Abstract
Some of the most frequently used antibiotics in apiculture for the treatment of bacterial brood diseases are oxytetracycline, chloramphenicol, sulphathiazole and streptomycin. Therefore, the aim of this research is to determine the degradation kinetics of the residua these antibiotics leave behind in different types of honey stored in dark at 25 °C. The examined honey samples (N=74) originating from the Croatian market had satisfactory physicochemical properties and pollen characteristics. Quantitative analyses of antibiotic residues were done using HPLC and ELISA methods. No antibiotic residues were found in any of the tested acacia, chestnut, floral, meadow and honeydew honey samples (N=74). In the next step, each of the tested honey samples was supplemented with one of the following antibiotics (in mg/kg): oxytetracycline 10, chloramphenicol 200, sulphathiazole 200 or streptomycin 0.5. Relatively high mass fractions of antibiotics have been added to the honey because the stability of each antibiotic is highly dependent on the spiked antibiotic mass fraction and also on its chemical structure. During a 6-month storage in the dark at 25 °C, the dynamics of degradation of the studied antibiotics was proven to differ dependent on the type of honey into which the antibiotic was added. The half-life of oxytetracycline in the acacia, floral, meadow and honeydew honey stored in the dark at 25 °C was 15, 16, 17 and 19 days, respectively, while in the chestnut honey the decomposition failed to be seen even after 60 days of storage. In all examined honey samples, the half-life of chloramphenicol and sulphathiazole was proven to be longer than 6 months. The fastest decomposition was seen of oxytetracycline added into the acacia honey, followed by streptomycin and sulphathiazole added into the same, while the longest decomposition delay was seen when chloramphenicol was added into the floral honey. According to the results obtained using a linear model of degradation kinetics, the longest oxytetracycline degradation was expected to occur in chestnut honey (116 days). Chloramphenicol and sulphathiazole are preserved the longest in floral (for 661 and 581 days, respectively) and streptomycin in meadow honey (for 321 days).
Highlights
Because they pollinate a number of various plant species, honey bees (Apis mellifera) are essential for the maintenance of biodiversity and are counted among insects of the outmost importance for the ecosystems [1]
In view of the foregoing, this study aims at investigating the degradation dynamics of antibiotics most commonly used in apiculture settings, added into acacia, chestnut, floral, meadow and honeydew honey
Calculations of the time needed for a complete antibiotic degradation in various types of honey stored in the dark at 25 °C revealed CAP and sulphathiazole (STZ) to degrade slower than OTC and STR under the same conditions and in the same honey types (Table 3)
Summary
Because they pollinate a number of various plant species, honey bees (Apis mellifera) are essential for the maintenance of biodiversity and are counted among insects of the outmost importance for the ecosystems [1]. Apiculture faces numerous challenges, including changes in agricultural practices, an extensive use of pesticides and an ever more frequent use of antibiotics administered to prevent bee infections caused by pathogenic microorganisms [2]. Forsgren [2] reports about a broad spectrum of specific pathogens that affect bee colonies; bacteria, viruses, fungi and endogenous and exogenous parasites being among them. Some of these microorganisms are harmful and can make bee colonies collapse. In order to prevent or treat brood infections, beekeepers usually administer a broad spectrum of antibiotics to protect their hives; tetracycline, sulphonamide, streptomycin and chloramphenicol being the most frequently used [3]. Antibiotic resistance represents a global public health problem due to the steadily rising number of resistant bacteria on the one hand, and the lack of antibiotics capable of efficiently treating infections caused by such multidrug resistant bacteria, on the other [7]
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