Effects of pyrethroid structure on rates of hydrolysis and oxidation by mouse liver microsomal enzymes

Studies on the metabolism rates of 44 pyrethroids and 24 model compounds in mouse liver microsomal systems serve to divide the substrates into three groups based on their ease of hydrolysis and oxidation. Primary alcohol esters of trans-substituted cyclopropanecarboxylic acids are most rapidly metabolized with hydrolysis generally serving as the major component of the total metabolism rate. Although hydrolyzed slowly or not at detectable rates, the primary alcohol cis-substituted cyclopropanecarboxylates, tetramethylcyclopropanecarboxylates, and p-chlorophenyl-α-isopropylacetates are rapidly oxidized. The highly insecticidal α-cyano-3-phenoxybenzyl esters are least susceptible to metabolic attack due to both reduced esterase rates attributable to α substitution in the alcohol moiety and reduced oxidase rates for which no adequate explanation is currently available. Other structural modifications in the acid and alcohol moieties are less important in determining the metabolism rates. The substrate specificities of the microsomal esterases and oxidases are compared with in vivo pyrethroid structure-biodegradability relationships.