Acute and delayed neurotoxicity of leptophos analogs

Nineteen O-halogenated-phenyl O-methyl phenylphosphonothionates were evaluated for acute toxicity (LD₅₀) to the female house fly Musca domestica L. and to the male Swiss white mouse, and for delayed neurotoxicity to the White Leghorn hen. The electron-withdrawing power of the phenyl substituents (Σσ^? values) correlate with the LD₅₀ values to house fly and mouse, with departures from linearity attributable to the steric hindrance of di-ortho-Cl substitution and by variations in the accessibility of the anionic site of acetylcholinesterase in the two species. The relationship with delayed neurotoxicity is less predictable although it clearly depends on suitable electron-withdrawing capacity. Delayed neurotoxicity also relates to a high degree of lipophilicity and prolonged residence time of the inhibitor in the nerve axon.     

Steric,electronic, and polar parameters that affect the toxic actions of O-alkyl,O-phenyl phosphonothionate insecticides

The toxic action of a series of O-alkyl, O-substituted-phenyl alkyl- and aryl-phosphonates and phosphonothionates have been evaluated by correlating the linear free energy parameters for steric (E_s), electronic (σ), and polar ($\text{σ}{}^1$) effects with topical LD₅₀ to the house fly and oral LD₅₀ to the white mouse. In molecules free from major steric interactions with the reactive P atom, variations in these linear free energy parameters account for >90% of the variations in the LD₅₀ values, and the degree of correlation with LD₅₀ is at least as precise as that with the biomolecular rate constants for inhibition of the target-site enzyme acetylcholinesterase. The value of correlations of linear free energy parameters with LD₅₀ in understanding quantitative structure-activity relationships is illustrated.     

Behavioural and electrophysiological investigation of 1-(7-ethoxygeranyl)-2-methylbenzimidazole on the house fly Musca domestica

The insecticidal properties of 1-(7-ethoxygeranyl)-2-methylbenzimidazole (EGMB) were investigated on larval and adult house flies. Unsynergised EGMB gave topical LD₅₀ values of 0.53 μg per female fly on NAIDM strain house flies. When flies were pretreated with 5.2 μg piperonyl butoxide, susceptibility was increased (LD₅₀ 0.12 μg per female fly). House fly larvae were less susceptible to EGMB (LD₅₀ 2.2 μg). Poisoning with EGMB resulted in a rapid reduction in locomotor activity of both larval and adult house flies. This reduction in locomotion was progressive and led to complete paralysis. Various parameters of larval nervous system function were investigated in larvae during these early phases of poisoning. As early as 15 min after dosing larvae with LD₉₅ doses of EGMB, sensory nerves were less responsive. Over a somewhat longer time (2–4 h), neurally evoked contractures were adversely affected by EGMB. In some cases, this effect appeared to be due to reduced postsynaptic potential amplitude; in other instances, it appeared to be due to an effect independent of neuromuscular transmission. The close temporal correlation between behavioural and electrophysiological observations suggests that the nervous and muscular systems are important sites of action of EGMB.     

Structure and insecticidal activity of picrotoxinin analogs

Picrotoxinin, a convulsant in mammals, was nontoxic when topically applied on whole house flies. When synergized with piperonyl butoxide, the topical LD₅₀ of picrotoxinin on house flies was 6.50 μg/g or 260 times less toxic on house flies than the synergized insecticide, carbofuran, a carbamate cholinesterase inhibitor.When perfused on the isolated thoracic ganglion of house fly, picrotoxinin was less potent in producing convulsions than carbofuran; however, when assayed on the desheathed thoracic ganglion, picrotoxin was more potent than carbofuran. This suggested a substantial barrier to picrotoxinin preventing diffusion into the house fly central nervous system.Of several picrotoxinin analogs synthesized the 2-iodo,4-isopropyl, 6-methylenebromidecyclohexane-γ-lactone was the most potent convulsant.     

Cross-Resistance to Imidacloprid in Strains of German Cockroach (Blattella germanica) and House Fly (Musca domestica)

The toxicity of a promising new insecticide, imidacloprid, was evaluated against several susceptible and resistant strains of German cockroach and house fly. Imidacloprid rapidly immobilized German cockroaches followed by a period of about 72 h during which some cockroaches recovered. After 72 h there was no further recovery. Imidacloprid-treated houseflies were immobilized more slowly than treated cockroaches, with the maximum effect observed after 72 h, and there was no recovery. Based upon 72-h LD₅₀ values imidacloprid was moderately toxic to German cockroaches (LD₅₀ values were 6–8 ng mg^-1) and had only low toxicity to house flies (LD₅₀ 140 ng mg^-1). Piperonyl butoxide (PBO) blocked the observed recovery in German cockroaches. PBO also greatly enhanced the 72-h LD₅₀ of imidacloprid from 43- to 59-fold in cockroaches and 86-fold in house flies. Two strains of German cockroach (Baygon-R and Pyr-R) showed >4-fold cross-resistance to imidacloprid. This cross-resistance could not be suppressed by PBO, suggesting that P450 monooxygenase-mediated detoxication is not responsible for this cross-resistance. Variation in the level of synergism observed with PBO (between strains) suggests the ‘basal’ level of monooxygenase-mediated detoxication of imidacloprid is quite variable between strains of German cockroach. The AVER and LPR strains of house fly showed significant cross-resistance to imidacloprid. PBO reduced the level of cross-resistance in AVER from >4·2-fold to 0·5-fold (i.e. the AVER strain LD₅₀ was half that of the susceptible strain when both were treated with PBO), but PBO did not suppress the cross-resistance in LPR. These data suggest monooxygenases are the mechanism responsible for cross-resistance to imidacloprid in AVER, but not in the LPR strain. © of SCI.     

Metabolic detoxication and synergistic ratio of lindane analogs in house flies

Biodegradability of lindane analogs using house fly whole body, microsomes, and microsome supernatant fraction was examined. It decreased in the order of alkoxy ～ methylthio > methyl analogs > lindane in the whole body experiments, as well as with microsomes in the presence of NADPH. With the supernatant in the presence of glutathione, a different trend was observed. The synergistic effects of piperonyl butoxide when used together with lindane analogs were mostly explained in terms of the inhibition of the microsomal metabolism. Piperonyl butoxide was also shown to inhibit the penetration of compounds into the fly body and to make the central nervous system of the American cockroach less sensitive to the action of insecticides causing after and repetitive discharges. It was observed that the value of the percentage of metabolic disappearance of insecticides after a certain period decreases as the dose level initially applied in the whole body experiments increases. The synergistic ratio parallels the percentage of disappearance value after the insecticidal activity test period when a dose corresponding to the unsynergized LD₅₀ is initially applied. When quantitative comparisons are required for biodegradability of insecticides using house flies as the test insects, it should be on the basis of direct metabolism experiments using a fixed dose throughout the series of insecticides, but not on the basis of the synergistic ratio.     

Structural modifications increase the insecticidal activity of ryanodine

The toxicity of ryanodine ( 1 ) and 9,21-didehydroryanodine ( 2 ) (the principal active ingredients of the botanical insecticide ryania) to adult female house flies (Musca domestica L.) is attributable to binding to the ryanodine receptor (ryr) and thereby disrupting the Ca²⁺-release channel. These ryanoids, assayed in house flies with piperonyl butoxide (PBO) to suppress cytochrome P450-dependent detoxification, give injected KD₅₀ values of 0·07–0·11 μg g^-1, injected LD₅₀ values of 0·39–0·45 μg g^-1 and topical LD₅₀ values of 12– 50 μg g^-1. They inhibit the [³H]ryanodine binding site of house fly and rabbit muscle with IC₅₀ values of 3–10 nM . This study examines the effect of structure on potency, with 15 variants of the cyclohexane substituents, two 4,6-cyclic boron and two methylated derivatives, and four modifications of the isopropyl and ester substituents. The most effective compound examined was 10-deoxy- 2 ( 3 ) which was more potent than 2 by 2–4-fold on injection and 29-fold applied topically following PBO (LD₅₀ 0·41 μg g^-1). Additional high-potency compounds were 10-oxo- 1 and the cyclohexane variants with lactam, 21-nor-9-oxo and 21-nor-10-deoxy substituents. Other modifications usually reduced toxicity. The injected knockdown potency of the ester ryanoids was generally related to their effectiveness in competing with [³H]ryanodine at the ryr of rabbit skeletal muscle. Two non-ester ryanoids, ryanodol and 9,21-didehydroryanodol, were found to be more toxic than predicted from their potency at the ryr and may therefore act in a different manner such as at a K⁺ channel, as suggested by Usherwood and Vais. Clearly ryanoids are challenging prototypes for a potential new generation of insecticides. © 1997 SCI.     

Quantitative structure-activity study of insecticidal 2-methoxy-5-(substituted-phenyl)-1, 3, 2-oxazaphospholidine 2-sulfides against Musca domestica L. by topical application

The quantitative relationship between the structure of 2-methoxy-5-(substituted-phenyl)-1, 3, 2-oxazaphospholidine 2-sulfides (5-PMOS) and their insecticidal activity against the house fly. Musca domestica L., was analyzed using reported physicochemical parameters and regression analysis. The electronic nature of the substituent on the phenyl group of 5-PMOS has the most significant effect on the activity, followed by hydrophobic and steric effects; the optimum value of Σρ is zero and the more hydrophobic the substituents on the phenyl group, the higher the insecticidal activity. The plots of observed pLD₅₀, values against calculated pLD₅₀ values for compounds having substituents in the ortho-position deviated downwards from those of compounds having substituents at the meta and/or para positions. This ortho-effect, which reduces the insecticidal activity of compounds having substituents at the ortho-position, was expressed by a dummy parameter D, which has the value 2 for di-ortho-substituted derivatives, 1 for mono-ortho-substituted derivatives and zero for others. Thus, the highest activity was obtained for 2-methoxy-5-phenyl-1, 3, 2-oxazaphospholidine 2-sulfide, and the activity was decreased by the introduction of any substituents on the phenyl group.     

Multiple Resistance in the Larger House Fly Musca domestica in Germany

Populations of the housefly Musca domestica isolated from farms in different German districts with strong resistance problems were compared to laboratory strains with varying resistance spectra. Resistance against pyrethroids, organophosphates and carbamates was tested using impregnated filter papers, and by topical application using a susceptible housefly strain (origin WHO) for comparison. The multi-resistant fly strains tested had a strong resistance against these insecticide groups, ranging from 37- to >10000-fold for organophosphates and 150- to >6600-fold for pyrethroids. The constituent enantiomer pairs of the α-cyano-pyrethroid cyfluthrin were tested, as was beta-cyfluthrin. With respect to multi-resistant fly strains, the isomers II and IV had the best activity, with LD₅₀ values of 0·012 and 0·014 μg per fly, respectively. In addition, different groups of insect growth regulators (juvenile hormone analogues, chitin synthesis inhibitors and one triazine derivative) were tested in a special larvicidal test. The chitin synthesis inhibitors were quite effective against multi-resistant M. domestica strains except for one strain with strong resistance against chitin synthesis inhibitors, developed after extensive treatments with benzoylphenylureas for several years. The fly strains tested were not resistant against cyromazine. Additionally, the insecticides were combined with the synergists piperonyl butoxide, tributylphosphorotrithioate (DEF) and Cibacron blue and tested against the fly strain with the strongest resistance spectrum (‘Grimm’) in comparison to the susceptible strain (‘WHO-N’). Piperonyl butoxide had the greatest effect on the efficacy of cyfluthrin followed by Cibacron blue and DEF. In a parallel investigation with susceptible and resistant house fly strains, different enzyme activities related with resistance mechanisms were tested, e.g. glutathione S-transferase (3·5-fold) and mixed-function oxidase (2·3-fold). Implications of these results for management of insecticide resistance in M. domestica are discussed.     

Monitoring of resistance of insecticides in house fly (Musca domestica) populations in hungary

Samples of 24 house fly (Musca domestica L.) populations were collected from animal farms in Hungary in 1990 and kept in the laboratory to determine their susceptibility to different types of insecticide: organochlorines, organophosphates, carbamates, pyrethroids, macrocyclic lactone and insect growth regulators. The adulticides were tested with topical bioassay in all 24 populations, the larvicides were studied with treated larval medium in 16 populations. The data were expressed as LD₅₀ and LC₅₀ values (ng fly ?1 and mg kg ?1 larval medium respectively). The percentages of populations which had resistance ratios > 10 at LD₅₀ or LC₅₀ were: 63% to DDT, 50% to methoxychlor, 13% to lindane, 83% to malathion, 63% to trichlorfon, 4% to propetamphos, 96% to dioxacarb, 46% to propoxur, 4% to methomyl, 13% to pyrethrum, 96% to bioresmethrin, 63% to permethrin, 58% to cypermethrin, 79% to SK-80, 79% to deltamethrin, 38% to invermectin, 0% to diflubenzuron, 0% to cyromazine. Correlation analysis showed a high degree of positive correlation among the adulticides except for ivermectin, bioresmethrin and SK-80. No cross-resistance was found between the larvicides and the conventional adulticides. Differences of insecticide resistance levels among the populations surveyed were studied by principal component and factor analysis. A fairly good relationship between resistance status and control practices used on farms was revealed. The populations originating from those farms where the application of adulticides had been frequent or regular and where high resistance was shown to most chemicals could be separated from the others.     

In vitro inhibition of acetylcholinesterase by O,O-dimethyl S-aryl phosphorothioates

In vitro inhibition of house cricket head, house fly head, and bovine erythrocyte acetylcholinesterase by O,O-dimethyl S-aryl phosphorothioates was studied by Main's kinetic treatment. The potency of the compounds as reflected by the bimolecular reaction constants (k_i) indicated that house fly head acetylcholinesterase was the most sensitive to the inhibition followed by house cricket head and bovine erythrocyte acetylcholinesterase. There are no linear relationships between the phosphorylation rate constants and the total binding energies for the inhibition of three enzymes by this series of compounds, suggesting that the initial binding and the phosphorylation rate are not related. The structure and activity relationships were analyzed by multiple regression analyses with the use of Hammett's sigma, alkaline hydrolysis rates of the compounds, and p_i constants. The hydrophobic bonding of the compound on the enzyme surface as reflected by the p_i constant played a significant role in the determination of the potency of the inhibition of house cricket head and house fly head acetylcholinesterase by those compounds. However, the alkaline hydrolysis rates of the compounds, or the Hammett's sigma values seems to play a more important role in the determination of the inhibition of bovine erythrocyte acetylcholinesterase. Moderate insecticidal activity toward house crickets, house flies, and mosquito larvae were found.     

Toxicokinetics of carbofuran in house fly, Musca domestica L

The kinetics of accumulation and elimination of lethal doses of [¹⁴C]carbofuran in the hemolymph of the house fly suggest a one-compartment open model. Carbofuran in the hemolymph appeared to be in equilibrium with that in the tissues very soon after treatment.Following topical application of carbofuran, the rate of onset of symptoms of poisoning was correlated with the amount of carbofuran in the hemolymph, and the onset of convulsions only occurred after the concentration of carbofuran in the hemolymph reached μM levels. This value correlated well with neurobioassays of known concentrations of carbofuran perfused in saline onto the isolated thoracic ganglion.Following topical doses, carbofuran concentration in the hemolymph reached a peak within an hour and then gradually declined. At an LD₆₀ dose, the initial decline in carbofuran concentration in the hemolymph over time was significantly slower than the decline after an LD₁₀ dose, suggesting saturation kinetics.Hemolymph was collected from house flies for up to 3 hr following topical application of toxic amounts of carbofuran. Thereafter, hemolymph volume decreased and blood samples could not be collected. Curiously, hemolymph samples could be collected for 5 hr from house flies that were injected with toxic doses of carbofuran.     

Insecticidal activity and microsomal metabolism of biooxidizable lindane analogs

The insecticidal activity of lindane analogs, in which some chlorine atoms were replaced by other groups susceptible to microsomal oxidative metabolism, was determined against mosquitos, house flies, and German cockroaches. When tested with a synergist, piperonyl butoxide, one of the methylthio analogs was as active as lindane, whereas several others were also highly active. By examining the ratio of synergized and unsynergized LD₅₀ values (synergistic ratio value), the highly insecticidal methylthio, methoxy, and methyl analogs appear to undergo metabolic detoxication effectively in house flies. By means of in vitro metabolism experiments using microsomal fraction from house fly abdomen, the methoxy, ethoxy, and methylthio analogs were shown to be metabolized rapidly at similar rates. The synergized insecticidal activities of these compounds against various insect species relate linearly with each other, suggesting that the oxidative degradation is inhibited by the synergist to a similar extent and that the transport process to the site of action is not a limiting factor in determining the relative insecticidal activity.     

Mechanisms of resistance to diflubenzuron in the house fly, Musca domestica (L.)

The mechanisms of resistance to the chitin synthesis inhibitor diflubenzuron were investigated in a diflubenzuron-selected strain of the house fly (Musca domestica L.) with > 1000 × resistance, and in an OMS-12-selected strain [O-ethyl O-(2,4-dichlorophenyl)phosphoramidothioate] with 380 × resistance to diflubenzuron. In agreement with the accepted mode of action of diflubenzuron, chitin synthesis was reduced less in larvae of the resistant (R) than of a susceptible (S) strain. Cuticular penetration of diflubenzuron into larvae of the R strains was about half that of the S. Both piperonyl butoxide and sesamex synergized diflubenzuron markedly in the R strains, indicating that mixed-function oxidase enzymes play a major role in resistance. Limited synergism by DEF (S,S,S-tributyl phosphorotrithioate) and diethylmaleate indicated that esterases and glutathione-dependent transferases play a relatively small role in resistance. Larvae of the S and R strains exhibited a similar pattern of in vivo cleavage of ³H- and ¹⁴C-labeled diflubenzuron at N₁C₂ and N₁C₁ bonds. However, there were marked differences in the amounts of major metabolites produced: R larvae metabolized diflubenzuron at considerably higher rates, resulting in 18-fold lower accumulation of unmetabolized diflubenzuron by comparison with S larvae. Polar metabolites were excreted at a 2-fold higher rate by R larvae. The high levels of resistance to diflubenzuron in R-Diflubenzuron and R-OMS-12 larvae are due to the combined effect of reduced cuticular penetration, increased metabolism, and rapid excretion of the chemical.     

CNS insensitivity to pyrethroids in the resistant kdr strain of house flies

Solutions of tetramethrin, RU 11679, or cismethrin caused uncoupled convulsions in 30–40 min in exposed thoracic ganglia from S_NAIDM house flies at concentrations down to 10^?10M: whereas these same compounds at 10^?6M concentrations failed to produce poisoning symptoms when perfused onto the exposed ganglia of the kdr strain of house fly. The pyrethroid analogs examined had a negative temperature coefficient of action on the exposed thoracic ganglia from S_NAIDM flies. DDT and GH-74 possessed positive temperature coefficients of action on the exposed thoracic ganglion of susceptible house flies. It is concluded that the central nervous system of the kdr strain of house fly is resistant to pyrethroid action; furthermore, the resistance appears to be widespread throughout the house fly nervous system, involving sensory, motor, and central neural elements.     

Heterocyclic Insecticides Acting at the GABA-Gated Chloride Channel: 5-Alkyl-2-arylpyrimidines and -1,3-thiazines

5-tert-Butyl-2-(4-ethynylphenyl)pyrimidine and the corresponding 2,5-disubstituted-4H-1,3-thiazine block the GABA-gated chloride channel at c.20and c.200 nm , respectively, measured as 50% inhibition of the binding of 1-(4-ethynylphenyl)-4-[³H]propyl-2,6,7-trioxabicyclo[2.2.2]octane (4′-ethynyl-4-n-[³H]propylbicycloorthobenzoate; [³H]EBOB) in house fly and mouse brain membranes, and they are also toxic to topically-treated flies with LD₅₀ values of 6–27 μg g⁻¹ alone and 2–6 μg g⁻¹ with piperonyl butoxide (PB) as synergist. In the pyrimidine series, the general pattern of effectiveness of substituents in the 5-position is tert-butyl>isopropyl≈cyclohexyl≈cyclopropyl>methyl, phenyl and 3- and 4-fluorophenyl, and in the 2-position is 4-ethynylphenyl≪4-bromophenyl. These planar pyrimidines and nearly-planar 4H-1,3-thiazines with 2-ethynylphenyl or 2-bromophenyl and 5-tert-butyl or 5-isopropyl substituents are more effective than the corresponding 6H-1,3-thiazine, 6-oxo-1,3-thiazines and 4,6-dioxo-1,3-thiazine examined, but they are less active than the analogous conformationally flexible trans-1,3-dioxanes and -1,3-dithianes. The heterocyclic moiety confers a region of high electron density and positions the 2- and 5-substituents in a linear or parallel relationship for optimal affinity at the receptor. Two observations indicate that the new pyrimidines and thiazines probably act as chloride channel blockers. First, the poisoning signs are identical to those of EBOB in both mice and house flies. Second, each of the pyrimidines, thiazines and dioxanes falls on the same correlation line for inhibition of [³H]EBOB binding and toxicity to house flies (with PB) as that obtained earlier for EBOB analogs, dithianes and polychlorocycloalkanes, suggesting that they all act at the same or closely coupled binding sites in the GABA-gated chloride channel.     

Potential of zimtaldehyde, 4-allyl-anisol, linalool, terpineol and other phytochemicals for the control of the confused flour beetle (Tribolium confusum J. d. V.) (Col., Tenebrionidae)

Toxicity and repellency effects of several pure compounds (of plant origin) against the confused flour beetle (Tribolium confusum) were investigated in a filter paper test. The compounds were α-pinen, β-pinen, 4-allyl-anisol, camphor, 1,8-cineol, eugenol, linalool, menthol, piperin, terpineol, thymol and zimtaldehyde. Five compounds (4-allyl-anisol, linalood, terpineol, thymol and zimtaldehyde) caused enough mortality of this insect to allow the determination of LD₅₀ and LD₉₅ values. Zimtaldehyde and 4-allyl-anisol showed the strongest toxicity effects with LD₅₀ values of 0.04–0.05 μl/cm² within an exposure period of 24 h. When the isolated fumigant effects were tested by separating the insects from the filter paper, the toxicity of zimtaldehyde (LD₅₀=0.29 μl/cm²) was much lower than that of 4-allyl-anisol (LD₅₀=0.10μl/cm²).     

Potential of zimtaldehyde, 4-allyl-anisol, linalool, terpineol and other phytochemicals for the control of the confused flour beetle (Tribolium confusum J. d. V.) (Col., Tenebrionidae)

Toxicity and repellency effects of several pure compounds (of plant origin) against the confused flour beetle (Tribolium confusum) were investigated in a filter paper test. The compounds were α-pinen, β-pinen, 4-allyl-anisol, camphor, 1,8-cineol, eugenol, linalool, menthol, piperin, terpineol, thymol and zimtaldehyde. Five compounds (4-allyl-anisol, linalood, terpineol, thymol and zimtaldehyde) caused enough mortality of this insect to allow the determination of LD₅₀ and LD₉₅ values. Zimtaldehyde and 4-allyl-anisol showed the strongest toxicity effects with LD₅₀ values of 0.04–0.05 μl/cm² within an exposure period of 24 h. When the isolated fumigant effects were tested by separating the insects from the filter paper, the toxicity of zimtaldehyde (LD₅₀=0.29 μl/cm²) was much lower than that of 4-allyl-anisol (LD₅₀=0.10μl/cm²).     

Studies on the chiral isomers of fonofos and fonofos oxon: I. Toxicity and antiesterase activities

The toxicity of the (R)_P and (S)_P chiral isomers and racemates of fonofos and fonofos oxon to insects and white mice were determined. (R)_P-Fonofos and (S)_P-fonofos oxon were 2- to 12-fold more toxic to house flies, mosquito larvae, and mice than were the corresponding enantiomers. The racemates were intermediate in toxicity. Stereoselectivity also was observed in the in vitro inhibition of house fly-head and bovine erythrocyte acetylcholinesterase, horse serum cholinesterase, chymotrypsin, trypsin, and a variety of esterases. In all cases the (S)_P-oxon was a more potent inhibitor than the (R)_P-oxon with k₁ ratios of $\text{(S)}{}_{\mathrm{<mtext>P</mtext>}}\text{(R)}{}_{\mathrm{<mtext>P</mtext>}}$ ranging from 4- to 60-fold. Further, differences in levels of house fly-head, mouse brain, and blood cholinesterase obtained from house flies and mice treated with the enantiomers and racemates of fonofos and fonofos oxon were observed. Differences in toxicity of the enantiomers and racemates to house flies and mice were more closely related to in vivo than to in vitro cholinesterase inhibition.     

Metabolism of O,S-dimethyl propionyl- and hexanoylphosphoramidothioate in the house fly and white mouse

The metabolism of O,S-dimethyl propionyl- and hexanoylphosphoramidothioate was investigated in the white mouse and house flies. Compared to the hexanoylphosphoramidothioate, the propionyl analog is approximately 35-fold more toxic to house flies and is 10-fold less toxic to mice. On a percentage basis, substantially larger amounts of methamidophos were detected in house flies treated topically with the propionylphosphoramidothioate than in flies treated with the hexanoyl derivative. The reverse was evident in the case of the mouse where much larger amounts of methamidophos were formed after oral treatment with the hexanoylphosphoramidothioate. Minor amounts of other metabolic products also were detected, including an unknown from the hexanoylphosphoramidothioate. Metabolism of the S-methyl moiety to carbon dioxide appeared to be a major pathway for metabolic degradation of both compounds in both the white mouse and house fly. The difference in toxicity of the two acylphosphoramidothioates to the mouse and house fly is attributed to difference in the amounts of methamidophos formed in the animals.