"FUNGICIDAL MIXTURE
FIELD OF INVENTION This invention relates to a fungicidal combination, comprising a phtalimide, a cinnamic acid derivative and a strobilurin, and the preparation and use of said composition for the control of fungi pathogens.
BACKGROUND OF THE INVENTION
In the field of crop protection, the use of a particular active substance for the control of specific fungi may become increasingly difficult in time, as a result of the adaptation of the mentioned fungi to the fungicide being used. This leads to the loss of effectiveness in the control of the pathogen, and, consequently, downfall in crop production and profitability.
A very well known and widely used form of approaching this problem is by using a combination of different active substances presenting different mechanisms of action (EPPO Standards, Good plant protection practices, EPPO Bulletin 32, pages 367-369, 2002).
Many different compounds are known for use as systemic, contact or soil fungicides. Examples of such compounds, which are available commercially, can be found in "The Pesticide Manual", Eighth Edition, 1987, edited by Charles R. Worthing and S. Barrie Walker, and published by The British Crop Protection Council.
Compound (I), Dimethomorph [IUPAC: 4-[3-(4-chlorphenyl)-3-(3,4- dimethoxyphenyl)acryloyl]morpholine], whose structural formula is:
is a systemic fungicidal active substance (see "The Pesticide Manual" 14th. Edition (2006), The British Crop Protection Council, pages 347 f.). It was disclosed for the first time in European Patent EP 120321.
However, Dimethomorph shows relatively low systemic activity against oomycetes such as Plasmopara spp and Phytophtora spp. (WO 98/46607).
Compound (II), azoxystrobin [IUPAC: methyl (2£)-2-{2-[6-(2- cyanophenoxy)pyrimidin-4-yloxy] phenyl} -3 -methoxy aery late], disclosed in the European Patent EP 0382375, has the
Azoxystrobin is a broad spectrum fungicide with protectant, curative, eradicant and systemic properties. It is used mostly to prevent spore germination and is commonly used as a protective treatment before or at the very early stage of disease development.
Nevertheless, various species of plant pathogenic fungi and oomycetes have developed resistance to this class of fungicides (Plant Disease, Vol. 91 , No. 11 , November 2007 , pp 1502- 15115) .
Compound of formula (III) is a well-known contact, protective leaf- fungicide. It was first described in patent US 2553770 and has the common name Folpet [IUPAC name: N-(trichloromethylthio hthalimide].
Although formulations containing contact fungicides are still commercially available, they are not taken up into the plant tissue, and only protect the plant where the spray is deposited. Since large amounts of active substance per hectare are required, they are not the optimal solution to prevent or treat diseases caused by fungi. References to the use of the above mentioned active ingredients in fungicide mixtures can be found in several patent documents:
European Patent EP 1319336 Bl relates to a process to produce suspension concentrates or water dispersible granules based on active ingredients with a melting point below 80 °C, as, for example, pyraclostrobin, triflosxystrobin or propiconazole, and to mixtures of one of these active ingredients with an extensive list of active substances that includes folpet, dimetomorph and azoxystrobin.
Patent application WO 2007/052256 A2 relates to a process for the production of water dispersible granules comprising at least one of an extensive list of active substances fungicides, insecticides and herbicides, which includes, among others, folpet, dimetomorph and azoxystrobin.
European Patent application EP 1028125 Al discloses a fungicidal composition comprising a dipeptide compound with general formula
and one or more fungicides selected from a list of 40 active ingredients, which includes folpet, dimetomorph and azoxystrobin.
European Patent EP 1289366 Bl relates to active agent combination comprising (2E/Z)-2-(2-((6-(3-chloro-2-methylphenoxy)-5-fluoro-4-pyrimidinyl)-oxy)-phenyl)-2- (methoxyimino-N-methylethanamide of formula
and one or more of a list of 82 fungicides including folpet, dimetomorph and azoxystrobin.
European Patent application EP 1326495 Al relates to a mixture of phenyl- pyrroline ketoenol derivatives of general formula
and one or more known fungicides and acaricides selected from a group comprising folpet , dimetomorph and azoxystrobin .
Patent application WO 03041728 Al relates to a fungicidal composition comprising phenyl-propargylether derivatives of the eneral formula
and one or more fungicides selected from a group comprising folpet, dimetomorph and azoxystrobin.
European Patent EP 0280348 Bl discloses combinations of fungicidal active ingredients, in particular mixtures of a cinnamic acid derivative and at least one
systemic, contact or soil fungicide, chosen from a list comprising folpet. One of the formulations claimed in EP 0280348 Bl is a mixture comprising Dimetomorph and Folpet, currently marketed under the trademark Forum F*. However, no reference is made to azoxystrobin.
A formulation comprising Azoxystrobin and Folpet (Quadris Max" from Syngenta) is also commercially available.
The above mentioned prior art references do not disclose the mixture of the above mentioned compounds I, II and III or the concentration ranges of the active ingredients in the mixture or application rates for an effective fungicidal action.
There is a need of agricultural formulations for a broader control over plant pathogenic fungi, in particular to resistant strains, with an application rate as low as possible, in order to obtain to an optimized toxicological and ecotoxicological behavior.
SUMMARY OF THE INVENTION The invention relates to a new fungicidal composition characterized by comprising dimetomorph, azoxystrobin and folpet.
In an aspect of the invention, the concentration range of dimetomorph is from 1 % to 20% by weight, the concentration range of azoxystrobin is from 1 % to 20% by weight, and the concentration range of folpet is from 20% to 50% by weight.
In another aspect of the invention, the composition further comprises surfactants and/or carriers, the surfactants are selected from the group comprising dispersing agents, wetting agents and anti-foam agents.
In a preferred embodiment of the invention, the fungicidal composition comprises 8 % by weight of dimetomorph, 8% of azoxystrobin and 40% by weight of folpet.
The invention also relates to the use of said fungicidal composition to treat the plant diseases selected from the group comprising Plasmopara (Downy mildew) on grapevines, uncinula on grapevines and phytophtho a on potatoes and tomatoes. The invention further relates to a process to treat crops from pathogen fungi characterized by applying to said crops a mixture of dimetomorph, azoxystrobin and folpet.
In an aspect of the invention, the process is characterized by applying 0.05 kg/ha to 0.3 kg/ha of dimetomorph, 0.05 kg/ha to 0.3 kg/ha of azoxystrobin and 0.5 kg/ha to 1.5 kg/ha of folpet.
DETAILED DESCRIPTION OF THE INVENTION
It is an objective of the present invention to provide a mixture of fungicidal active substances presenting high effectiveness in the control of fungi.
It was surprisingly found that by combining dimethomorph (compound I) with azoxystrobin (compound II) and folpet (compound III), a synergistic effect in the biological efficacy is observed, resulting in an unexpected increase in efficacy when compared to the efficacy of each of the active ingredients or with binary mixtures of the above mentioned active ingredients. This synergistic effect that results in the broadening of control over pathogenic fungi is probably due to resistance breakdown as an effect of the combination of three active ingredients with different biological mechanisms of action: folpet is a contact phthalimide, dimetomorph is an inhibitor of cellular wall formation and azoxystrobin is an inhibitor of mitochondrial respiration.
The compositions according to the invention can be used in a preventive or curative form for controlling pathogens in useful plants, in particular phytopathogenic fungi in several crops. Particularly, the compositions described in the invention are effective against plant pathogenic fungi belonging to the classes Ascomycota (Uncinula) and Oomyceta (Phytophthora, peronospora, pseudoperonospora, albugo, bremia, plasmopara, pythium) . According to the invention, useful plants are selected from the group comprising grape vines, potatoes, tomatoes and lettuce. The above group exemplifies the plants in which the present invention could be used upon.
The compositions according to the present invention are particularly useful for controlling the plant diseases selected from the group comprising Plasmopara on grapevines, uncinula on grapevines, phytophthora on potatoes and tomatoes.
Furthermore, the compositions according to the present invention delay the appearance and development of oomycete strains, particularly resistant to dimethomorph, especially Plasmopara spp and Phytophtora spp strains.
The concentrations of the three active substances used in the present invention are in the range of 1-20% for compound I, in the range of 1-20% for compound II, and in the range of 20-50% for compound III.
Accordingly, and depending on the desired effect, the application rates of the mixture according to the invention are from 0.05 to 0.3 kg/ha of compound I, from 0.05 to 0.3 kg/ha of compound II, and from 0.5 to 1.5 kg/ha of compound III. When controlling the harmful fungi pathogenic to the various cultures mentioned, particularly in grapevine, the application of the mixture of the active ingredients I, II and III is carried out by spraying the plants after bud burst during each vegetative cycle.
The formulations are prepared in a known manner, for example, by mixing the active compounds with carriers and surfactants. The preparation of the formulations encompassed in the present invention is known in the art and use well-known additives. In general, the formulations comprise from 22 to 90% by weight of the active substances. The active substances are employed in a purity of from 90% to 100% , preferably from 94% to 100% .
As an example, the formulation of a Wettable Powder (WP) is carried out using the following composition and procedure:
Compound I
Compound II
Compound III
Alkylnaphtalenesulphonate salt
Lignossulphonate / condensed naphtalene sulfonate
Antifoam (Polyorganosiloxane)
Kaolin
Compounds I, II and III, are mixed and subsequently milled in a jet mill, until a sufficiently fine particle size (about 95 % of the particles under 10 μηι) is obtained. The previous mixture is added to the remaining constituents listed in the above table, and all components mixed in a suitable mixer (ex. Nautamix mixer).
The same active ingredients can be formulated as Water Dispersible granules (WG), using the following composition and procedure:
% w/w
Compound I 8
Compound II 8
Compound III 40
Alkylnaphtalenesulphonate salt 3
Lignossulphonate / condensed naphtalene sulfonate 5
Antifoam (Polyorganosiloxane) 0.1
Kaolin up to 100
Compounds I, II and III, are mixed and subsequently milled in a jet mill, until a sufficiently fine particle size (about 95 % of the particles under 10 μΐη) is obtained.
The previous mixture is added to the remaining constituents listed in the above table, and all components mixed in a suitable mixer (ex. Nautamix mixer).
Water (5-20% of the solids mass) is added to the previous mixture in order to form a homogeneous "paste" , which is afterwards fed into a "basket" type extruder, where the material is forced through a perforated screen (0.8 mm to 1 mm diameter) by extrusion blades.
Moist granules from the extruder are fed into the Spheronizer, where a spinning plate promotes collisions of the granules against the equipment walls and against other granules, resulting in their plastic deformation, forming spheres.
The resulting product is dried with a stream of hot air in a fluidized bed drier. The formulations obtained by the above procedures were submitted to stability tests for 14 days at 54 °C, and were shown to be stable, since analytical measurements demonstrated that there was no significant degradation of the active ingredients.
The association of the active ingredients according to the invention can be further presented, for example, in the form of directly sprayable suspensions or dispersions, emulsions, oil dispersions or dustable powders, to be applied by means of spraying, atomizing or dusting.
The fungicidal action of the mixture according to the invention can be demonstrated by the experiment below:
Fungicidal action
Grapevines of the variety Muller-Thurgau were cultivated in the greenhouse under standard conditions. Cuttings with one bud took roots in perlite and were potted into a soil mixture (Floraton 1) in pots of 9x9 cm.
Plants with at least five fully developed leaves were selected for the experimental procedure. Four to five fully developed leaves were picked from each plant, randomly distributed and treated or used as a control. An isolate of Plasmopara viticola was used for the evaluation of the curative activity of the individual products for the control of the downy mildew.
For the production of spores, infected plants were incubated in the dark during the night, the newly generated sporangia harvested and put into distilled water. Concentration was determined with a Fuchs-Rosenthal counting chamber and adjusted to 50 000 spores/ml.
In order to test of the fungicidal activity of the products, the leaves were inoculated with P. viticola. Five leaves were selected, placed into Petri dishes with moist filter paper, with the lower side upward and inoculated with the above mentioned sporangia suspension.
Afterwards, during the night, an incubation in the dark under moist conditions (moist chamber) followed.
Next day, the inoculated leaves were dipped into the fungicide solutions contained in 100 ml in beaker glasses for complete wetting, afterwards dried under sterile conditions and again placed into the Petri dishes in a chamber thermostatically kept at a temperature of 21 °C and relative humidity higher than 90% .
The evaluation of the attack on leaves was carried out seven days after inoculation (expressed as attack on leaves, in percentage).
The fungicidal effect after one or two days from inoculation was analysed.
The trial was carried out (in duplicate) at "State Service Center Rhein Pfalz Breitenneg 71, Neustade", Germany.
Efficacy (E) was calculated using Abbott's formula:
Ε=(1-α/β)χ100 wherein a corresponds to the fungicidal infection of the treated leaves, in percentage, and β corresponds to the fungicidal infection of the untreated (control) leaves, in percentage.
An efficacy of 0 means that the infection level of the treated leaves corresponds to that of the untreated control leaves, and an efficacy of 100 means that treated leaves were not infected.
The expected efficacies of the mixture of the active ingredients are determined using Colby's formula and compared with the observed efficacies (Colby, S.R. , "Calculating synergistic and antagonistic response of herbicide compositions", Weeds 15, pp 20-22, 1967)
EE= x + y - x X y/100 wherein:
-EE is the expected efficacy, in percentage, when using the mixture of the active compounds A and B at the concentrations a and b.
-x is the efficacy, in percentage, when using active compound A at the concentration a;
-y is the efficacy, in percentage, when using active compound B at the concentration b;
If the observed efficacy (E) exceeds the expected (calculated) one (EE), the mixture presents synergistic effect.
The results from the assays were worked using the above formulas and are presented in Tables A and B.
TABLE A
Curative efficacy on leaves inoculated with Plasmopara viticola
Active ingredient concentrations in Efficacy (%) the suspension, ppm Observed Expected
1st day
11+ III 100+500 26.5
I 100 60.6
1+ 11+ III 100+ 100+500 81.8 71.0
2st day
11+ III 100+500 34.3
I 100 68.6
1+ 11+ III 100+ 100+500 84.6 79.4
TABLE B
When the leaves are treated with a suspension containing the mixture of three active ingredients according to the invention one day after the fungi inoculation, the observed efficacy is about 10% higher than the efficacy we would expect taking into account the results obtained by any of the binary mixtures and the remaining active substance.
When the treatment is carried out two days after the inoculation the observed efficacy is still 5 % higher than the efficacy we would expect taking into account the results obtained by any of the binary mixtures and the remaining active substance.
The test results show that mixtures according to the invention present a synergistic effect, which results in an unexpected increase in efficacy against Downy mildew (Plasmora viticola) .