Braz. J. Biol., 2016,  vol. 76, no. 2, pp. 396-401396396 http://dx.doi.org/10.1590/1519-6984.16714 Original Article Effects of seasonal variations and collection methods on the mineral composition of propolis from Apis mellifera Linnaeus Beehives E. A. Souzaa, R. Zaluskia, N. Veigab and R. O. Orsia* aNúcleo de Ensino, Ciência e Tecnologia em Apicultura Racional – NECTAR, Departamento de Produção Animal – FMVZ, Universidade Estadual Paulista – UNESP, Distrito de Rubião Jr., s/n, CEP 18618-000, Botucatu, SP, Brazil bDepartamento de Produção e Exploração Animal – FMVZ, Universidade Estadual Paulista – UNESP, Distrito de Rubião Jr., s/n, CEP 18618-000, Botucatu, SP, Brazil *e-mail: orsi@fmvz.unesp.br Received: August 14, 2014 – Accepted: March 17, 2015 – Distributed: May 31, 2016 Abstract The effects of seasonal variations and the methods of collection of propolis produced by Africanized honey bees Apis mellifera Linnaeus, 1758, on the composition of constituent minerals such as magnesium (Mg), zinc (Zn), iron (Fe), sodium (Na), calcium (Ca), copper (Cu), and potassium (K) were evaluated. Propolis was harvested from 25 beehives by scraping or by means of propolis collectors (screen, “intelligent” collector propolis [ICP], lateral opening of the super [LOS], and underlay method). During the one-year study, the propolis produced was harvested each month, ground, homogenized, and stored in a freezer at -10 ºC. Seasonal analyses of the mineral composition were carried out by atomic absorption spectrophotometry and the results were evaluated by analysis of variance (ANOVA), followed by Tukey-Kramer’s test to compare the mean values (p<0.05). The results showed that seasonal variations influence the contents of 5 minerals (Mg, Fe, Na, Ca, and Cu), and the propolis harvesting method affects the contents of 4 minerals (Mg, Zn, Fe, and Ca). Keywords: seasonality, macro- and micro-mineral, propolis collectors, spectrophotometry, quality. Efeitos de variações sazonais e métodos de coleta sobre a composição mineral de própolis de colmeias de Apis mellifera Linnaeus Resumo A influência da sazonalidade e de métodos de produção de própolis por abelhas africanizadas Apis mellifera Linnaeus, 1758, sobre a concentração de magnésio (Mg), zinco (Zn), ferro (Fe), sódio (Na), cálcio (Ca), cobre (Cu) e potássio (K) foram avaliados. 25 colmeias foram utilizadas, e a colheita de propolis ocorreu por raspagem ou a partir de coletores (tela, coletor de própolis “inteligente” – CPI, abertura lateral da melgueira – ALM e calço). Durante um ano a própolis foi colhida mensalmente, homogeneizada e armazenada em freezer a -10 ºC. A análise sazonal de minerais foi realizada por espectrofotometria de absorção atômica e os resultados avaliados por análise de variância (ANOVA) seguida do teste de Tukey-Kramer para comparação de médias (p<0,05). Os resultados demostraram que a sazonalidade afetou o conteúdo de cinco minerais (Mg, Fe, Na, Ca e Cu) e os métodos de coleta afetaram o conteúdo de quatro minerais (Mg, Zn, Fe e Ca). Palavras-chave: sazonalidade, macro e micro-minerais, coletores de própolis, espectrofotometria, qualidade. 1. Introduction Propolis, a gummy and balsamic substance, is a honeybee product obtained from resinous material. It is collected by bees from flowers, buds, and exudates of plants and is known to have a broad spectrum of biological properties (Mello and Hubinger, 2012; Toreti et al., 2013). The quality and amount of propolis produced are linked to seasonal variations, methods of collection (Inoue et al., 2007; Toreti et al., 2013), geographical diversity, plant sources, and bee species (Mello and Hubinger, 2012). The method of harvesting may affect the production of propolis in beehives, and depending on the stimulus for resin collection by the collectors, it may add excess beeswax to the propolis, thereby altering its mineral composition. Propolis is a well-known antioxidant used in the food and drug industry (Simões-Ambrosio et al., 2010; Toreti et al., 2013; Huang et al., 2014). The regional chemical composition of propolis can interfere in its biological properties (Simões-Ambrosio et al., 2010; Braz. J. Biol., 2016,  vol. 76, no. 2, pp. 396-401 397 Variation of mineral contents in propolis 397 Toreti et al., 2013; Bankova et al., 2014, Souza et al., 2014). The presence of phenolic compounds, steroids, terpenes, and amino acids in propolis has been extensively studied (Sawaya et al., 2011; Finger et al., 2014). Until 2000, over 300 chemical components belonging to the phytochemical classes flavonoids, terpenes, organic acids, and phenolics have been identified in propolis (Huang et al., 2014). Recently, some researchers investigated the inorganic constituents in propolis and found that its mineral composition varied according to the geographical zone. Korn et al. (2013) evaluated macro- and micro-minerals in natural propolis harvested in Bahia state in the northeast of Brazil, and they found that these propolis samples were not contaminated by potentially toxic species and were a good source of magnesium (Mg), calcium (Ca), potassium (K), and iron (Fe). Finger et al. (2014) studied the concentrations of 11 representative metals in some regions of the Paraná state in South Brazil, and they demonstrated that the concentrations of aluminum (Al), Ca, and Mg differed in some regions, which could be used to identify not only the geographical origin of propolis, and to identification of specific zones with environmental contamination. Similar studies have been undertaken in other countries such as those by Cantarelli et al. (2011) in Argentina, Gong et al. (2012) in China, and Bonvehí and Bermejo (2013) in Spain. The human body requires about 20 different minerals in order to function properly. These minerals are indispensable for the maintenance of life, growth, and reproduction (Máhán and Escott-Stump, 2004), and can be classified as macro-or micro-minerals. Macro-minerals such as Ca, Mg, K, sodium (Na), sulfur (S), chloride (Cl), and phosphorus (P) are needed in amounts higher than 100 mg/day. On the other hand, micro-minerals such as copper (Cu), zinc (Zn), Fe, iodine (I), selenium (Se), and manganese (Mn) are needed in amounts lower than 100 mg/day (Máhán and Escott-Stump, 2004). Micronutrient deficiencies, which result from a lack of essential vitamins and minerals, are a major public health problem in many countries worldwide. According to the World Health Organization (WHO, 2014), more than two billion people worldwide suffer from one or more micronutrient deficiency. To our knowledge, no prior study has investigated the mineral composition of propolis produced by different collectors. Because propolis has important applications in the field of medicine (e.g., raw material in drug formulation) and in the food industry (e.g., as a supplement), it is important to determine how local variables such as seasons and methods of collection can influence the composition of propolis, and subsequently affect its biological and nutritional properties. Therefore, the goal of this study was to evaluate the effects of seasonal variations and collection methods on the mineral content of propolis produced by the Africanized Apis mellifera Linnaeus, 1758. 2. Material and Methods The experiment was conducted at the Beekeeping Production Area of Edgárdia Farm, Faculty of Veterinary Medicine and Animal Science, UNESP, Botucatu, São Paulo, Brazil, 22°82′S and 48°39′W, with a humid subtropical (Cfa) climate and an average elevation of 488 m. Twenty-five colonies of Africanized A. mellifera, housed in Langstroth hives, were used. The colonies were free of diseases or parasites and each had a naturally mated queen. Colonies were not genetically selected for a specific propolis collection. They were standardized according to the number of brood frames and were randomly distributed and organized to only produce propolis. Each type of collector was used to harvest propolis from 5 colonies, as described below: 1. Scraping: Harvest was performed with a chisel, scraping inside the hive, frames, and lid. 2. Screen: A plastic screen with 2 mm spacing was used under the lid of the hive. 3. Intelligent Collector Propolis (ICP): Adapted supers with mobile side battens (2 cm), were placed between the lid and the nest of the beehive. Battens from each side were removed every week to stimulate propolis production. 4. Lateral Opening of Supers (LOS): Adapted supers with lateral opening of dimensions 16 cm × 8 cm, sealed with translucent and flexible plastic to prevent changes in the nest thermoregulation, but allowing the entrance of luminosity, were used. 5. Underlay: Wooden block, 2 cm high, was placed between the lid and the nest of the beehive to form an opening for the bees to deposit propolis. Every month, the propolis produced using each type of collector was harvested, ground, homogenized, and stored in a freezer at -10 ºC. The experiment was conducted from August 2010 to August 2011. The analyses for Mg, Zn, Fe, Na, Ca, Cu, and K were performed at the Agricultural and Environmental Laboratory (Agrilab), in Botucatu, São Paulo, Brazil. Qualitative and quantitative analyses of minerals were performed by atomic absorption spectrometry, following the methodology described by Sarruge and Haag (1974). A Varian model 12/1475 Spectro was used to determine concentrations of Mg, Zn, Fe, Na, Ca, Cu, and K. The detection limits for these minerals were set at 0.03, 0.04, 0.01, 0.05, 0.10, 0.07, and 0.02 ppm, respectively. Further, 1 g of each propolis sample was weighed in pyrex-type tubes and nitropercloric acid solution was added (6:1 nitric acid: perchloride acid) to each tube. Samples were placed in thermostatically laminar flow block digester (Tecnal, type TE-040/25) and heated to 250 °C for 2.5 hours to digest and eliminate organic materials. The samples were then suspended in distilled Braz. J. Biol., 2016,  vol. 76, no. 2, pp. 396-401398 Souza, E.A., et al. 398 water and the volume was made up to 25 mL, before spectrophotometric measurements were performed. Before the first sample reading, the pattern solutions for each analyzed metal were used to calibrate the equipment. The results were expressed in mg kg-1. The following Formula 1 was used to calculate the metal quantity in propolis: ( ) ( ) ( ) reading metal – white reading × dilution volume 25 mLMetal concentration mg/kg sample weight g ( ) 1 = (1) The mineral concentration was evaluated by analysis of variance (ANOVA), followed by Tukey-Kramer’s test, to verify differences between mean values. They were considered statistically different when p<0.05 (Zar, 2010). 3. Results The macro-mineral content (Ca, Mg, K, and Na) present in propolis samples estimated based on the location (Botucatu region), season, and the method of propolis collection are presented in Table 1. The Ca content in the propolis collected using the scraping was higher during summer and winter (3985.9 ± 663.2 mg/kg and 2066.7 ± 563.0 mg/kg, respectively) than during autumn (1423.8 ± 989.9 mg/kg). Similarly, the Ca content in the propolis collected using the LOS method was higher during summer and winter (2526.3 ± 348.2 and 2417.2 ± 624.8 mg/kg, respectively) than during spring and autumn (889.3 ± 240.5 and 1101.8 ± 615.9 mg/kg, respectively). With regard to the method of collection, the Ca content in propolis collected using ICP was higher (2420.08 ± 1614 mg/kg) than that in propolis collected using the plastic screen (738.3 ± 366.5 mg/kg), specifically during autumn. The Mg content in propolis collected using the scraping was higher during summer and winter (1545.5 ± 613.9 and 1021 ± 134.5 mg/kg, respectively) than during autumn (897.9 ± 605.6 mg/kg). For the underlay method, the Mg content in propolis collected during spring was higher (3849.4 ± 478.8 mg/kg) than that collected during summer, autumn, and winter (1239.3 ± 386.4; 1220.4 ± 318.2 and 1234.4 ± 154.8 mg/kg, respectively). In relation to the method of collection, the Mg content in propolis collected by the underlay method was higher (3849.4 ± 478.8 mg/kg) than that collected using the LOS method (415.2 ± 80.4 mg/kg), specifically during spring. The K content of propolis did not differ significantly due to seasonal variations and collection methods. The Na content of propolis collected using the LOS method was higher during autumn and winter (344.8 ± 96.8 and 396.0 ± 152.2 mg/kg, respectively) than during spring and summer (32.4 ± 5.1 and 71.8 ± 5.2 mg/kg, respectively). Similarly, the Na content in the propolis collected using underlay method was higher during summer, autumn, and winter (196.2 ± 103.3; 302.7 ± 114.6 and 387.8 ± 206.3 mg/kg, respectively) than during spring (61.7 ± 13.7 mg/kg). The content of micro-minerals (Cu, Zn, and Fe) present in the propolis samples obtained based on the location (Botucatu region), season, and method of collection are presented in Table 2. The Cu content in propolis produced using the scraping was higher during summer and winter (12.24 ± 1.4 and 11.5 ± 2.6 mg/kg, respectively) than during spring and autumn (4.3 ± 0.3 and 4.2 ± 0.4 mg/kg, respectively). Table 1. Averages and standard deviation of macro-mineral contents (Ca, Mg, K, and Na) (mg/kg–1) found in propolis according to seasonality and production method (Scraping, Screen, “Intelligent” Collector Propolis [ICP], Lateral Opening of the Super [LOS], and Underlay) in Botucatu, São Paulo, Brazil. Mineral (mg/kg) Season Scraping Screen ICP LOS Underlay Calcium (Ca) Spring 2187.2 ± 1430.9ABa 1274.9 ± 634.3Aa 1994.9 ± 808.7Aa 889.3 ± 240.5Ba 2261.4 ± 661.8Aa Summer 3985.9 ± 663.2Aa 2360.7 ± 1062.2Aa 3292.1 ± 735.7Aa 2526.3 ± 348.2Aa 3112.2 ± 812.0Aa Autumn 1423.8 ± 989.9Bab 738.3 ± 366.5Ab 2420.08 ± 1614.1Aa 1101.8 ± 615.9Bab 2291.7 ± 1301.4Aab Winter 2066.7 ± 563.0Aa 1808.7 ± 548.9Aa 2675.33 ± 695.16Aa 2417.2 ± 624.8Aa 2286.3 ± 177.3Aa Magnesium (Mg) Spring 1303.2 ± 1382.0ABab 1001.4 ± 983.3Aab 1682.3 ± 1322.5Aab 415.2 ± 80.4Ab 3849.4 ± 478.8Aa Summer 1545.5 ± 613.9Aa 1076.9 ± 366.6Aa 1831.9 ± 550.2Aa 2166.7 ± 1251.4Aa 1239.3 ± 386.4Ba Autumn 897.9 ± 605.6Ba 698.5 ± 175.4Aa 5665.1 ± 7366.7Aa 749.6 ± 164.5Aa 1220.4 ± 318.2Ba Winter 1021.3 ± 134.5Aa 1210.2 ± 561.6Aa 1362 ± 145.1Aa 1157.5 ± 261.2Aa 1234.4 ± 154.8Ba Potassium (K) Spring 2546.9 ± 1092.9Aa 2065.3 ± 235.9Aa 1809.9 ± 398.4Aa 1904.3 ± 140.5Aa 2777.9 ± 687.4Aa Summer 1809.9 ± 398.4Aa 6230.9 ± 1643.7Aa 6726.3 ± 3682.1Aa 2804.8 ± 487.0Aa 4124.2 ± 1851.4Aa Autumn 5321.5 ± 3171.7Aa 4254.6 ± 2903.1Aa 6027.8 ± 3606.3Aa 2026.9 ± 241.1Aa 4623.7 ± 358.2Aa Winter 4136.4 ± 657.9Aa 4908.7 ± 2816.0Aa 4677.6 ± 1451.8Aa 3149.8 ± 2008.2Aa 4148.5 ± 870.2Aa Sodium (Na) Spring 69.0 ± 32.1Aa 66.2 ± 24.9Aa 35.5 ± 11.7Aa 32.4 ± 5.1Ba 61.7 ± 13.7Ba Summer 245.0 ± 225.4Aa 186.2 ± 100.6Aa 194.9 ± 120.3Aa 71.8 ± 5.2Ba 196.2 ± 103.3Aa Autumn 197.3 ± 132.6Aa 220.4 ± 153.8Aa 293.2 ± 141.4Aa 344.8 ± 96.8Aa 302.7 ± 114.6Aa Winter 404.1 ± 148.3Aa 351.7 ± 159.6Aa 284.0 ± 171.8Aa 396.0 ± 152.2Aa 387.8 ± 206.3Aa Averages followed by the same uppercase letter followed by the same capital letter in the column do not differ from each other according to Tukey´s Test (p<0.05). Averages followed by the same small letter in the row do not differ from each other according to Tukey´s Test (p<0.05). Braz. J. Biol., 2016,  vol. 76, no. 2, pp. 396-401 399 Variation of mineral contents in propolis 399 In the case of Zn, seasonal variation did not alter the mineral content in propolis. Based on the collection method used, the Zn content in the propolis collected using ICP was higher (87.43 ± 43.3 mg/kg) than that collected using the scraping (30.8 ± 19.8 mg/kg), specifically in autumn. The Fe content in propolis collected using the LOS method was higher during summer and winter (413.0 ± 96.4 and 343.8 ± 141.2 mg/kg, respectively) than during autumn (57.7 ± 49.8 mg/kg). The Fe content in propolis collected using the underlay method was higher during spring (528.6 ± 63.5 mg/kg) than during summer and autumn (246.7 ± 121.3 and 181.0 ± 35.7 mg/kg, respectively). In relation to the method of collection, the Fe content in propolis collected using the ICP method was higher (397.6 ± 132.1 mg/kg) than that collected using the screen method (131.5 ± 51.4 mg/kg), specifically during winter. 4. Discussion The results of this study show that the season of propolis harvest and the method used can interfere with the mineral content composition of this bee product. It is important to note that the bees in this study were located in the same place and collected resins in the same area; therefore, they were exposed to the same soil and climatic conditions. However, bees collect resins from different plant sources throughout the year and the collection method can influence the collection of resin, which could explain the seasonal differences in the mineral content of propolis. Bastos et al. (2011) have demonstrated that some plants produce more resins in certain periods. For example, in rainy seasons, it is observed that A. mellifera bees and other insects show an increased attraction to plants, resulting in collection of greater amounts of resin (Bastos et al., 2011). The contents of macro- and micro-minerals in the soil can also differ based on the geographical region (Espinoza et al., 1991; Alloway, 2013), thus influencing the type of minerals available to plants. Specific plants can produce resins with different mineral content. According to Raven and Johnson (2002), the absorption of nutrients in the soil varies according to the requirements of each plant species, their development, and climate conditions. Furthermore, pollen content in propolis could interfere with the study results, as pollen represents approximately 5% of the final composition of propolis (Huang et al., 2014). The pollen present in propolis may vary according to the botanical origin (Freitas et al., 2011), and the minerals in pollen are affected by geographic and seasonal variations (Morgano et al., 2012) as well. Collectively, these factors can influence the mineral composition of propolis. Therefore, possible differences in the resin collected, due to plant diversity or preference of bees to a certain plant species during a specific season, could explain the results obtained herein. The mineral composition of propolis has also found to vary according to the collection method, which may be attributable to the wax content. Conditions of resin scarcity and the stimulus the bees receive from the propolis collectors can cause them to add an excess amount of wax to the propolis produced, thereby interfering with the mineral content. Silva et al. (2006) have shown that periods of resin scarcity (that overlap with periods of low precipitation) contribute to the increased wax content in propolis. Korn et al. (2013) reported that propolis from the Bahia state is a good source of Ca, K, Mg, and Fe; however, comparison of the mean values obtained in the present study showed that the contents of these elements and of Na and Cu were higher, whereas that of Zn was within the reported range. Comparison of the mean values obtained in this study to those previously recorded in the Paraná state (Finger et al., 2014) showed that Ca and Mg concentrations were within the reported range, Zn concentration was Table 2. Averages and standard deviation of micro-mineral contents (Cu, Zn and Fe) (mg/kg–1) found in propolis according to seasonality and production method (Scraping, Screen, “Intelligent” Collector Propolis [ICP], Lateral Opening of the Super [LOS], and Underlay) in Botucatu, São Paulo, Brazil. Mineral (mg kg–1) Season Collection Method Scraping Screen ICP LOS Underlay Copper (Cu) Spring 4.3 ± 0.3Ba 4.8 ± 2.0Aa 2.7 ± 0.6Aa 5.3 ± 0.8Aa 6.5 ± 3.7Aa Summer 12.24 ± 1.4Aa 9.4 ± 7.0Aa 8.0 ± 6.7Aa 5.7 ± 0.7Aa 7.5 ± 6.3Aa Autumn 4.2 ± 0.4Ba 3.2 ± 3.1Aa 4.6 ± 1.8Aa 6.1 ± 3.1Aa 6.2 ± 1.1Aa Winter 11.5 ± 2.6Aa 12.4 ± 2.3Aa 6.9 ± 6.9Aa 11.0 ± 3.4Aa 11.8 ± 1.7Aa Zinc (Zn) Spring 113.5 ± 16.9Aa 145.7 ± 43.3Aa 91.1 ± 7.5Aa 131.8 ± 22.4Aa 85.3 ± 11.6Aa Summer 68.2 ± 55.2Aa 55.2 ± 15.6Aa 55.7 ± 20.4Aa 101.0 ± 3.8Aa 45.5 ± 23.4Aa Autumn 30.8 ± 19.8Ab 49.3 ± 13.7Aab 87.1 ± 43.3Aa 79.9 ± 43.8Aab 44.3 ± 9.9Aab Winter 74.64 ± 15.2Aa 66.5 ± 10.6Aa 95.9 ± 41.1Aa 64.0 ± 3.2Aa 63.3 ± 18.8Aa Iron (Fe) Spring 459.5 ± 272.0Aa 273.9 ± 125.6Aa 242.1 ± 109.4Aa 179.7 ± 67.6ABa 528.6 ± 63.5Aa Summer 228.9 ± 46.2Aa 176.1 ± 36.9Aa 278.6 ± 262.4Aa 413.0 ± 96.4Aa 246.7 ± 121.3Ba Autumn 156.2 ± 88.3Aa 92.3 ± 35.3Aa 172.1 ± 53.5Aa 57.7 ± 49.8Ba 181.0 ± 35.7Ba Winter 325.6 ± 122.2Aab 131.5 ± 51.4Ab 397.6 ± 132.1Aa 343.8 ± 141.2Aab 391.4 ± 26.5ABa Averages followed by the same capital letter in the column do not differ from each other according to Tukey´s Test (p<0.05). Averages followed by the same small letter in the row do not differ from each other according to Tukey´s Test (p<0.05). Braz. J. Biol., 2016,  vol. 76, no. 2, pp. 396-401400 Souza, E.A., et al. 400 higher, and K and Na concentrations were lower. These comparisons show that propolis from different Brazilian areas have different mineral composition and that propolis from the Botucatu region is a good source of Ca, K, Mg, Zn, Fe, Na and Cu. Comparison of the mean values of mineral concentrations in propolis recorded in the present study with those recorded by Gong et al. (2012) showed that Ca concentrations were within the reported range; however, Mg and K concentrations were higher, whereas Na, Zn, and Fe concentrations were lower. Compared to propolis produced in South Spain (Bonvehí and Bermejo, 2013), the concentrations of Ca, Na, and Fe reported in our study were very similar and those of Mg, K, and Cu were within the reported range. However, Zn concentrations were relatively low. Macro- and micro-minerals are important for maintaining good health (Máhán and Escott-Stump, 2004; Alsafwah et al., 2007). Owing to the significance of propolis in the food and drug industry, this study demonstrates that it is important know the origin, period, and method of propolis collection, as these factors can influence the mineral composition of propolis. 5. Conclusion The evaluation of the mineral composition of propolis contributes to the understanding of its quality and shows that not only seasonal variations but also the collection method influences the mineral contents present in the propolis produced. On the basis of the results of this study, we can conclude that the propolis collection method affects the concentration of macro-mineral Ca and Mg; and of micro-mineral Zn and Fe; whereas seasonal variations affect the concentration of macro-mineral Ca, Mg, and Na; and of micro-minerals Fe and Cu. 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