Patent Description:
As pesticide resistance increases, and impacts on food production as well as, e.g. ornamental crops, there is a growing need to provide new active compounds that are effective against pests. At the same time, there is increasing scrutiny of pesticides and their potential impact on end-consumers of the crop as well as on the environment. The desire for "safe" food, all year round, is ever increasing.

As a result, there has been considerable interest in recent years in biorationals, including biopesticides, which are products with a low environmental impact. Typically biorationals are biologically-derived or, if synthetic, they are structurally and functionally similar to natural products.

Biopesticides aim to fulfil the following criteria:
<NPL>
relates to a risk assessment of a particular formulated product which comprises maltodextrin. <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, <CIT>, and <CIT> each relate to compositions comprising maltodextrin for a range of different applications.

Viewed from a first aspect, the present invention provides use of a composition comprising:.

Viewed from a further aspect, the present invention provides the use as hereinbefore described as an insecticide or as an acaricide.

Viewed from a further aspect, the present invention provides a method of controlling pests, comprising applying an effective amount of a composition as hereinbefore described to an area requiring insect control, and wherein said method excludes therapeutic treatment of an animal or human body.

As used herein, the term "pesticide" refers to any substance that may be used to control (e.g. inhibit the growth of, repel and/or kill) unwanted organisms (i.e. pests) including plants, insects, animals, fungi, molluscs, arthropods, larvae, nematodes, microorganisms and algae.

As used herein, the term "insecticide" refers to a pesticide that may be used to control (e.g. inhibit the growth of, repel and/or kill) insects.

As used herein, the term "acaricides" refers to a pesticide that may be used to control (e.g. inhibit the growth of, repel and/or kill) Acari, including ticks and mites.

As used herein the term "maltodextrin" refers to a mixture of polysaccharides, each comprising D-glucose monomer units. Each polysaccharide present in the mixture contains <NUM> to <NUM> monomer units.

As used herein the term "chain length" refers to the number of monomer, i.e. glucose, units present in the polysaccahride.

As used herein the term "dextrose equivalent" refers to a measure of the amount of reducing sugars present in maltodextrin. It is used to characterise the molecular weight of the maltodextrin. It is measured by Layne-Eynon titration based on the reduction of copper (II) sulphate in an alkaline tartrate solution.

As used herein, the term "active ingredient" refers to any compound which is biologically active in the target organisms.

As used herein, the term "composition" refers to an administrable or useable form. Compositions often include additional ingredients other than the active ingredients, e.g. pesticide, to improve the properties of the composition e.g. to make the composition more stable and/or easier to handle, store and/or apply.

The present invention relates to use of a composition comprising:.

Maltodextrin is an oligosaccharide comprising (e.g. consisting of) D-glucose units. It has the repeat unit shown below:
<CHM>.

The D-glucose units may be linked by alpha (α) and/or beta linkages, but are preferably linked by alpha (α) linkages. The D-glucose units may be linked by (<NUM>-><NUM>) and/or (<NUM>-><NUM>) glycosidic bonds, but are preferably linked by (<NUM>-><NUM>) glycosidic bonds. Preferably the predominant linkage present in the oligosaccharides is α-<NUM>-><NUM> glycosidic linkages. The term chain length refers to the number of monomer (i.e. glucose) units present in the oligosaccharide. Thus a dimer has a chain length of <NUM>, a trimer has a chain length of <NUM> and so on. Maltodextrin typically contains oligosaccharies having chain lengths of <NUM> to <NUM>.

Maltodextrin is commercially available. Commercially available maltodextrin is generally derived from corn, potato or rice starch by hydrolysis (e.g. acid, enzyme and/or bacterial hydrolysis). The properties of the maltodextrin depend, inter alia, on the nature of the starch from which it is derived as well as the hydrolysis method employed. The compositions of the present invention comprise a specific maltodextrin.

The maltodextrin present in the compositions of the present invention preferably derives from corn, potato or rice starch and more preferably from rice starch. This is because rice starch inherently comprises a higher proportion of oligosaccharides having a shorter chain length (i.e. <NUM>-<NUM>). The average chain length of the oligosaccharides present in the maltodextrin present in the compositions of the invention is preferably <NUM>-<NUM> and more preferably <NUM>-<NUM>, based on the number of oligosaccharides of each chain length between <NUM>-<NUM> present. This is different to many commercially available maltodextrins, which tend to mainly comprise monomers and dimers, i.e. they do not predominantly comprise oligosaccharides.

The maltodextrin present in the compositions of the invention comprises at least <NUM> % oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>. The relatively high percentage of oligosaccharides having a chain length of <NUM>-<NUM> in the maltodextrin is believed to be responsible for the high level of pesticidal activity demonstrated by the compositions of the invention. In preferred compositions of the present invention the maltodextrin comprises <NUM>-<NUM> %, more preferably <NUM>-<NUM> % and still more preferably <NUM> to <NUM> % oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Maltodextrin comprising at least <NUM> % oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM> comprises a relatively high amount of shorter chain oligosaccharides compared to the overall range of chain lengths present in the oligosaccharide mixture. Preferably the percentage or proportion of oligosaccharides of any given chain length present in maltodextrin is determined by high performance liquid chromatography (HPLC), preferably HPLC with evaporative light scattering detection (ELSD) and still more preferably by the method described in the examples section herein. This method detects the number of molecules of each chain length present. Thus maltodextrin comprising at least <NUM> % oligosaccharides having a chain length of <NUM>-<NUM>, based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>, refers to maltodextrin having at least <NUM> % of its molecules being of chain length <NUM>-<NUM> based on the total number of oligosaccharide molecules present.

Preferably the maltodextrin present in the compositions of the invention comprises a mixture of oligosaccharides having a chain length of <NUM>, <NUM>, <NUM>, <NUM> and <NUM>. Preferably at least some oligosaccharide of each of the chain lengths <NUM>, <NUM>, <NUM>, <NUM> and <NUM> is present.

As hereinbefore described it is thought that the presence of a relatively high percentage of oligosaccharides having a chain length of <NUM>-<NUM> in the maltodextrin is responsible for the high level of pesticidal activity. More specifically, and without wishing to be bound by theory, it is thought that the greater ability of the oligosaccharides having a chain length of <NUM>-<NUM> compared to longer chain oligosaccharides to irreversibly absorb water may be responsible for the higher level of pesticidal activity observed via a dehydration mechanism.

Preferably the maltodextrin present in the compositions of the invention comprises at least <NUM> % of oligosaccharide having a chain length of <NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>. More preferably the maltodextrin comprises <NUM>-<NUM> % and still more preferably <NUM>-<NUM> % of oligosaccharide having a chain length of <NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Preferably the maltodextrin present in the compositions of the invention comprises at least <NUM> % of oligosaccharide having a chain length of <NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>. More preferably the maltodextrin comprises <NUM>-<NUM> % and still more preferably <NUM>-<NUM> % oligosaccharide having a chain length of <NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Preferably the maltodextrin present in the compositions of the present invention comprises less than <NUM> % of oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>. More preferably the maltodextrin comprises <NUM>-<NUM> %, still more preferably <NUM>-<NUM> % and yet more preferably <NUM>-<NUM> % of oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Preferably the maltodextrin present in the compositions of the present invention comprise less than <NUM> % of oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>. More preferably the maltodextrin comprises <NUM>-<NUM> % of oligosaccharides and still more preferably <NUM>-<NUM> % oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Preferably the maltodextrin present in the compositions of the present invention comprises <NUM>-<NUM> % and more preferably <NUM>-<NUM> % of monomer, especially glucose, based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Preferably the maltodextrin present in the compositions of the present invention comprises <NUM>-<NUM> % and more preferably <NUM>-<NUM> % of dimer, especially maltose, based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

Another way in which the structure of maltodextrin is characterised is by its dextrose equivalent (DE). The theoretical defintion of DE is: <MAT> wherein Mn is the number average molecular weight of the sample.

It can be seen from this equation that the higher the molecular weight of the sample, i.e. the longer the chain length of the oligosaccharide, the lower DE will be. Preferably the maltodextrin present in the compositions of the present invention has a DE of <NUM>-<NUM>, more preferably <NUM> to <NUM> and still more preferably <NUM> to <NUM>. Preferably DE is measured according to the method described above.

The pesticidal composition may comprise, preferably may consist of: maltodextrin; surfactant; and water, wherein the maltodextrin has a dextrose equivalent of <NUM>-<NUM>. The maltodextrin comprises at least <NUM> % oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>. In more preferred compositions of the present invention the maltodextrin comprises <NUM>-<NUM> %, more preferably <NUM>-<NUM> % and still more preferably <NUM> to <NUM> % oligosaccharides having a chain length of <NUM>-<NUM> based on the overall oligosaccharide mixture having chains of length <NUM>-<NUM>.

In preferred compositions of the present invention the number average molecular weight (Mn) of the maltodextrin is <NUM>-<NUM>/mol, more preferably <NUM>-<NUM>/mol and still more preferably <NUM>-<NUM>/mol. Mn is preferably determined by gel permeation chromatography.

The composition of the present invention comprises a surfactant. Any conventional surfactant may be used. The surfactant may be selected from anionic surfactants, cationic surfactants, zwitterionic surfactants, non-ionic surfactants and mixtures thereof. Preferably, however, the surfactant is a non-ionic surfactant.

Representative examples of preferred non-ionic surfactants include polyoxyethylene fatty esters (e.g. polysorbate <NUM> [poly(oxyethylene)sorbitan monooleate], polysorbate <NUM> [poly(oxyethylene)sorbitan monostearate], polysorbate [poly(oxyethylene)sorbitan monopalmitate], poly(oxyethylene)sorbitan monolaurate, poly(oxyethylene)sorbitan trioleate and polysorbate <NUM> [poly(oxyethylene)sorbitan tristearate]), polyoxyethylene hydrogenated castor oils (e.g. polyoxyethylene hydrogenated castor oil <NUM>, polyoxyethylene hydrogenated castor oil <NUM>, polyoxyethylene hydrogenated castor oil <NUM> and polyoxyethylene hydrogenated castor oil <NUM>), polyoxyethylene polyoxypropylene glycols (e.g. Pluronic F68, Pluronic P123, Pluronic P85, Pluronic F127 and Pluronic L-<NUM>), polyoxyl <NUM> stearate and sucrose fatty esters.

In preferred compositions of the present invention the surfactant is a polyoxyethylene fatty ester. Still more preferably the surfactant is selected from polysorbate <NUM> (e.g. Tween® <NUM>), polysorbate <NUM> (e.g. Tween® <NUM>) and mixtures thereof.

Preferred compositions of the present invention are in the form of a dispersion, a suspension or a solution. More preferably the compositions are in the form of a solution.

The composition is preferably provided in the form of a concentrate. When supplied in the form of a concentrate, the composition preferably comprises <NUM>-<NUM>/L of maltodextrin, more preferably <NUM>-<NUM>/L maltodextrin and still more preferably <NUM>-<NUM>/L maltodextrin. When supplied in the form of a concentrate, the composition preferably comprises <NUM>-<NUM> % w/v of surfactant, more preferably <NUM>-<NUM> % w/v surfactant and still more preferably <NUM>-<NUM> % w/v surfactant, based on the total volume of the composition. When supplied in the form of a concentrate, the composition preferably comprises <NUM>-<NUM> % w/v of water, more preferably <NUM>-<NUM> % w/v water and still more preferably <NUM>-<NUM> % w/v water, based on the total volume of the composition.

When supplied in the form of a concentrate, the composition is preferably diluted with water prior to use. Preferably the amount of concentrate <NUM>-<NUM> %vol, more preferably <NUM> to <NUM> %vol and still more preferably <NUM> to <NUM> %vol, based on the volume of water. In ready-to-use form, the composition of the invention preferably comprises <NUM>-<NUM>/L of maltodextrin, more preferably <NUM>-<NUM>/L maltodextrin and still more preferably <NUM>-<NUM>/L maltodextrin. In ready-to-use form the compositions of the invention preferably comprise <NUM>-<NUM> % w/v of surfactant, more preferably <NUM>-<NUM> % w/v of surfactant and still more preferably <NUM>-<NUM> % w/v of surfacant, based on the total volume of the composition. In ready-to-use form the composition of the invention preferably comprises <NUM>-<NUM> % w/v water, more preferably <NUM>-<NUM> % w/v water and still more preferably <NUM>-<NUM> % w/v water, based on the total volume of the composition.

When the composition of the invention is in ready-to-use form, it preferably has a rotational viscosity at <NUM> of <NUM> to 150mPa. s and more preferably <NUM> to <NUM> mPa. Still more preferably the composition of the invention, in ready-to-use form has a rotational viscosity at <NUM> of <NUM> to <NUM> mPa. s and more preferably <NUM> to <NUM> mPa. This enables the composition to be readily sprayed, e.g. onto crops, using conventional spraying apparatus.

In some preferred compositions of the invention maltodextrin is the sole active ingredient.

Alternatively, the compositions of the present invention optionally comprise one or more additional ingredients. The one or more additional ingredients may comprise one or more further active ingredients, one or more non-active ingredients or a combination thereof.

When a further active ingredient is present in the composition of the invention, it is preferably another insecticide and/or an acaricide. Representative examples of insecticides include chlorpyrifos, carbofuran, fibronil, abamectin, acephate, acetamiprid, acrinathrin, cypermethrin, endosulfan, azadirachtin, azinphos-ethyl, azinphos-methyl, Beauveria bassiania, bendiocarb, benfuracarb, bensultap, Cry toxins, cyfluthrin, cypermethrin, bifenthrin, bufencarb, buprofezin, butacarb, cadusafos, carbaryl, carbofuran, carbosulfan, cartap, cartap hydrochloride, chlorantraniliprole, chlorfenapyr, chlorfenvinphos, chlorfluazuron, chlormephos, chlorpyrifos, chlorpyrifos-methyl, chromafenozide, clothianidin, cyantraniliprole, cyfluthrin, cyhalothrin, cypermethrin, deltamethrin, diazinon, dicrotophos, diflubenzuron, dimethoate dinotefuran, disulfoton, emamectin, emamectin benzoate, endosulfan, endothion, endrin, EPN, esfenvalerate, etaphos, ethiofencarb, ethion, ethiprole, ethoate-methyl, etofenprox, fenamiphos, fenazafior, fenethacarb, fenitrothion, fenobucarb, fenpropathrin, fensulfothion, fenthion, fenthion-ethyl, fenvalerate, fipronil, flonicamid, flubendiamide, flucythrinate, fonofos, fufenozide, furathiocarb, gamma- cyhalothrin, gamma-RCR, halfenprox, halofenozide, heptenophos, hyquincarb, imidacloprid, indoxacarb, isazofos, isobenzan, isocarbophos, isofenphos, isofenphos-methyl, isoprocarb, isothioate, isoxathion, kinoprene, cyhalothrin, lepimectin, lufenuron, malathion, Metarhizium anisopliae, Metarhizium brunneum, methamidophos, methomyl, methoxyfenozide, mevinphos, mexacarbate, milbemectin, monocrotophos, nitenpyram, novaluron, omethoate, oxamyl, oxydemeton-methyl, oxydeprofos, oxydisulfoton, parathion, parathion-methyl, penfluron, permethrin, phenthoate, phorate, phosalone, phosfolan, phosmet, phosphamidon, pirimetaphos, pirimicarb, pirimiphos-ethyl, pirimiphos-methyl, primidophos, profenofos, profluthrin, promecarb, propaphos, propoxur, prothiofos, pymetrozine, pyrafluprole, pyridalyl, pyrifluquinazon, pyriprole, pyriproxyfen, spinetoram, spinosad, spirotetramat, sulfoxaflor, sulprofos, tau-fluvalinate, tebufenozide, tebufenpyrad, teflubenzuron, tefluthrin, tetramethylfluthrin, theta-cypermethrin, thiacloprid, thiamethoxam, thicrofos, thiocyclam, thiocyclam oxalate, thiodicarb, thiometon, thiosultap, thiosultap-disodium, thiosultap-monosodium, thuringiensin, tolfenpyrad, triazophos, triflumuron, zeta-cypermethrin and mixtures thereof.

Representative examples of acaricides include permethrin, ivermectin, dicofol, abamectin, acequinocyl, bifenazate, chlorpenafyr, clofentezine, cyflumetofen, cypermethrin, dicofol, etoxazole, fenazaquin, fenpyroximate, hexythiazox, imidacloprid, propargite, pyridaben, spiromesifen, spirotetramat and mixtures thereof.

When a further active ingredient is present in the composition of the invention, it is preferably present in an amount that will provide pesticidal activity. The skilled person will readily be able to determine such an amount. In preferred compositions of the present invention, however, maltodextrin is the sole active ingredient present.

When a further non-active ingredient is present in the composition of the present invention, it is preferably selected from bait substances, antifoaming agents, buffers, pH modifiers, antioxidants, biostimulants, preservatives (e.g. mould inhibitors), binding agents, bird deterrents (e.g. dyes), animal repellents, wetting agents, odour masking agents, UV protecting agents and mixtures thereof. When present, the amount of non-active ingredient present in the composition (e.g. in ready to use form) of the present invention is preferably <NUM>-<NUM> % w/v and more preferably <NUM>-<NUM> % w/v.

Preferred compositions of the present invention, however, consist essentially of, and more preferably, consist of maltodextrin, surfactant and water.

A method for making a pesticidal composition is also described, comprising mixing: maltodextrin, surfactant, and water. Any conventional mixing method may be used, e.g. stirrer, shaker etc. Optionally the mixture is heated to improve the dissolution.

Preferred methods further comprise purifying maltodextrin prior to its incorporation into the composition. In particularly preferred methods the maltodextrin is first purified to remove at least some, and more preferably substantially all, of the oligosaccharides having a chain length of <NUM>-<NUM> from the oligosaccharide mixture. In other further preferred methods the maltodextrin is purified to remove at least some, and more preferably substantially all, of the monomers and dimers present in the oligosaccharide mixture. Any conventional purification technique may be used, e.g. centrifugal separation, chromatography etc..

A still further preferred method of the invention comprises:.

In particularly preferred methods, partial hydrolysis of starch is carried out using acid, enzymes, bacteria or a combination thereof. Enzyme hydrolysis is generally preferred as it allows more control over the hydrolysis reaction. For instance, an enzyme with specificity for certain linkages may be chosen. Regardless of the type of hydrolysis employed, preferably the starch is first dispersed in water and allowed to swell prior to carrying out the hydrolysis reaction.

The present invention provides the use of the composition hereinbefore described as a pesticide. The compositions of the invention may be used as a pesticide in an agricultural or non-agricultural environment, e.g. as a crop pesticide. Examples of non-agricultural uses include control of pests in stored grains, beans and other foodstuffs as well as in textiles (e.g. clothing and carpets), pest control in ornamental plants, forests, and on turf such as lawns, golf courses and pastures and pest control in houses (e.g. in wooden parts) and other buildings and structure, e.g. sheds, decks, fencing etc..

Preferably, however, the composition of the invention is used as a pesticide in agriculture. Preferably the composition of the invention is used as a plant pesticide and still more preferably as a crop plant pesticide. The crop may be edible or non-edible. Examples of crops that may be protected using the compositions of the invention include potatoes, sweet potatoes, grain, cereals, fruits, vegetables, pulses, legumes, brassicas, beets (e.g. sugar beets), ornamental flowering crops and ornamental non-flowering crops. Certain preferred crops include any solanaceae (e.g. tomato, potato, tobacco, aubergine, peppers), any cereal or grain crops (e.g. barley, wheat, oats, triticale, maize, rice, rye, adlay millet, sorghum, millet, teff, fonio or spelt), any leguminous crops (e.g. pea, chickpea, common bean, soybean, cowpea, lentil, alfalfa, peanut, mung bean or groundnut), any vegetable crops (e.g. Brassicaceae, Allium family, cucurbit family, carrot or lettuce), any Malvaceae (e.g. cotton), and any ornamental flowering crops (e.g. chrysanthemum, carnation or rose). Especially preferred crops are selected from tomato, cocoa, citrus, pome fruit (e.g. apple), potatoes, sweet potatoes, brassicas, beets and grains, more preferably from potatoes and grain. Grains of particular interest are cereal grains, such as wheat, rice, maize, barley and oats, preferably wheat, rice and maize.

The compositions of the present invention are used as a pesticide. More preferably the compositions of the invention may be used as an insecticide or as an acaricide.

Examples of insects that may be controlled include eggs, larvae, nymphs and adults of the order Hemiptera, e.g. psyllidae and pseudococcidae, with examples being Pear psylla (Cacopsylla pyri), cocoa mealybugs (e.g. Planococcoides njalensis and Exallomochlus hispidus, amongst others) and aphids (e.g. Aphidoidea, where economic injurious species are colloquially known as 'greenfly' and 'blackfly', examples of which are Myzus persicae, Aphis gossypii, Aphis fabae. Insects of the order Thysanoptera, known as 'thrips', may also be controlled. Examples include Western Flower Thrips (Frankliniella occidentalis) gladiolus thrips (Thrips simplex) and melon thrips (Thrips palms). Insects of the order Lepidoptera, e.g. fall armyworm (Spodoptera frugiperda), diamondback moth (Plutella xylostella), cotton bollworm (Helicoverpa armigera), European corn borer (Ostrinia nubilalis) may also be controlled.

Examples of Acari (mites) that may be controlled include eggs, larvae, nymphs and adults of spider mites and red mites in the family Tetranychidae (e.g. European red mite (Panonychus ulmi Koch), two spotted spider mite (Tetranychus urticae Koch), McDaniel mite (Tetranychus mcdanieli McGregor)); flat mites in the family Tenuipalpidae (e.g., citrus flat mite (Brevipalpus lewisi McGregor)); rust and bud mites in the family Eriophyidae, foliar feeding mites, i.e. dust mites in the family Epidermoptidae, follicle mites in the family Demodicidae, grain mites in the family Glycyphagidae; ticks in the family Ixodidae, commonly known as hard ticks (e.g., deer tick (Ixodes scapularis Say), Australian paralysis tick (Ixodes holocyclus Neumann), American dog tick (Dermacentor variabilis Say), lone star tick (Amblyomma americanum Linnaeus)) and ticks in the family Argasidae, commonly known as soft ticks (e.g., relapsing fever tick (Ornithodoros turicata), common fowl tick (Argas radiatus)); scab and itch mites in the families Psoroptidae, Pyemotidae, and Sarcoptidae.

The present invention therefore also provides a method of controlling pests (e.g. insects and acari), comprising applying an effective amount of a composition as hereinbefore described to an area requiring insect control, and wherein said method excludes therapeutic treatment of an animal or human body.

The compositions of the invention may be applied to an area to be treated using any conventional apparatus. Preferably, however, the composition of the invention is applied by spraying.

The present invention as hereinbefore described may be employed in any space requiring pest control. The invention may be used outdoors or indoors, in open or enclosed spaces. The present invention preferably provides the use as hereinbefore described in a field, glasshouse, cloche, polytunnel, grain bin, silo, shipping container, warehouse (e.g. a potato or grain storage warehouse, preferably a potato storage warehouse), barn or controlled environment room.

The invention will now be described by the following non-liming examples and Figures, wherein:.

Maltodextrins, oligosaccharides, maltose and dextrose were purchased from Sigma Aldrich and CarboSynth.

The total maltodextrin content was measured using High Performance Liquid Chromatography - Evaporative Light Scattering Detector (HPLC-ELSD) according to the following method: A HPLC instrument from Waters Alliance, equipped with a Waters <NUM> ELSD (<NUM> psi, drift tube set at <NUM>, nebuliser set at <NUM> % power and heating), was used with a ACE Excel <NUM> NH<NUM> (<NUM> x <NUM>) column set at <NUM> and a flow rate of <NUM>/min. The HPLC system and data collection was controlled by Empower software. Mobile phase A was deionized water (<NUM> %), mobile phase B was acetonitrile (<NUM> %), the injector flush solvent was a <NUM>:<NUM> (v/v) solution of deionized water:acetonitrile and the pump piston back-wash/seal wash was a <NUM>:<NUM> (v/v) solution of deionized water:acetonitrile. The injection volume was <NUM>µl.

The following mobile phase gradient was used.

Deionised water was used as a diluent in all samples. Stock reference solution of maltodextrin, was prepared in duplicate (<NUM>/ml). The reference maltodextrin (<NUM> ± <NUM>) was weighed, added to a volumetric flask (<NUM>) and sonicated for <NUM> minutes. A retention marker solution containing different sugars and oligosaccharides was prepared singularly at a concentration of <NUM>/ml. Each sugar/oligosaccharide sample was weighed (<NUM> ± <NUM>), added to a single volumetric flask (<NUM>), made up with diluent and sonicated for <NUM> minutes. The test samples were prepared at a concentration of <NUM>/ml. The test sample was weighed (<NUM> ± <NUM>), added to volumetric flask (<NUM>) made up with diluent and sonicated for <NUM> minutes.

System suitability tests were performed prior to the analysis and the following run sequence was used: A sample of blank solvent was injected once. The retention marker solution was injected once. The first working reference solution was injected five times to check repeatability. The second working reference solution was injected at different known concentrations for linearity and generation of the calibration curve for quantification. The blank sample of diluent was injected once for the carry over check and then injected again. The test samples were injected in duplicate. The second working solution was injected again at varying known concentrations in duplicate for linearity and to generate the calibration curve. The blank sample of diluent was injected once at the end of the run sequence.

The repeatability of the working reference solutions was determined. The first working reference solution was injected five times and the second working solution was injected twice. The repeatability was determined by calculating the relative standard deviation (RSD) of the main peak area. The ratio of response factors was also calculated to give the repeatability of the standard. The acceptance criterion was ≤<NUM> % for RSD and between <NUM> and <NUM> for ratio of response factors.

The mean retention time of each component in the retention marker solution injection had an acceptance criteria within the range of ± <NUM> minute and RSD must be <<NUM> %.

Maltodextrin peak area was determined as the sum of all peak areas corresponding to chain lengths of <NUM> to <NUM>. Calibration curves for the quantification of maltodextrin, and its constituent oligosaccharides of different chain lengths in the test samples was generated by injecting the varying known amounts of the working reference solutions. The relevant peak area(s) (y) was plotted against the known analyte concentration (x) and then used to calculate the amount of the relevant compound in the conventional manner.

Dynamic vapor sorption (DVS) is a gravimetric technique that measures how quickly and how much of a solvent (water) is absorbed by a sample. It does this by varying the vapor concentration surrounding the sample and measuring the change in mass which this produces.

The main component of the DVS system is an ultra-sensitive recording microbalance capable of measuring changes in sample mass lower than <NUM> part in <NUM> million. The DVS instrument is housed in a temperature controlled incubator. This ensures high instrument baseline stability as well as accurate control of the relative humidity generation. The required vapour humidities are generated by mixing dry and saturated vapour gas flows in the correct proportions using accurate mass flow controllers. Humidity probes are situated just below the sample and reference holders to give independent verification of system performance.

In the experiment carried out a known mass of sample (i.e. maltodextrin) was weighed into a DVS pan and placed into the chamber and allowed to equilibrate at <NUM>%RH. The temperature was fixed at <NUM>. The humidity was then increased from <NUM>-<NUM>%RH in increments of <NUM>%RH. The mass of the sample was allowed to stabilise at each humidity condition. The humidity was subsequently reduced from <NUM>%RH back to <NUM>%RH. Again, the sample mass was allowed to stabilise at each step. The rate at which the material takes on moisture as well as the mass retained after the desorption cycle indicates the hygroscopicity of a material.

The sample weight change was used to plot a water isotherm which illustrates the affinity of the sample to take on water.

The objective of this experiment was to demonstrate insecticidal/acaricidal activity based on maltodextrin chain length by comparing the dose-response curves of maltodextrins of different DE value on the spider mite, Tetranychus urticae. The maltodextrins were compared to monosaccharide (dextrose), disaccharide (maltose) as well as a commercially available insecticide.

Each compound listed in Table <NUM> below was suspended in water with <NUM>% Tween <NUM> and diluted to <NUM> different concentrations ranging from <NUM>/L to <NUM>/L of active substance.

Ten adult T. urticae were placed onto bean leaf discs, Phaseolus vulgaris, of <NUM> diameter. Treatments were applied onto the mites at a rate of <NUM>/cm<NUM> using a laboratory compressed gas atomizer. The leaf discs were left to dry under a laminar flow cabinet before being sealed with a vented lid and incubated at <NUM>, <NUM>% RH and <NUM>:8D light regime. Assessment of mite mortality was conducted <NUM> after treatment application.

The dose-response curves, shown in <FIG>, were estimated using the 'dose. p' function in the MASS library of R statistics and plotted using the 'predict' function. Significant differences among LD<NUM> values were compared using the 'comped' function in the 'drc' package.

All maltodextrins demonstrated activity against T. urticae to some degree. The steepest dose-response curve and highest rate of mortality was seen with maltodextrin DE <NUM> - <NUM>. It demonstrated a similar rate of mortality to the commercial formulation, but was active at a significantly lower dose, e.g. it achieved a mortality rate of ><NUM> % at a lower dose. The curves of maltose and dextrose were less steep but followed the same general trajectory. Maltodextrin DE <NUM> - <NUM> demonstrated a significantly different dose-response with lower rates of mortality among T.

The distribution of chain lengths in each maltodextrin was analysed by the HPLC-ELSD method described above. The results are shown in Table <NUM> below and in <FIG>.

A comparison of some of the key data from the above table is provided in Table <NUM> below.

The HPLC-ELSD data show that maltodextrin DE <NUM>-<NUM> and DE <NUM>-<NUM> are similar in terms of their distribution of oligosaccharide chain lengths. In contrast maltodextrin DE <NUM>-<NUM> and DE <NUM>-<NUM> are quite different in their distribution of chain lengths compared to maltodextrin DP <NUM>-<NUM>. Maltodextrin DE <NUM>-<NUM> and DE <NUM>-<NUM> each have a much higher percentage of shorter oligosaccharide chain lengths (i.e. <NUM>-<NUM>) compared to maltodextrin DP <NUM>-<NUM>. Additionally the maltodextrin DE <NUM>-<NUM> and DE <NUM>-<NUM> were found to be completely lacking the longer chain lengths present in maltodextrin DP <NUM>-<NUM>, i.e. <NUM>+.

The maltodextrins were analysed by DVS, according to the method described above, to compare the propensity of each of the maltodextrins to take up moisture under different humidity conditions. A single sorption/desorption cycle was used and the mass change was plotted against relative humidity (%). The results are shown in Table <NUM> below and in <FIG>.

<FIG>, the DVS isotherm plot for maltodextrin DE <NUM>-<NUM>, exhibits two distinct rates of moisture uptake, where a faster uptake was observed from the sample above <NUM>% RH. Upon completion of the desorption cycle, the sample was observed to have deliquesced. <FIG>, the DVS isotherm plot for maltodextrin DE <NUM>-<NUM>, exhibits a similar curve. <FIG>, the DVS isotherm plot for maltodextrin DP <NUM>-<NUM>, shows a sharp increase in mass between <NUM> and <NUM> % RH and thereafter the sample mass increases more slowly to a maximum of <NUM> %. There is a slight hysteresis observed upon desorption, however, the sample mass recovers close to the starting mass and no observation of deliquescence was recorded. The difference in the behaviour of the maltodextrins in DVS analysis can be seen in <FIG> which shows the isotherm overlap for maltodextrin <NUM>-<NUM> and DP <NUM>-<NUM>.

From a comparison of the datasets it was concluded that maltodextrin DE <NUM>-<NUM> and DE <NUM>-<NUM>, which each contain a higher proportion of oligosaccharides having a chain length of <NUM>-<NUM> compared to maltodextrin DP <NUM>-<NUM>, demonstrates an overall higher mass gain and are observed to undergo deliquescence indicating a higher propensity for moisture uptake. The water uptake occurs rapidly above <NUM> % RH. In contrast for maltodextrin DP <NUM>-<NUM>, which contains a lower proportion of oligosaccharides having a chain length of <NUM>-<NUM>, moisture uptake is higher at lower RH % and the sample returns close to its starting mass upon desorption with no evidence of deliquescence.

The results of the dose response study confirm that maltodextrin with a relatively high DE are more active against spider mites and achieve high mortality rates at lower doses. The maltodextrin with a lower DE exhibited relatively less activity and achieved a significantly lower mortality rate even at the highest dose at which it was used.

Claim 1:
Use of a composition comprising:
(i) maltodextrin;
(ii) surfactant; and
(iii) water,
wherein said maltodextrin comprises at least <NUM> % oligosaccharides having a chain length of <NUM> to <NUM> based on the overall oligosaccharide mixture having chains of length <NUM> to <NUM>, as a pesticide,
and wherein said use excludes therapeutic treatment of an animal or human body.