Browsing by Subject "kirjolohi"
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(2021)Pharmaceutical contaminants in waste and surface waters have been recognized as an emerging risk to environmental health. Bioaccumulation of pharmaceuticals increases the risk of adverse effects in off-target species, as the chemical concentration within the organism exceeds the concentration of the surrounding environment. An organism’s ability to metabolize foreign organic compounds influences the likelihood of bioaccumulation. Current methods for predicting bioaccumulation in aquatic organisms are labour intensive or too simplistic to cover the variety of chemical and physiological processes involved and may lead to over or underestimations of environmental risk. A promising approach to improve bioaccumulation predictions, without the need of excessive animal testing, is to incorporate in vitro biotransformation data into computational models. The primary aim of this study was to assess whether selected pharmaceuticals (diclofenac, gemfibrozil, haloperidol, levomepromazine, levonorgestrel, sertraline and risperidone), that are well metabolized in humans through key biotransformation pathways, are metabolized by rainbow trout (Oncorhynchus mykiss) liver enzymes under physiologically relevant conditions (11°C, pH 7.8). A secondary aim was to produce fish in vitro intrinsic clearance (CLint, in vitro) data, that could potentially be used as input in computational models to predict bioaccumulation. In vitro biotransformation was studied using a single vial approach according to the Organisation for Economic Co-operation and Development (OECD) Test Guideline 319B: Determination of in vitro intrinsic clearance using rainbow trout liver S9 sub-cellular fraction (RT-S9). Depletion of the test compounds were measured during a 3-hour incubation period. High-performance liquid chromatography with ultraviolet detection (HPLC–UV) was used for qualitative and quantitative analysis of the samples. Levomepromazine, levonorgestrel and sertraline showed significant substrate depletion compared to negative controls while gemfibrozil, haloperidol, and risperidone did not seem to be metabolized. The results for verapamil were inconclusive. Levomepromazine displayed a higher in vitro intrinsic clearance rate (26 ml/h/g liver) than diclofenac (6.2 ml/h/g liver). These results are in accordance with previous studies and support the notion that a direct comparability between fish and human metabolism cannot be assumed, highlighting the need of fish in vitro biotransformation studies. The apparent lack of in vitro metabolism of risperidone, haloperidol, and gemfibrozil combined with their lipophilicity suggest that they are more likely to accumulate within rainbow trout, compared with the compounds that showed depletion during the assays, although repetitions and additional studies are needed to confirm this.
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(2022)The aim of this master’s thesis was to investigate whether drug-induced inhibition of cytochrome P450 enzymes (CYP), especially time-dependent inhibition (TDI), could be the reason for bioaccumulation of the pharmaceuticals present in the aquatic environment in fish and whether the in vitro method could identify pharmaceuticals causing an environmental risk, which should primarily be investigated more closely. The half-maximal inhibitory concentrations (IC50) of seven antimicrobial drugs detected in the environment (erythromycin, clarithromycin, ketoconazole, clotrimazole, miconazole, ciprofloxacin, and sulfamethoxazole) and three known human time-dependent inhibitors (furafylline, diltiazem and verapamil) chosen for the validation of the method, were determined by EROD (7-ethoxy-resorufin-O-deethylase) and BFCOD (7-benzyloxy-4-trifluoromethyl-coumarin-O-debenzyloxylase) activities. The IC50 shift method and commercially available rainbow trout (Oncorhynchus mykiss) liver microsomes were used in determinations. The known human time-dependent inhibitors chosen for the validation of the method, furafylline (EROD) and diltiazem (BFCOD) proved to be possible time-dependent inhibitors also in rainbow trout in vitro, but this was not observed for verapamil (BFCOD). All antimicrobial drugs, except ciprofloxacin, inhibited more selectively BFCOD-reaction, as in human. In the case of sulfamethoxazole, inhibition was not observed at the concentrations used (0–500 µmol/L). Both enzyme activities (EROD and BFCOD) were inhibited in rainbow trout by ketoconazole, clotrimazole and miconazole. Among antimicrobial drugs acting as time-dependent inhibitors in human, erythromycin inhibited BFCOD activity in a time-dependent manner also in rainbow trout, but this was not observed for clarithromycin. Strongest inhibitors for CYP enzymes of rainbow trout in vitro were ketoconazole (EROD, IC50=4,19 µM and BFCOD, IC50=2,31 µM) and clotrimazole (EROD, IC50=33,78 µM and BFCOD, IC50=1,55 µM). The IC50 values of diltiazem, erythromycin, clarithromycin, ciprofloxacin, and verapamil were of the same order of magnitude as in human. The IC50 values of furafylline, ketoconazole, clotrimazole and miconazole were several times higher in rainbow trout than in human. Based on the results of this study, the IC50-shift method is also valid for fish, but there are differences in the inhibition potencies between human and fish, and the inhibition potency of human CYP enzymes cannot therefore directly predict enzyme inhibition of fish or the mechanism of inhibition. The In vitro measured IC50 values of rainbow trout were several orders of magnitude higher than the average concentrations of the pharmaceutical residues measured in the environment. Exposure to pharmaceutical mixtures is long-term, so interactions and bioaccumulation may still be possible due to inhibition of CYP enzymes. Developing a valid in vitro method for environmental risk assessment would be important, as animal experiments are ethically challenging.
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