Technology, Department of Food Engineering; 2019. 86 p. http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/659
» http://earsiv.odu.edu.tr:8080/xmlui/handle/11489/659

[50] ⁵⁰
O'Callaghan YC, Shevade AV, Guinee TP, O'Connor TP, O'Brien NM. Comparison of the nutritional composition of experimental fermented milk: Wheat bulgur blends and commercially available kishk and tarhana products. Food Chem. 2019 Apr 25;278:110-8. https://doi.org/10.1016/j.foodchem.2018.11.026
» https://doi.org/10.1016/j.foodchem.2018.11.026

	Values
pH	6.62
Total acidity (%)	5.3
Ash (%)	6.8
Protein (%)	8.75
Fat (%)	0.99
Salt (%)	0.31
Total Dietary Fiber	16.58
Antioxidant Activity (mMol Trolox equiv/g dry sample)	1.98
Total Phenolic Compounds (mM gallic acid/g dry sample)	199.07
Color Value
L*	32.08
a*	18.9
b*	16.6

RP Addition Rate (%)	RPSVT				RPVT
RP Addition Rate (%)	L*	a*	b*	∆E*	L*	a*	b*	∆E*
Control	80.66±0.10^f	10.07±0.02^b	23.30±0.09^d	31.84±0.08^c	83.23±0.11^g	4.32±0.07^a	16.97±0.11^a	23.17±0.19^a
0.5	80.10±0.12^e	9.41±0.07^a	21.88±0.08^a	30.82±0.17^a	82.70±0.04^f	5.85±0.08^b	20.08±0.19^b	26.32±0.23^b
1.0	79.67±0.38^d	9.59±0.10^a	22.70±0.23^c	31.66±0.46^bc	81.14±0.16^e	6.81±0.00^d	21.20±0.01^c	28.38±0.09^c
1.5	79.59±0.16^d	9.54±0.16^a	22.03±0.31^a	31.25±0.41^ab	80.36±0.03^d	6.21±0.01^c	21.18±0.04^c	28.46±0.06^c
2.0	78.09±0.06^c	9.89±0.06^b	22.62±0.01^bc	32.62±0.08^d	77.57±0.11^c	6.49±0.05^e	24.14±0.22^d	32.13±0.29^d
2.5	77.71±0.20^b	10.32±0.12^c	22.55±0.22^bc	33.03±0.37^d	76.84±0.06^b	6.89±0.02^e	24.23±0.02^d	32.80±0.06^e
3.0	75.82±0.10^a	10.36±0.05^c	22.21±0.07^ab	33.93±0.16^e	73.73±0.05^a	6.83±0.03^e	24.73±0.09^e	34.98±0.05^f

	Water Holding Capacity (mL/g)		Foaming Capacity (mL/mL)
RP Addition Rate (%)	RPSVT	RPVT	RPSVT	RPVT
Control	1.07±0.01^a	1.08±0.01^a	0.13±0.02^d	0.15±0.02^a
0.5	1.10±0.02^ab	1.16±0.01^b	0.12±0.01^d	0.13±0.02^ab
1.0	1.10±0.02^ab	1.21±0.01^bc	0.09±0.01^cd	0.12±0.02^ab
1.5	1.14±0.05^abc	1.21±0.01^bc	0.08±0.01^bc	0.12±0.01^ab
2.0	1.16±0.03^bc	1.27±0.01^c	0.06±0.01^abc	0.12±0.01^ab
2.5	1.17±0.01^bc	1.32±0.02^d	0.04±0.00^ab	0.10±0.02^ab
3.0	1.19±0.00^c	1.33±0.02^d	0.03±0.02^a	0.09±0.01^b

RP Addition Rate (%)	Dry Matter (%)		Moisture (%)		Ash (%)
RP Addition Rate (%)	RPSVT	RPVT	RPSVT	RPVT	RPSVT	RPVT
Control	91.17±0.71^a	94.34±0.14^a	8.82±0.71^a	5.66±0.14^a	2.55±0.03^a	2.58±0.06^a
0.5	92.31±0.56^ab	94.76±0.25^a	7.69±0.38^ah	5.24±0.25^a	2.94±0.02^b	2.64±0.03^b
1.0	92.60±0.25^ab	94.64±0.10^a	7.40±0.25^ab	5.36±0.10^a	2.96±0.02^b	2.78±0.02^b
1.5	92.07±1.17^a	94.47±0.08^a	7.93±1.17^ab	5.53±0.09^a	3.20±0.15^c	2.92±0.03^c
2.0	91.70±0.72^a	94.51±0.38^a	8.30±0.72^ab	5.49±0.39^a	3.26±0.01^c	2.93±0.02^c
2.5	92.79±0.48^ab	94.71±0.60^a	7.21±0.48^ab	5.29±0.60^a	3.27±0.02^c	2.95±0.03^c
3.0	93.79±0.47^b	94.12±0.70^a	6.21±0.47^b	5.88±0.70^a	4.25±0.04^d	3.61±0.02^d

	a_w		pH		Total Acidity (%)
RP Addition Rate (%)	RPSVT	RPVT	RPSVT	RPVT	RPSVT	RPVT
Control	0.53±0.00^f	0.36±0.00^c	5.68±0.01^d	5.95±0.00^d	10.83±0.47^a	10.50±0.41^a
0.5	0.49±0.00^e	0.39±0.00^g	5.68±0.01^d	5.93±0.01^d	11.50±0.82^ab	10.83±0.24^ab
1.0	0.34±0.00^b	0.40±0.00^f	5.65±0.00^c	5.90±0.00^d	12.50±0.71^ab	12.33±1.03^abc
1.5	0.42±0.00^d	0.39±0.00^e	5.64±0.01^c	5.88±0.00^c	14.00±0.41^bc	12.33±1.65^abc
2.0	0.35±0.00^c	0.37±0.00^d	5.61±0.01^b	5.85±0.00^c	15.50±0.41^cd	12.33±1.03^abc
2.5	0.26±0.00^a	0.21±0.00^a	5.45±0.01^a	5.64±0.00^b	15.50±1.22^cd	13.00±0.41^bc
3.0	0.35±0.00^b	0.22±0.00^b	5.45±0.01^a	5.56±0.00^d	17.00±0.82^d	13.67±1.03^c

Brasil

Brasil

Determining Some Quality Characteristics of Vegan Tarhana Added with Red Beet (Beta Vulgaris Var. Cruenta) Powder

Abstract

HIGHLIGHTS

INTRODUCTION

MATERIAL AND METHOD

Material

Method

Production of Red Beet Powder

Production of Vegan Tarhana with Red Beet Powder and Sauce

Production of Sauce-free Vegan Tarhana with Red Beet Powder

Physicochemical Analyses

Determination of Total Phenolic Content

Determination of Antioxidant Activity

Microbiological Analyses

Scanning Electron Microscope

Sensorial Analysis

Statistical Analysis

RESULTS

Raw Material Analysis Results

**Analysis Results of Vegan Tarhana Added with Red Beet (Beta Vulgaris Var. Cruenta) Powder Additive**

Sensorial Analysis Results

DISCUSSION

CONCLUSION

REFERENCES

Funding:

Edited by

Editor-in-Chief:

Associate Editor:

Publication Dates

History

RP Addition Rate(%)	RPSVT		RPVT
RP Addition Rate(%)	TMAB	TYM	TMAB	TYM
Control	4.18±0.03^c	3.97±0.03^c	4.01±0.02^c	3.85±0.06^c
0.5	4.19±0.08^c	3.97±0.02^c	3.85±0.03^a	3.48±0.03^a
1.0	4.10±0.02^b	3.70±0.02^b	4.05±0.03^c	3.81±0.02^c
1.5	4.10±0.07^b	3.61±0.15^ab	3.85±0.02^a	3.69±0.03^bc
2.0	3.93±0.02^a	3.48±0.01^a	4.02±0.03^c	3.81±0.02^c
2.5	3.94±0.03^a	3.92±0.02^c	3.94±0.02^b	3.62±0.03^b
3.0	3.94±0.02^a	3.79±0.04^bc	3.82±0.02^a	3.61±0.02^b

RP Addition Rate (%)	Protein (%)		Fat (%)		Salt (%)
RP Addition Rate (%)	RPSVT	RPVT	RPSVT	RPVT	RPSVT	RPVT
Control	9.68±0.03^a	10.38±0.02^a	4,23±0,26^a	2.40±0.16^a	2.31±0.07^a	2.24±0.12^c
0.5	11.21±0.08^b	10.51±0.03^b	3,14±0,03^b	1.19±0.01^b	2.57±0.01^b	2.05±0.03^b
1.0	11.78±0.02^c	11.46±0.03^c	2,99±0,01^b	1.16±0.02^b	2.75±0.03^c	1.91±0.01^b
1.5	11.96±0.07^d	11.62±0.02^d	1,95±0,03^c	0.72±0.06^c	2.94±0.01^d	1.51±0.01^a
2.0	12.86±0.02^e	11.71±0.03^r	1,36±0,02^d	0.59±0.01^cd	3.14±0.03^de	1.43±0.02^a
2.5	13.05±0.03^f	11.83±0.02^f	0,60±0,16^e	0.48±0.01^d	3.24±0.02^ef	1.40±0.00^a
3.0	13.18±0.02^f	12.48±0.02^g	0,13±0,05^f	0.38±0.02^d	3.34±0.03^f	1.35±0.02^a

RP Addition Rate (%)	Phenolic Substance (mg GAE/100 g)		Antioxidant Capacity (µM TE/g)		Total Dietary Fiber (%)
RP Addition Rate (%)	RPSVT	RPVT	RPSVT	RPVT	RPSVT	RPVT
Control	30.41±0.15^a	17.25±0.07^a	1.46±0.03^a	1.59±0.02^a	1.96±0.02^a	1.47±0.02^a
0.5	31.26±0.27^b	23.45±0.6^b	1.55±0.03^b	1.93±0.01^b	2.24±0.01^b	2.11±0.02^b
1.0	32.00±0.12^b	25.00±0.24^c	1.65±0.03^c	1.98±0.02^b	2.72±0.01^c	2.12±0.02^b
1.5	36.24±0.58^c	29.29±0.79^d	1.93±0.02^d	2.07±0.07^c	3.08±0.01^e	2.27±0.01^c
2.0	36.91±0.39^c	30.04±0.28^d	1.95±0.01^d	2.18±0.03^d	3.99±0.01^f	2.40±0.01^d
2.5	37.07±0.70^c	31.32±0.35^e	2.02±0.01^e	2.21±0.02^d	5.00±0.00^g	3.10±0.02^e
3.0	41.30±0.63^d	32.23±0.35^f	2.04±0.02^e	2.28±0.02^e	5.01±0.02^g	3.42±0.01^f