Methomyl

The study was conducted to according OECD guideline 308 to evaluate the anaerobic aquatic metabolism of [14C]-labelled test substance in two water-sediment systems. The degradation of [14C]-labelled test substance was investigated in two water/sediment systems for up to 92 days under anaerobic conditions in the dark at 20±2°C. The water/sediment systems were from Chula, Tift County, Georgia, USA and Wabasha County, Minnesota, USA. The Tift water had a pH of 7.8, while the sediment was characterized as loamy sand with a pH of 8.0 and organic matter content of 0.6%. The Wabasha water had a pH of 7.4, while the sediment was characterized as a loam with a pH of 5.9 and organic matter content of 10.8%.

The water phase of the test systems were treated with [14C]- labelled test substance at a nominal rate of 5 μg a.i./mL water. The test systems were incubated in darkness at approximately 20 ± 2°C. Due to the volatility of many of the test substance degradates, anaerobic incubations were performed in static test systems and measurements of pH, dissolved oxygen (DO), and redox potentials were obtained using representative controls. Prior to separation of water and sediment layers, duplicate test systems from each sediment/water system were connected to a series of traps to collect volatile radioactivity. The gases exiting the test vessels were passed through a set of traps consisting of an Orbo™ tube followed by ethylene glycol, four organic solvent cold-traps in dry ice (two methanol and two acetonitrile), two aqueous KOH traps, ethanolamine:2-ethoxyethanol, and finally a second Orbo™ tube. The volatile traps were all analyzed by LSC, and the Orbo™ tubes were extracted with methanol and radioassayed by LSC.

Duplicate samples were analyzed at 0, 1, 3, 7, 14, 21, and 30 days (Wabasha) or 0, 1, 3, 7, 14, 21, 30, 62, and 92 days (Tift) after application. The water and sediment layers were first separated by decanting. The water layer was analyzed by LSC followed by direct injection onto reversed-phase HPLC. The sediment layer was extracted with 2:1 methanol: water and centrifuged to separate the extract. This extraction was repeated twice for a total of three extractions. Sediment extracts were analyzed by LSC. For representative sediment extracts containing >5% of the applied radioactivity, the pH was adjusted to >10.4 to retain any 14CO2 and 14C-acetic acid that may have been present, and the extract was rotary evaporated and analyzed by LSC before being analyzed by HPLC. The material lost upon concentration of the sediment extracts was presumed to be 14C-acetonitrile as all other degradates would not have volatilized during this concentration.

For both sediment systems, the average material balance was >90% until parent had degraded to <40% of the applied radioactivity (%AR). Once the parent had degraded to <40% AR, the production of volatile radiolabeled degradates led to a loss of mass balance at these later sampling intervals. Overall, the mean material balance was 96.5 ± 9.5% and 76.9 ± 20.2% of the applied radioactivity (%AR) for the [14C]- labelled test substance treated Tift and Wabasha samples, respectively.

Radioactivity in the water layer generally decreased over the course of the study from a mean of 101% and 95.0% AR at Day 0 to a mean of 44.8% and 16.2% AR at termination for the Tift and Wabasha systems, respectively. At Day 0, the mean extractable radioactivity from the Tift and Wabasha sediments was 3.4% and 1.5% AR, respectively. Extractable residues in the Tift sediment increased to a maximum of 9.2% (14 days) and were 6.2% at termination (92 days). Extractable residues in the Wabasha sediment increased to a maximum of 9.1% AR (7 days) and were 4.7% at termination (30 days). Non-extractable residues increased during the study, reaching a mean maximum of 27.5% (92 days) and 8.7% AR (14 days) for the Tift and Wabasha samples, respectively. No radioactivity above 4.1% AR was observed in the Tift volatile traps. The Wabasha volatile traps yielded a maximum of 22.9% AR (14 days), followed by a decline to 20.8% AR at 30 days. In the Wabasha traps, 14CO2 reached a maximum of 8.7% AR (14 days) followed by a decline to 1.5% AR at 30 days.

In the water layer of the Tift system, average levels of test substance decreased from 95.9% AR at day 0 to 2.4% AR at the end of the 92-days incubation. The major transformation products in the water layer were 14C-acetonitrile and dissolved 14CO2 which reached maximums of 29.7% and 22.3% AR at 62 and 92 days, respectively. 14C-Acetonitrile declined slightly to 20.2% of AR at 92 days. Three minor degradates, IN-X1177, 14C-acetamide, and 14C-acetic acid were also detected. IN-X1177 (<1% AR) was only observed at 7 days, and 14C-acetic acid was only observed in the 7 and 14 day samples with a maximum of 2.6% AR at 14 days. 14C-Acetamide reached a maximum concentration of 4.4% AR (14 and 21 days) before declining to 0% AR at 62 days. The largest single unassigned radioactive residue was 3.5% AR at 30 days.

Analysis of the Tift sediment extracts was complicated by the presence of volatile radioactivity. Direct evaporation of these extracts led to the loss of the majority (>70%) of the radioactivity. The extracts were adjusted to a basic pH with KOH in order to retain dissolved 14CO2 or 14C-acetic acid, if present. Neither test substance nor 14C-acetamide is appreciably volatile, so they were retained as well. Thus, volatile radioactivity lost upon concentration was presumed to be 14C-acetonitrile since this compound forms azeotropes with both methanol and water, and would be very volatile. After addition of base, selected sediment samples were concentrated by rotary evaporation and analyzed by HPLC. The major residue observed in the sediment extracts, based on volatility from base, was 14C-acetonitrile, which reached a maximum of 6.4% AR at 21 days before declining to 3.4% at 92 days. 14C-Acetamide increased gradually to 2.0% AR at 21 days and declined to <1% at 92 days. Traces of test substance (≤0.4% AR) and IN-X1117 (≤0.6% AR) were observed. No other radioactive residue exceeded 1.2% AR.

Non-extractable residues in the Tift sediment increased steadily throughout the study and reached a maximum of 27.5% AR at 92 days. Fractionation using a humic/fluvic acid extraction clearly showed that the majority of these bound residues reside within the humin fraction. At 92 days, approximately 7.6% AR was associated with the fulvic acid fraction, 0.3% AR was associated with the humic acid fraction, and approximately 19.7% AR was associated with the residual solids or humin fraction.

In the water layer of the Wabasha system, levels of test substance rapidly decreased from 88.6% AR at Day 0 to 0% AR at Day 14. The major transformation products in the water layer were 14C-acetamide, 14C-acetonitrile, and dissolved 14CO2, which reached maximums of 18.4%, 21.3%, and 20.3% AR at 7, 7, and 14 days, respectively. Both 14C-acetamide and 14C-acetonitrile declined to 0% AR by 30 days, and dissolved 14CO2 declined to 12.5% AR at 30 days. A minor degradate, 14C-acetic acid, was also detected at a maximum of 2.6% AR at 7 days. The largest single unassigned radioactive residue was 4.7% AR at 1 day.

Evaporation of the Wabasha sediment extracts led to the loss of the majority of the radioactivity, so the same process was followed as indicated above for the Tift sediment. The major residue observed in the sediment extracts, based on volatility from base, was 14C-acetonitrile, which reached a maximum of 6.7% AR at 7 days before declining to 2.3% at 30 days. 14C-Acetamide was observed in the sediment extracts as a minor component and ranged from 1.5 to 2.5% of AR in the sediment. No other radioactive residue, including test substance, was observed in the Wabasha sediment extracts.

Non-extractable residues increased to a maximum of 8.7% AR at 14 days before declining slightly to 7% of AR at 30 days.

The majority of the radioactivity in both test systems was found in the water layer until after the majority of the parent had degraded, and test substance was not observed to any significant extent in any sediment extracts. Therefore, degradation kinetics for [14C] labelled test substance was performed using the radioactive residues from only the water layer. The DT50 and DT90 values for [14C] labelled test substance was calculated by a single first-order (SFO) kinetic fit using ModelMaker® 4.0. The DT50, DT90 value and rate constants for [14C]-labelled test substance in the water layer of Tift (Sandy loam) sediment/water system was 20.5 days, 68.2 days and 0.034 respectively. The DT50, DT90 value and rate constants for [14C]-labelled test substance in the water layer of Wabasha (Sandy loam) sediment/water system was 2.5 days, 8.3 days and 0.278 respectively.