Erzurum’un Farklı Coğrafi Bölgelerinden Elde Edilen Balların Kalite Değerlendirmesi ve Biyoaktif Bileşen Analizi
Yıl 2024,
Cilt: 22 Sayı: 3, 215 - 223, 18.12.2024
Adem Savaş
,
Halil İbrahim Binici
,
İhsan Güngör Şat
,
Mustafa Kiliç
Öz
Son yıllarda, toplumlar arasında sağlıklı ve işlevsel olarak algılanan gıdalara olan ilgide kayda değer bir artış olmuştur. İnsan beslenmesinde önemli bir rol oynayan balın bileşimi çeşitli faktörlerden etkilenmektedir. Bu çalışmanın amacı, on beş farklı bal örneğini çeşitli kalite kriterlerine göre analiz etmek ve 5-hidroksimetilfurfural (HMF) ve fenolik bileşen içeriklerini belirlemektir. Bu kapsamda Erzurum ili sınırları içerisinde yer alan beş farklı coğrafi bölgeden bal örnekleri temin edilmiştir. pH, nem, toplam şeker, indirgen şeker,sükroz, prolin, 5-hidroksimetilfurfural (HMF) ve fenolik bileşen değerleri arasında istatistiksel olarak önemli (P<0.05) bir fark olduğu tespit edilmiştir. Bal örneklerinin HMF içeriklerinin 5.20-108.12 mg/kg arasında, fenolik bileşen içeriklerinin ise nd-202.95 mg/kg arasında değiştiği belirlenmiştir. Bal örneklerinin HMF içeriklerinin Türk Gıda Kodeksi Bal Tebliği’ne (Tebliğ No: 2020/7) uygun olduğu belirlenirken, pirolin ve HMF içerikleri bakımından sadece bir örneğin kodeksle uyumlu olmadığı tespit edilmiştir.
Teşekkür
The author Mustafa Kılıç are supporting by the Council of Higher Education (CoHE, Yükseköğretim Kurulu, YÖK) with 100/2000 PhD Scholarship Project.
Kaynakça
- [1] Binici, H.İ., Savaş, A. (2024). The effects of lycopene on health and fields of use. Journal of Advanced Natural Sciences and Engineering Researches, 8(6), 158-161.
- [2] Savaş, A. (2024). Fındık meyvesinin besinsel içeriği üzerine kısa bir perspektif. Gıda Bilimi ve Mühendisliği Araştırmaları, 3(1), 100-103.
- [3] Geana, E.I., Ciucure, C.T. (2020). Establishing authenticity of honey via comprehensive Romanian honey analysis. Food Chemistry, 306, 125595.
- [4] Savaş, A., Oz, E., Oz, F. (2021). Is oven bag really advantageous in terms of heterocyclic aromatic amines and bisphenol-A? Chicken meat perspective. Food Chemistry, 355, 129646.
- [5] Se, K.W., Wahab, R.A., Yaacob, S.N.S., Ghoshal, S.K. (2019). Detection techniques for adulterants in honey: Challenges and recent trends. Journal of Food Composition and Analysis, 80, 16-32.
- [6] Wang, Y., Cai, W., Li, L., Gao, Y., Lai, K.H. (2023). Recent advances in the processing and manufacturing of plant-based meat. Journal of Agricultural and Food Chemistry, 71(3), 1276-1290.
- [7] Zhang, G., Abdulla, W. (2022). On honey authentication and adulterant detection techniques. Food Control, 108992.
- [8] Al-Kafaween, M.A., Alwahsh, M., Mohd Hilmi A.B., Abulebdah, D.H. (2023). Physicochemical characteristics and bioactive compounds of different types of honey and their biological and therapeutic properties: A comprehensive review. Antibiotics, 12(2), 337.
- [9] Hossain, M.L., Lim, L.Y., Hammer, K., Hettiarachchi, D., Locher, C. (2022). A review of commonly used methodologies for assessing the antibacterial activity of honey and honey products. Antibiotics, 11(7), 975.
- [10] Stagos, D., Soulitsiotis, N., Tsadila, C., Papaeconomou, S., Arvanitis, C. (2018). Antibacterial and antioxidant activity of different types of honey derived from Mount Olympus in Greece. International Journal of Molecular Medicine, 42(2), 726-734.
- [11] Pauliuc, D., Dranca, F., Oroian, M. (2020). Antioxidant activity, total phenolic content, individual phenolics and physicochemical parameters suitability for Romanian honey authentication. Foods, 9(3), 306.
- [12] Afrin, S., Giampieri, F., Gasparrini, M., Forbes-Hernández, T.Y., Cianciosi, D. (2018). The inhibitory effect of Manuka honey on human colon cancer HCT-116 and LoVo cell growth. Part 2: Induction of oxidative stress, alteration of mitochondrial respiration and glycolysis, and suppression of metastatic ability. Food & Function, 9(4), 2158-2170.
- [13] Tosi, E., Ciappini, M., Re, E., Lucero, H. (2002). Honey thermal treatment effects on hydroxymethylfurfural content. Food Chemistry, 77(1), 71-74.
- [14] Fallico, B., Zappala, M., Arena, E., Verzera, A. (2004). Effects of conditioning on HMF content in unifloral honeys. Food Chemistry, 85(2), 305-313.
- [15] Cianciosi, D., Forbes-Hernández, T.Y., Afrin, S., Gasparrini, M., Reboredo-Rodriguez, P. (2018). Phenolic compounds in honey and their associated health benefits: A review. Molecules, 23(9), 2322.
- [16] Mutlu, C., Erbaş, M., Arslan Tontul, S. (2017). Bal ve diğer arı ürünlerinin bazı özellikleri ve insan sağlığı üzerine etkileri. Akademik Gıda, 15(1), 75-83.
- [17] Uçar, M., Kemal, M., Kanbur, E.D., Kara, Y., Özcelik, A.E. (2023). The botanical, physicochemical, and biochemical characteristics of Northern Cyprus honeys. European Food Research and Technology, 249(6), 1531-1541.
- [18] Cemeroğlu, B.S. (2013). Meyve ve Sebze İşleme Teknolojisi. Bizim Grup Basımevi, Ankara, Türkiye, 312.
- [19] International Honey Commission. (2009). Harmonised methods of the international honey commission. URL< http://www. bee-hexagon. net/en/network. htm> Accessed, 23, 16. International Honey Commission. (2009). Harmonised methods of the international honey commission. URL< http://www. bee-hexagon. net/en/network. htm> Accessed, 23, 16.
- [20] Alwazeer, D., Elnasanelkasim, M.A., Çi̇çek, S., Engin, T., Çiğdem, A., Karaoğul, E. (2023). Comparative study of phytochemical extraction using hydrogen-rich water and supercritical fluid extraction methods. Process Biochemistry, 128, 218-226.
- [21] Kayacier, A, Karaman, S. (2008). Rheological and some physicochemical characteristics of selected Turkish honeys. Journal of Texture Studies, 39(1), 17-27.
- [22] Güzel, N., Bahçeci, K.S. (2020). Çorum yöresi̇ ballarinin bazi ki̇myasal kali̇te parametreleri̇nin değerlendi̇ri̇lmesi̇. Gıda, 45(2), 230-241.
- [23] Silva, L.R., Videira, R., Monteiro, A.P., Valentão, P., Andrade, P.B. (2009). Honey from Luso region (Portugal): Physicochemical characteristics and mineral contents. Microchemical Journal, 93(1), 73-77.
- [24] Ajlouni, S., Sujirapinyokul, P. (2010). Hydroxymethylfurfuraldehyde and amylase contents in Australian honey. Food Chemistry, 119(3), 1000-1005.
- [25] Khalil, M.I., Moniruzzaman, M., Boukraâ, L., Benhanifia, M., Islam, M.A., (2012). Physicochemical and antioxidant properties of Algerian honey. Molecules, 17(9), 11199-11215.
- [26] Machado, A.M., Tomás, A., Russo-Almeida, P., Duarte, A., Antunes, M. (2022). Quality assessment of Portuguese monofloral honeys. Physicochemical parameters as tools in botanical source differentiation. Food Research International, 157, 111362.
- [27] Massous, A., Ouchbani, T., Lo Turco, V., Litrenta, F., Nava, V. (2023). Monitoring Moroccan honeys: physicochemical properties and contamination pattern. Foods, 12(5), 969.
- [28] Nouri, M. (2023). The correlation of plant species and geographical regions on biological component and antioxidant potential of different honey. Journal of Food Biosciences and Technology, 13(1), 61-74.
- [29] Oroian, M., Ropciuc, S., Paduret, S. (2018). Honey authentication using rheological and physicochemical properties. Journal of food science and technology, 55, 4711-4718.
- [30] Özgüven, M., Demircan, E., Özçelik, B. (2020). Çeşitli yörelerimizde üretilen çiçek ballarının fizikokimyasal özelliklerinin belirlenmesi ve Türk Gıda Kodeksi’ne uygunluğunun değerlendirilmesi. Avrupa Bilim ve Teknoloji Dergisi, (20), 321-326.
- [31] Ecem Bayram, B.N., Kutlu, N., Gercek, Y.C. (2023). Utilization of response surface methodology in optimization of proline extraction from Castanea sativa honey. Chemistry & Biodiversity, 20(3), e202201092.
- [32] Turkish Food Codex. (2020) Turkish Food Codex Communiqué on Honey (No: 2020/7). (Access date: 10.03.2023).
- [33] Altunay, N. (2022). Experimental design of magnetic ionic liquid ultrasound-assisted dispersive liquid-liquid microextraction for the determination of 5-HMF in honey samples. Journal of Food Composition and Analysis, 114, 104817.
- [34] Tomczyk, M., Czerniecka-Kubicka, A., Miłek, M., Sidor, E., Dżugan, M. (2023). Tracking of thermal, physicochemical, and biological parameters of a long-term stored honey artificially adulterated with sugar syrups. Molecules, 28(4), 1736.
- [35] Ayoub, W.S., Zahoor, I., Dar, A.H., Farooq, S., Mir, T.A. (2023). Exploiting the polyphenolic potential of honey in the prevention of chronic diseases. Food Chemistry Advances, 3, 100373.
- [36] Becerril-Sánchez, A.L., Quintero-Salazar, B., Dublán-García, O., Escalona-Buendía, H.B. (2021). Phenolic compounds in honey and their relationship with antioxidant activity, botanical origin, and color. Antioxidants, 10(11), 1700.
- [37] Alshammari, G.M., Ahmed, M.A., Alsulami, T., Hakeem, M.J., Ibraheem, M.A., Al-Nouri, D.M. (2022). Phenolic compounds, antioxidant activity, ascorbic acid, and sugars in honey from ingenious hail province of Saudi Arabia. Applied Sciences, 12(16), 8334.
- [38] Andrade, P., Ferreres, F., Amaral, M.T. (1997). Analysis of honey phenolic acids by HPLC, its application to honey botanical characterization. Journal of Liquid Chromatography & Related Technologies, 20(14), 2281-2288.
- [39] Can, Z., Yildiz, O., Sahin, H., Turumtay, E.A., Silici, S. (2015). An investigation of Turkish honeys: Their physico-chemical properties, antioxidant capacities and phenolic profiles. Food Chemistry, 180, 133-141.
- [40] Pham, T.N., Nguyen, T.V., Le, D.T., Diep, L.M.N., Nguyen, K.N. (2022). Phenolic profiles, antioxidant, antibacterial activities and nutritional value of Vietnamese honey from different botanical and geographical sources. Agri Engineering, 4(4), 1116-1138.
- [41] Oz, E., Savaş, A., Ekiz, E, Oz, F. (2021). Mangalda pişirilmiş sebzelerin polisiklik aromatik hidrokarbon içeriği. Çukurova Tarım ve Gıda Bilimleri Dergisi, 36(1), 13-22.
- [42] Savaş A., Ekiz, E., Elbir, Z., Savaş, B.D., Proestos, C. (2023). Advantageous effects of sumac usage in meatball preparation on various quality criteria and formation of heterocyclic aromatic amines. Separations, 10(1), 29.
- [43] Savas, A., Oz, E., Elbir, Z., Oz, F. (2024). Effect of dry aging on quality parameters, protein profile and protein oxidation level of beef. International Journal of Food Science & Technology, 59(10), 7598-7609.
Quality Assessment and Bioactive Component Analysis of Honey from Different Geographical Regions in Erzurum, Türkiye
Yıl 2024,
Cilt: 22 Sayı: 3, 215 - 223, 18.12.2024
Adem Savaş
,
Halil İbrahim Binici
,
İhsan Güngör Şat
,
Mustafa Kiliç
Öz
In recent years, there has been an increasing interest on foods that are perceived to be healthy and functional among societies. The composition of honey, which plays an important role in human nutrition, is influenced by a number of factors. The aim of this study was to analyze fifteen different honey samples according to various quality criteria and to determine their 5-hydroxymethyl furaldehyde (HMF) and phenolic contents. In this context, honey samples were obtained from five distinct geographical regions within the Erzurum city area in Türkiye. There were statistically significant (P<0.05) differences in the pH, moisture, total sugar, reducing sugar, sucrose, proline, 5 (HF) and phenolic content values among the honey samples. HMF contents of samples varied between 5.20 and 108.12 mg/kg, and their phenolic contents ranged from non-detected to 202.95 mg/kg. While the HMF contents of honey samples were in accordance with the Turkish Food Codex Honey Communiqué (Communiqué No: 2020/7),with an exception of only one sample in terms of its proline and HMF contents.
Kaynakça
- [1] Binici, H.İ., Savaş, A. (2024). The effects of lycopene on health and fields of use. Journal of Advanced Natural Sciences and Engineering Researches, 8(6), 158-161.
- [2] Savaş, A. (2024). Fındık meyvesinin besinsel içeriği üzerine kısa bir perspektif. Gıda Bilimi ve Mühendisliği Araştırmaları, 3(1), 100-103.
- [3] Geana, E.I., Ciucure, C.T. (2020). Establishing authenticity of honey via comprehensive Romanian honey analysis. Food Chemistry, 306, 125595.
- [4] Savaş, A., Oz, E., Oz, F. (2021). Is oven bag really advantageous in terms of heterocyclic aromatic amines and bisphenol-A? Chicken meat perspective. Food Chemistry, 355, 129646.
- [5] Se, K.W., Wahab, R.A., Yaacob, S.N.S., Ghoshal, S.K. (2019). Detection techniques for adulterants in honey: Challenges and recent trends. Journal of Food Composition and Analysis, 80, 16-32.
- [6] Wang, Y., Cai, W., Li, L., Gao, Y., Lai, K.H. (2023). Recent advances in the processing and manufacturing of plant-based meat. Journal of Agricultural and Food Chemistry, 71(3), 1276-1290.
- [7] Zhang, G., Abdulla, W. (2022). On honey authentication and adulterant detection techniques. Food Control, 108992.
- [8] Al-Kafaween, M.A., Alwahsh, M., Mohd Hilmi A.B., Abulebdah, D.H. (2023). Physicochemical characteristics and bioactive compounds of different types of honey and their biological and therapeutic properties: A comprehensive review. Antibiotics, 12(2), 337.
- [9] Hossain, M.L., Lim, L.Y., Hammer, K., Hettiarachchi, D., Locher, C. (2022). A review of commonly used methodologies for assessing the antibacterial activity of honey and honey products. Antibiotics, 11(7), 975.
- [10] Stagos, D., Soulitsiotis, N., Tsadila, C., Papaeconomou, S., Arvanitis, C. (2018). Antibacterial and antioxidant activity of different types of honey derived from Mount Olympus in Greece. International Journal of Molecular Medicine, 42(2), 726-734.
- [11] Pauliuc, D., Dranca, F., Oroian, M. (2020). Antioxidant activity, total phenolic content, individual phenolics and physicochemical parameters suitability for Romanian honey authentication. Foods, 9(3), 306.
- [12] Afrin, S., Giampieri, F., Gasparrini, M., Forbes-Hernández, T.Y., Cianciosi, D. (2018). The inhibitory effect of Manuka honey on human colon cancer HCT-116 and LoVo cell growth. Part 2: Induction of oxidative stress, alteration of mitochondrial respiration and glycolysis, and suppression of metastatic ability. Food & Function, 9(4), 2158-2170.
- [13] Tosi, E., Ciappini, M., Re, E., Lucero, H. (2002). Honey thermal treatment effects on hydroxymethylfurfural content. Food Chemistry, 77(1), 71-74.
- [14] Fallico, B., Zappala, M., Arena, E., Verzera, A. (2004). Effects of conditioning on HMF content in unifloral honeys. Food Chemistry, 85(2), 305-313.
- [15] Cianciosi, D., Forbes-Hernández, T.Y., Afrin, S., Gasparrini, M., Reboredo-Rodriguez, P. (2018). Phenolic compounds in honey and their associated health benefits: A review. Molecules, 23(9), 2322.
- [16] Mutlu, C., Erbaş, M., Arslan Tontul, S. (2017). Bal ve diğer arı ürünlerinin bazı özellikleri ve insan sağlığı üzerine etkileri. Akademik Gıda, 15(1), 75-83.
- [17] Uçar, M., Kemal, M., Kanbur, E.D., Kara, Y., Özcelik, A.E. (2023). The botanical, physicochemical, and biochemical characteristics of Northern Cyprus honeys. European Food Research and Technology, 249(6), 1531-1541.
- [18] Cemeroğlu, B.S. (2013). Meyve ve Sebze İşleme Teknolojisi. Bizim Grup Basımevi, Ankara, Türkiye, 312.
- [19] International Honey Commission. (2009). Harmonised methods of the international honey commission. URL< http://www. bee-hexagon. net/en/network. htm> Accessed, 23, 16. International Honey Commission. (2009). Harmonised methods of the international honey commission. URL< http://www. bee-hexagon. net/en/network. htm> Accessed, 23, 16.
- [20] Alwazeer, D., Elnasanelkasim, M.A., Çi̇çek, S., Engin, T., Çiğdem, A., Karaoğul, E. (2023). Comparative study of phytochemical extraction using hydrogen-rich water and supercritical fluid extraction methods. Process Biochemistry, 128, 218-226.
- [21] Kayacier, A, Karaman, S. (2008). Rheological and some physicochemical characteristics of selected Turkish honeys. Journal of Texture Studies, 39(1), 17-27.
- [22] Güzel, N., Bahçeci, K.S. (2020). Çorum yöresi̇ ballarinin bazi ki̇myasal kali̇te parametreleri̇nin değerlendi̇ri̇lmesi̇. Gıda, 45(2), 230-241.
- [23] Silva, L.R., Videira, R., Monteiro, A.P., Valentão, P., Andrade, P.B. (2009). Honey from Luso region (Portugal): Physicochemical characteristics and mineral contents. Microchemical Journal, 93(1), 73-77.
- [24] Ajlouni, S., Sujirapinyokul, P. (2010). Hydroxymethylfurfuraldehyde and amylase contents in Australian honey. Food Chemistry, 119(3), 1000-1005.
- [25] Khalil, M.I., Moniruzzaman, M., Boukraâ, L., Benhanifia, M., Islam, M.A., (2012). Physicochemical and antioxidant properties of Algerian honey. Molecules, 17(9), 11199-11215.
- [26] Machado, A.M., Tomás, A., Russo-Almeida, P., Duarte, A., Antunes, M. (2022). Quality assessment of Portuguese monofloral honeys. Physicochemical parameters as tools in botanical source differentiation. Food Research International, 157, 111362.
- [27] Massous, A., Ouchbani, T., Lo Turco, V., Litrenta, F., Nava, V. (2023). Monitoring Moroccan honeys: physicochemical properties and contamination pattern. Foods, 12(5), 969.
- [28] Nouri, M. (2023). The correlation of plant species and geographical regions on biological component and antioxidant potential of different honey. Journal of Food Biosciences and Technology, 13(1), 61-74.
- [29] Oroian, M., Ropciuc, S., Paduret, S. (2018). Honey authentication using rheological and physicochemical properties. Journal of food science and technology, 55, 4711-4718.
- [30] Özgüven, M., Demircan, E., Özçelik, B. (2020). Çeşitli yörelerimizde üretilen çiçek ballarının fizikokimyasal özelliklerinin belirlenmesi ve Türk Gıda Kodeksi’ne uygunluğunun değerlendirilmesi. Avrupa Bilim ve Teknoloji Dergisi, (20), 321-326.
- [31] Ecem Bayram, B.N., Kutlu, N., Gercek, Y.C. (2023). Utilization of response surface methodology in optimization of proline extraction from Castanea sativa honey. Chemistry & Biodiversity, 20(3), e202201092.
- [32] Turkish Food Codex. (2020) Turkish Food Codex Communiqué on Honey (No: 2020/7). (Access date: 10.03.2023).
- [33] Altunay, N. (2022). Experimental design of magnetic ionic liquid ultrasound-assisted dispersive liquid-liquid microextraction for the determination of 5-HMF in honey samples. Journal of Food Composition and Analysis, 114, 104817.
- [34] Tomczyk, M., Czerniecka-Kubicka, A., Miłek, M., Sidor, E., Dżugan, M. (2023). Tracking of thermal, physicochemical, and biological parameters of a long-term stored honey artificially adulterated with sugar syrups. Molecules, 28(4), 1736.
- [35] Ayoub, W.S., Zahoor, I., Dar, A.H., Farooq, S., Mir, T.A. (2023). Exploiting the polyphenolic potential of honey in the prevention of chronic diseases. Food Chemistry Advances, 3, 100373.
- [36] Becerril-Sánchez, A.L., Quintero-Salazar, B., Dublán-García, O., Escalona-Buendía, H.B. (2021). Phenolic compounds in honey and their relationship with antioxidant activity, botanical origin, and color. Antioxidants, 10(11), 1700.
- [37] Alshammari, G.M., Ahmed, M.A., Alsulami, T., Hakeem, M.J., Ibraheem, M.A., Al-Nouri, D.M. (2022). Phenolic compounds, antioxidant activity, ascorbic acid, and sugars in honey from ingenious hail province of Saudi Arabia. Applied Sciences, 12(16), 8334.
- [38] Andrade, P., Ferreres, F., Amaral, M.T. (1997). Analysis of honey phenolic acids by HPLC, its application to honey botanical characterization. Journal of Liquid Chromatography & Related Technologies, 20(14), 2281-2288.
- [39] Can, Z., Yildiz, O., Sahin, H., Turumtay, E.A., Silici, S. (2015). An investigation of Turkish honeys: Their physico-chemical properties, antioxidant capacities and phenolic profiles. Food Chemistry, 180, 133-141.
- [40] Pham, T.N., Nguyen, T.V., Le, D.T., Diep, L.M.N., Nguyen, K.N. (2022). Phenolic profiles, antioxidant, antibacterial activities and nutritional value of Vietnamese honey from different botanical and geographical sources. Agri Engineering, 4(4), 1116-1138.
- [41] Oz, E., Savaş, A., Ekiz, E, Oz, F. (2021). Mangalda pişirilmiş sebzelerin polisiklik aromatik hidrokarbon içeriği. Çukurova Tarım ve Gıda Bilimleri Dergisi, 36(1), 13-22.
- [42] Savaş A., Ekiz, E., Elbir, Z., Savaş, B.D., Proestos, C. (2023). Advantageous effects of sumac usage in meatball preparation on various quality criteria and formation of heterocyclic aromatic amines. Separations, 10(1), 29.
- [43] Savas, A., Oz, E., Elbir, Z., Oz, F. (2024). Effect of dry aging on quality parameters, protein profile and protein oxidation level of beef. International Journal of Food Science & Technology, 59(10), 7598-7609.