IE58471B1 - Insecticidal composition comprising more than one active ingredient - Google Patents

Description

This invention relates to insecticidal compositions comprising more than one pyrethroid active ingredient of the Formula (I) the use thereof, the active ingredients and a process for the preparation of the same.

In the present specification the spatial configuration of the substituents related to the chiral carbon atom denoted with L'.oc is characterized by S and R, respectively. The designations cis and trans, respectively, mark the position of the ij substituents attached to carbon atom ”3” of the cyclopropane ring related to the spatial configuration of the substituents of carbon atom 1. The absolute spatial configuration of the substituent attached to carbon atom ”1 is denoted with the prefix IR” and IS, respectively.

In the present specification the various enantiomers and enantiomer-pairs are designated with the following abbreviations: Ia mixture of lb mixture of Ic mixture of Id mixture of If IReisS Ig IRtransS Ih IScisR Ii IStransR It is known that pyrethroids of the Formula (I) (known under the generic name cypermethrin) belong to the valuable family of synthetic pyrethroids and are useful as insecticide (Hungarian patent No. 170,866). These compounds may be prepared by reacting m-phenoxy-benzaldehyde cyanohydrin with the corresponding cyclopropane carboxylic acid chloride in the presence of a base CPestic. Sci. 6, 537-··. (1975)1· The product thus obtained consists of eight stereoisomers i.e. of a mixture of four enantiomer-pairs. If a 60:40 mixture of the corresponding trans & and. cis cyclopropane carboxylic acid, chlorides is used., the mixture contains 18-19 % of enantiomer-pair Ia, 21-22 % of enantiomer-pair Ic, 26-27 % of enantiomer-pair lb and. 33-34 % of enantiomer-pair Id.

According to prior art the stereoisomers of cypermethrin show different biological activity. It is generally accepted that the activity of molecules comprising cis cyclopropane carboxylic acids is superior to that of the corresponding trans derivatives CPest. Sci. 7, 273 (1976)].

In the comparative biological tests of various pyrethroids CPest. Sci. 9, 112-116 (1978)] the cis and trans stereoisomers - including the cypermethrin stereoisomer-pairs - were evaluated together.

The comparative tests were carried out on Musca domestica L. and Phaedon cochleariae Pab species. Concerning tne chloro derivatives from the trans isomers activity data of IRtransS (Ig) and IRtransR were disclosed. The said data show that while the IRtransS isomer possesses a strong activity - the IRtransR isomer is considerably less active Caccording to the test the activity related to bioresmetrine (100) amounts to 1400 and 81, respectively, on Musca domestica and to 2200 and 110, respectively, on Phaedon cochleariae]. It was disclosed further on that the activity of a mixture of both t) tested, isomers was lower than the calculated value. Thus the isomers showed an antagonism rather than the expected synergism and the rate of antagonism amounted to 1.42 and 1.46 on house fly and mustard beetle, respectively.

As a result of the said tests and publications the trans isomers and mixtures thereof were pushed to the background of biological interest and research was focused to active cis derivatives and mixtures thereof. This lead to the development of alphametrine (isomer mixture of IReisS and IScisR (Ia) of the chloro derivatives) and decametrine (comprising the IReisS isomer (If) of the bromo derivatives] .

Similar data were set forth for the bromo derivative; on mustard beetle the rate of antagonism amounts to 1.48.

According to an aspect of the present invention there is provided a synergistic insecticidal composition containing more than one active ingredient and being harmless to environment characterized by comprising in an amount of from 0.001 to 99 % by weight a synthetic pyrethroid of the Formula (I) containing at least 95% of the IRtransS and IStransR enantiomer-pair (lb) out of the possible eight isomers - optionally in admixture with an amount of up to 100 % by weight of one or more activator(s) and auxiliary agent(s), particularly antioxidants, stabilising agents, wetting agents, emulsifying agents, dispersing agents, antifoam agents, diluents and/or fillers.

Thus according to the present invention there are provided insecticidal compositions comprising an isomer mixture having a purity of at least 95 %· The said isomer mixture is a new crystalline substance, the physicochemical data thereof being disclosed in the Examples.

The present invention is based on the recognition that isomer-mixture Ib possesses useful and advantageous biological properties. This is surprising even if it is taken into consideration that in the field of pyrethroids of the Formula (I) extended experimental work was accomplished and a number of publications and patents were published.

Thus the present invention is based on the recognition that when using a combination of the IRtransS isomer Ig (being the most active trans isomer of the compounds of the Formula (I)) and the IStransR isomer Ii (being ranged among the less ac25 tive isomers from the remaining seven isomers) no antagonism characteristic of the earlier published isomer-pairs is observed.

Moreover a synergistic effect occurs over the additive effect of the pure Ig and Ii isomers when used per se.

The above recognition enables a new type of selection from the isomers of synthetic pyrethroids in order to develop a new active ingredient type having outstanding properties. The said new active ingredient shows various advantages over hitherto known isomer selections: - lower toxicity on warm-blooded species and humans; - more economical manufacturing process; - smaller damage caused to useful parasites and bees .

A significant and decisive advantage of the isomer-mixture lb of the present invention is that it causes no allergy and skin diseases which were generally observed on the use of the corresponding cis cypermethrin isomers of similar activity.

The synergistic activity of the components of the isomer-mixture lb is so much the more surprising as no similar synergism takes place between the components of the isomer mixture Ia.

According to aspects of the present invention there are provided the selected isomer pair, an insecticidal composition conprising the same and a process for the preparation and the use thereof.

According to a still further aspect of the present invention there is provided a process for the preparation of the said new isomer pair. According to a particularly important aspect of the present invention there is provided a process for the preparation of the cypermethrin isomer-pair lb which enables the highly economical preparation of an active ingredient having the same order of activity as the active ingredient which was hitherto available only by means of the very expensive isolation procedure of a pure and single cis isomer.

According to a further aspect of the present invention there is provided a synergistic insecticidal composition containing more than one active ingredient and being harmless to environment characterized by comprising in an amount of from 0.001 to 99 % by weight a synthetic pyrethroid of the Formula (I) containing at least 95% of the IRtransS and IStransR enantiomer-pair (lb) out of the possible eight isomers - optionally in admixture with an amount of up to 100 % by weight of one or more activator(s) and auxiliary agent(s), particularly antioxidants, stabilising agents, wetting agents, emulsifying agents, dispersing agents, antifoam agents, diluents and/or fillers .

According to a further aspect of the present invention there is provided an isomer mixture lb having a purity of at least 95 % and comprising the IRtransS and IStransR enantiomer-pair of the Formula (I).

The physical constants of the said enantiomer-pair are as follows: IR(KBr) 9C=O = 1735 cm1 NMR (CDC13) 2; 1.69d IH Cl; 2.32 m IH C3; 5«6,d. IH Cl; 6.39 s IH alphaproton.

The said pure enantiomer-pair is a white crystalline material, never described in prior art according to our best knowledge. The melting point of the 1:1 mixture of the isomers amounts to 80.5-81.5 °C. It is to be noted that the components Ig and Ii of the isomer-pair are not crystalline per se. Accordingly in addition to biological and economical advantages the combination of the present invention facilitates the process of manufacture, the formulation procedure, storing and method of treatment as well.

The isomer-pair lb of the present invention is superior to the known combinations from the point of view of side'effects , too. The new isomer-pair of the present invention has a very low toxicity on bees and does not damage useful entomophages and parasites (see biological Examples 4 and 5). This is due to the repellant effect, preferable persistence and suitable inherent activity of the active ingredient. As a result of the above advantageous properties the insecticidal composition of the present invention may be useful in integrated plant protecting technology (IPM = Integrated Pest Management).

The present invention is based on the further recognition that the enantiomer-pair of the present invention has substantially the same insecticidal activity as the enantiomer-pair Ia hut is significantly less toxic to warm-blooded species. This is clearly substantiated by the selectivity index ( 7800) being the quotient of approximative LD^q toxicity values on rats ( 5000 mg/kg) and house fly (0.64 mg/kg). The said selectivity index of the enant iomer-pair Ia amounts to 50/0.45 = 111.

The isomer-pair Ih is less toxic to parasites than the isomer-pair Ia and this is of particular importance. For this reason the insecticidal composition of the present invention may be used more safely, because on the edge of the sprayed area and after treatment (i.e. in area treated with a small concentration of the active ingredient) the parasites and bees are not killed. The repellant effect of the isomer-pair Ih is outstandingly good, too.

The insecticidal compositions of the present invention comprising the isomer-pair Ih in admixture with known additives may he formulated in forms suitable for direct use.

The compositions of the present invention may he ULV (ultra-low-volume) compositions, spray, dispersible powders, granules, wettable and other powders, stable emulsions etc. The said compositions ii Λ are suitable for the pesticidal treatment of vegetables, orchards, fields of cereals and other large scale cultures. Due to the low toxicity the compositions of the present invention are particularly suitable for combating .flying insects and pests having a hidden mode of life in households, stables and also for use in bathing of domestic animals and for the treatment of pasture .

According to a further aspect of the present invention there is provided the use of the said insecticidal compositions. It is preferred to use the said compositions under field conditions at a rate of 2-25 g of active ingredient per hectare.

The insecticidal compositions of the present invention may comprise in addition to the isomer-pair Ih activators and further synergists, e.g. piperonyl butoxide. The said additives strengthen the efficiency of the active ingredient without increasing the toxicity to warm-blooded species.

According to a preferred embodiment of the present invention there are provided dispersible granules comprising 1-99 % by weight of the active ingredient in admixture with 99-1 % by weight of suitable additives. As auxiliary agent e.g. 0.1-1 % by weight of anionic and/or non-ionic surfactants may be used, such as alkali salts of alkyl-aryl sulfonic acids, alkali salts of condensation products of alkyl aryl sulfonic acids and formaldehyde, alkyl-aryl-polyglycol £ 9 ether, sulfated long-chained alcohols, polyethylene oxides, sulfated fatty alcohols, fatty acid polyglycol esters and various other commercially available surfactants.

The insecticidal compositions of the present invention may also be formulated in the form of concentrates comprising preferably 5-50 % by weight of the active ingredient in admixture with 50-95 % by weight of additives which enable the formation of a stable emulsion when emulsifying the emulsion concentrate in or in the presence of water.

As additive 1-20 % by weight of a tenside and/or 0.1-5 % hy weight of a stabilising agent may be used and the mixture may be preferably filled up to 100 % with an organic solvent.

It is preferred to use as tenside a mixture of anionic and non-ionic tensides having a HLB-value of 8-14. The following tensides may be preferably applied: calcium salts of alkyl aryl sulfonic acids, mono and diesters of phosphoric acid, nonyl and tributyl phenol polyglycol ethers, adducts of fatty alcohols and ethylene oxide, fatty acid polyglycol esters, ethylene oxide-propylene oxide block polymers etc.

As solvent preferably mixtures of aromatic hydrocarbons (e.g. xylenes), cyclohexanol, butanol, methyl ethyl ketone, isopropanol etc. may be used.

The compositions of the present invention may also comprise further synergists which enable the reduction of the amount of the active ingredient. For this purpose preferably piperonyl butoxide may be applied.

According to a further aspect of the present invention there is provided a process for the preparation of a product containing at least 95% of the enantiomer-pair IRtransS + IStransR (lb) out of the eight possible isomers of the compounds of the Formula (I) from mixtures comprising other isomers of further components, too.

The enrichment of cypermethrin mixtures in isomers having presumably a higher activity is described in several patent specifications. According to a patent publication LC.A. Vol. 95, (1981), Japanese Pat. KOKAI No. 57755/81] a crystalline cypermethrin isomeric mixture comprising 86.9 % of Ic, 9.5 % of Ia and 5.6 % of Ib+Id is prepared by seeding a mixture comprising 53·5 % of Ic, 38.7 % of Ia and 7·8 % of Ib+Id. In this case it was expected that the biological activity of the compounds remaining in the mother-lye would be higher.

It is the object of the other known procedures, too, to prepare cis isomer-pairs or substances enriched in cis isomer-pairs. According to a known process a mixture of enantiomer-pairs Ia and Ic is subjected to epimerisation to convert the Ic enantiomer-pair into Ia enantiomer-pair and to produce the known alphametrine and decametrine, respectively, hy asymmetrical transformation [Chem. and Ind. , P/larch 19, 1985, 199-204; British patent application No. 13308; EP No. 0 067461; Dutch patent No. 888431, see Derwent 79766D].

Prior art is silent in teaching any methods directed to the preparation of trans isomers.

According to a further aspect of the present invention there is provided a process for the preparation of an isomer mixture lb containing at least 95% of the enantiomer-pair IRtransS and IStransR - i.e. substantially only two out of the eight possible isomers of the compounds of the Formula (I) - from mixtures comprising also other isomers of the Formula (I) which comprises a) preparing a saturated solution from a mixture comprising the desired isomers in admixture with further possible isomers with a protic or apolar aprotic inert organic solvent, seeding the solution with a seeding crystal consisting of the enantiomer-pair IRtransS + IStransR and isolating the precipitated crystals at a temperature between +30 °C and -30 °Cj or b) seeding a melt of a mixture comprising the desired isomers in admixture with further possible isomers at a temperature between 10 °C and 60 °C with a seeding crystal consisting of the lRtransS+ +lStransR enantiomer-pair, crystallizing at a Ο ο temperature between 30 C and -10 C, and if desired suspending the mixture thus obtained in a protic or apolar aprotic organic solvent at a temperature between -10 °C and -20 °C and isolating the separated crystals; or c) subjecting a mixture comprising the desired isomer-pair lb in admixture with further possible isomers to chromatography in an organic solvent preferably on a silica gel or Kieselguhr adsorbent ; or d) dissolving a mixture comprising trans isomers of the compounds of the Formula CO in a protic or apolar aprotic solvent, seeding the solution with a seeding crystal consisting of the enantiomer-pair IRtransS + IStransR (lb), isolating the precipitated crystalline product lb, and thereafter if desired epimerising the mixture comprising lb + Id being present in the mother-lye with an organic or inorganic base and if desired repeating the said step and/or the crystallizing step; or e) dissolving the mixture comprising the trans isomers in a secondary or tertiary organic amine base comprising 4-9 carbon atoms - optionally by adding an organic solvent - and seeding the solution thus obtained with a seeding crystal consisting of IRtransS + IStransR isomers and thereafter isolating the precipi16 tated crystals.

According to variants a) and e) of the process of the present invention one may preferably proceed by using a hydrocarbon, C-^_^ chlorinated hydrocarbon, dialkyl ether or alcohol as organic solvent. The said solvents may be straight or branched chained, and cyclic or alicyclic, respectively.

It is preferred to carry out seeding with a seeding crystal in the presence of an antioxidant - particularly tertiary butyl hydroxy toluene or 2,2,4-trimethyl-quinoline - and to use ethanol, isopropanol petrolether or hexane as solvent.

According to variant d) of the process of the present invention it is preferred to use a ^4-10 Qhhane, cycloalkane, C^L-g alkanol and/or ^5-8 cycl°alhanol or a mixture thereof as solvent.

One may particularly advantageously use hexane, petrolether, cyclohexane, methanol, ethanol or isopropanol .

In the epimerisation step ammonia, secondary or tertiary alkyl amines or cyclic amines may be used as basic substance. Thus one may preferably use triethyl amine, diethyl amine, morpholine, pyrrolidine piperidine, diisopropyl amine, ephedrine, triethylene diamine, benzyl amine, n-butyl amine, secondary butyl amine, tetrabutyl ammonium hydroxide, sodium hydroxide, potassium tertiary butoxide, sodium isopropoxide or an ion-exchanging resin comprising a quaternary ammonium compound or a catalytic amount of an amine having a large molecular weight.

As solvent it is preferred to use methanol, ethanol, isopropanol, petrolether or hexane.

The said reaction variants may be particularly economically used if the total manufacturing line comprises the use and preparation of isomers of the Formula (I) other than lb, too.

\ If the synthetic cypermethrin manufacturing process makes it possible and if it is the aimed object of the invention to manufacture only a mixture of trans cypermethrins hy means of one of the esterifying procedures, variant e) of the process of the present invention is particularly suitable for the economical manufacture of isomer-pair Ih. According to the said variant e) namely the complete amount of the trans mixture is converted into the desired enantiomer-pair Ih.

According to variant e) it is preferred to use triethyl amine, morpholine, pyrrolidine, piperidine, diisopropyl amine, ephedrine or secondary butyl amine as organic amine base.

It was a pre-condition of the feasibility of variant e) to provide and prepare highly pure seeding crystals having a purity over 95 % and melting above 80 °C from the non-crystallizing pure isomers Ii and Id. This enables the aimed directed Ad asymmetrical transformation.

One may proceed futher on preferably by dissolving the mixture in the amine in the presence of an organic solvent. For this purpose the solvents enumerated by variant a) may be used.

According to variant a) one may proceed by dissolving the isomer mixture of trans cypermethrins - comprising the IRtransS, IStransR, IRtransR and IStransS isomers - in triethyl amine. Crystalline starting materials are dissolved at a temperature between 40 °C and 70 °C and the solution obtained may be filtered. An oily cypermethrin mixture may be dissolved at room temperature as well.

Crystallization of the IRtransS + IStransR isomer-pair may be carried out by seeding the solution at room temperature with crystals of a 1:1 mixture of the IRtransS and IStransR isomers (recommended purity 99.8 %) and thereafter subjecting the mixture thus obtained to crystallization at a temperature between 0 °C and 20 °C with or without stirring. The precipitated crystals are separated by filtration or centrifuging and the mother-lye adhered to the surface of the crystals is washed off with an alkane (preferably a solvent of the cycloalkane type particularly petrolether). The united mother-lyes are completely concentrated. The said crystallization procedure may be repeated. The asymmetrical transformation may be preferably accomplished in a dry inert gas (prefer19 ably nitrogen) atmosphere.

According to the above process a IRtransS + IStransR isomer-mixture having a purity of about 95 % may be prepared with a yield of 80 % per step. The purity may be increased to 99-99.5 % by means of further recrystallization from an alcohol, particularly isopropanol.

If the base serves as solvent, too, it is preferred to use an amine base having a water content not higher than 0.2-0.4 %. Cis isomer contaminations of the trans cypermethrin mixture used as starting material may decrease the yield.

The insecticidal compositions of the present invention are harmless to environment and can be used particularly in household and stables for combating flying insects and pests having a hidden mode of life and also for bathing domestic animals and for the treatment of pasture.

Further details of the present invention are to be found in the following chemical and biological examples without limiting the scope of protection to the said Examples.

Chemical Examples Example 1 g of a cypermethrin mixture consisting of 18.2 % of Ia, 21.8 % of Ic, 26.8 % of Ib and 33.2 % of Id are dissolved in 50 ml of a 95:5 mixture of n-hexane and tetrahydrofuran. The solution is subjected to chromatography on a column comprising 500 g of silica gel G. 25 ml fractions are collected by using a 95:5 mixture of n-hexane and tetrahydrofuran as eluting agent. Fractions corresponding to an R^ value of 0.2 are collected (as TLC running mixture a 95:5 mixture of n-hexane and tetrahydrofuran is used). The said fractions are evaporated in vacuo.

The residue thus obtained (2.9 g) is dissolved in 29 ml of ethanol at 45 °C and crystallized at 0 °C. The precipitated product is filtered off, washed twice with 10 ml of icecold ethanol each and dried in vacuo. Thus 2.6 g of a white crystalline product are obtained, mp: 80.2 °C.

Analytical characteristic data: Rf = 0.2 (Kieselguhr G plate, 95:5 mixture of n-hexane and tetrahydrofuran) IR (KBr) = 1735 cm1 V* —- u NMR (CDCl-p 8 (ppm) = 1.22, 1.27, CMe2; 1.69, d, IH Cl; 2.32, m, IH C3; 5.6, d, IH Cl’; 6.39, s, IH, C alpbaproton.

-CM. ft.

Example 2 To 10 g of a crystalline trans cypermethrin mixture (comprising 53.9 % of IRtransR and IStransS isomers and 43.3 % of ib isomers ac5 cording to gas chromatography) 15 ml of anhydrous triethyl amine are added. The mixture is heated under nitrogen and under constant stirring to 60 °C, whereupon the solution is quickly filtered and cooled to 30 °C. The clear colourless solution thus obΙθ tained is seeded with a seeding crystal of a 1:1 mixture of lb isomers, cooled to room temperature and allowed to crystallize for a day. The mixture is filtered cold. The product is dried at room temperature. Thus 8.4 g of a snow-white crystalline product are 15 obtained. Mp.: 79.5-80.5 °C. According to gas chromatography analysis the product comprises 95 % of a 1:1 mixture of the desired lb isomers. The mother-lye is evaporated. On repeating the above steps 1.05 g of white crystalline product are obtained as second θ crops, mp.: 79-80 °C.

The united product is recrystallized from 50 ml of isopropanol. 8.5 g of a snow-white crystalline product are obtained as.first crops, mp.: 80.5 °C, active ingredient content 9θ %. On further recrystal5 lization 7.5 g of a crystalline product are obtained, mp.: 81.5 °C, active ingredient content above 99.5 %· IR (KBr) = 1735 cm1 NMR (CDC13) (ppm) = 1.22, 1.27 CMe2; 1.69, d, IH Clj 2.32, m, IH C3; 5.6, d, IH Cl’; 6.39, s, IH, C alphaproton.

Example 3 100 g of an oily crude (purity 95 %) trans cypermethrin mixture (comprising 48 % of IRtransR and IStransS isomers and 47 % of Ih isomers according to gas chromatography) are dissolved in a solution of 150 ml of anhydrous triethyl amine and 0.2 g of tertiary butyl hydroxy toluene under stirring. The solution is quickly filtered, seeded, twice crystallized and recrystallized in an analogous manner to Example 2. Thus 82 g of snow-white crystalline isomer pair lb are obtained, mp.: 80-80.5 °C, active ingredient content 97-5 %· Example 4 g of oily trans cypermethrin mixture (comprising 85 % of IRtransR and IStransS isomers and 14 % of lb isomers) are dissolved in 15 ml ,of anhydrous triethyl amine under stirring at room tempera ture, whereupon the solution is filtered and crystallized as described in Example 2. Thus 8 g of snow-white crystalline isomer mixture lb are obtained, mp.: 79-80.5 °C.

Example 5 g of crystalline trans-cypermethrin (comprising 52 % of IRtransR and. IStransS isomers and. 47 % of lb isomer-pair) are dissolved, in 15 ml of tri-n-propyl amine at 50 °C. The solution is filtered, cooled to 30 °C and seeded with a seeding crystal consisting of a 1:1 mixture of the lb isomers. The mixture is allowed to crystallize for 48 hours. Thus 8.2 g of a snow-white crystalline product are obtained, mp.: 78-80 °C. Purity 95 % (according to gas chromatography analysis).

Example 6 One proceeds according to Example 5 except that 15 ml of tributyl amine are used as base.

Thus 7-5 g of snow-white crystalline isomer-pair lb are obtained, mp.: 77-79 °C, purity 93 %.

Example 7 One proceeds according to Example 5 except that 15 ml of triisopropyl amine are used as base. Thus 7·5 g of snow-white crystalline isomer-pair lb are obtained, mp.: 78-80 °C, purity 95.5 %.

Example 8 One proceeds according to Example 5 except that 15 ml of diisopropyl amine are used as base.

Thus 8.0 g snow-white crystalline isomer-pair Ih are obtained, mp.: 78-80 °C, purity 95-5 %· Example 9 g of trans cypermethrin (comprising 48 % of IRtransS and IStransR isomers and 49 % of id isomer-pair) are dissolved in 50 ml of isopropanol under stirring and heating whereupon 2 ml of an aqueous ammonium hydroxide solution are added (specific weight 0.880 g/ml). The solution is seeded with seeding crystals of the isomer-mixture Ih, stirred at 20 °C for 24 hours, cooled to 0 - 5 °C, and stirring is continued at this temperature. The suspension is filtered, the product is washed with isopropanol and petrolether and dried. Thus 6 g of white crystalline isomer-pair lb (1:1) are obtained, mp.: 78-79 °C, purity 92 % (GC analysis). From the mother-lye 1.5 g of white crystalline product are obtained as second crops. Mp.: 78-79 °C. The composition of the second crops is identical with that of the crystals of the first generation.

Example 10 g of trans cypermethrin (comprising 54 % of IRtransS and IStransR isomers and 45 % of isomers id are dissolved in 100 ml of petrolether (b.p.: 60-80 °C) whereupon 1 ml of a 0.5 molar sodium carbonate solution and a 1:1 vol. mixture of water and methanol comprising 10 w/v of tetrabutyl ammonium bromide are added. The solution is seeded with a seeding crystal according to Example 2, allowed to crystallize for 4 days, filtered, washed with petrolether and dried. Thus 6.8 g of white crystalline isomer-pair Ih are obtained, mp.: 78-80 °C, purity 95 %, (GC analysis ).

Example 11 g of crystalline trans cypermethrin (comprising 52 % of IRtransS and IStransR isomers and 47 % of IRtransR and IStransS isomers) are dissolved in 100 ml of petrolether at 50-60 °C. To the solution 0.02 g 2,6-di-tertiary butyl-4-methyl-phenol is added. After filtration the filtrate is seeded at 30 °C with seeding crystals consisting of a 1:1 mixture of the Ih isomers. Crystallization is accomplish ed as disclosed above. Thus 3.8 g of snow-white crystalline isomer-pair lb (1:1) are obtained, mp.: 77-79 °C, purity 93 %· On recrystallization from petrolether the melting point rises 80.5 °C. The crystallization mother-lye is epimerised in a separate step.

Example 12 g of crystalline trans cypermethrin (comprising 45 % of IRtransS and IStransR isomers and 53 % of IRtransR and IStransS isomers) are dissolved in 75 ml of isopropanol ab 50-60 °C. 'l'he solution is treated in an analogous manner to Example 11. Thus 3.6 g snow-white crystalline isomer-pair Ih are obtained. According to gas chromatography analysis the purity of the 1:1 mixture amounts to 94 %· Mp.: °C. Further recrystallization is accomplished as described in Example 2. Thus a product having an ac- tive ingredient content above 99 % is obtained. The crystallization mother-lye is epimerised in a separate step.

Example 13 Into an apparatus equipped with a stirrer the mother-lye obtained according to Example 11 (a solution enriched in isomer Id) is introduced and 1 g of Dowex Type 2x4 mesh (serva) basical ion-exchanging resin are added. The heterogenous suspension is stirred at 40 °C for 12 hours, filtered, washed 15 twice with 2 m3, of isopropanol each. According to gas chromatography the solution comprises 41 % cf lb isomer-pair and 46 % of Id isomer. The solution is evaporated and crystallized as described in Example 11.

Example 14 One proceeds according to Example 13 except that petrolethei* is used as solvent. According to gas chromatography analysis the solution comprises 39 % of lb isomer and 56 % of the IR transR and IStransS isomers .

Example 15 g of colourless oily cypermethrin (comprising 30 % of Ih, 31 % of Id, IS % cf Ia and 21 % of Ic) are seeded with seeding crystals of a 1:1 mixture of the lb isomers and allowed to crystallize at 7 °C for a week. The viscous crystalline oil obtained is cooled to -15 °C, suspended in 10 ml of a 1:1 mixture of isopropanol and diisopropyl ether cooled to -15 °C and filtered cold. The crystals thus obtained are washed with 5 ml of icecold isopropanol and dried at room temperature. Thus 2 g of white crystalline? product Ih are obtained, mp.: 78-80 °C, purity 96 % (GC). On recrystallization from 13 ml of hexane 2.25 g of a snow-white crystalline product are obtained, mp.: 80-81 °C, active ingredient content 99 %.

Example 16 g of cypermethrin (comprising 30 % of lb, 31 % of Id, 18 % of Ia and. 21 % of Ic) are dissolved in 100 ml of warm isopropanol whereupon 0.02 g of 2,5-di-tertiary butyl-4-methyl-phenol is added. The solution is clarified with 0.2 g of charcoal, filtered warm and the filtrate is seeded at 30 °C with a seeding crystal consisting of a 1:1 mixtui'e of the lb isomers. The mixture is allowed to crystallize at 10 °C for 24 hours, at 0 °C for 48 hours and finally at -5 °C for 24 hours (crys28 tallization is accomplished, so that an oily separation of the product should, be avoided.). The crystals are filtered cold, washed with isopropanol and dried, at room temperature. Thus 2.6 g of snow-white crystalline Ib isomer-pair (1:1) are obtained, mp.: 78-80 °C, purity 95 %· On recrystallization from hexane 2.3 g of a snow-white crystalline product are obtained, mp.: 80-81 °C, active ingredient content 99 %.

Formulation examples Example 17 Emulsifiable concentrates (EC) are prepared by admixing the following components: EG Component Isomer-pair Ib Cyclohexanol Atlox 3386 B Atlox 3400 B Odourless mineral oil 5_EC Component Isomer-pair Ib Cyclohexanol Atlox 3386 B Atlox 3400 B Colourless mineral oil Amount, kg/kg 0.105 0.290 0.020 0.045 0.540 Amount, kg/kg 0.050 0.290 0.020 0.045 0.595 In a dose of 20 g of active ingredient/ha the composition 5 EC gives the same protection against Colorado beetle as a preparation of identical composition hut comprising isomer Ia (alphametrine composition) .

A solution of 1.5 g of isomer-pair Ib and 1.5 g of fatty alcohol polyglycol ether is homogenized in a powder homogenizer with 30 g of synthetic silicic acid (Wessalon S), 60 g of talc (pH 7.1), 5 g of saccharose and 3.35 g of dodecyl benzene sulfonic acid. Thus a thin flowing powder is obtained.

Example 19 g of isomer-pair ih are diluted with 2 g of ethanol. The solution is admixed in a powder homogenizer with 5 g of calcium lignosulphonate, 5 g of nonyl-phenyl polyglycol ether (E0=20) and 70 g of calcium carbonate. The product thus obtained is ground in an Alpine 100 type mill. According to CIPAC the floatability amounts to 81 %; wetting time = 18 seconds.

Biological Examples Example 20 The comparative activity tests of enantiomer-pairs la and Ih on bean weevil (Acanthoscelides obtectus), flour-beetle (Tribolium confosum) and sheep maggot fly (Lucilia sericata) show that enantiomer-pair lb is more active than enantiomer-pair Ia.

The results are summarized in Table 1.

Table 1 Species . Enantiomer Dose (mg/disc) pair 0.02 0.07 0.22 mortality % 0.67 2.0 6.0 5 A. obtectus Ia 10 0- 63 100 100 100 (imago) lb 32 55 87 100 100 100 T. confusum Ia 0 18 51 100 100 100 (imago) lb 14 73 100 100 100 100 L. sericata Ia 0 30 29 57 60 65 10 (imago) lb 22 55 70 75 100 100 The test is carried out as follows: The stereoisomers are dissolved in a 1:2 mixture of mineral oil and acetone and filter paper discs (Whatman No. 1., diameter 9 cm) are impregnated with the corresponding dosage of the solution of the active ingredient. The acetone is allowed to evaporate and the insects are examined on filter paper discs placed into Petri-dishes. Three parallels are used for each dose and 15 animals are placed in each Petri-dish. Mortality rate is determined after 24 hours.

The corrected mortality % data are calculated by means of the Abbot formula.

Example 21 In Table 2 the synergism between the stereoisomers of the enantiomer-pair Ih is proved.

The test is carried out on T. confusom and the following results are obtained by the contact method for various active ingredient doses.

Table 2 Dose (mg/disc) 0.11 0.33 1.00 3.00 mortal ity % IStransR Ii 0 0 71 90 IRtransS lg 80 94 100 100 lb enantiomer-pair 90 100 100 100 The test is carried out according to the method described in Example 20.

Example 22 In Table 3 the values of the Ig and Ii isomers and those of the lb isomer-pair are disclosed. The data are topically measured.

Table 3 LD^q (ng/insect) T. confusum LD^q (ng/insect) Musca domestica cypermethrin stereoisomers measured expected synerg. factor measured expected synerg. factor Ig IRtransS 73.6 - - 13.4 - - Ii StransR 1291.8 - - 141.9 - - lb 51.9 139.3 2.68 12.8 24.5 1.92 ih*» t> J The above data prove the synergism between the trans isomers on both species.

The tests are carried out as follows: a) Musca domestica The active ingredients are dissolved in 2-ethoxyethanol (cellosolve) and 0.3 /ul droplets of the solutions are applied onto the dorsal cuticulum of 3-5 days’ old female house flies. 10 animals are used and 2 parallels are carried out for each dose. The tests are carried out for 5 dose levels between activity limits of 0 % and 100 %. After treatment the flies are placed into glass vials. Mortality is determined after 24 hours. Data are transformed to log^O dosage and probit mortality. LD^q and confidence interval values are calculated by linear regression analysis of the log-probit data. The expected values required for the calculation of synergism are obtained by means of harmonic average. The synergistic factoi· is the quotient of the expected and measured values . b) T. confusum The active ingredients are dissolved in 2-ethoxyethanol and 0.3 yul droplets of the solutions are applied onto the abdominal side of 1-2 weeks old imagos. Treatment is carried out with 2 parallels and 20 animals for each dose by using 5 dose levels in Μ the range between activity Limits of 0 % and 100 %.

Evaluation and determination of LDcr. values and 50 synergistic factors are carried out as described in Example 21.

Example 23 Residual contact test on adults of Aphidinus matricanae Adults of A. matricariae are exposed to residues of the active ingredients freshly applied on glass plates forming cages then the survivors are counted.

Treatments: test product(s) and control treated with water.

Replicates: at least 3· Plot size (net): 1 cage.

Parasites of known age 24 hours are used.

The products are applied at 5-1 ppm concentration, to each of the glass plates. females of A. matricariae are intro20 duced into each cage and supplied with honey as food.

The number of females surviving exposure is determined after 1.5 and 24 hours, in independent runs. Total number of survivors is calculated for each cage.

The results are summarized in Table 4.

Table 4 Concentration ppm 1 ppm lh lh 5h 24h hours m o r t a 1 i t y % Ia 100 100 100 96 Ib 100 0 75 88 control 0 0 0 1.5 Example 24 Direct contact test on pupae of A. matricariae Mature pupae of A. matricariae on paprika leaves in Petri dishes are exposed to a direct spray of the active ingredients.

Two or three days before emergence paprika leaves with parasitized pupae are used. The leaves are laid on filter paper in a plastic Petri dish.

The filter paper is moistened.

Application of treatment: see Example 23.

The pieces of leaf are transferred after treatment to clean Petri dish bottems. The trays are stored in a climatic chamber at 20 °C temperature, % relative humidity and a light-dark cycle of 16-8 h. Surviving pupae hatch after 2-3 days. The num bens of hatched and dead pupae are counted. Results are shown in Table 5.

Table 5 concentration (ppm) 30 10 . ,.. mortality ί5 1 lb 61. 0 0 0 0 deltametrin 75.0 33.0 0 0 control 0 0 0 0 Example 25 10 The active ingredients are dissolved in 2-ethoxyethanol and 0.3 /ul droplets of the solutions are applied onto the abdominal sterna of potato beetle (Leptinotarsa decemlineata) imagos. The treatments are carried out hy using two parallels and 10 insects for each dose. After treatment the insects are placed into Petri-dishes and mortality is determined after 48 hours. The results are set forth in Table 6.

Table 6 cypermethrin enantiomers Dose ( 0.05 0.10 24 hours’ /Ug/insect) 0.20 mortality % 0.40 lb 0 25 75 85 cypermethrin 0 20 45 75 Example 26 T. confusum (small flour-beetle) imagos are treated according to Example 20 and percental mortality is determined after 24 hours. The dose of piperonyl butoxide (referred to furtheron as PBO) amounts to 0.5 mg/disc. The results are disclosed in Table 7. It caN he seen that enantiomer-pair lb can be synergized at a higher level than isomer pair Ia.

Table 7 Active ingredient 0.4 Dose (mg/disc) 0.025 0.2 24 hours’ 0.1 morta 0.05 lity % Ia 96 53 12 0 0 Ia + PBO 100 58 16 0 0 Ih 100 85 51 10 0 Ih + PBO 100 91 68 39 9 Example 27 The active ingredients are dissolved in 2-ethoxyethanol and the solutions are applied in the form of 0.2 yul droplets onto the hack of fall webworm (Hyphantria cunea) of Ly-Lg larvae stage. The treated worms are placed on strawberry leaves in Petri-dishes. The test is carried out hy using 5 doses; 2 parallels and 10 insects for each dose. The killed worms are counted after 24 hours and the percental mortality rate is calculated. The results are summarized in Table 8.

Table 8 Dose (zug/larvae) cypermethrin. stereoisomers 0.023 0.047 24 houi 0.094 0.188 ?s’ mortality 0.375 lb 10 15 30 70 80 cypermethrin 0 0 25 50 75 Example 28 Prom a 5 EC formulation according to Example 17 50-, 100-, 200-, 400-, 800- and 1β00-fold diluted emulsions are prepared by diluting with water. 0.5 ml of the emulsions are sprayed onto glass plates whereupon after drying 10 Colorado beetles (L. decemlineata) imagos are placed on each glass plate and the insects are covered. The tests are carried out with 6 doses by carrying out 3 parallels for each dose. The killed insects are counted after 48 hours and the percental mortality rate is calculated. The results are shown in Table 9.

Table_9 Dilution EC l600x 800x 400x 200x lOOx 50x formulation mortality % 5 cypermethrin 0 17 33 50 67 83 Ib 0 13 37 57 87 100 Example 29 The insecticidal effect is tested on bean weevil (Acanthoscelides obtectus) imagos. The killed insects are counted after 24 hours and the percental mortality rate is calculated. The results are shown in Table 10.

Table 10 Dilution EC l600x 800x 400x 200x lOOx 50x formulation mortality % cypermethrin 0 3 10 20 43 60 Ib 3 10 20 37 53 67

Claims (8)

1. A synergistic insecticidal composition containing more than one active ingredient and being harmless to environment characterized by comprising in an amount of from 0.001 to 99 % by weight a synthetic pyrethroid of the Formula (I) (I) containing at least 95% of the IRtransS and IStransR enantiomer-pair (lb) out of the possible eight isomers - optionally in admixture with an amount of us to 100 % by weight of one cr more activator(s) end auxiliary agent(s), particularly antioxidants, stabilising agents, wetting agents, emulsifying agents, dispersing agents, antifoam agents , diluents and/or fillers .

2. Isomer mixture cf the Formula (I) containing at least 95% of enantiomer-pair IRtransS and having the following IR and NMR data: ft ϊ & i) IR (KBr) 9 C=O = 1735 cm. NMR (CDCl^) 8 (ppm) = 1.22, 1.27, CMe 2 ; 1.69, d, IH ci; 2.32 m, IH C3; 5.6, d, IH Cl’; 6.39, s, IH, C alpbaproton containing enant iomer and the IR

3. . A crystalline isomer mixture of the Formula (I) at least 95% of the IRtransS and IStransR pair having a melting point of 80.5-81.5 °C and NMR data according to Claim 2.

4. · A process for the preparation of an 10 isomer mixture lh containing at least 95% of the enantiomer-pair IRtransS and IStransR - i.e. substantially only two out of the eight possible isomers of the compounds of the Formula (I) - b) comprising the desired isomers in admixture with further possible isomers with a protic or apolar aprotic inert organic solvent, seeding the solution with a seeding crystal consisting of the enantiomer-pair IRtransS + IStransR and isolating the precipitated crystals at a temperature between +30 °C and -30 °Cj or seeding a melt of a mixture comprising the desired isomers in admixture with further possible isomers at a temperature between 10 °C and 60 °C with a seeding crystal consisting of the IRtransS and IStransR enantiomer-pair, crystallizing at a temperature between 30 °C and -10 °C, and if desired suspending the mixture thus obtained in a protic or apolar aprotic organic solvent at a temperature between -10 °C and -20 °( and isolating the separated crystals; or subjecting a mixture comprising the desired isomer-pair lb in admixture w chromatograph in an organic solvent ι further possible >re* era'o.L' on bent; or dissolving a mixture comprising trans isomers of the compounds cf the “’ormula (I) in a protic cr apolar aprotic solvent, seeding the solution with a seeding crystal consisting of the enantiomer- -pair IRtransS + IStransR (lb), isolating the precipitated crystalline product lb, and thered) after if desired epimerising the mixture comprising lb + Id being present in the mother-lye with an organic or inorganic base and if desired repeating the said step and/or the crystallising step; or e) dissolving the mixture comprising the trans isomers in a secondary or tertiary organic amine base comprising 4-9 carbon atoms - optionally by adding an organic solvent - and seeding the solution thus obtained with a seeding crystal consisting of IRtransS + IStransR isomers and thereafter isolating the precipitated crystals.

5. Process according to variant a) or e) of Claim 4 which comprises using as organic solvent a C 1 _- | 2 hydrocarbon, a C-, j- dialkyl ether JL “ / a Cq_£ chlorinated hydrocarbon, or a Cq_qQ alcohol, wherein the said solvents and cyclic or may be straight or branched chained alicyclic, respectively. o. Process according to vanani Claim 4 wmc! ;omprises carrying out the seeding operation with the seeding crystal in the presence of an antioxidant - preferably tertiary butyl hydroxy toluene or 2,2,4-trimethylquinoline - and using ethanol, iscpropancl or hexane as solvent. i roc according to variant, d Claim 4 which comprises using a C^_ 1Q alkane, C c_-]_o cycloalkane, C^_q alkanol and/or C^g cycloalkanol or a mixture thereof - preferably hexane, petrolether, cyclohexane, methanol, ethanol or isopropanol - as 5 solvent.

6. 8. Process according to variant d) of Claim 4 which comprises carrying out epimerisation by adding ammonia, a secondary or tertiary alkyl amine or a cyclic amine as basic, substance.

7. 10 θ. Process according to variant d) of Claim 4 which comprises using methanol, ethanol or isopropanol as solvent. 10. Process according to variant e) of Claim 4 which comprises using triethyl amine, 15 morpholine, pyrrolidine, piperidine, diisopropyl amine, ephedrine cr secondary butyl amine ss orgenic amine base . 10. A synergistic insecticidal composition according to Claim 1, substantially as hereinbefore 2 0 described and exemplified.

8. 11. A process according to Claim 4 for the preparation of an isomer mixture lb containing at least 95% of an enantiomer-pair IRtransS and IStransR, substantially as hereinbefore described and exemplified. 25 12. An isomer mixture lb containing at least 95% of an enantiomer-pair IRtransS and IStransR, whenever prepared by a process claimed in a preceding claim.