Methomyl

The study was conducted according to guideline OECD 304 and EPA 835.4100 to evaluate the rate of degradation of [14C]test substance in three soils. The soils used were Porterville (sandy loam, 0.53% OC, pH 7.8), Nambsheim (sandy loam, 1.8% OC, pH 7.5), and LRA-E1 (silt loam, 5.1% OC, pH 5.5).

The test system was acclimatized for up to 11 days prior to treatment. [14C]test substance labelled in the 1-14C position was used. The test substance was applied to the soil at a nominal rate of 0.4 μg/g dry soil weight, correspondent to a 400 g a.i./ha application rate assuming 10 cm incorporation and 1.0 g/cm³ soil density. Treated vessels were incubated for up to 38 days under aerobic conditions in the dark at 20 ± 2°C at pF 2 moisture.

The test systems consisted of polypropylene Nalgene® bottles connected to flow-through systems for each soil. Test flasks were connected to traps for the collection of CO2 and non-specific volatile organic compounds. Samples were analyzed immediately following test substance application (Day 0) and after 1, 2, 4, 7, 10, 14, 30, and 38 days of aerobic incubation.

Soil samples were extracted three times with 50:50 methanol:water. Extractable soil radioactivity was quantified by LSC and the radioactive components were quantified by reversed phase HPLC with on-line radiodetection. Non-extractable 14C-residues were quantified by combustion analysis.

The material balance was quantitative for all samples and was in the range 91.5 to 102.9% applied radioactivity (% AR).

The extractable radioactivity was quantitative at time 0 in all soils (>99.5%). All three soils showed similar degradation, with the sandy loam (Nambsheim) soil displaying the most extensive degradation.

In the sandy loam (Nambsheim) soil, extractable radioactivity decreased progressively with study duration to 5.1% AR by the final timepoint, while non-extractable residue increased to 33.8% AR by Day 10. The amount of 14CO2 increased over the study duration, reaching a maximum of 65.6% AR. Volatile organics traps were analyzed at termination with no activity present.

In the sandy loam (Porterville) soil, extractable radioactivity decreased progressively with study duration to 8.7% AR by the final timepoint, while non-extractable residue increased to 30.6% AR by termination. The amount of 14CO2 increased over the study duration, reaching a maximum of 58.5% AR. Volatile organics traps were analyzed at termination with no activity present.

In the silt loam (LRA-E1) soil, extractable radioactivity decreased progressively with study duration to 4.6% AR by the final timepoint, while non-extractable residue increased to 41.0% AR by Day 14. The amount of 14CO2 increased over the study duration, reaching a maximum of 55.2% AR. Volatile organics traps were analyzed at termination with no activity present.

Degradation in all soils proceeded primarily via microbial degradation through mineralization. No major metabolites (>10% AR) were observed, though IN-X1177 did reach 6.5% AR in the sandy loam (Porterville) soil at Day 14 before decreasing to below 1% AR over the remainder of the study. Multiple minor metabolites were observed in the polar region of the chromatographic method, but no single metabolite reached >10% AR. The maximum percentage of each metabolites observed and expressed as % AR of IN-X1177 in sandy loam (Porterville), sandy loam (Nambsheim) and silt loam (LRA-E1) was 6.5 (Day 14), 2.5 (Day 2) and 1.9 (Day 2 and 4) respectively.

Test substance and metabolite IN-X1177 were initially assigned by comparison of the HPLC retention times with respective reference standards. The identity of unchanged test substance was then confirmed by LC/MS analysis.

The percentage of test substance was plotted against time for each soil type and the degradation rate (DT50 and DT90) determined using SFO kinetics. The DT50 value for sandy loam (Porterville), sandy loam (Nambsheim) and silt loam (LRA-E1) was 11.6, 2.06 and 6.18 days respectively. DT90 values for sandy loam (Porterville), sandy loam (Nambsheim) and silt loam (LRA-E1) was 38.4, 6.85 and 20.5 days respectively with X² 5.28, 4.87 and 4.52.

Test substance degrades to multiple components by a variety of processes primarily via microbial degradation to mineralization. Test substance would be expected to dissipate from the environment from aerobic soils

The study was conducted according to guideline EPA 162 -1 to evaluate the aerobic metabolism of test substance in Madera, California Soil. Microbially active loam soil (pH 7.8, organic matter 0.9 percent), was treated with [1-14C]-labelled test substance at a concentration of 4.1 ppm. This treatment rate was equivalent to approximately 8 pounds’ active ingredient per acre or approximately 2.2 times the maximum label rate. Deionized water was added to each soil sample to maintain 75 percent field moisture capacity. The soils were incubated in the dark at 25 ± 1°C. Duplicate soil samples were harvested immediately after dosing and after aging aerobically 1, 2, 4, 8, 14, and 21 days, and 1, 2, and 3 months.

[1-14C]-labelled test substance was rapidly metabolized in this soil with a half-life of approximately 11 days. The major metabolic product was 14CO2 with over 75 percent of the radiolabel mineralized during the three-month study period. Extractable metabolites included minor amounts of methomyl oxime (methyl-N-hydroxythioacetimidate, MHTA) and two polar products, all of which were individually 3.3 percent or less of the applied radioactivity at any time during the study. Unextractable radioactivity (bound) increased with time for the first month, constituting 24 percent of the applied radioactivity at 1 month, then declined to 14 percent at 3 months. The majority of the unextractable radioactivity was associated with the soil organic matter and was further fractionated into the soluble and insoluble humin and fulvic acid fractions.

The study was conducted according to guideline EPA 162-2 to evaluate the anaerobic metabolism of [1-14C]-labelled test substance in Madera, California Soil. Microbially active loam soil (pH 7.8, organic matter 0.9%), was treated with [1-14C]-labelled test substance at a concentration of 4.1 ppm. This treatment rate was equivalent to approximately 8 pounds active ingredient per acre or approximately 2.2 times the maximum label rate. Deionized water was added to each soil sample to maintain soil moisture at 75% field moisture capacity. The soils were first incubated aerobically for 14 days and then converted to anaerobic conditions for 60 days. The soil samples were kept in the dark at 25 ± 1°C during both aerobic and anaerobic incubation periods. Duplicate soil samples were harvested at 7, 14, 30 and 60 days after the soils were converted to anaerobic conditions

[1-14C]-labelled test substance was rapidly metabolized in this soil with a half- life of approximately 11 days under aerobic conditions and approximately 14 days under anaerobic conditions. The major metabolic product was 14CO2 with days under anaerobic conditions. approximately 35% of the radiolabel mineralized to CO2 during the two-and-a-half-month period. Extractable metabolites included minor amounts of methomyl oxime (S-methyl-N-hydroxythioacetimidate, MHTA) and two polar products, all of which were individually 2.8% or less of the applied radioactivity at the final anaerobic (60 days) sampling point. Unextractable radioactivity (bound) increased to 30.3% at the Day 7 anaerobic sampling point and declined to 24.4% at the Day 60 (final) anaerobic sampling point. The majority of the unextractable radioactivity was associated with the soil organic matter and was further fractionated into the soluble and insoluble humin and fulvic acid fractions.