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Physicochemistry, microbiology, fatty acids composition and volatile profile of traditional Söğle tulum (goat’s skin bag) cheese

Abstract

Söğle cheese is a type of traditional tulum (goat’s skin bag) cheese produced from goat’s milk or a mixture of goat’s and sheep’s milk in Küçük Söğle and Büyük Söğle villages, Antalya, Turkey. This is the first study that aimed to investigate the physicochemistry, microbiology, fatty acids composition and volatile profile of traditional Söğle cheeses ripened in goat’s skins for three months in wells. The pH and titratable acidity values, total solids, fat, protein and salt contents of the Söğle cheese samples ranged from 4.9 to 5.5, from 1.4 to 2.6%, from 46.5 to 55.0%, from 2.0 to 4.5%, from 34.9 and 42.2% and from 4.1 to 8.2%, respectively. The highest proportion of fatty acids in all cheese samples was palmitic acid (C16:0). The lactobacillus, lactococcus, total aerobic mesophilic bacteria and yeast and mold counts in the cheese samples were found to be between 7.1 and 8.5 log cfu/g, 7.8 and 8.7 log cfu/g, 7.6 and 8.5 log cfu/g and 1.0 and 4.8 log cfu/g, respectively. Fifty-three volatile components were identified in the cheese samples including 13 esters, 7 ketones, 5 acids, 2 aldehydes, 5 alcohols, 12 terpenes, and 9 miscellaneous compounds. Ketones and terpenes were the predominant volatile compounds.

Key words
traditional cheese; goat’s skin bag; Tulum; volatile composition

INTRODUCTION

Traditional products have specific characteristics that differentiate them from other similar products in the same category by use of traditional ingredients, traditional composition or traditional type of production and/or processing method. In recent years, there has been a growing interest in consuming traditional cheeses in many countries, including Turkey, mainly because of non-use of any additives in their production process and their beneficial effects on human health (Hayaloglu et al. 2007HAYALOGLU AA, CAKMAKCI S, BRECHANY EY, DEEGAN KC and MCSWEENEY PL. 2007. Microbiology, biochemistry, and volatile composition of Tulum cheese ripened in goat’s skin or plastic bags. J Dairy Sci 90: 1102-1121., Shahbazi et al. 2017SHAHBAZI Y, NIKOUSEFAT Z and KARAMI N. 2017. Occurrence, seasonal variation and risk assessment of exposure to aflatoxin M1 in Iranian traditional cheeses. Food Control 79: 356-362.). As one of the most popular cheese types, tulum cheese made either from sheep’s milk, goat’s milk, a combination of sheep’s and goat’s milk, or cow’s milk is traditionally produced in many regions of Turkey (Sert and Akin 2008SERT D and AKIN N. 2008. Production methods of some important traditional tulum cheeses in Turkey. In: 10th Turkish Food Congress. Proceedings, Erzurum, p. 20.). Tulum cheese types are named according to the regions where they are produced, such as Erzincan (Savak), Divle, Cimi and Izmir (Bayar and Ozrenk 2011BAYAR N and OZRENK E. 2011. The effect of quality properties on Tulum cheese using different package materials. Afr J Biotechnol 10(8): 1393-1399., Adanacioglu and Albayram 2012ADANACIOGLU H and ALBAYRAM Z. 2012. A conjoint analysis of consumer preferences for traditional cheeses in Turkey: A case study on tulum cheese. Korean J Food Sci An 32(4): 58-46.).

Söğle cheese is a type of tulum cheese produced from May to September when milk is abundant in Küçük Söğle and Büyük Söğle villages, located in the town of Elmalı in the province of Antalya, in Turkey (Figure 1). Söğle cheese is made from goat’s milk or a mixture of goat’s and sheep’s milk without using any starter culture. Cheese milk prepared from goat’s milk or a mixture of sheep’s and goat’s milk is heated to 40°C in wood fire and skimmed by commercial small fat separators according to the producers’ needs. Then, commercial rennet (1/20000: Mayasan Food Industries AS, Istanbul, Turkey) is added to the skimmed milk. After coagulation of the skimmed milk in about 35 min, the curd is heated to 50°C. The heated curd is poured into plastic bags, and then kept at ambient temperature (about 15-20°C) for five days for whey draining. After whey draining, the curd is crumbled by hand and dry-salted. The crumbled and salted curd is transferred into the new plastic bags and kept under pressure by placing stones on these plastic bags at ambient temperature for two days. At the end of the second day, the curd is crumbled by hand and dry-salted for a second time. Then, the curd is filled into the tulum (goat-skin bag), excessive air in the tulum is removed by placing stones on the tulum. Söğle cheese in the tulum is ripened in wells with a depth of about 10 meters and at a temperature of about 10°C for 3 months. Söğle cheese has high dry matter and protein contents with a crumbly texture and a piquant flavor. Physicochemical and microbiological properties of tulum cheeses include Söğle cheese vary depending on type and microbial diversity of raw milk, production method, and ripening conditions such as temperature, time and cheese packaging material (Sert et al. 2014)SERT D, AKIN N and AKTUMSEK A. 2014. Lipolysis in Tulum cheese produced from raw and pasteurized goats’ milk during ripening. Small Rum Res 121: 351-360.. Moreover, physicochemical and microbiological properties of some of tulum cheese types such as Erzincan, Cimi, Divle and Kargı have been introduced in previous studies. Cheese properties vary according to geographical features of the region in which the milk animals are fed, such as geology, climate, pedology and topography, natural microbial and botanical flora, and production methods (Karoui et al. 2005KAROUI R, BOSSET JO, MAZEROLLES G, KULMYRZAEV A and DUFOUR E. 2005. Monitoring the geographic origin of both experimental French Jura hard cheeses and Swiss Gruyère and L’Etivaz PDO cheeses using mid-infrared and fluorescence spectroscopies: a preliminary investigation. Int Dairy J 15: 275-286.). Söğle cheese is a type of tulum cheese, however the milk used in the production of Söğle cheese is not used in the production of any other tulum cheese types. Therefore, because of the composition of milk used in production of Söğle cheese and some differences in its production method (e.g. ripening in wells located in Söğle plateau for three months and heat treatment by using wood fire), Söğle cheese has its own characteristics which make it different from other tulum cheese types. To the best of our knowledge, there is no study in the scientific literature that has focused on Söğle cheese. The aim of this study was to investigate the physicochemical and microbiological properties, fatty acid composition and volatile profile of Söğle cheese.

Figure 1
Location map for cheese sampling (Antalya, Turkey) (a), Elmalı in Antalya (b), Küçük Söğle and Büyük Söğle villages in Elmalı (c).

MATERIALS AND METHODS

MATERIALS

Five different Söğle cheeses (C1, C2, C3, C4, and C5) ripened for three months in wells located in Söğle plateau (altitude of 1400 m, Elmalı, Antalya) were collected from different local producers in Büyük Söğle and Küçük Söğle villages in October 2017. Sample photographs of collected cheeses C1 and C4 produced in Büyük Söğle and Küçük Söğle villages are given in Figure 2. The cheeses C1, C2 and C3 were produced with a mixture of goat’s (80%) and sheep’s milk (20%) while the cheeses C4 and C5 were produced with goat milk (100%). All milks used in Söğle cheese production were skimmed by centrifugation. The cheeses were individually vacuum packed after purchase and stored at 4°C until analysis carried out.

Figure 2
Photographs of collected Söğle tulum cheeses C1 (a) and C4 (b) produced in Büyük Söğle and Küçük Söğle villages, Elmalı, Antalya, Turkey.

PHYSICOCHEMICAL ANALYSES

The cheese samples were analyzed for total solids by the gravimetric method, and for fat by the Gerber method (Turkish Standards Institute 1995TURKISH STANDARDS INSTITUTE. 1995. Turkish standard for white brined cheese. TS 591, Ankara.). The pH values of the cheeses were measured using a pH-meter (6173 pH, Jenco, USA) and the titratable acidity was determined as % lactic acid according to Turkish Standards (Turkish Standards Institute 1995TURKISH STANDARDS INSTITUTE. 1995. Turkish standard for white brined cheese. TS 591, Ankara.). The measurement of salt contents in the cheese samples was carried out by the Mohr titration method (Turkish Standards Institute 1995TURKISH STANDARDS INSTITUTE. 1995. Turkish standard for white brined cheese. TS 591, Ankara.), and total nitrogen contents of the cheeses were determined by the Dumas method by the Dumatherm analyzer (Gerhardt GmbH & Co. KG, Königswinter, Germany). Protein content was calculated by using the factor 6.38.

FATTY ACID ANALYSIS

Fat from the cheese samples was extracted according to the method of Renner (1993)RENNER E. 1993. Milchpraktikum Skriptum zu den Übüngen, Giesen: Justus Liebig Universitat, p. 76.. Cheese samples (about 20 g) were ground with 6-8 g of kieselguhr (Fluka Chemie GmbH, Buchs, Switzerland) and mixed with 200 mL diethyl ether (Fluka Chemie GmbH, Buchs, Switzerland). The mixture was blended for 1 min and was filtered using rough filter paper (0.18 mm in thickness, 82 g/m2 in weight). The filtered solution (diethyl ether-lipid extracts) was concentrated using a rotary evaporator (Scilogex, USA) at 40°C under vacuum to a final volume of approximately 1-3 mL for analysis. The lipid extracts were flushed with nitrogen until dry, and stored at -20°C for further analysis in glass vials. Fatty acid methyl esters (FAMEs) were prepared according to Yilmazer and Secilmis (2006)YILMAZER M and SECILMIS H. 2006. Investigation of the derivatization conditions of some free fat acids in methanolic HCl medium. In: III National Analytical Chemistry Congress, Proceedings, Çanakkale, p. 422-424.. One mL of 1.5 M methanolic HCl was added to extracted fat sample (200 µL) and kept at 80°C for two hours. Then, it was cooled to room temperature and 0.5 mL water was added, and the FAMEs were extracted using 1 mL hexane. Fatty acids analysis was carried out using an Agilent 78890A (Agilent Technologies, Wilmington, DE, USA) gas chromatograph equipped with a Agilent 5975 C (Agilent Technologies, Wilmington, DE, USA) quadrapole mass spectrometer detector (MS) operated in the electron impact ionization mode at 70 eV. Fragment ions were analyzed over 30-500 m/z mass range in scan mode. Analysis was performed with a CP-SIL 88 fused silica capillary column for FAME (100 m x 0.25 mm i.d., 0.2 µm film thickness; Chrompack, Midelburg, The Netherlands). The injection volume was 1 µL. Injector and detector temperatures were 240°C. Helium was used as the carrier gas and the flow rate was 1mL/min. Temperature of column oven was programmed to 60°C for 4 min, from 60 to 175°C at 13°C/min for 27 min, from 175 to 215°C at 4°C/min for 5 min, 215 to 240°C at 4°C/min for 15 min. The split ratio was set to 1:20. Data handling was performed using MSDCHEM software. Standard mix of FAMEs (Supelco® 37 Component FAME Mix, Cat. No. 47885 U) was obtained from Sigma-Aldrich (Interlab A.S., Istanbul, Turkey).

VOLATILE COMPOUND ANALYSIS

Grated cheese sample (3 g) was placed in 15 mL glass vial with PTFE/silicone septa (Supelco, 27159) and the vial was kept in a water bath at 45°C for 15 min. The volatile compounds of the sample were adsorbed from headspace of vial by Carboxen®/Polydimethylsiloxane (CAR/PDMS) 75 μm fibre with a manual holder (Supelco, Cat No.: 57318, Bellefonte, Pennsylvania, USA) at 45°C for 30 min. The fibre was properly conditioned before the initial use in GC injector according to the instructions provided by the manufacturer. After sampling the SPME, fibre was immediately thermally desorbed into the GC injection port. A desorption time of 5 min at 250°C was adopted. The volatiles were analyzed by a Shimadzu GC-MS-QP2010 SE (Shimadzu Co., Kyoto, Japan) gas chromatography-mass spectrometry (GC-MS) equipped with low-polarity Rxi-5Sil MS fused-silica column (30 m×0.25 mm internal diameter (id)×0.25 μm film thickness (df), Cat No.: 13623; Restek Corp., Bellefonte, PA, USA). Injector and detector temperatures were 250°C. Helium was used as the carrier gas and the flow rate was 1.61 mL/min. The injection was performed in split mode with a split ratio of 10:1. Temperature of column oven was set to increasing from 40°C (2 min holding time) to 250°C at the rate of 4°C/min (5 min holding time at 250°C). MS detector was operated in the electron impact ionization mode at 70 eV. The mass spectra of the individual volatile compounds were compared to those provided by the National Institute of Standards and Technology (NIST) library, Wiley, Tutor, Flavor and Fragrance Natural and Synthetic Compounds (FFNSC).

MICROBIOLOGICAL ANALYSES

Ten gram of cheese samples were diluted with 90 mL sterile Ringer solution (1/4 strength) in a polyethylene bag and homogenized using a Stomacher (Seward 80 Biomaster, Seward Limited, West Sussex, United Kingdom). Serial dilutions were made and appropriate dilutions were plated onto the selective media. The number of total aerobic mesophilic bacteria in the cheese samples was determined on Plate Count Agar (PCA) incubated aerobically at 30°C for 48 h. The counts of lactobacilli and lactococci in the samples were measured with MRS (de Man, Rogosa and Sharpe) Agar at 35°C for 72 h and with M17 Agar at 37°C for 48 h, respectively. Yeasts and molds were enumerated using Potato Dextrose Agar (PDA) incubated aerobically at 24°C for five days (Karagozlu et al. 2009KARAGOZLU C, KILIC S and AKBULUT N. 2009. Some characteristics of Cimi Tulum cheese from producing goat milk. Bulg J Agric Sci 15(4): 292-297.).

RESULTS AND DISCUSSION

The pH and titratable acidity values and the total solids (TS), fat, fat in TS, protein, protein in TS, salt and salt in TS contents of the Söğle cheeses are given in Table I. The pH and titratable acidity values of the Söğle cheese samples ranged from 4.9 to 5.5 and from 1.4 to 2.6%, respectively. The results of the pH measurements in the samples are in agreement with other researches, while the titratable acidity values in 3 of 5 samples were higher than the values reported in other studies (Tarakci and Durmus 2016TARAKCI Z and DURMUS Y. 2016. Effects of packaging materials on some ripening characteristics of Tulum cheese. Mljekarstvo 66: 293-303., Sert et al. 2014SERT D, AKIN N and AKTUMSEK A. 2014. Lipolysis in Tulum cheese produced from raw and pasteurized goats’ milk during ripening. Small Rum Res 121: 351-360.). Lactic acid bacteria, which are naturally present in raw milk, can produce high concentration of lactic acid from lactose that results in an increase in the acidity of cheese (Gurses and Erdogan 2006GURSES M and ERDOGAN A. 2006. Identification of lactic acid bacteria isolated from Tulum cheese during ripening period. Int J Food Prop 9: 551-557.). Dinkci et al. (2007)DINKCI N, AKALIN AS, GONÇ S and UNAL G. 2007 Isocratic reverse-phase HPLC for determination of organic acids in Kargi tulum cheese. Chromatographia 66(Suppl 1): 45-49. presented that levels of citric acid, acetic acid, propionic acid and formic acid were unexpectedly high in Kargı tulum cheese due to the heterofermentative metabolism of non-starter microbiota that can produce some organic acids from lactose and lactic acid. In our study, TS contents of the Söğle cheese samples varied from 46.5 to 55.0%, as shown in Table I. Hayaloglu et al. (2007) have reported that the average TS contents of tulum cheeses ripened in plastic or goat’s skin bags for 90 days were between 51.0 and 61.4%. The TS contents of tulum cheeses should be higher than 55% according to the regulation for tulum cheese prescribed by Turkish Food Codex (Ministry of Agriculture and Forestry 2015MINISTRY OF AGRICULTURE and FORESTRY. 2015. Turkish food codex cheese notification. Ankara, Turkey: No. 2015/6.). The TS contents in 4 out of 5 Söğle cheese samples were lower than the limit set by the Turkish Food Codex. The mean fat and fat in TS contents of Söğle cheese samples varied from 2.0 to 4.5% and from 3.6 to 9.3%, respectively. The fat in TS contents determined in Söğle cheese samples were lower than those reported by some authors, including Hayaloglu et al. (2007), Dinkci et al. (2012)DINKCI N, UNAL G, AKALIN AS, VAROL S and GONC S. 2012. Kargı tulum peynirinin kimyasal ve mikrobiyolojik özellikleri. Ege Univ Zir Fak Derg 49: 287-292. and Sengul et al. (2014). Söğle cheese can be considered as a variety of fat-free cheese, because cheese with fat in TS less than 10% is classified as fat-free cheese, according to the regulation of Turkish Food Codex for tulum cheese (Ministry of Agriculture and Forestry 2015MINISTRY OF AGRICULTURE and FORESTRY. 2015. Turkish food codex cheese notification. Ankara, Turkey: No. 2015/6.). Thus, the low TS contents in Söğle cheese samples were associated with the low fat contents in them. The protein contents in Söğle cheese samples ranged from 34.9 to 42.2%. Protein contents of the Söğle cheese samples were found to be higher than those reported in previous studies (Bayar and Özrenk 2011BAYAR N and OZRENK E. 2011. The effect of quality properties on Tulum cheese using different package materials. Afr J Biotechnol 10(8): 1393-1399., Sengul et al. 2014SENGUL M, ERKAYA T, DERVISOGLU M, AYDEMIR O and GUL O. 2014. Compositional, biochemical and textural changes during ripening of Tulum cheese made with different coagulants. Int J Dairy Technol 67: 373-383., Tarakci and Durmus 2016TARAKCI Z and DURMUS Y. 2016. Effects of packaging materials on some ripening characteristics of Tulum cheese. Mljekarstvo 66: 293-303., Celik and Tarakci 2017CELIK OF and TARAKCI Z. 2017. The effects of starter cultures on chemical, biochemical and sensory properties of low-fat Tulum cheeses during ripening. Int J Dairy Technol 70: 1-9.).

TABLE I
Physicochemical characteristics of Söğle cheese samples ripened for three months (n = 2)*.

Salt contents affect microbial and enzymatic activities in cheese by controlling water activity, and change the biochemical, textural and sensory properties of cheese during ripening (Guinee 2004GUINEE TP. 2004. Salting and the role of salt in cheese. Int J Dairy Technol 57: 99-109.). Salt and salt in TS of Söğle cheese samples ranged from 4.1 to 8.2% and from 8.6 to 15.0%, respectively. According to the Turkish Food Codex Regulation, the amount of salt in TS should be less than 5% in tulum cheeses (Ministry of Agriculture and Forestry 2015). Salt in TS content of the Söğle cheese samples were found to be higher than the limit value prescribed by the Turkish Food Codex. This may be due to the fact that Söğle cheese is produced by a different method than other tulum cheeses.

Fatty acid (FA) compositions of lipid fraction from cheese samples are given in Table II. Free fatty acids (FFA), especially short- and medium-chain fatty acids, which are the result of lipolysis in cheese, directly contribute to the cheese flavor (Park 2001PARK YW. 2001. Proteolysis and lipolysis of goat milk cheese. J Dairy Sci 84: 84-92.). Short and medium chain fatty acids in four Söğle cheese samples were listed as capric acid (C10:0), caprylic acid (C8:0), caproic acid (C6:0) and butyric acid (C4:0) according to their contents. These results are in agreement with the results of Sengul et al. (2014), who reported that capric acid was the main short chain FFA present in the tulum cheese samples produced with different coagulants. Palmitic acid (C16:0), oleic acid (C18:1 n-9), myristic acid (C14:0) and stearic acid (C18:0) were the long chain fatty acids with the highest ratios in Söğle cheese samples. Palmitic acid was found to be a major fatty acid in all Söğle cheese samples. Similar results were reported by Sert et al. (2014) where the contents of palmitic acid were the highest with 28.87 and 28.80% of total FAs contents in 90-day-ripened tulum cheeses produced by using raw and pasteurized goat’s milk, respectively. The values of saturated short and medium-chain (C4:0 to C12:0) FAs content of milk fat in Söğle cheese samples ranged from 16.83% to 25.07% with an average of 21.99%. Yilmaz et al. (2005)YILMAZ G, AYAR A and AKIN N. 2005. The effect of microbial lipase on the lipolysis during the ripening of Tulum cheese. J Food Eng 69: 269-274. have reported the average values for the sum of short (C4:0-C8:0) and medium-chain (C10:0-C14:0) fatty acids for tulum cheeses with microbial lipase at different ratios as 24-25g/100g cheese and 21-22g/100g cheese, respectively. Similarly, reported values for the sum of saturated short and medium-chain (C4 to C12) FAs of 15 Uruguayan goat cheese samples ranged from 13.50% to 27.70% (20.70% average) (Vieitez et al. 2016)VIEITEZ I, IRIGARAY B, CALLEJAS N, GONZALEZ V, GIMEREZ S, ARECHAVALETA A, GROMPONE M and GAMBARO A. 2016. Composition of fatty acids and triglycerides in goat cheeses and study of the triglyceride composition of goat milk and cow milk blends. J Food Compost Anal 48: 95-101.. In terms of long chain fatty acids, the average content of the sum of saturated fatty acids (C14:0-C20:0) for five Söğle cheese samples was about 50% of total FAs contents. Karagozlu et al. (2009) have reported similar ratios for the sum of saturated C14:0-C20:0 fatty acids in Cimi tulum cheeses. As indicated in Table II, SFAs and MUFAs in the Söğle cheeses were determined to be respectively 69.9-75.0% and 18.2-22.3%. Our results are also agreement with the results of Kinik et al. (2005)KINIK O, GURSOY O and SECKIN AK. 2005. Cholesterol content and fatty acid composition of most consumed Turkish hard and soft cheeses. Czech J Food Sci 23: 166-172..

TABLE II
Fatty acid compositions (g/100g of total fatty acids) of Söğle cheese samples ripened for three months (n = 2)*.

A total of 53 volatile compounds were detected by SPME-GC-MS analysis in all cheese samples, and were classified into the following chemical groups: esters (5.74%), acids (10.66%), ketones (43.63%), aldehydes (0.38%), alcohols (8.83%), terpenes (29.61%) and miscellaneous (1.16%) (Table III). Ketones and terpenes were the predominant volatile compounds. Carboxylic acid contents and esters were relatively low in the studied cheeses due to their low fat contents.

TABLE III
Relative abundance (%) of volatile compounds isolated from Söğle cheese samples (n = 2).

Ketones, which have typical odors and low perception thresholds (Bontinis et al. 2012), are the products of lipid degradation formed by β-oxidation and decarboxylation of fatty acids (Poveda et al. 2008). Seven ketones were identified in Söğle cheese samples with 2-butanone being the most abundant compound in all cheese samples (Table III). 2-Butanone was previously detected as the major ketone compound in different goat milk cheeses including Gokceada (Hayaloglu et al. 2013bHAYALOGLU AA, YASAR K, TOLU C and SAHINGIL D. 2013b. Characterizing volatile compounds and proteolysis in Gokceada artisanal goat cheese. Small Rum Res 113: 187-194.), Xinotyri (Bontinis et al. 2012), Ibores (Delgado et al. 2011) and Teleme (Massouras et al. 2006MASSOURAS T, PAPPA EC and MALLATOU H. 2006. Headspace analysis of volatile flavour compounds of teleme cheese made from sheep and goat milk. Int J Dairy Technol 59: 250-256.). 2-Butanone is responsible for the buttery odor, and it derives from 2,3-butanedione (diacetyl) during lactose or citrate metabolism by microorganisms (McSweeney and Sousa 2000MCSWEENEY PLH and SOUSA MJ. 2000. Biochemical pathways for the production of flavour compounds in cheese during ripening: a review. Lait 80: 293-324., Hayaloglu et al. 2013aHAYALOGLU AA, TOLU C, YASAR K and SAHINGIL D. 2013a. Volatiles and sensory evaluation of goat milk cheese Gokceada as affected by goat breeds (Gokceada and Turkish Saanen) and starter culture systems during ripening. J Dairy Sci 96: 2765-2780.). 2-Heptanone, 2-nonanone and 3-hydroxy-2-butanone (acetoin) were also detected in most of the studied cheeses (Table III). These ketones have been detected in different goat cheese types (Le Quéré et al. 1998LE QUÉRÉ JL, PIERRE A, RIAUBLANC A and DEMAIZIÈRES D. 1998. Characterization of aroma compounds in the volatile fraction of soft goat cheese during ripening. Lait 78: 279-290., Poveda et al. 2008POVEDA JM, SANCHEZ-PALOMO E, PEREZ-COELLO MS and CABEZAS L. 2008. Volatile composition, olfactometry profile and sensory evaluation of semi-hard Spanish goat cheeses. Dairy Sci Technol 88: 355-367., Boltar et al. 2016BOLTAR I, ČANŽEK MAJHENIČ A, JUG T, MUJIĆ I, JOKIĆ S and BAVCON KRALJ M. 2016. The impact of some parameters on volatile compounds in hard type cheeses. Croat J Food Sci and Technol 8(2): 74-82.).

Terpenes are secondary plant metabolites that are ingested by herbivores and subsequently found in associated animal-origin foods including milk. Terpene content of forage varies greatly according to the plant species (Cornu et al. 2005). Therefore, terpenes are important for determining the geographical origin of a cheese (Cornu et al. 2005CORNU A, KONDJOYAN N, MARTIN B, VERDIER-METZ I, PRADEL P, BERDAGUÉ JL and COULON JB. 2005. Terpene profiles in Cantal and Saint-Nectaire-type cheese made from raw or pasteurised milk. J Sci Food Agric 85: 2040-2046., Bontinis et al. 2012BONTINIS THG, MALLATOU H, PAPPA EC, MASSOURAS TH and ALICHANIDIS E. 2012. Study of proteolysis, lipolysis and volatile profile of a traditional Greek goat cheese (Xinotyri) during ripening. Small Rumin Res 105: 193-201.). Twelve terpenes were identified in the cheeses with a mean percentage of 29.61±8.89. Limonene was the most abundant (from 17.11 to 31.11%) terpene compound in all cheeses. High limonene content was found in soft raw goat cheese by Sablé et al. (1997)SABLÉ S, LETELLIER F and COTTENCEAU G. 1997. An analysis of the volatile flavor compounds in a soft raw goat milk cheese. Biotechnol Lett 19: 143-146.. Limonene has been reported to be associated with citrus-like flavor in some cheeses (Nogueira et al. 2005NOGUEIRA MCL, LUBACHEVSKY G and RANKIN SA. 2005. A study of the volatile composition of Minas cheese. LWT-Food Sci Technol 38: 555-563.). Limonene were also found at low levels in 60-day- ripened Gokceada goat milk cheeses and 90-day-ripened Ibores goat milk cheeses studied by Hayaloglu et al (2013b) and Delgado et al. (2011), respectively. β-myrcene, p-cymene, β-pinene and γ –terpinene were detected in all the cheese samples (Table III). Similarly, β-myrcene, α- and β-pinene and caryophyllene were determined in traditional Greek goat cheese Xinotyri (Bontinis et al. 2012). The differences in terpene profiles of Söğle cheese samples in this research may be explained by the differences in consumed herbs by the small ruminants, differences in cheese production steps and microbial flora differences among the cheeses (Cornu et al. 2005CORNU A, KONDJOYAN N, MARTIN B, VERDIER-METZ I, PRADEL P, BERDAGUÉ JL and COULON JB. 2005. Terpene profiles in Cantal and Saint-Nectaire-type cheese made from raw or pasteurised milk. J Sci Food Agric 85: 2040-2046.).

It was well known that carboxylic acids were formed by three main biochemical pathways (proteolysis, lipolysis and glycolysis) during cheese ripening (McSweeney and Sousa 2000). Carboxylic acids were the third most abundant volatile compounds isolated from the Söğle cheeses at the end of 90-day ripening period. Five carboxylic acids were detected and acetic acid was the most abundant carboxylic acid (ranging from 4.93 to 11.20%) in all the cheese samples. Acetic acid was also detected as the most abundant carboxylic acid in different goat milk cheeses including starter-free Gokceada goat cheese (Hayaloglu et al. 2013b) and Xinotyri cheese (Bontinis et al. 2012). Butanoic (rancid), hexanoic (sour/dirty/sweet), octanoic (sweaty/fatty/rancid/goat) and decanoic (waxy/rancid/cheese/dry) acids, which are formed by lipolysis and contribute to cheese flavor (Poveda et al. 2008POVEDA JM, SANCHEZ-PALOMO E, PEREZ-COELLO MS and CABEZAS L. 2008. Volatile composition, olfactometry profile and sensory evaluation of semi-hard Spanish goat cheeses. Dairy Sci Technol 88: 355-367., Ozmen Togay et al. 2017OZMEN TOGAY S, GUNESER O and KARAGUL YUCEER Y. 2017. Evaluation of physicochemical, microbiological, sensory properties and aroma profiles of goat cheeses provided from Canakkale. Int J Dairy Technol 70: 514-525.), were also detected in the cheese samples. These fatty acids have been identified in different goat cheeses previously (Carunchia Whetstine et al. 2003CARUNCHIAWHETSTINE ME, KARAGUL-YUCEER Y, AVSAR YK and DRAKE MA. 2003. Identification and quantification of character aroma components in fresh Chevre-style goat cheese. J Food Sci 68: 2441-2447., Chiofalo et al. 2004CHIOFALO B, ZUMBO A, COSTA R, LIOTTA L, MONDELLO L, DUGO P and CHIOFALO V. 2004. Characterization of Maltese goat milk cheese flavor using SPME-GC/MS. S Afr J Anim Sci 34(Suppl. 1): 176-180., Ozmen Togay et al. 2017OZMEN TOGAY S, GUNESER O and KARAGUL YUCEER Y. 2017. Evaluation of physicochemical, microbiological, sensory properties and aroma profiles of goat cheeses provided from Canakkale. Int J Dairy Technol 70: 514-525.).

Esters are significant cheese flavor contributors due to their high volatility at ambient temperatures (Bontinis et al. 2012). They are formed by the esterification of short- to medium-chain fatty acids and primary and secondary alcohols (Engels et al. 1997). Thirteen ester compounds were detected in Söğle cheese samples, and constituted 2.02-7.40% of the total volatile fraction. The most abundant esters were ethyl esters; ethyl decanoate, ethyl octanoate and ethyl hexanoate were present in all studied cheese samples. Ethyl butanoate (0.11-2.13%) was also detected in the cheese samples except cheese sample C2 (Table III). Ethyl esters were also the predominant esters found in different goat cheeses such as Maltese (Chiofalo et al. 2004), semi-hard Spanish goat cheese (Poveda et al. 2008) and Gokceada artisanal goat cheese (Hayaloglu et al. 2013b). Ethyl laurate was detected in three Söğle cheese samples. This compound is the ester of ethyl alcohol and lauric acid and has a light, fruity odor (Winter 2009WINTER R. 2009. A consumer’s dictionary of food additives. 7th ed., New York: Three Rivers Press, 608 p.). Ethyl laurate was also identified in Sicilian goat cheese by Mondello et al. (2005). Esters detected in cheese are described as having sweet, fruity (especially ethyl esters) with floral notes at low concentrations and yeasty notes at high concentrations (Engels et al. 1997ENGELS WJM, DEKKER R, DE JONG C, NEETER R and VISSER S. 1997. A comparative study of volatile compounds in the water-soluble fraction of various types of ripened cheese. Int Dairy J 7: 255-263., Curioni and Bosset 2002CURIONI PMG and BOSSET JO. 2002. Key odorants in various cheese types as determined by gas chromatography-olfactometry. Int Dairy J 12: 959-984., Delgado et al. 2011DELGADO FJ, GONZALEZ-CRESPO J, CAVA R and RAMIREZ R. 2011. Formation of the aroma of a raw goat milk cheese during maturation analysed by SPME-GC-MS. Food Chem 129: 1156-1163.). Esters can contribute to cheese flavor by minimizing the sharpness imparted by fatty acids and the bitterness from amines (Curioni and Bosset 2002).

Aldehydes originate from amino acids either by transamination or Strecker degradation. They are transitory compounds and are not concentrate in cheese because they are rapidly transformed to alcohols or the corresponding acids (Hayaloglu et al. 2013a, b, Delgado et al. 2011). Only two aldehydes (benzaldehyde and/or 3-methyl propanal) were detected in three Söğle cheese samples. Benzaldehyde, which is responsible for bitter almond note, has been detected in some goat cheeses (Hayaloglu et al. 2013a, b, Kondyli et al. 2016KONDYLI E, PAPPA EC and SVARNAS C. 2016. Ripening changes of the chemical composition, proteolysis, volatile fraction and organoleptic characteristics of a white-brined goat milk cheese. Small Rum Res 145: 1-6.). The branched aldehyde 3-methylpropanal was listed amongst the odor compounds of Grana Padano cheese (Moio and Addeo 1998) and Blue cheese (Heath 1981HEATH HB. 1981. Source book of flavors. New York: AVI Book, 864 p.). According to Moio and Addeo (1998)MOIO L and ADDEO F. 1998. Grana Padano cheese aroma. J Dairy Res 65: 317-333., very low levels of aldehydes in cheeses indicated a regular ripening and their higher levels are responsible for serious off-flavor.

A total of five alcohols were detected in ripened Söğle cheeses. Ethanol had the highest level among the total volatile fraction of cheese samples with 4.88-10.66%. Ethanol was also detected as most abundant alcohol compound in numerous goat milk cheeses (Sablé et al. 1997SABLÉ S, LETELLIER F and COTTENCEAU G. 1997. An analysis of the volatile flavor compounds in a soft raw goat milk cheese. Biotechnol Lett 19: 143-146., Mondello et al. 2005MONDELLO L, COSTA R, TRANCHIDA PQ, CHIOFALO B, ZUMBO A, DUGO P and DUGO G. 2005. Determination of flavor components in Sicilian goat cheese by automated HS-SPME-GC. Flavour Fragr J 20: 659-665., Massouras et al. 2006MASSOURAS T, PAPPA EC and MALLATOU H. 2006. Headspace analysis of volatile flavour compounds of teleme cheese made from sheep and goat milk. Int J Dairy Technol 59: 250-256., Bontinis et al. 2012BONTINIS THG, MALLATOU H, PAPPA EC, MASSOURAS TH and ALICHANIDIS E. 2012. Study of proteolysis, lipolysis and volatile profile of a traditional Greek goat cheese (Xinotyri) during ripening. Small Rumin Res 105: 193-201.). Ethanol, which plays a significant role in formation of esters, is mostly produced by the fermentation of lactose and by the catabolism of alanine (Hayaloglu et al. 2013b). 3-methyl-1-butanol, a branched-chain primary alcohol, was identified in low abundance in all the cheese samples in our study. 3-methyl-1-butanol, which have lower detection thresholds (Delgado et al. 2011), is formed by the reduction of the aldehyde produced from leucine (Curioni and Bosset 2002) and gave a fruity/floral note (Sablé et al. 1997). It was identified in different goat milk cheeses (Delgado et al. 2011DELGADO FJ, GONZALEZ-CRESPO J, CAVA R and RAMIREZ R. 2011. Formation of the aroma of a raw goat milk cheese during maturation analysed by SPME-GC-MS. Food Chem 129: 1156-1163., Hayaloglu et al. 2013a, Boltar et al. 2016). Small relative abundances of 2-heptanol, 2-nonanol and 2-phenethyl alcohol in some Söğle cheeses were determined. These alcohols were also detected in ewe’s milk cheeses ripened in tulums or plastic bags (Hayaloglu et al. 2007) and some other goat cheeses (Mondello et al. 2005MONDELLO L, COSTA R, TRANCHIDA PQ, CHIOFALO B, ZUMBO A, DUGO P and DUGO G. 2005. Determination of flavor components in Sicilian goat cheese by automated HS-SPME-GC. Flavour Fragr J 20: 659-665., Boltar et al. 2016BOLTAR I, ČANŽEK MAJHENIČ A, JUG T, MUJIĆ I, JOKIĆ S and BAVCON KRALJ M. 2016. The impact of some parameters on volatile compounds in hard type cheeses. Croat J Food Sci and Technol 8(2): 74-82.). Phenylethanol, is among the most odorous aromatic alcohols, is responsible for rose flower notes (Curioni and Bosset 2002).

Nine miscellaneous compounds were detected at very low percentages in four Söğle cheese samples. Styrene, which is responsible for a strong plastic odor, was detected only in two cheese samples. Six hydrocarbons, a phenolic compound (3-methyl phenol) and a sulfur compound (dimethyl disulfide) were also identified. Hydrocarbons are secondary products of lipid autoxidation and are precursors for aromatic compounds formation (Hayaloglu et al. 2007). Sulfur compounds, which are the result of degradation of methionine and cysteine, give garlic, onion, or very ripe cheese odors (Bontinis et al. 2012).

The results of some microbial properties of Söğle cheese samples are shown in Table IV. At the end of 90-day-ripening period, mean counts of Lactobacillus spp. and Lactococcus spp. in the cheese samples were found to be between 7.1 and 8.5 log cfu/g and 7.8 and 8.7 log cfu/g, respectively. Gurses and Erdogan (2006) reported that many of LAB isolated tulum cheese samples belong to the genus Lactobacillus, the number of Lactobacillus in the samples increased during the ripening period, and the number of other genera did not change in a significant amount. Lactococcus counts of Söğle cheese samples were higher than those found in some other tulum cheese samples, which were below 7 log cfu/g (Karagozlu et al. 2009KARAGOZLU C, KILIC S and AKBULUT N. 2009. Some characteristics of Cimi Tulum cheese from producing goat milk. Bulg J Agric Sci 15(4): 292-297., Oner et al. 2004ONER Z, SAGDIC O and SIMSEK B. 2004. Lactic acid bacteria profiles and tyramine and tryptamine contents of Turkish tulum cheeses. Eur Food Res Technol 219: 455-459.). However, Cakmakci et al. (2008)CAKMAKCI S, DAGDEMIR E, HAYALOGLU AA, GURSES M and GUNDOGDU E. 2008. Influence of ripening container on the lactic acid bacteria population in Tulum cheese. World J Microbiol Biotechnol 24: 293-299. stated that the Lactococcus species rapidly disappeared three months after the ripening period for tulum cheese samples. The total aerobic mesophilic bacteria counts ranged from 7.6 to 8.5 log cfu/g, while the counts of yeast and mould varied from 1.0 to 4.8 log cfu/g in Söğle cheese samples. These results are in agreement with the results of Karagozlu et al. (2009), who reported that average amounts were determined as 8.5 log cfu/g for total mesophilic bacteria and 1.6 log cfu/g for yeast in Cimi tulum cheeses. Oksuztepe et al. (2005)OKSUZTEPE G, PATIR B and CALICIOGLU M. 2005. Identification and distribution of lactic acid bacteria during the ripening of Şavak tulum cheese. Turk J Vet Anim Sci 29: 873-879. found that the total aerobic mesophilic bacteria and yeast and mold counts in Savak tulum cheeses produced using raw sheep’s milk were 2.2x107 and 2.7x104 cfu/mL, respectively. The counts of total aerobic mesophilic bacteria in tulum cheeses packed in goat skin, plastic barrels and ceramic pots were 7.8, 6.8 and 5.9 log cfu/g, respectively (Ceylan et al. 2007CEYLAN ZG, CAGLAR A and CAKMAKCI S. 2007. Some physicochemical, microbiological, and sensory properties of tulum cheese produced from ewe’s milk via a modified method. Int J Dairy Technol 60(3): 191-197.). These differences in microbiological properties in tulum cheeses, including Söğle cheese, could be related to the production methods, storage time and conditions, chemical composition and acidity of the cheeses, and the interaction between the microorganisms, as well as raw milk microflora used in cheese production.

TABLE IV
Microbiological properties of Söğle cheese samples after ripening period of three months (n = 2)*.

CONCLUSIONS

As the first scientific study on traditional Söğle cheese, physicochemical and microbiological properties, fatty acid composition and volatile profile of five different Söğle cheeses ripened for three months were presented in this paper. In general, chemical composition parameters such as TS, salt, salt in TS, fat, fat in TS, protein and protein in TS in the Söğle cheese samples were different from those of other tulum cheeses due to differences in the production process and/or chemical and microbiological properties of milk used for cheese production. Capric acid and palmitic acid were the main short and long chain FFAs, respectively in all the Söğle cheese samples, while the fatty acid compositions of all the cheese samples were quite different among them. Ketones and terpenes were the predominant volatile chemical components in the isolated fifty three compounds. Like other tulum cheeses such as Savak, Divle and Cimi tulum cheeses, Lactobacillus and Lactococcus spp. constituted the dominant microflora. Söğle cheese with low fat content may be appealing to tulum cheese consumers who prefer foods low in fat content. Although Söğle cheese is locally produced and sold at relatively higher prices, there is a need for standardized production process for Söğle cheese to expand its production and consumption. Therefore, future studies should focus on establishing a standard production process for Söğle cheese.

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Publication Dates

  • Publication in this collection
    25 Oct 2018
  • Date of issue
    Oct-Dec 2018

History

  • Received
    26 Mar 2018
  • Accepted
    21 May 2018
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