Use of biometric, hematologic, and plasma biochemical variables, and histopathology to assess the chronic effects of the herbicide prometryn on Common Carp.

BACKGROUND: Effects of acute and subchronic exposure of fish to s-triazine herbicides have been well documented, but data on the effects of prometryn on blood analytes in carp at environmentally realistic concentrations are lacking. OBJECTIVE: The objective of the study was to determine whether biometrics, blood analytes, and histopathology could serve as bioindicators in fish living in waters polluted by triazine. METHODS: Fish were exposed to prometryn at concentrations of 0.51 (reported concentration in Czech rivers), 8.0, and 80 µg/L for 14, 30, and 60 days. Prior to and during this period, biometrics, blood analytes, and histopathology were evaluated. RESULTS: After 60 days' exposure to 8.0 and 80 µg/L of prometryn, spleen weights (P < .05) and lactate (P < .01) levels were significantly lower, and concentrations of HGB (P < .01) and MHC (P < .01) and MCHC (P < .01) were higher, relative to controls. After 30 and 60 days' exposure to 0.51, 8.0, and 80 µg/L of prometryn, AST activity, calcium, magnesium, and inorganic phosphate levels were lower (P < .01), while creatinine concentration and ALT activity were higher (P < .01) than in controls. Glucose was higher after exposure to 80 µg/L after 30 and 60 days, and after 60 days' exposure to 8.0 µg/L. Renal histology revealed severe hyaline degeneration of the epithelial cells of caudal kidney tubules in fish at all exposure levels. CONCLUSIONS: This study shows effects in fish blood at a concentration of 0.51 µg/L of prometryn, a significant finding in view of prometryn reaching a maximum of 4.4 µg/L or less in European rivers. Select blood analytes, such as creatinine, and histologic changes in caudal kidney are potential biomarkers for monitoring residual triazine pesticides in Common Carp.

[Determination of 15 kinds of pesticides in blood by gas chromatography-mass spectrometry].

OBJECTIVE: To develop the method of gas chromatography-mass spectrometry (GC-MS) for simultaneous determination of 15 herbicides in blood. METHODS: 2ml of blood in vitro were sampled, concentrated and extracted with dichloromethane, reconstant with methanol agents of Gulonic acid lactone solution, and detected by GC-MS. RESULTS: Experimental results show that diazinon, atrazine, prometryn, methyl parathion, butachlor, bifenthrin at 4-80 microg/L, phorate, malathion, 2,4-D butyl ester, chlordane, fenpropathrin at 10-200 microg/L, alpha-endosulfan, beta-endosulfan, cyhalothrin at 20-400 microg/L, dimethoate at 40-800 microg/L, with good linear response. The correlation coefficient (r2) were between 0.998-1.000, respectively. The recovery of all analysts averaged between 56%-128% in blood samples. The detection limits of all compounds between 0.05 and 1.00 microg/L. The lower limit of quantification between 0.20 and 3.001 microg/L. CONCLUSION: The methods is apply to detect the content of analysts in blood samples.

Metabolic acidosis in prometryn (triazine herbicide) self-poisoning.

INTRODUCTION: Prometryn is a triazine herbicide, which is one of the most extensively used groups of herbicides. The mechanism of acute triazine herbicide toxicity in humans is not known. We report a first case of acute prometryn poisoning. CASE REPORT: A 62-year-old male ingested 50 g of prometryn and ethanol in a suicide attempt. On arrival two hours after ingestion, he was somnolent and vomited. Seven hours after ingestion laboratory tests showed metabolic acidosis with a calculated anion gap of 47.5 mmol/L and lactate of 23.4 mmol/L. Gas chromatography/mass spectrometry revealed serum prometryn concentrations of 48.1 mg/L. Hemodialysis corrected metabolic acidosis, but the serum prometryn concentration increased to 67.7 mg/L. The lactate level after hemodialysis was 11.7 mmol/L and returned within normal limits 47 hours after ingestion. The patient was discharged without any sequelae after psychiatric evaluation. CONCLUSION: In high anion gap metabolic acidosis we should consider poisoning with prometryn and other triazine herbicides. Hemodialysis corrects metabolic derangements, but it does not lower serum prometryn concentration.

Metabolism of [(1)(4)C]prometryn in rats.

[(1)(4)C]Prometryn, 2, 4-bis(isopropylamino)-6-(methylthio)-s-triazine, was orally administered to male and female rats at approximately 0.5 and 500 mg/kg; daily urine and feces were collected. After 3 or 7 days rats were sacrificed, and blood and selected tissues were isolated. The urine and feces extracts were characterized for metabolite similarity as well as for metabolite identification. Over 30 metabolites were observed, and of these, 28 were identified mostly by mass spectrometry and/or cochromatography with available reference standards. The metabolism of prometryn was shown to occur by N-demethylation, S-oxidation, S-S dimerization, OH substitution for NH(2) and SCH(3), and conjugation with glutathione or glucuronic acid. Rat liver microsomal incubations of prometryn were conducted and compared to the in vivo metabolism. Both in vivo and in vitro phase I metabolisms of prometryn were similar, with S-oxidation and N-dealkylation predominating. The involvement of cytochrome P-450 and flavin-containing monooxidase in the in vitro metabolism of prometryn was investigated.