BE1030406A1 - METHOD FOR REDUCING THE QUANTITY OF CYANOBACTERIA IN AN AQUATIC ENVIRONMENT - Google Patents

Abstract

Method for reducing the quantity and/or activity of cyanobacteria present in an aquatic environment comprising detecting cyanobacteria in at least one area of the aquatic environment, and applying a composition substantially to all of said at least one area of the aquatic environment , said composition comprising particles of one or more aluminosilicate and one or more microorganisms and being characterized in that at least one aluminosilicate of said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and in which the microorganisms adhere to said aluminosilicate having a tetrahedral structure .

Description

METHOD FOR REDUCING THE QUANTITY OF CYANOBACTERIA OF A

AQUATIC ENVIRONMENT

Technical field

The present invention relates to a method for reducing the quantity of cyanobacteria present in an aquatic environment.

The present invention also relates to a use of a composition for reducing the cyanobacteria load of a pond and/or a lake and/or a river and/or a marsh and/or a marsh. marine area and/or a river.

Technological background of the invention

Cyanobacteria, or cyanophyceae, are bacteria

Gram-negative, photosynthetic comprising several thousand species of bacteria. Cyanobacteria are among the oldest organisms on Earth and are present almost everywhere on our planet, in the oceans, in fresh waters as well as in soils and in extreme environments such as hot springs, hypersaline waters, deserts and the polar regions. Cyanobacteria are particularly suited to growing in low-oxygen environments. Cyanobacteria can be present in unicellular form, in colonial form or in filamentous form. Cyanobacteria are important players in marine ecosystems, notably forming phytoplankton. However, certain cyanobacteria form harmful algal blooms leading to the disruption of aquatic ecosystems and can cause poisoning of wildlife and humans through the production of toxins {(cyanotoxins). Today, cyanobacteria blooms pose a serious threat to aquatic environments and public health. Indeed, due to the harmful proliferation of cyanobacteria in bodies of water representing a danger to the health of humans and animals, the authorities regularly close water points that have become toxic. These harmful proliferations of cyanobacteria are increasing in frequency and magnitude around the world, particularly due to an increasing accumulation of nitrogen, phosphate and organic matter in many bodies of water due to human activities. .

It is therefore important to be able to find solutions to reduce the load, the quantity, of cyanobacteria and/or the activity of cyanobacteria in numerous water points so as to maintain the aquatic ecosystem of these water points and so as to avoid poisoning of animals and/or humans, particularly in swimming pools.

State of the art

To combat the cyanobacteria load in an aquatic environment, there are physical solutions consisting of removing the — cyanobacteria contained in sludge and/or in floating matter from the aquatic environment manually and/or using siphons, scrapers, skimmers, etc. Ultraviolet and UV radiation treatments also exist to fight against cyanobacteria. However, these UV treatments cause violent lysis during which the metabolism of cyanobacteria induces the secretion of cyanotoxins. Solutions allowing suitable ventilation and/or suitable circulation also exist to combat the proliferation of cyanobacteria.

Chemical solutions to combat cyanobacteria also exist, such as treatments with herbicides or antibiotics. Although these solutions are effective in ensuring a short-term reduction in the quantity and/or activity of cyanobacteria present in an aquatic environment, these chemical solutions can also create an imbalance in the ecosystem of the aquatic environment, causing deleterious effects. in the medium and long term for the aquatic environment. In addition, these solutions can induce mutations and resistance mechanisms in cyanobacteria.

Finally, biological solutions also exist to combat cyanobacteria present in an aquatic environment. Indeed, document CN113149339 describes a composite material for the treatment of cyanobacterial blooms, characterized in that the composite material comprises clay minerals, flocculants and functional microorganisms; in which, the functional microorganisms are loaded on the clay minerals. Although the composition has certain merits for the treatment of cyanobacteria, the inventors have noticed that the microorganisms present on the composite material, necessary to combat the growth of cyanobacteria, are not very stable in the long term, with a survival and growth rate limited in extreme conditions such as aquatic environments poor in oxygen and/or very rich in organic matter, which reduces the ability to fight against cyanobacteria and/or which prevents the re-emergence of cyanobacteria from being effectively blocked. In addition, the inventors have also noticed that a composite material comprising microorganisms could be useful for reducing the quantity and/or activity of cyanobacteria in an aquatic environment on the condition that this composite material is distributed effectively in the aquatic environment.

Summary of the invention:

The present invention aims to overcome the drawbacks of the state of the art by providing a method for reducing the quantity of cyanobacteria present in an aquatic environment comprising the steps of:

- an identification of one or more areas of said aquatic environment in which a presence of cyanobacteria is detected, - an application of a composition substantially over all of said one or more areas of the aquatic environment, said composition comprising particles of one or more aluminosilicate and one Or = several microorganisms and being characterized in that at least one aluminosiicate of said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and in which the microorganisms adhere to said aluminosiicate having a tetrahedral structure.

Indeed, a method for reducing the quantity of cyanobacteria present in an aquatic environment according to the present invention in which one or more areas of the aquatic environment presenting cyanobacteria are identified during a first step followed by an application of a composition substantially on the entire area(s) of the aquatic environment identified makes it possible to optimize the action of the composition to reduce the quantity and/or activity (metabolism, and/or emergence) of cyanobacteria. Indeed, the development of cyanobacteria generally takes place in aquatic environments with low water circulation. Therefore, it is important to identify the places where cyanobacteria are present in the aquatic environment so as to distribute the composition so that this composition is in as much contact as possible with the cyanobacteria. Indeed, the microorganisms present in the composition used in the process according to the present invention will consume, in order to survive and proliferate, nutrients from the aquatic environment necessary for cyanobacteria to survive and proliferate, which leads to a lack of nutrients for the cyanobacteria and therefore a reduction in cyanobacteria in the aquatic environment. The composition used in the process according to the present invention will therefore be all the more effective if it is in close contact with the cyanobacteria present in the aquatic environment. In addition, the inventors have noticed that the tetrahedral structure of the particles of one or more aluminosilicate present in the composition used in the process according to the present invention forms an adequate microenvironment allowing the microorganisms of the composition to adhere to it and to be there. protected from the external environment rich in cyanobacteria, which thus promotes the proliferation of these microorganisms in the face of cyanobacteria. The microorganisms in the composition will therefore be able to proliferate by consuming the nutrients necessary for the proliferation of cyanobacteria while being safe in a suitable microenvironment, which makes it possible to effectively reduce the population of cyanobacteria in the aquatic environment. Furthermore, in the presence of conditions less favorable to the proliferation of microorganisms such as for example in the event of thermal, chemical and/or osmotic shock, or in the absence of nutrients in the aquatic environment, the tetrahedral structure of the aluminosilicate(s) of the composition provides also a favorable microenvironment for the sporulation of the microorganism(s). This microenvironment favorable to sporulation in the event of conditions unfavorable to proliferation allows the microorganisms in the composition to survive for a long period of time, which also prevents the re-emergence of cyanobacteria in the aquatic environment when new favorable conditions are again present. The method according to the present invention therefore not only makes it possible to reduce the load of cyanobacteria present in an aquatic environment but also provides a long-term, ecological and inexpensive solution making it possible to prevent the re-emergence of cyanobacteria in the aquatic environment, despite adverse conditions. extremes which may occur in the aquatic environment which may affect the proliferation of the microorganisms present in the composition used in the process according to the present invention.

The present invention also relates to a use of a composition for reducing the cyanobacteria load and/or the activity (metabolism and/or emergence) of cyanobacteria in a pond and/or a lake and/or a river and/or a marsh and/or a marine area and/or a river, said composition comprising particles of one or more aluminosilicate and one or more microorganisms and being characterized in that at least one aluminosilicate said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and in which microorganisms adhere to said aluminosilicate having

A tetrahedral structure.

According to the present invention, the term “reducing the cyanobacteria load and/or the activity of cyanobacteria” is preferably understood to mean a reduction in the quantity of cyanobacteria, a reduction in the number of cyanobacteria and/or a reduction in the proliferation of cyanobacteria. cyanobacteria and/or a reduction in the metabolic activity of cyanobacteria and/or a reduction in the emergence of cyanobacteria and/or a bacteriostatic impact on the cyanobacteria.

Other characteristics and advantages of the present invention will be derived from the following non-limiting description, and with reference to the examples.

The method for reducing the quantity of cyanobacteria in an aquatic environment according to the present invention comprises a first step in which an area of said aquatic environment is identified in which a presence of cyanobacteria is detected. Then, a composition is applied substantially to the entire area of the aquatic environment identified, the composition comprising particles of one or more aluminosilicate and one or more microorganisms and being characterized in that at least one aluminosilicate of said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and in which the microorganisms adhere to said aluminosilicate having a tetrahedral structure.

According to the present invention, the term “aquatic environment” means an aquatic environment of fresh water or salt water such as for example a pond, a body of water, an aquarium, a river, a river, a course water, a marsh, a port area, a marine area, a lake, etc.

Advantageously, the presence of cyanobacteria in the aquatic environment is detected visually and/or by photography and/or by microscopy on a sample of the aquatic environment and/or by a genetic test on a sample of the aquatic environment and/or by an ELISA test on a sample of the aquatic environment, ELISA test directed for example against cyanotoxins produced by cyanobacteria and/or by fluorimetry and/or by satellite images and/or airborne images.

Preferably, the composition further comprises particles of one or several porous calcium carbonate and/or pumice stone. In fact, particles of porous calcium carbonate and/or pumice stone provide the microorganisms in the composition with an additional porous support promoting the proliferation of these microorganisms.

In addition, being defined by a large exchange surface, these particles of porous calcium carbonate and/or pumice stone allow the microorganisms in the composition to carry out effective biological purification of the aquatic environment, reducing the load of organic matter in the aquatic environment. .

Advantageously, the particles of one or more aluminosilicate and/or the particles of one or more porous calcium carbonate and/or said particles of pumice comprise a population of particles having a determined average particle size of between 20 µm and 6000 µm, preferably between 50 um and 4000 um, more preferably between 150 um and 3000 um, even more preferably between 200 um and 2000 um, between 250 um and 2000 um, favorably between 300 um and 1000 um. Preferably, the population of particles having a determined average particle size represents more than 50%, preferably more than 70%, more preferably more than 80%, favorably more than 90% of all of said particles of one or more aluminosilicate and/or or all of said particles of one or more porous calcium carbonate and/or all of said particles of pumice. Indeed, a population of particles having an average particle size determined according to the present invention representing the majority of the particles of the composition allows the particles to be sufficiently large to position themselves on the carpet of cyanobacteria present for example in the bottom of the aquatic environment and /or on surfaces present in the aquatic environment. However, these particles, or a fraction of these particles, are also small enough to also be present in the water current and/or to move in the presence of eddies. Indeed, the movement of the aluminosilicate particles and/or the porous calcium carbonate particles present in the composition allows a better distribution of the composition in the aquatic environment, thereby promoting contact between the composition and the cyanobacteria of the composition. aquatic environment, and therefore favoring the process according to the present invention.

Advantageously, at least one of said one or more microorganisms being mainly in sporulated form. Indeed, if at least one microorganism of the composition used in the process according to the present invention is in sporulated form, this microorganism in sporulated form can either exit sporulation and enter the proliferation phase in the presence of conditions favorable to proliferation in the aquatic environment or remain in sporulated form in the presence of conditions unfavorable to growth while waiting for conditions favorable to proliferation to arise. In this way, the composition used in the process according to the present invention provides both a short-term solution for reducing the quantity of cyanobacteria present in the aquatic environment because microorganisms are present in non-sporulated form in the composition, but also provides a long-term solution allowing microorganisms in sporulated form to survive any unfavorable conditions in the aquatic environment and to enter into proliferation once favorable conditions for growth return, thus preventing the re-emergence of cyanobacteria and/or making it possible to reduce the quantity of cyanobacteria in the aquatic environment in the long term.

For the purposes of the present invention, the term "long term" means a period of time of several days or several weeks or several months and/or a period of time during which unfavorable conditions have appeared which may favor the sporulation of at least one microorganism present in the composition and/or maintain in sporulated form said at least one microorganism in sporulated form present in the composition used in the process according to the present invention.

Advantageously, said one or more microorganisms is part of a group of microorganisms consisting of

Bacillus subtilis, Bacillus licheniformis, Pseudomonas putida, Pseudomonas fluorescens, Alcaligenes sp, Acinetobacter sp, Arthrobacter sp,

Nitrosomonas sp, Nitrobacter sp, Lactobacillus helveticus, Lactococcus lactis, Pseudomonas sp, Botrytis cinerea, Sporotrichum dimorphosphorum,

Trchoderma reesei, Trichoderma harzianium, Trichoderma artroviride,

Rhodococcus erythropolis, Phanerochaete chrysosporium,

Saccharomyces cerevisiae, Propionibacterium sp, Paracoccus sp. More preferably, said one or more microorganisms is part of a group of microorganisms consisting of Bacillus subtilis, Bacillus licheniformis, Pseudomonas putida, Arthrobacter sp, Nitrosomonas sp,

Sporotrchum dimorphosphorum, Trichoderma reesei, Trichoderma harzianium, Trichoderma artroviide, Rhodococcus = erythropolis,

Phanerochaete chrysosporium.

Particularly advantageously, the composition according to the invention comprises Bacillus subtilis.

Advantageously, said one or more aluminosilicate is part of a group of aluminosilicates comprising tetrahedral aluminosilicates (tectosilicates) comprising zeolites and/or feldspars, and/or phyllosiicates comprising smectites, micas and/or kaolinites. Preferably, the composition has a content of tetrahedral aluminosilicates (tectosilicates) of at least 10% by weight relative to the weight of said composition, preferably at least 30%, favorably at least 35%, in which the tetrahedral aluminosilicates (tectosilicates ) preferably comprising zeolites and/or feldspars, preferably in which the zeolites comprising at least 40% chabazite by weight relative to the weight of the zeolites and/or preferably in which the feldspars comprising at least 40% sanidine in weight compared to the weight of feldspars. Indeed, a composition having such a content of tectosilicates (aluminosilicates having a tetrahedral structure) makes it possible to have an adequate microenvironment for the microorganisms of the composition favoring their protection and their growth, which makes it possible to favorably reduce the quantity and/or l activity of cyanobacteria present in the aquatic environment. Preferably, the aluminosilicates (tectosilcates) have a chabazite content of between 20% and 50% by weight relative to the total weight of aluminosilicate, preferably between 25% and 45%, favorably around 35%. Favorably, the phyllosilicates have a smectite content of between 50% and 90% by weight relative to the weight of the phyllosilicates, preferably between 60% and 85%, favorably around 75%.

Preferably, at least one of the aluminosilicates is tetrahedral, chosen from zeolites, preferably chabazite, phillipsite and/or stiloite, or feldspars. Particularly preferably, at least one of the tetrahedral silicates is a zeolite such as chabazite. In addition, the composition may comprise another tetrahedral aluminosilicate and/or a phyllosilicate, preferably chosen from mica, smectite, kaolinite, vermiculites, glauconites, chlorites and their mixtures. Preferably, the composition comprises at least 20% of tetrahedral aluminosilicate (weight of tetrahedral aluminosilicates: total weight of aluminosilicates) and/or at least 5% of smectites (weight of smectites: total weight of aluminosilcates). More preferably, the composition comprises between 20% and 90%, even more preferably between 30% and 80%, of tetrahedral aluminosilicate (weight of tetrahedral aluminosilicates: total weight of aluminosilicates) and/or between 5% and 75%, of preferably between 10% and 50%, more preferably between 20% and 40% of smectites (weight in smectites: total weight in aluminosilicates).

Preferably, said one or more porous calcium carbonate is chosen from calcite, aragonite, limestone, chalk and crushed shell.

Advantageously, said composition further comprises one or more trace elements forming part of a group of trace elements comprising magnesium sulfate, iron sulfate, manganese sulfate, disodium hydrogen phosphate, sulfate ammonium sulfate, zinc sulfate, ferrige chloride, calcium sulfate, potassium sulfate, copper sulfate, and sodium chloride, preferably said trace element(s) are added in a content of at minus 5% (weight of said trace element(s): weight of tetrahedral aluminosilicate).

Advantageously, a quantity of the composition of between 0.02 kg and 2 kg, preferably between 0.05 kg and 1 kg, more preferably between 0.07 kg and 0.8 kg, favorably between 0.1 kg and 0 .3 kg is applied for an area of 1 m? or a volume of 1 m° of said zone of the aquatic environment.

Favorably, the composition comprises a minimum amount of one or more microorganisms per kg of the composition of 10A8 CFU/kg. Advantageously, the composition comprises a quantity of one or more microorganisms per kg of the composition of between 10A8 CFU/kg and 10A15 CFU/kg, favorably between 10A9 CFU/kg and 10A13 CFU/kg, advantageously between 10M10 CFU/kg kg and 10A12 CFU/kg.

Preferably, the method according to the present invention further comprises, after a predetermined period of time following the application of the composition, one or more additional applications of the composition substantially over the entire area of the aquatic environment. Indeed, one or more additional applications of the composition makes it possible to reinforce the impact of the composition on the ecosystem of the aquatic environment by reducing the quantity and/or activity of cyanobacteria present in the aquatic environment.

Preferably, the predetermined time period is between 3 days and 400 days, preferably between 5 days and 200 days, favorably between 7 days and 100 days.

Advantageously, said one or more additional applications of the composition depends on the reduction in the quantity and/or activity of the cyanobacteria present in the area of the aquatic environment after the predetermined period of time following the application of the composition. Indeed, it is advantageous to carry out one or more additional applications of the composition to further promote the reduction of the quantity and/or activity of cyanobacteria present in the area of the aquatic environment.

The present invention also relates to the use of a composition for reducing the cyanobacteria load and/or the activity of cyanobacteria in a pond and/or a lake and/or a river and/or 'a marsh and/or a marine area and/or a river, said composition comprising particles of one or more aluminosilicate and one or more microorganisms and being characterized in that at least one aluminosilicate of said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and in which the microorganisms adhere to said aluminosilicate having a tetrahedral structure.

Advantageously, in the use of the composition according to the present invention, the composition further comprises particles of one or more porous calcium carbonate and/or pumice stone.

Preferably, in the use of the composition according to the present invention, the composition has a determined average particle size of between 20 um and 6000 um, preferably between 50 um and 4000 um, more preferably between 150 um and 3000 um, even more preferably between 200 um and 2000 um, between 250 um and 2000 um, favorably between 300 um and 1000 um. Advantageously, in the use of the composition according to the present invention, the composition further comprises one or more trace elements forming part of a group of trace elements comprising magnesium sulfate, iron sulfate, manganese sulfate, disodium hydrogen phosphate, ammonium sulfate, zinc sulfate, ferric chloride, calcium sulfate, potassium sulfate, copper sulfate and sodium chloride, preferably the said one or more trace elements are added in a content of at least 5% (weight of said trace element(s): weight of tetrahedral aluminosilicate). Favorably, in the use of the composition according to the present invention, the microorganisms are chosen from the group consisting of Bacillus subtilis,

Bacillus licheniformis, Pseudomonas putida, Pseudomonas fluorescens,

Alcaligenes sp, Acinetobacter sp, Arthrobacter sp, Nitrosomonas sp,

Nitrobacter sp, Lactobacillus helveticus, Lactococcus lactis, Pseudomonas sp, Botrytis cinerea, Sporotrichum dimorphosphorum, Trichoderma reesei,

Tichoderma harzianium, Trichoderma ortroviride, Rhodococcus erythropolis, Phanerochaete cChrysosporium, Saccharomyces cerevisiae,

Propionibacterium sp, Paracoccus sp. More favorably, the microorganisms are chosen from the group consisting of Bacillus subtilis,

Bacillus licheniformis, Pseudomonas putida, Arthrobacter sp, Nitrosomonas sp, Sporotrichum dimorphosphorum, Trichoderma reesei, Trichoderma harzianium, Trichoderma artroviide, Rhodococcus = erythropolis,

Phanerochaete chrysosporium.

Examples.-

Example 1.- identification of an area of an aquatic environment containing cyanobacteria

The inventors have identified an area representing an approximate surface area of 100 m? in a body of water in which the zone included an initial quantity of cyanobacteria distributed more or less uniformly over the entire surface of the bottom of the identified zone of the body of water. The inventors identified the area comprising cyanobacteria visually.

Example 2.- Composition to be applied to an area of an aquatic environment containing cyanobacteria according to the process of the present invention.

The composition to be applied to an area of an aquatic environment containing cyanobacteria comprises a first mixture where aluminosilicates are mixed with trace elements in the proportions indicated in table | considering a total quantity of 1 kg. A quantity of 10410 microorganisms comprising more than 60% of

Bacillus subtilis and a quantity of 1 g of bose corbonée metabolizable by microorganisms (source of energy and amino acids) are added to this first mixture.

Table 1: Proportion of aluminosilicate and trace elements present in the first mixture according to the present invention

Compounds Proportion

CE eenmenel

CuS04 02-190

Aluminosiicate 300-890 tetrohedral

The first mixture is carried out for 24 hours at a temperature of 20°C with constant stirring.

During a second mixture, 15 kg of porous calcium corbonate (limestone) and 2.5 kg of aluminosificates comprising 40% chanazite {chabozlte weight: total weight of aluminosificates] are added to 1.25 kg of the first mixture to give the second mixture. This second mixture is then dried at a temperature of 20°C for 24 hours to obtain a composition having a humidity level of less than 7% [water weight: second mixture weight).

Example 3.- Administration of a composition to an area of an aquatic environment containing cyonobacteria.

The inventors carried out a first administration, first spreading, of the composition of Example 2 on the area of the aquatic environment identified in Example 1. For this first administration, the inventors spread, in a substantially uniform manner, a quantity of 0.2 kg of composition per m2 of the aquatic environment area,

This first administration was carried out at the beginning of spring.

Then, the inventors carried out a second administration, second spreading, at the end of the fall. This second spreading is identical to the first spreading using the same quantity of composition per rm” of the aquatic environment zone as for the first spreading. 19 months after the first spreading, a visual inspection of the area of the treated aquatic environment was carried out to determine the quantity of residual cyanobacteria. The inventors determined that, 10 months after the first spreading at a location in the water surface, the quantity visible cyanobacteria (opis covering the bottom} or the activity of these cyonobacteria had decreased by more than 90% compared to the activity or the quantity of cyanobacteria present in an identified and distinct area of the body of water, not treated by ia composition according to the invention.

It is of course understood that the present invention is in no way limited to the embodiments described above and that many modifications can be made without departing from the scope of the appended claims.

Claims (20)

1. Method for reducing the quantity of cyanobacteria present in an aquatic environment comprising the steps of: - An area of said aquatic environment is identified in which the presence of cyanobacteria is detected, - a composition is applied to said area of the aquatic environment, said composition comprising particles of one or more aluminosilicate and one or more microorganisms and being characterized in that at least one aluminosilicate of said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and hence the microorganisms adhere to said aluminosilicate having a tetrahedral structure. 2. The method according to claim 1, wherein said composition further comprises particles of one or more porous calcium carbonate and/or pumice. 3. The method according to claim 1 or claim 2, wherein said particles of one or more aluminosilicate and/or said particles of one or more porous calcium carbonate and/or said particles of pumice comprise a population of particles having a determined average particle size between 20 um and 6000 um, preferably between 50 um and 4000 um, more preferably between 150 um and 3000 um, even more preferably between 200 um and 2000 um, between 250 um and 2000 um, favorably between 300 um and 1000 um. 4. The method according to claim 3, in which said population of particles having a determined average particle size represents more than 50% by weight (weight of the particles of the defined particle size: total weight of the particles), preferably more than 70%, more preferably more than 80%, favorably more than 90% of all of said particles of one or more aluminosilicate and/or all of said particles of one or more porous calcium carbonate and/or all of said particles of pumice. 5. The method according to any one of the preceding claims, wherein at least one of said one or more microorganisms being mainly in sporulated form. 6. The method according to any one of the preceding claims, in which said one or more microorganisms is part of a group of microorganisms consisting of Bacillus subtilis, Bacillus licheniformis, Pseudomonas putida, Arthrobacter sp, Nitrosomonas sp, Sporotrchum dimorphosphorum, Tichoderma reesei , Trichoderma harzianium, Trichoderma artroviride, Rhodococcus erythropolis, Phanerochaete chrysosporium and a mixture thereof. 7. The method according to any one of the preceding claims, wherein said one or more aluminosilicate is part of an aluminosilicate group having a tetrahedral structure comprising zeolites and/or feldspars, and/or phyllosiicates comprising smectites , micas and/or kaolinites. 8. The process according to claim 7, in which said composition has a content of tetrahedral aluminosilicates of at least 10% by weight relative to the weight of said composition, preferably at least 30%, favorably at least 35%, in in which said tetrahedral aluminosilicates preferably comprise zeolites and/or feldspars, preferably in which the zeolites comprising at least 40% chabazite by weight relative to the weight of the zeolites and/or preferably in which the feldspars comprising at least 40% of sanidine by weight relative to the weight of the feldspars. 9. The process according to claim 7 or claim 8, in which the aluminosilicates have a chabazite content of between 20% and 50% by weight relative to the total weight of aluminosilicate, preferably between 25% and 45%, favorably by around 35%. 10. The process according to any one of claims 7 to 9, in which the phyllosilicates have a smectite content of between 50% and 90% by weight relative to the weight of the phylosilicates, preferably between 60% and 85%, so favorable by around 75%. 111. The process according to any one of claims 2 to 10, wherein said one or more porous calcium carbonate is chosen from calcite, aragonite, limestone, chalk, and crushed shell. 12. The method according to any one of the preceding claims, wherein said composition further comprises one or more trace elements forming part of a group of trace elements comprising magnesium sulfate, iron sulfate, sulfate manganese, disodium hydrogen phosphate, ammonium sulfate, zinc sulfate, ferric chloride, calcium sulfate, potassium sulfate, copper sulfate, and sodium chloride, preferably the said one or more trace elements are added in a content of at least 5% (weight of said trace element(s): weight of tetrahedral aluminosilicate). 13. The method according to any one of the preceding claims, in which a quantity of said composition of between 0.02 kg and 2 kg, preferably between 0.05 kg and 1 kg, more preferably between 0.07 kg and 0. 8 kg, favorably between 0.1 kg and 0.3 kg is applied for a surface area of 1 m2 or a volume of 1 m3 of said area of the aquatic environment. 14. The method according to any one of the preceding claims, further comprising, after a predetermined period of time following the application of the composition, one or more applications = additional: of said composition substantially over all of said area of the aquatic environment. 15, The method according to claim 14, wherein said one or more additional applications of said composition depends on a reduction in said quantity and/or activity of cyanobacteria present in said zone of the aquatic environment after said predetermined period of time following said application of the composition. 16. Use of a composition to reduce the cyanobacteria load and/or the activity of cyanobacteria in a pond and/or a lake and/or a river and/or a marsh and/or 'a marine area and/or a river, said composition comprising particles of one or more aluminosilicate and one or more microorganisms and being characterized in that at least one aluminosilicate of said one or more aluminosilicate is an aluminosilicate having a tetrahedral structure and wherein the microorganisms adhere to said aluminosilicate having a tetrahedral structure. 17. Use of a composition according to claim 16, wherein said composition further comprises particles of one or more porous calcium carbonate and/or pumice. 18. Use of a composition according to claim 160u 17, in which said composition has a determined average particle size of between 20 um and 6000 um, preferably between 50 um and 4000 um, more preferably between 150 um and 3000 um, even more preferably between 200 um and 2000 um, between 250 um and 2000 um, favorably between 300 um and 1000 um. 19. Use: of a composition according to any one of claims 16 to 18, wherein said composition further comprises one or more trace elements forming part of a group of trace elements comprising magnesium sulfate, sulfate iron, manganese sulfate, disodium hydrogen phosphate, ammonium sulfate, zinc sulfate, ferric chloride, calcium sulfate, potassium sulfate, copper sulfate and sodium chloride, preferably the said oligo(s) elements are added in a content of at least 5% (weight of said trace element(s): weight of tetrahedral aluminosilicate). 20. Use of a composition according to any one of claims 16 to 19, in which the microorganisms are chosen from the group consisting of Bacillus subtilis, Bacillus licheniformis, Pseudomonas putida, Arthrobacter sp, Nitrosomonas sp, Sporotrichum dimorphosphorum, Trichoderma reesei, Tichoderma harzianium, Trichoderma artroviride, Rhodococcus erythropolis, Phanerochaete chrysosporium and a mixture thereof.