Field of the invention The present invention relates to an improved granular formulation , having enhanced storage stability, gradual release of azadirachtins for application to plant rhizosphere, the said formulation comprising of neem seed extract, an inert carrier particulate, a lipophilic substance, and a colorant. The invention also relates to a process for the preparation of the said granular formulation.

Background and Prior art of the Invention Protecting plants from pest is a complex task. Usually different pest effects the growth of various parts of the plant through out its life cycle. It is a general practice to apply plant protection chemicals or pesticides to protect plants from various pests for obtaining higher crop yields in agriculture, horticulture, floriculture and silviculture. These chemicals are also used to protect plants in gardens, lawns and household plants. Most of the damage due to the pest and diseases occur on visible aerial parts of the plant and hence it is a practice to spray plant protection chemicals on aerial parts to control pest. The conventional plant protection agents mostly act as contact poisons to pests resulting mortality or their suppression and protection to plant. The effectiveness of the plant protection agents which act on the basis of their contact toxicity depends on the type of formulation, efficiency of the spray mechanisms which provide effective coverage and penetrability of the active compound on the aerial parts of the plant. Generally 4tis reported that aerial sprays leaves 20-30% of wastage of the product due to drift during the spray which result wastage of valuable active ingredients apart from inherent leakage of the toxic compounds into air, water and soil causing contamination to the environment. These problems can be avoided using systemic plant protection molecules which can be absorbed by the plant when delivered to the plant rhizosphere through various delivery systems such as granules, pellets etc. Most of the plant protection chemicals are toxic to non target organisms and humans apart from their longer persistence in the environment. Due to increasing awareness of the environmental and toxicity concerns of these chemicals there has been a demand for alternative molecules which are active against target pest but safer to human and non-target organisms, and bio-degradable causing no harm to the environment. Extracts of various parts of the neem tree (Azadirachta indica A. Jussj such as leaves, bark, seeds etc. have been long known to have insect and disease control properties. The seed kernel in particular possesses the most active limonoids, such as Azadirachtins A and B and structurally related compounds such as Azadirachtins D, E, F, H, I, K, and the like, along with nimbin, salannin, azadiradione and the like. All the natural azadirachtins have been reported to have a very high growth disturbing activity against Epilachna vaήvestis, with LC50S in the range of 0.3 to 2.8 ppm (H.Rembold and I. Puhlmann, 1995). More than hundred terpenoid compounds are reported from the neem seed/fruit of the neem tree. Azadirachtins A has been tested against more than 400 insects and found to be active as antifeedant, insect growth regulation, ovicidal etc. thereby reducing insect population unlike neurotic insecticide. Being natural, they are highly degradable leaving no residues in the environment. Further the neem components are reported to be safer to target organisms and mammals and hence ideal agents replacing conventional toxic agents used in crop and public health.

Various methods have described to extract these active components from various parts of neem tree in the crude or semi crude forms to be used in commercially acceptable vehicles in the form of liquid and solid formulations such as powders, water dispersible granules etc. The crude neem seed extracts obtained after removal of lipid component normally comprises of about 20-45% of Azadriachtins A and B and have been shown to be potent insect growth regulator and feeding deterrent and form as potential active ingredients in commercial pest control formulations. These active molecules, however, are rather large and complex, and having acid and base sensitive functional groups and tend to be unstable when comes in contact with usual formulation ingredients, thus posing a major limitation for successful development of commercial formulations of these extracts in stable form.

So far, azadirachtins has been widely formulated in liquid forms to be applied as an emulsion or solution to agriculture crops. Various organic solvents and other inorganic additives have been used as carriers in order to make a cost effective and efficacious delivery system. The use of such carriers in commercial formulations is rather limited since many solvents are reported to be deleterious by causing degradation of azadirachtins. Dureja (1999) has studied the degradation of azadirachtins A in various solvents for 25 days at 29 +/- I0C. The results indicated that 50% of degradation of azadirachtin. A in methanol and acetone, 75-80% in methylene chloride, carbon tetrachloride and chloroform and about 85% in ethanol and water. Storage-stable azadirachtins containing extracts and formulations, and methods of their preparation have been proposed. U.S. Patent No. 4,556,562 reports that the stability of azadirachtins in ethanol emulsions increased by diluting the concentration of azadirachtins to between 2000 and 4000 ppm and adjusting the pH to between 3.5 and 6.0. U.S. Patent No. 4,946,681 reports greater stability for azadirachtins in solutions of aprotic solvents containing less than 2-5% of water. U.S. Patent No. 5,001,146 indicates that azadirachtins stability is improved adjusting the concentration of polar aprotic solvent to at least 50% by volume and by decreasing water content to less than 15% by volume. U.S. Patent No.5, 001,146 further indicates that azadirachtins stability depends upon the type of solvent employed, and that stability requires storage in certain enumerated aprotic and alcohol solvents. U.S. Patent No. 5,736,145 reports a storage stable aqueous composition containing azadirachtins A and U.S. Patent No. 5,827,521 indicates a stable azadirachtins formulation containing aliphatic dihydroxylated alcohols of more than 80% by volume and optionally with sunscreens and antioxidants. U.S. Patent No.5, 352, 697 describes the enhancement of stability of azadirachtins in solution by the presence of an epoxide, preferably an epoxidized vegetable oil. All these methods describe the enhancement in stability of extracts containing azadirachtins in the liquid form prepared from neem seed kernel with organic solvents. European Patent No. 9216109 describes making an extract of neem seed in solid form with greater stability. U.S. Patent No. 5,635,193 reports that a solid containing azadirachtins is stabilized by limiting moisture and volatile polar solvents to less than 1% and 5% respectively. Higher stability is suggested for the extract if formulated with 0.05% to 2% surfactant and 99% of solid diluent (75% of azadirachtins after 2 weeks of storage at 540C). But no details were given with respect to the type of solid diluents and surfactants. Preparation of stable neem seed extracts from the kernel of neem seed was reported in U.S. Patent No. 5,695, 763, European patent No. 579,624 and Indian Patent 181,845. Though, various extracts with stable azadirachtins have been reported, shelf life for azadirachtins in a formulated state is still a concern. Azadirachtins being unstable in various surfactants, organic solvents, and in different combinations of solvent and surfactant in liquid formulations which is a serious limitation for the development of a longer shelf stable commercial product. Normal pesticide formulations contain various solvents made mostly from petroleum, and there is a concern that usage of such solvents in specialty pesticide formulations, especially meant for organic farming, veterinary application, and the like, is discouraged. The use of such solvents, even at a lower rate demands large amounts of surfactants and other additives which makes the cost of the formulations high. The use of a broader range of ingredients in liquid formulations and the associated problem of instability in such formulations is also a serious concern for the commercial success of azadirachtins containing crop protection agents. Moreover, azadirachtins especially Azadirachtin A, found to be highly photo labile and tend to degrade fast when applied on plant surfaces. The mode of action of azadirachtins in providing protection to plants against insects is quite different from the synthetic chemical molecules, the later of which act mostly due to their contact toxic property. The azadirachtins act as a repellent, antifeedant and growth regulator and hence they need to be exposed, absorbed or entered into the insect systems for their control. Borer type of insects and insects which have hard scale bodies are difficult to control through foliar application due to lack of contact.. Compounds which possess systemic property are ideal for control of such insects. Azadirachtins were reported to possess systemic property and is readily absorbed by plants when applied to plant rhizosphere. Hence, a delivery system to deliver the azadirachtins into the plant rhizosphere will ensure effective protection of plants from borers as well as scaly sucking insects. Even though, the aqueous emulsions of formulations containing azadirachtins can be applied to the soil, because of its total exposure to water and soil it tend to degrade faster and unavailable for longer period of protection. Hence, the effective and economical use of azadirachtins is not possible with any of the existing liquid formulations and meant for foliar applications. There is a need for an efficient delivery system to transfer azadirachtins to the plant rhizosphere without any significant loss of its content then releasing it slowly for plant protection. This can be fulfilled through a granular formulation the type which has been used for delivering systemic plant protecting agents in agriculture and horticulture crops.

Granules are the most widely used and most versatile of the available pesticide delivery systems since their inception in the late 1940s. In these systems, the granules act as diluent as well as a carrier for the plant protection agents. The large number of particles per unit weight of the granules allows the granules to be applied per unit area at a rate which is toxic to the pest but which will not cause damage to desirable life forms and undesired drift. The available granule carriers are majority of natural, both inorganic and botanical and some are synthetic made out of the natural (botanicals) or synthetic components. But to be effective, they must have properties of (a) adequate liquid holding/ sorptive capacity (b) chemically inert and (c) free flowing nature.

The inorganic category of carriers comprise of clays, attapulgite, bentonite, kaolin, sepiolite, kieselguhr, diatomaceous earth, talc, brick fragments sand, white carbon and vermiculite. The botanical category comprises corn cobs, walnut shells, rice hulls, and wood, starch natural plant fibers and pumice of distinct particles within the range of 4 to 80-mesh (U.S. Standard). While low in cost, the clays often times need to be treated with a deactivator prior to formulation to prevent decomposition of the active ingredient. Corn cobs have been a primary source of inert granular carriers, but their extensive use and occasional drought conditions leading to inadequate supply and as a costly alternative.

The effectiveness of the granule product is dependent not only upon the nature of active ingredient but also upon the nature of inert ingredient used as the carrier which acts as the transfer mechanism for the active ingredient. If the carrier does not effectively release the active ingredient, the active compound will never reach its intended target. Importantly such a carrier should be inert to active ingredients and should also not cause degradation to active ingredients.

Thus, selection of an effective carrier is an essential step in the development of a successful granular formulation. It is indeed a critical task to choose a suitable carrier for azadirachtins due to its highly reactive nature with acidic/ basic and ionic nature of these carriers and other additives used in the granulation. The Applicant has tested the suitability of usual carriers such as sand, bentonite, clay etc. for azadirachtins granular formulation. It is observed that azadirachtins is highly susceptible to undergo rapid degradation in contact with these carriers when formulated in conventional manner. This limits the use of these carriers directly for formulations containing azadirachtins. Further, azadirachtins being readily soluble in water, normal methods of impregnation with these carriers without binders result in immediate release of azadirachtin into the soil as soon as it comes in contact with water, which is undesirable. The use of known binders such as polyvinyl alcohol, rosin, pressmud wax, sugar, clay along with usual carriers such as sand and bentonite have got limitation as they have caused rapid degradation to azadirachtins. Accordingly, there is a need to identify a solid carrier which provide higher stability to azadirachtins and capable of delivering the azadirachtins as desired into the plant rhizosphere. As azadirachtin molecules are thermo-labile, the extrusion methods of granular preparation which require several ingredients such as emulsifiers, polymers, binders, drying agents etc. and rather high temperatures during extrusion will lead to its degradation during the process. Hence, various granulation processes described in the prior art which are mostly suitable to synthetic chemical molecules are not ideal for bio-molecules such as azadirachtins with the available carriers and additives. Various prior art methods described on preparation of granular pesticide formulations were based on two different processes. 1. Extrusion granulation process, involve blending of active ingredient, with various additives such as waxes, surfactants, polymers, inorganic salts etc, melt/ mixing in water and extrude the fluid through a die to form granules of desired diameter. The extrudate is then fed into a dryer to reduce the moisture content of the granules to yield free flowing product. 2. Spray formulation process, in which, the pesticide is dissolved in an appropriate solvent or molten state is sprayed onto the inert particles. One of the important features of the granular formulation is its ability to release the pesticide active compound in a controlled manner. Several prior art methods were known to achieve controlled release of active substances from granulated forms which is achieved by encapsulation process. The encapsulation involves coating particulate matter for releasing of an active agent over a prolonged period. Such processes have been developed based upon the use of organic polymers of non-polymeric organic materials such as fats and waxes as the coating material. Typical prior art processes are described, for example, in US Patent Nos. 2800457, 2800458, 3041466, 3415758, 3429827, 3594327, 3639256 and 3674704. It is well known that biocidal materials can be incorporated into an elastomer matrix and caused to release at a rate efficacious with pest destruction. US Pat. No. 3417181 teaches that organotin toxicants can be dissolved in an elastomer-type matrix and caused to release through a diffusion-dissolution mechanism when exposed to water. The bio-active agents such as organic pesticides required to be soluble in elastomers such as natural rubber, styrene-butadiene rubber etc. (US Pat. Nos. 3590119, 3426473, 3851053 and 3639583. Prior art methods are known to cause an insoluble organic agent to emit from a plastic dispensing unit by using a third phase material that is (a) soluble to some extent in said plastic, and (b) will carry said organic agent in solution or serve as a migratory pathway for said agent to reach the surface of said dispenser. To achieve these complex properties to the granules it may require varied chemicals and conditions such as emulsification, polymerisation, cross linking etc. using inorganic salts, bases, acids and organic solvents, polymers etc. (US Pat. Nos.2956073, 3116201, 3705938, 3864468), Pesticides granules have been prepared by both macro and micro encapsulation processes, placed in ceramic materials, included in biodegradable polymers, mixed with porous mineral supports, coated with cellulosic derivatives, combined with poly-urea compounds and included with gypsum and other supports to protect the pesticide from the environment and to ensure a controlled release in an attempt to substantially control pest populations. In addition to the above prior art patent documents, the following patent documents refers to either the granular formulation comprising azadirachtins and/or its process for preparation. US Patent Nos.4,065,558, 4341759, 4,370,160, 4,464, 317, 4,485,103, 4,732,762, 4,971,796, 5,130,171, 5,229,356, 5,435,821, 5,484,600, 5,556,631, 5,562,914, 5,945,114 6,090,415, EP Patent No.0200288, 0848906, 0966882, GB Patent No.2127690, IN Patent No.189,080, WO 0205641, 02087342 & 9409627. Table

Some Prior-art methods for preparation of different types of granular formulations.

The above prior art documents have been considered in entirety in the present application. It is also clear from the details furnished in the above table limitations associated with both the prior art composition comprising azadirachtin and the process for the preparation of these compositions. The present invention has provided a composition comprising azadirachtins and its process for the preparation of said composition by overcoming with the limitations of the prior art.

Novelty Thus, there is a need for an effective and stable granular formulation of neem seed extract containing azadirachtins and a process to obtain azadirachtins based granules in stable form. This objective has been achieved by the Applicant by providing an improved granular formulation comprising neem seed extract containing azadirachtins for the purpose of protecting plants from insect damages when applied at the plant rhizosphere. The improved granular formulation has enhanced storage stability with gradual release of active principle azadirachtins from the granules. Also, the carrier used to achieve the efficient granular formulation is an easily available solid material, found compatible with the thermolabile azadirachtins only when it is coated with a liphophilic substance. The surprising results of the present invention provides a combination of enhanced storage stability and gradual release of azadirachtins in a formulation containing neem seed extract by using Iipoohilic substance which imparts the characterstic of deactivator and binder which has never been achieved in the prior art granular formulations.

Objects of the Invention An object of the present invention is to provide an improved granular formulation of neem seed extract essentially comprising of Azadirachtins for the purpose of protecting plants from insect damage. Another object of the invention is to provide a granular formulation which can be applied to a plant rhizosphere. Yet another object of the invention is to provide a granular formulation having enhanced storage stability. Still another object of the invention is to provide granular formulation which releases gradually Azadirachtins when applied to plant rhizosphere. Another object of the invention is to provide a granular formulation for systemic application. Still yet another object of the present invention uses a lipophilic substance as a deactivator to protect the azadirachtins from degrading due to its contact with the carrier. Still another object of the invention is to provide lipophilic substance as a binder acting as a permeable membrane for establishing the contact between water and neem seed extract used. Another object of the invention is to provide formulation in which the neem seed extract containing azadirachtins is sandwiched between the impregnated inert particulate and a lipophlic substance coating. Yet another object of the invention is to provide a safe, bio-degradable and environment friendly formulation. Still yet another objective of the invention is to provide a substitute for toxic and persistant chemical plant protecting agents to the formulations. Still another object of the invention wherein the solid carrier is modified by coating with a lipophilic substance to enhance the stability of azadirachtins of the neem seed extract used in the formulation. Still yet another object of the invention is to provide a carrier and other ingredients which are of natural origin, environmentally safe and inert to achieve desired activity.

SUMMARY OF THE INVENTION The present invention relates to an improved granular formulation of neem seed extract having enhanced storage stability, gradual release of azadirachtins for application to plant rhizosphere. The said formulation comprising of sand as a carrier, at least one lipophilic substance as binder, a colorant and azadirachtins containing neem extract providing the release of azadirachtins gradually and effectively at the point of application. The invention also relates to a process for the preparation of the said formulation by coating the carrier by a lipophilic substance, subsequently impregnating the coated carrier with neem seed extract followed by coating with a colorant and finally lipophilic substance by spraying and drying at a temperature of up to 5O0C. It is to be understood that both the foregoing general description and the following detailed description are exemplary and explanatory only and are intended to provide further explanation of the present invention, as claimed.

Description of Tables: Table 1 -Formulation recipe and percentage Azadirachtins release in water run test Table 2 - Stability data of Azadirachtins Table 3 -Mortality of BPH fed on rice seedlings treated with the granular formulations Table 4 - Monitoring of systemic absorption of Azadirachtins in rice seedlings DETAILED DESCRIPTION OF THE PRESENT INVENTION In accordance with the objective, the present invention describes an improved granular formulation having enhanced storage stability, controlled release of Azadirachtins on application to plant rhizosphere to prevent plants from insect damage, the said composition comprising of: Ingredients Wt./Wt(%) i. Neem seed extract 0.03 to 50.00 ii. Carrier 48.50 to 99.30 iii. Colorant 0.01 to 0.04 iv. Lipophlic substance . 0.50 tol .50

In an embodiment of the present invention describes preferred granular formulation comprising of: Ingredients Wt./Wt(%). 1. Neem seed extract 0.075 to 12.50 2. Carrier 86.70 to 99.20' 3. Colorant 0.02 to.0.03 4. Lipophlic substance 0.60 to 0.75 Another embodiment of the invention provides a process for preparing granular formulation, wherein the said process comprising steps of: a) washing optionally the carrier with water, drying at about 6O0C, sieving to obtain dried carrier, b) coating the dried carrier of step (a) with lipophilic substance dissolved in an organic solvent, c) impregnating the coated carrier of step (b) with neem seed extract dissolved in a solvent, drying in a stream of hot air at a temperature ranging between 4O0C and 5O0C, - d) coating with colorant dissolved in a solvent by spraying the step (c) impregnated material, drying at about 4O0C to below 5O0C, and e) coating finally the material of step (d) with a lipophilic substance, drying at about 4O0C to up to below 5O0C, to obtain the required granular formulation. The invention uses neeni seed extract having azadirachtins content ranging between 0.03 to 5 0% The azadirachtins content is preferably up to 1.0%. The carrier used is selected from silicious substances preferably sand. The preferable carrier used is river sand. The particle size of sand used ranges between 12 to 32 mesh, preferably 16 to 32 mesh size. The moisture content of sand used is up to below 2.0%. The lipophilic substance used for coating is selected from the group consisting of low melting hydrocarbon wax category of vegetable and animal origin preferably beeswax and paraffin wax. The colorant used is selected from the group consisting of synthetic and natural substance such as crystal violet, methyl violet, natural bixin turmeric and mixtures thereof. The invention provides organic solvent for dissolving lipophilic substance selected from the group consisting of low boiling hydrocarbons, ethers, ketones, aldehydes, esters, such as n-hexane, petroleum ether, diethyl ether, acetone, ethylacetate and like. The neem seed extract used is dissolved in a solvent selected from the group consisting of ethers, ketones, alcohols, aldehydes, esters such as diethylether, ethylacetate, acetone, and methanol and like. The azadirachtins containing neem extracts are prepared from neem seed and used for intended application as a plant protection agent. Since, azadirachtins control pest not through contact toxicity but through insect growth regulating property and possess systemic property, it can be effectively used with a delivery system, usually in solid granular form, which makes the plant to absorb azadirachtins when the granules are applied to the plant rhizosphere. Insects such as borers and sucking in nature with hard scaly bodies are also effectively controlled with such a method which make azadirachtins entry into the insect when they feed on the granule treated plants. Conventional liquid azadirachtins formulations fail to control these insects effectively when they are applied on plants as sprays. As azadirachtins is highly reactive to various carriers due to their acidic or basic nature and ionic nature, selection of suitable carriers is critical for the development of a stable granule formulation. Various processes which involve encapsulation or blending of various ingredients and making granules by extrusion are rather complex and require costly equipment and ingredients which make the product very expensive. These processes also have limitation to be used for, azadirachtins as they use drastic process conditions such as high temperature, melting of various ingredients, chemicals such as surfactants, polymers, proteinaceous materials, pH modifiers, ionic solvents, water etc. which are highly detrimental to azadirchtin causing degradation in the process. With an intention to develop a simple and cost effective granular formulation for azadirachtins containing neem extract we have initially tested agriculturally accepted carriers such as sand, bentonite etc. Granulation is carried out by spraying the solutions of azadirachtins containing neem extract dissolved in different solvents such as ethyl acetate, methanol, cyclohexanone etc. Evaluation of stability of azadirachtins in these formulations under standard accelerated conditions at 540C indicated higher degradation of azadirchtin which made these carriers unsuitable if formulated by methods hitherto known. Further, azadirachtins being highly soluble in water, its release in water is rather rapid which is undesirable for an ideal granular formulation. We have made several formulations using cheaper carriers such as sand, bentonite etc and various additives, studied their stability and release of azadirachtins when in contact with water. The limitations noticed for azadirachtins thus surprisingly got answered while studying the phenomenon of release of azadirachtins coated on sand granules with lipophilic substances used as a binder. One of the formulations provided higher stability to the azadirchtin which involves the following process. The natural river sand available locally is procured and cleaned with water to free it from mud and low density impurities. The dried sand is sieved to obtain particles with 16 to 32 mesh size. The sand is coated with a lipophilic substance preferably beeswax or paraffin wax, 1%, preferably 0.5%, most preferably 0.25% which is dissolved in a lipophilic solvent such as hydrocarbons by any normal method of spray or by direct contact of wax solution with sand granules. The hydrocarbon used for dissolving wax is selected from lower hydrocarbons, hexane, petroleum ether etc. of boiling point around 60-800C. The wax impregnated granules are dried under the current of hot air up to below 5O0C to obtain free flowing particles. The wax impregnated sand particles thus obtained are treated with azadirachtins containing neem extract equivalent to 1.2% azadirachtins, most preferably 0.1% azadirachtins dissolved in a suitable solvent. The solvent used for dissolving azadirachtins containing neem extract may be of medium to polar in nature such as esters, alcohols, ketones, aldehydes etc. Preferred solvents are ethyl acetate, methanol and acetone. The treatment of azadirachtins containing neem extract solution to the wax coated granules may be accomplished by direct treatment or by spraying, blending and dried under a current of hot air, preferably up to below 5O0C or under vacuum to obtain free flowing granules. The azadirachtin coated particles thus obtained are further treated with the lipophilic substance preferably beeswax or paraffin wax at 1%, preferably 0.5%, most preferably 0.25% which is dissolved in a lipophilic solvent such as hydrocarbons by any normal method of spray or by direct contact of wax solution with sand granules. The 5 hydrocarbon used for dissolving wax is selected from lower hydrocarbons, hexane, petroleum ether etc. having boiling point around 60-800C. The resultant granules are dried by normal drying methods to remove bound solvents preferably up to below50°C and/or under vacuum. The granules thus obtained retains azadirachtin without any change during the process of their preparation and possess higher storage stability and gradual release of 10 bio-active compounds (10-15% as observed in 'water run-off test') at the application site and give desired activity for its intended use. The amount of bio-active compounds present in the granule formulation can be any amount effective to have intended activity, such as, but not limited to, reducing or eliminating insect damage to trees and/or crops. Preferably the amount of azadirachtins 15 present in the pesticide formulation is from about 0.03 weight % to about 5.0 weight % based on the weight of the granule formulation, and more preferable from about 0.03 to about 1 0 weight % based on the weight of the granule formulation. In terms of the neem seed extract, the neem seed extract is preferably present in an amount, ranging from about 0.075 to about 50.0 w/w % of pesticide granular formulation. Most preferably, the ■ 20 azadirachtins present in the pesticide formulation ranges from about 0.03 to 5.0 w/w % The method for producing the bio-active compounds such as azadirachtins is described in U.S. Patent No. 5,695,763, which is incorporated herein in its entirety. In general, the azadirachtins are recovered preferably from the seeds of a neem tree by crushing the seeds and then extracting the azadirachtins and other active ingredients from 25 the crushed seeds with water. The extraction of azadirachtins and other active ingredients from the water is accomplished using a non-aqueous solvent which is not miscible with water and has a high solubility of azadirachtins than water, or by using a surfactant having a turbidity temperature between 20° and 8O0C. The concentrated azadirachtins is then recovered from the second extracting solution. The azadirachtins containing solution is 30 then concentrated to produce a concentrate containing azadirachtins which is added to a liquid hydrocarbon, thus forming a precipitate comprising azadirachtins which is then recovered for use in pesticide formulations. The method described in Indian Patent No. 181,845 which can also be adopted for the preparation of neem seed extracts comprising azadirachtins. The azadirachtins can also be recovered according to the method described in U.S. Patent Nos. 5,124, 349 and 5,397,571. The former described preparation of neem extract which comprise of de-fatting coarsely ground neem seeds with a non-polar solvent followed by extraction of azadirachtins from de-fatted neem seeds using a polar aprotic solvent. The process described in US Patent 5,397,571 involves extracting ground neem seeds with a co-solvent mixture of a non-polar and a polar solvent to obtain a neem extract having both the hydrophilic azadiracthins containing portion and the hydrophobic neem oil portion of the seeds. The resultant hydrophobic and hydrophilic extracts are concentrated by removing respective solvent to obtain 'neem extract' containing azadirachtins and other lipophilic components. The neem extract is then treated with a low polar solvent to precipitate azadirachtins-containing portion of the extract. The solid is separated by filtration, dried to obtain about 10-20% of azadirachtins in it. Other conventional methods which involve crushing, solid liquid extraction, chromatography, precipitation and like may also be used for the preparation of neem seed extract containing azadirachtins. With respect to the lipophilic organic substances used in the present invention are beeswax, or paraffin wax preferably paraffin wax which is about 2% weight % or less by weight of the granule formulation and preferably 0.25 - 1.0 weight % by weight of the granules. With respect to the carriers, it is sand, preferably natural sand, and its chemically related particles most preferably river sand of 16 to 32 mesh size. The moisture content of the sand is preferably up to below 2%. The granule formulation may additionally be made distinguishable by incorporating a colorant after impregnation of azadirachtins containing neem extract. The colorants may be synthetic compounds such as crystal violet, methyl violet, brilliant blue, indigo carmine, erythrosine, allura red, tatrazine, sunset yellow, fast green, carmosine, ponceau 4R, cochineal red A, red 2G, green S, brown HT, brilliant black BN, Iron oxides, quinoline yellow, lithol rubine BK etc or natural in origin such as curcumin, lutein, carotenes, lycopene, carmine, betanin, anthoxyanin, chlorophyll, carbon black, bixin, capsanthin etc. and the weight of which may be less than 1% and most preferably 0.05% by weight of the granule formulation. The colorant can be incorporated before the final coating of wax. The colorant is dissolved in methanol or ethyl acetate and sprayed over neem seed extract coated granules, dried under the current of air below 500C and/or under vacuum. The granular formulation described herein can be prepared by conventional mixing/blending techniques such as spraying or direct addition of various ingredients to the solid carrier in appropriate conventional equipment. Preferably, the lipophilic substance is dissolved in a hydrocarbon solvent, preferably in hexane and sprayed or added to the sand granules before and after treatment of azadirchtin containing neem extract. The solution of azadirchtin containing neem extract is prepared by dissolving in an appropriate solvent preferably in low boiling polar solvents such as acetone, ethyl acetate etc. and then sprayed or applied directly over wax coated sand particles. The drying of coated granules^ at the end of each stage of application of wax, azadirachtins containing neem extract and colorant is carried out at a temperature below 5O0C and/or under vacuum. The granular azadirachtin formulation of the present invention on analysis has shown the retention of azadirachtins content without any change during the manufacturing process. The granular azadirachtins formulations described herein are storage stable which is evidenced by subjecting accelerated heat degradation of the formulation. Thus 85% by weight of the azadirachtins originally present remains after 28 days of storage at 540C in a sealed container which is equivalent to two years of shelf life at an average storage conditions of temperature 25 Deg C. Further the granular azadirachtins formulation of the present invention meets the desired specification of a commercial agrochemical granular formulation that such a granule should release the active ingredient less than 15% of its nominal value in 10 minutes when the granules are brought in contact with water. Thus, the present invention provides cost effective process for preparation of azadirachtin granular formulation by using very minimal ingredients and less costly equipment and demonstrate higher stability to azadirachtins during the process and post process storage; releasing the azadirachtins in quantities which are sufficient for bio-activity and meeting granular specifications in general. The ability of the granule formulations of the present invention to contain all natural substances and yet be storable for longer periods has advantages over commercially available other liquid formulations since in many specialty application, the use of organic solvents is discouraged due to environmental concerns. The above mentioned features of the present invention thus make the process and product unique for successful commercial application. Additional features and advantages of the present invention will be set forth in part in the description which follows, and in part will be apparent from the description, or may be learned by practice of the present invention. The objectives and other advantages of the present invention will be realized and obtained by means of the elements and combinations particularly pointed out in the written description and appended claims. To achieve these and other advantages, and in accordance with the purpose of the present invention, as embodied and broadly described herein, the present invention relates to a granular formulation of azadirachtins containing neem extract comprising sand as a carrier, at least one lipophilic substance as a deactivator and binder, bio-active compounds such as azadirachtins and other limonoid containing neem extract. The following examples are for the purpose of illustration of the invention and should not be construed to limit the scope of the present invention. EXAMPLES Example I

Encapsulation of azadirachtins in granular formulation

Neem seed extracts containing azadirachtins is formulated in granular formulations using various carriers, binders/additives. The critical parameters of encapsulation and stability of active ingredients are evaluated using suitable methods in order to identify ideal carriers and binders for the neem seed extract. The extent of encapsulation of azadirachtins in all these formulations is determined according to 'water run-off test' as per the method prescribed in Bureau of Indian Standard specification IS: 6940-1982. According to the method, 1O g of the granules are taken into a 100 ml burette plugged with cotton, added 50 ml water to the granules: Water is collected from the burette after 15 minutes and analyzed for azadirachtins content by HPLC as per the method prescribed in Bureau of Indian Standard specification IS: 14299- 1995. The percentage of release of azadirachtins from the granules is given in the Table 1.

A. Neem seed extract granules prepared by conventional methods

Granular formulations 1 and 2 of azadirachtins containing neem extract are prepared by conventional manner as follows. To 474 g of sand particles are mixed with 20 g of white clay in a 2 lit conical flask. 1 g of polyvinyl acetate is dissolved in 15 ml of boiling water to which added neem seed extract 1.22 g (eq. to 0.1% azadirachtins), noigen- 1.16 g, crystal violet-0.15 g and sugar-5 g. The contents are thoroughly mixed to obtain a clear solution. The solution is then added slowly to sand-clay mixture while stirring the contents thoroughly. After the addition is completed, the wet granules are transferred onto a glass tray and dried at a temperature up to below 50° C for 8 hrs (Formulation 1). The granules aie subjected to water 'run-off test' to find out the extent of encapsulation. The results indicate 90% release of azadirachtins from the granulated product. The granules used for insect control generally releases about 15% of their active ingredient when subjected to this test. To further improve the encapsulation in Formulation 1, the granules are coated with beeswax as described below. 1.25 g of beeswax is dissolved in 15 ml of n-hexane. The wax solution is added drop wise to 250 g of above granules taken in a 1 lit conical flask. The contents are thoroughly mixed for few minutes and transferred into a glass tray and dried under a current of air or in a hot air over at a temperature below 50° C for 2 hrs (Formulation 2). The resulting wax coated granules are subjected to water runoff test. The results indicate 72% release of azadirachtins, a slight improvement as against granules without wax coat. This indicates that the conventional methods for preparation of agrochemical granules using inert carriers such as sand are not suitable for azadirachtins as they quickly release azadirachtins in contact with water which is undesirable. Even coating with wax at levels of 0.25-0.5% has resulted only slight improvement in encapsulation. Use of higher quantities of wax than 0.5% to improve the encapsulation could not be possible as agglomeration of granule particles is noticed. In addition to low encapsulation, the granules have shown shorter shelf life for azadirachtins which indicate that it may be due to the presence of several ingredients used in the preparation of granules which have caused degradation due to their adverse effects on azadirachtin. Hence use of several ingredients which is seen in general in conventional granules preparation may have limitation when applied for azadirachtins granules preparation.

B. Studies on Impregnation of neem seed extract containing azadirachtins in granular form.

With an objective to identify a process and composition with minimum number of additives but improved encapsulation and stability for azadirachtins, granular compositions 3 to 30 were prepared. Carriers such as sand and bentonite, binders or additives such as poly vinyl alcohol (PVA), rosin, beeswax, paraffin wax, pressmud wax, turpentine oil, neem oil, pine oil and polyethylene glycol (PEG) were used. The compositions of these formulations (100 g each) are given in Table 1 and the process for their preparation is as follows. Example II:

Preparation of Formulations: Formulations are prepared as per the procedures mentioned in example I-A

Example III:

Formulations 3-24: These formulations are prepared using sand without pre-treatment.

Step 1: Sand preparation: The sieved river sand, particle size of 16-32 mesh, is washed with water and dried under hot current of air (50-700C) until the bound moisture content reaches to below 2%. Commercial Bentonite is used directly without washing. Step 2: Impregnation ofneem seed extract containing azadirachtins: About 98.7 g of the sieved particles of sand or bentonite (12-30 mesh) are taken in a conical flask. To this added slowly about 0.3 g of neem seed extract (eq to 0.1% of Azadirachtins) solution dissolved in 5 ml of ethyl acetate. The contents are mixed thoroughly and dried under the current of air. Step 3: Coating of different binders over neem extract impregnated granules : The neem seed extract impregnated granules are taken in a conical flask and solutions of various binders alone or in combination are dissolved in 5 ml of (Beeswax - 0.25 - Ig ; Rosin — 0.1-0.5 g, Turpentine oil - I g; Neem oil - Ig) are added drop wise. The contents are mixed thoroughly and dried under the current of air to obtain free flowing granules.

Example IV:

Formulations: 25-30

These formulations are with sand and bentonite granules which are pre-coated with beeswax/paraffin wax before coating neem seed extract and other binders with the purpose of improving encapsulation. The process involves the following steps: Step 1: Preparation of river sand: The river sand is sieved to obtain sand particles of size of 16 to32 mesh, washed with water and dried under hot current of air until the bound moisture content reaches to below 2%. Commercial bentonite is used directly without washing. Step 2: Pre-coating of wax on carrier: To about 98 g of sand or bentonite obtained in Step 1 is added drop wise solution of binders (beeswax, 0.25 g; paraffin wax, 0.25 g) dissolved in about 5 ml of n-hexane. The contents are thoroughly mixed for uniform distribution of wax substance over the surface of sand, dried in current of air to obtain free flowing particles. Step 3: Impregnation of neem seed extract containing azadirachtins: 0.3 g of neem seed extract (eq to 0.1% of azadirachtins) is dissolved in about 5 ml of methanol and

the solution is added drop wise to the wax coated particles obtained in Step 2. The contents are mixed thoroughly and dried under the current of air or in a hot air oven at 5O0C for 2 hours. Step 4: Post coating of wax on neem seed extract impregnated granules: The

neem seed extract impregnated granules obtained in Step 3 is treated slowly with respective solutions of wax (beeswax, 0.75 g; paraffin wax, 0.75 g; pressmud wax, 0.75 g) prepared as in step 2. The contents are mixed thoroughly and dried under the current of air or in a hot air oven at a temperature below 5O0C for 2 hrs to obtain free flowing granules. The use of water from step 2 onwards are avoided as it is known to degrade azadirachtins and also leads to difficulty in drying at preferably low temperatures Hence, the usual binders such as guar gum, gum arabic etc. which are hydrophilic in nature could not be used due to their insolubility in solvents..

The extent of encapsulation is tested using 'water run-off test as described in Example IA and the results are given in Table 1.

Table 1

(Note: Aza = Azadirachtins)

The results indicate that the granules made by coating of azadirachtins containing neem extract directly on to sand (Formulation 3) without any binder gave faster release of

azadirachtins. Binders such as polyethylene glycol, polyvinyl alcohol haven't provided controlled release of azadirachtins where as beeswax and rosin have imparted gradual release to azadirachtins. Further, granules which are made with sand or bentonite carriers pre-coated with wax have provided comparatively higher encapsulation.

Example V

Stability of granules with different carriers and additives possessing higher

encapsulation of azadirachtins containing neem extract: The formulations which have shown improved encapsulation by releasing of about

15% azadirachtins in 'water run-off test Example 1 (Table 2) are studied for their stability under accelerated conditions at 54 +/- 20C. About 80 g. of granules of each formulation are taken into air tight glass vials and incubated in hot air oven for 28 days. Samples are taken 10 out from the oven at designated intervals and analysed for azadirachtins by HPLC as per the method prescribed in Bureau of Indian Standard specification IS: 14299-1995. The degradation of azadirachtins in these formulations is given in Table 2.

NA = Not Analysed,

The results indicate that formulations which are made of sand as a carrier and 5 beeswax as a deactivator/binder have higher stability to azadirachtins to those made of

bentonite carrier and rosin, turpentine oil, neem oil as binder/additives even though the

latter have shown higher encapsulation of azadirachtins (Example 1). But in view of stability of azadirachtins these additives were found unsuitable to be used in the formulation. The formulations which are made out of sand carrier and beeswax/paraffin

10 wax as deactivator/binder have shown both stability and higher encapsulation. The stability and encapsulation are further improved if azadirachtins containing extracts are

coated on wax-coated sand granules and is one of the inventive concepts in the subject matter of the present application.

Example VI

15 A. Efficacy of azadirachtins containing neem seed extract granular formulation against, Nilaparvata lugens (Ijrown plant hopper, BPH) insect on rice

The azadirachtins containing granular formulation, 25, prepared according to the

present invention is tested against BPH insects. The insects used for bioassay are from

cultures maintained in the laboratory. Rice seedlings are raised in trays and maintained in 0 the laboratory and 30 day old seedlings are used in the study. The test solutions containing

25 ppm, 50 ppm and 100 ppm of azadirachtins are prepared by adding required quantity of granules (5.5, 11 and 22 g respectively) in 200 ml of water taken in pet jars(Jar 1, Jar 2 and Jar 3 respectively). A bunch of rice seedlings are immersed in the treated solutions. For bio-efficacy evaluation, nine seedlings from each of the pet jars (1-3) are taken out after 24 hrs of treatment and planted in clay pots (3 x 3 plants) in three replications for each concentration. Plants which are not treated with granules are served as control. The seedlings are then enclosed in mylar cages (10 cm dia & 30 cm high). Ten newly emerged BPH nymphs are transferred in to each of the cages and the top of each mylar cage is covered with wet muslin cloth. The pots are watered continuously through out the study. The mortality of BPH insects is observed on 1st, 3rd, 5th, 7th, 9th, 11th, and 14th days after treatment and the corrected mortality is determined using Abbot's formula.

Table 3: Mortality of BPH fed on rice seedlings treated with the granular formulation of the present invention.

*Corrected mortality is in parenthesis

The bio-efficacy results indicate 93-100% mortality of BPS which is attributed to the granules.

B. Systemic absorption of azadirachtins by rice plants treated with azadirachtins granules:

Systemic absorption of azadirachtins is monitored in rice seedlings immersed in the three jars containing granule treated water. The seedlings are removed from each of the jar on 1st and 3rd days, extracted and analyzed for azadirachtins content by HPLC (Table 4). Table 4

The HPLC results indicate absorption of azadirachtins by rice seedlings in proportion to the dosage of the granules which gave 25, 50 and 100 ppm respectively.

Example VII

Preparation of azadirachtins containing neem seed extract granules in ton quantities as per the present invention involves the following steps.

Step-1: Sand preparation: The sand of required particle size, 1190μ/550μ (16 -

32 mesh), is obtained by sieving 4450 kg of raw river sand in a sieve shaker. This sand is taken in a Mild steel tank provided with an agitator and washed with hot water at about

700C to remove the adhering impurities. The water is discarded and the cleaned sand thus

obtained is transferred to a Mild steel dryer. Drying takes place at 600C under normal

conditions over a period of 4 hrs. The clean sand of 1000 kg with moisture content in the sand is <0.05% is obtained. 989.3 kg of the dried sand is charged on to a coating pan. Step-2: Pre-wax coating: n-Hexane, 58.3 kg (eq. to 5.83% of the batch size) is taken into a stainless steel 304 mixing vessel. Gradually, with agitation, 2.5 kg of Paraffin wax (eq. to 0.25%) is added and the addition is done at 60 Deg C. The Paraffin wax gets dissolved in the n-Hexane completely, typically within one hour. The paraffin wax solution is sprayed slowly at the rate of 14.5 kg/hr on to the sand, rotating in the pan at a speed of 10 rpm. The drying is done simultaneously by means of hot air blower

mechanism by maintaining the temperature below 500C, preferably at about 470C to

ensure uniform coating of paraffin wax on the sand the coating process is carried out for

four hours. Step-3: Impregnantion of neem seed extract containing azadirachtins: Ethyl

acetate, 58.3 kg (eq. to 5.83% of the batch size) is taken into a stainless steel 304 mixing vessel. Gradually, with agitation, about 3.245 kg of extract equivalent to 1.0 kg of 100% Azadirachtins (eq. to 0.12% of the batch size) is added. Agitation is continued until the complete dissolution of the extract in methanol is obtained, typically within one hour. The neem seed Extract solution thus obtained is sprayed slowly at the rate of 14.5 kg/hr on to the wax coated sand granules, in the pan rotating at a speed of 10 rpm. The drying is done simultaneously by means of hot air blower rotating mechanism by maintaining the temperature below 500C, preferably at about 420C to ensure uniform impregnation of neem seed extract on the wax coated sand granules. This process is carried out for four hours. Step-4, Coating with coloring agent: Ethyl alcohol, 11.6 kg (eq. to 1.16% of the batch size) is taken into a stainless steel 304 mixing vessel. Gradually, with agitation, 0.2 kg of Methyl violet (eq. to 0.02% of the batch size) is added. Agitation is continued until it is completely dissolved, typically for one hour. This solution is sprayed gently at the rate of 3 kg/hr on to the Azadirachtins containing neem seed extract impregnated sand granules, in the pan rotating at a speed of 10 rpm. The drying is done simultaneously by means of hot air blower mechanism by maintaining the temperature below 500C. To ensure uniform coating of the coloring agent, the process is carried out for four hours. Step-5, Post-wax coating: n-Hexane, 58.3 kg (eq. to 5.83% of the batch size) is taken into a stainless steel 304 mixing vessel. Gradually, with agitation, 5 kg of Paraffin wax (eq. to 0.5% of the batch size) is added and the addition is done at 60 Deg C. The paraffin wax is dissolved in the n-Hexane completely, typically within one hour. The solution is sprayed gently at the rate of 14.5 kg/hr on to the color coated sand granules, in the pan rotating at a speed of 10 rpm. The drying is done simultaneously by means of hot air blower mechanism by maintaining the temperature below 5O0C , preferably 470C. To ensure uniform coating of paraffin wax over color coated sand granules, the process is carried out for four hours. Step 6: Packing: The dried formulated product is packaged in thick double polythene bags of thickness not less than 0.062 mm each inside high density polyethylene drums, fiber board cartons, or mild steel drums. Package sizes include 5, 10 and 20 kilograms. Main Advantages:

1) Enhanced storage stable granular pest control formulation containing azadirachtins.

2) Gradual release of active constituents' azadirachtins from the granular formulation enabling prolonged efficacy.

3) Cost effective formulation and a simple process for the preparation of the same.

4) Eco-friendly granular formulation ideal for organic agriculture.

5) Easy availability of solid carriers and other ingredients used in the granular formulation