EP4266878A1 - Device for assisting in capturing mosquitoes - Google Patents

Abstract

The present invention relates to a device and its use for controlling insect pests and disease vectors. More specifically, the present invention relates to a device comprising a composition for assisting in capturing mosquitoes, containing a stable mixture of olfactory substances, on a solid or semi-solid support, which stimulates, and assists in the capture of insects that serve as bait for mosquito traps.

Description

Description

MOSQUITO CATCH AID DEVICE

The present invention relates to a device and its use for the control of harmful insects and disease vectors. More specifically, the present invention relates to a device comprising a composition for aiding the capture of mosquitoes, containing a stable mixture of olfactory substances which stimulate insects, in order to serve as a lure for mosquito traps. The present invention preferably relates to the device comprising the composition on a solid support and its use in trapping mosquitoes.

[0002] Mosquitoes represent a real threat to public health, particularly in tropical countries or hot regions, where their proliferation leads each year to diseases such as malaria, dengue fever, chikungunya or others which may be more serious. such as malaria which still remains unvaccinated. Indeed, thousands of species of mosquitoes feed on the blood of host species such as animals and especially humans. In recent years, the number of cases of diseases caused by mosquito bites has increased, particularly in Africa where the ravages of this insect make it a real disease vector. The World Health Organization deplores more than a million victims of malaria each year in the world. To another extent, global warming has also caused the rise of mosquito species in regions that were once uncommon to them, we have thus been able to identify a marked increase in the population of tiger mosquitoes in the south of France. The control of these populations is therefore a global issue.

[0003] Several methods exist to limit damage. Mosquito biting is markedly reduced by the use of insecticide-treated bed nets, improved housing construction to prevent entry of mosquitoes, and the spraying of residual insecticides indoors. dwellings. The spread of mosquitoes can also be controlled by destroying aquatic breeding sites. The development of various body repellents in gel, cream or lotion is also significant in the fight against mosquitoes.

[0004] Other mosquito control methods include physical traps into which insects are attracted by means of attractant compositions. In its most basic form, the trap uses a light as an attractant and then a fan to draw the mosquitoes into a catch net. But this poses limits in the context of diurnal species that are not very sensitive to light. Alternative attractants can also be used or combined, such as heat, sound, carbon dioxide (CO2) and/or chemical baits. There are also different modes of capture and/or physical killing such as electrified traps or sticky traps. Many measures have therefore been deployed for mosquito control, and the most common are to repel mosquitoes through various chemical or biological agents having a repellent effect.

[0005] However, and in order to better prevent the nuisance caused by mosquitoes, solutions should be proposed to increase the effectiveness of trapping. The optimization of mosquito trapping is generally done using baits of different natures.

[0006] Mosquitoes are known to use a variety of olfactory signals to locate the host. Human beings naturally emit odors that attract mosquitoes, these odors form a veritable attractive chemical cocktail resulting from the volatile compounds produced by breathing, the skin and the microbiota present on its surface. The insect has many olfactory receptors that allow it to find a target to feed on. Consequently, traps have been combined with chemical agents likely to attract mosquitoes in order to increase the trapping of the latter, in particular by using the sensitivity to carbon dioxide (CO2) of the vast majority of mosquitoes of the Culex or Aedes genus.

[0007] This is particularly the case for the traps marketed under the Biogents® brand. Adding CO2 to the trap dramatically increases the capture rate of tiger mosquitoes as well as all other mosquito species and various blood-sucking insects. The kit releases pure CO2 from the specialized emitter nozzle which is designed to optimize the dispersion of carbon dioxide. The CO2 flow can be regulated using a specialized regulator. Mosquito traps are equipped with a CO2 kit which attracts mosquitoes by mimicking human breathing and releasing carbon dioxide into the air and skin compounds in appropriate concentrations. When humans exhale, they release carbon dioxide into their surroundings. Exhaled air containing carbon dioxide as well as skin compounds is an attractive stimulus that is carried by the wind. Mosquitoes follow these plumes to find their blood source. These traps use attractants based on organic acid and ammonia in combination with CO2 to achieve good trapping performance. However, although effective, these traps absolutely require a permanent supply of CO2 to guarantee effectiveness in attracting other species of mosquitoes. The user must therefore, in addition to finding attractant refills, monitor the CO2 supply to the trap in order to maintain its effectiveness. In addition, the use of greenhouse gases greenhouse and the emission of heat relating to these traps is inadvisable during the summer period, the preferred season for mosquitoes.

[0008] Application US2014/322360 (Al) describes a trapping device which uses CO2 as an attractant but also a method for generating CO2 and attracting hematophagous arthropods which comprises the oxidation of at least one organic substance liquid such as ethanol, during which CO2, EbO and heat are produced. It is a catalytic reaction, one of the end products of which is CO2. However, the volatility of the gases resulting from this reaction does not allow the attraction to be maintained over time. This document does not disclose a device comprising a composition on a solid support to improve the effectiveness of trapping, nor a mixture of substances helping to capture mosquitoes.

The present invention aims to provide a new device comprising a composition to help capture mosquitoes in traps and improve their effectiveness. The use of organic compounds such as acids and certain bases can be a means of mimicking the odors released by the human microbiota.

[0010] The prior art describes various attractants and odoriferous substances highlighted for their effect on mosquitoes, but there remains a need to improve their effectiveness and ease of use.

The prior art, and in particular the patent application W02010101462 describes different combinations of such substances, including those of the present application, but these do not constitute real mixtures within the same composition usable as such. Indeed, patent application WO2010/101462 clearly shows in FIG. 1 that the constituents tested are placed in different containers, placed simultaneously in the trap and do not constitute one and the same stable composition. Another experiment uses strips of nylon, each dipped in only one of the constituents, said impregnated strips then being placed together in the trap. This results in a mixture of odors but there is no single stable composition made up of all these substances together. Indeed, the applicant has found that the composition of choice to aid in the capture of mosquitoes must contain all the ingredients described in the application. However, mixing the different active agents together in solution does not make it possible to obtain a stable composition. This is why the prior art proposes the use of all these substances on separate supports in a trap where only the odors mix. The solution proposed by WO2010/101462 cannot be transposed to a marketable product. Indeed, taken independently, these substances are acids or bases and can be toxic or irritating. It appears dangerous to offer such products to the user, without the possibility of controlling the doses and proportions used. In addition, the disclosed substances do not show their effectiveness only in the presence of CO2, unlike the applicant's solution in which the mixture is effective while freeing itself from the use of CO2. The prior art does not propose a single stable composition of a mixture of substances helping to capture mosquitoes and in no way suggests making such a composition incorporated on a support.

In order to avoid the various drawbacks mentioned above, the present invention describes a new device consisting of a composition comprising several compounds, on a solid or semi-solid support and a method for its use as an attractant for mosquitoes. . Surprisingly, the device according to the invention prevents the degradation of the composition containing a mixture of capture aid substances and ensures better efficiency of their power over time.

The invention relates on the one hand to a new capture aid device for mosquitoes comprising a mixture of several odorous compounds on a solid or semi-solid support and on the other hand to a method of using this device. preventing degradation of the composition and ensuring better effectiveness of the composition as a bait over time.

By stable according to the invention is meant a physical stability of the composition and a chemical stability of the active agents within the composition.

[0015] Indeed, it is known that the chemical substances, in mixture, in particular in solution and in contact with the external environment can oxidize or undergo various degradations, likely to limit the effects of the composition and to alter its effectiveness. It is therefore common to use CO2 as a synergist of odorous agents recognized by mosquitoes. Surprisingly, the applicant has found that the mixture of organic compounds consisting of a liquid solution composed of at least three compounds chosen from hexanoic acid, lactic acid, ammonia, cyclopentanone, and 3-methyl - 1-butanol, once incorporated on a porous support, makes it possible to stabilize the mixture and to improve its effectiveness in terms of capturing mosquitoes and this by freeing itself from the use of CO2. One of the objectives of the present invention is also to propose a device whose manufacturing process remains simple to implement and transposable to an industrial scale.

The invention therefore relates to a device for capturing mosquitoes consisting of a solid or semi-solid support comprising a composition containing a stable mixture of at least three compounds chosen from hexanoic acid, lactic acid, ammonia, cyclopentanone, and 3-methyl-1-butanol. Preferably, the stable mixture is composed of four compounds, more particularly hexanoic acid, lactic acid, cyclopentanone, and 3-methyl-1-butanol. In a particularly preferred mode according to the invention, the device for capturing mosquitoes consists of a solid support or semi-solid comprising a composition containing a stable mixture of hexanoic acid, lactic acid, ammonia, cyclopentanone, and 3-methyl-1-butanol.

By solid or semi-solid support is meant a support consisting of an absorbent material chosen from thermoplastic polymers, plant materials, mineral materials or a gel.

The support of the device according to the invention is a porous and absorbent material in the form of chips, granules or any other form likely to be used with an apparent density of between 150 g/L and 1500 g/L.

[0019] According to the present invention, the support may be a thermoplastic polymer chosen from polyamides, polyurethanes, polyvinylacetates, 1 ethylvinyl acetate.

According to the present invention, the mineral materials are chosen from pozzolan, diatomite, sepiolite or slag.

According to the present invention, the plant materials are chosen from corn cob, wood chips, cork, bamboo fiber, cellulose or cellulose acetate.

The invention preferably relates to a support chosen from cellulose acetate, cork, sepiolite or corn cob.

[0023] More preferably, the support is chosen from corn cob because it has several advantages. Its structure in the form of granules makes it easy to incorporate the mixture of compounds. In addition, the introduction of the device in the form of corn cob granules within the trap, and its elimination, are easier compared to a powder form, often encountered for solid supports such as, for example, acetate of cellulose or sepiolite.

According to the present invention, the corn cob used has a particle size between 150 μm and 4500 μm, preferably between 3100 and 4500 μm.

Preferably, the amount of solid or semi-solid support used in the trap is between 0.3 and 10 grams, preferably 0.5 and 2 grams. In a particularly preferred mode, the solid support is corn cobs used in an amount of between 0.5 and 2 grams and preferably equal to 1 gram.

It is understood within the meaning of the invention that the supports used have a high absorption capacity. The corn cob, for example, comprises an internal alveolar structure which greatly increases the exchange surface with a liquid solution, which allows the absorption of said solution. The porous network of said supports and the neutral pH of their surface will advantageously allow a gradual release and the maintenance over time of a composition for aiding the capture of mosquitoes and this without the addition of CO2 as a synergist agent . According to the invention, the device comprises the support on which the capture aid composition is incorporated. The composition is a liquid solution comprising a mixture of at least 3 compounds chosen from lactic acid, ammonia, hexanoic acid, 3-methyl-1-butanol and cyclopentanone, preferably the four compounds: acid lactic acid, hexanoic acid, 3-m ethyl-1-butanol and cyclopentanone. According to a particularly preferred embodiment, the composition is a liquid solution comprising a mixture of the five compounds lactic acid, ammonia, hexanoic acid, 3-methyl-1-butanol and cyclopentanone.

The composition used in the device according to the invention therefore preferably comprises, as a percentage of the total device, namely the support and the incorporated liquid composition:

- 0.01 to 10% lactic acid,

- 0.005 to 2% ammonia,

- 0.005 to 10% hexanoic acid,

- 0.005 to 10% of 3-methyl-1-butanol,

- 0.01 to 15% cyclopentanone.

More preferably, the composition used in the device according to the invention comprises as a percentage of total device:

- 0.01 to 5% lactic acid,

- 0.005 to 1% ammonia,

- 0.005 to 1% hexanoic acid,

- 0.005 to 2% of 3-methyl-1-butanol,

- 0.01 to 1% cyclopentanone.

In a preferred embodiment, the composition thus obtained is incorporated into the solid or semi-solid support in a concentration of between 1 and 5%, preferably between 2 and 3% by weight of the total device. In a particularly preferred mode, the solid support is corn cob containing between 2 and 3% of composition according to the invention by weight of the total device.

The device according to the invention therefore preferably comprises, as a percentage of the total device:

- 0.01 to 10% lactic acid,

- 0.005 to 2% ammonia,

- 0.005 to 10% hexanoic acid,

- 0.005 to 10% of 3-methyl-1-butanol,

- 0.01 to 15% cyclopentanone

- between 90 and 99% solid support.

More preferably, the device according to the invention comprises as a percentage of total device:

- 0.01 to 5% lactic acid,

- 0.005 to 1% ammonia, - 0.005 to 1% hexanoic acid,

- 0.005 to 2% of 3-methyl-1-butanol,

- 0.01 to 1% cyclopentanone

- between 97 and 98% solid support.

In another mode according to the invention, the composition comprises said mixture in solution in a solvent, more particularly in ethanol.

According to a second mode, the composition therefore comprises, by weight relative to the total weight of the composition, between:

- 0.01 to 10% lactic acid,

- 0.005 to 2% ammonia,

- 0.005 to 10% hexanoic acid,

- 0.005 to 10% of 3-methyl-1-butanol,

- 0.01 to 15% cyclopentanone,

And the complement to 100% in solvent.

Preferably, the composition comprises, by weight relative to the total weight of the composition between:

- 0.05 to 1% lactic acid,

- 0.1 to 2% ammonia,

- 0.05 to 1% hexanoic acid,

- 0.1 to 2% of 3-methyl-1-butanol,

- 0.1 to 2% cyclopentanone, and the balance at 100% ethanol.

In the case of the composition with solvent, said composition is incorporated into the solid or semi-solid support in a concentration of between 2 and 20%, preferably between 5 and 15%. In a particularly preferred mode, the solid support is corn cob containing 10% of composition according to the invention by weight of the total device.

Similarly, the invention also relates to the device for its use to help capture mosquitoes within a trap. Indeed, the device comprises a stable mixture of olfactory substances which stimulates and attracts insects, in order to serve as a lure for anti-mosquito traps. Surprisingly, the applicant has shown that the composition alone, a mixture consisting of lactic acid, ammonia, hexanoic acid, 3-methyl-1-butanol and cyclopentanone, without support, had less effectiveness in capturing mosquitoes that said composition incorporated on the solid or semi-solid support according to the invention. Just as surprisingly, when each component is incorporated independently on a solid support per component and then when all the solid supports are put together in the trap, these show less efficiency than the mixture of the components put together, in the form of a stable composition, on a single solid support. The applicant has thus demonstrated that the use of a solid support or semi-solid in the presence of such a composition formed a more effective and easy to use mosquito capture aid.

The invention also relates to the use of a device to aid in the capture of mosquitoes and also relates to the solid or semi-solid support of said device for stabilizing a liquid solution consisting of lactic acid, ammonia, hexanoic acid, 3-methyl-1-butanol and cyclopentanone.

The invention also relates to a method for assisting in the capture of mosquitoes using a device characterized in that it comprises the steps consisting of:

- prepare a liquid solution comprising a stable mixture of olfactory substances which stimulate insects, in order to serve as a lure to help capture mosquitoes,

- contacting an effective amount of said solution on a solid or semi-solid support.

- place the support in a mosquito trap.

The invention preferably relates to a method for helping to capture mosquitoes using a device characterized in that it comprises the steps consisting of:

- prepare a liquid solution comprising a mixture of at least 3 compounds from lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone.

- contacting an effective amount of said solution on a solid or semi-solid support.

- place the support in a mosquito trap.

The invention preferably relates to a method for assisting in the capture of mosquitoes using a device characterized in that it comprises the steps consisting of:

- prepare a liquid solution comprising a mixture of lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone,

- bringing an effective quantity of said solution into contact with a solid or semi-solid support, preferably corn cob,

- place the support in a mosquito trap.

The mosquito capture aid device according to the invention can be offered in different formats, dispensed in the form of a single-dose sachet or box, corresponding to the quantity necessary for use within the trap. A non-limiting example of presentation may be single-dose sachets of 1 gram of corncob support incorporating the composition, a mixture of lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone . In another mode, the device can be offered in a packaging of different sizes or weights with instructions indicating the quantities to be used in the trap.

[0043] In the remainder of the application and the following examples, the mixture of lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone will be referred to interchangeably as a mixture or Mix. By recomposed Mix is meant the compounds independently incorporated on solid supports [0044] [Fig 1] represents a diagram of the experimental device.

[0045] [Fig 2] shows the results of the mosquito capture rate, obtained from different combinations of compositions tested.

[0046] [Fig 3] shows the results of the mosquito capture rate depending on the nature of the solid support used

[0047] [Fig 4] shows the results of the mosquito capture rate for a device comprising the mixture without solvent incorporated on two types of support.

[0048] [Fig 5] shows the comparative results of a trap and activator device according to the invention and of various traps and activators on the market.

[0049] Example 1: Presentation of the trap and its operation

As shown in Figure 1, the mosquito trap used for these tests diffuses specific heat and light to attract mosquitoes. A suction system located below the light source then draws the insects attracted into a receptacle intended to accommodate the trapped mosquitoes. Procedure of the trap test:

The tests take place in a lighted room of approximately 10 m ³ , where the temperature is maintained at 27±2°C and where the relative humidity is between 50 and 75%. The trap is introduced into a 30*30*30 cm cage with PVC frames and mosquito net walls, placed in the center of the room on a table (h=74 cm). 1 gram of corn cobs containing the mixture of compounds according to the invention, or 10% of the mixture when the latter is in solution in a solvent, is deposited in the dedicated compartment of the trap. 30 female mosquitoes aged 5 to 15 days, looking for a host and having had no access to food during the 2 hours preceding the test, are then introduced into the cage using a mouth aspirator , then the trap is activated for 6 hours. At the end of the test, the trap is turned off and the uncaptured females are counted and eliminated with an insect vacuum cleaner. The trap tray collecting the insects is then opened and the number of females trapped is in turn noted and the mosquitoes eliminated.

Example 2: Composition 1 of the mixture according to the invention

Preparation procedure:

Add all liquid components to a beaker and stir.

Example 3: Composition 2 of the mixture according to the invention

Preparation procedure:

Add all liquid components to a beaker and stir.

Example 4: Composition 3 of the mixture according to the invention

Preparation procedure:

Add all liquid components to a beaker and stir.

Example 5: Composition 4 of the mixture according to the invention

Preparation procedure:

Add all liquid components to a beaker and stir.

Example 6: Device 5 according to the invention,

Preparation procedure

- add all the liquid components in a beaker and stir

- Introduce the solid support into a reactor

- Put under agitation

- Add the mixture of compounds via the pouring funnel

- When the compound appears dry, drain and recover the device according to the invention.

Example 7: Device 6 according to the invention

Example 8: Device 7 according to the invention

Example 9: Device 8 according to the invention

Example 10: Device 9 according to the invention

Example 11: Evaluation of the mosquito capture power of different combinations of the Mix on corn cob

[Fig 2] shows the capture rate results obtained from different combinations of compositions tested.

- None: Only the attractive power of the trap alone using specific light and heat has been evaluated.

- Corn cob + Mix recomposed without ammonia: Each of the 4 components of the mixture: hexanoic acid, lactic acid, cyclopentanone, and 3-methyl-1-butanol was incorporated alone on a corn cob support. The 4 different roundups thus obtained are put together just before the trapping test and placed in the trap.

- Corn Cobs + Recomposed Mix: Each of the 5 components of the Mix: hexanoic acid, lactic acid, ammonia, cyclopentanone, and 3-methyl-1-butanol, is incorporated alone on a corn cob support. The 5 different roundups thus obtained are put together just before the trapping test. - Corn cob only.

- Corn cob + Mix recomposed without the 2 acids (hexanoic acid and lactic acid): Each of the 3 components ammonia, cyclopentanone, and 3-methyl-1-butanol was incorporated alone on a corn cob support. The 3 different roundups thus obtained are put together just before the trapping test and placed in the trap.

- Corn cob + Mix, namely the composition of the mixture in a solvent according to the invention: A solution containing the 5 components mixed in ethanol is incorporated on a single and unique support in corn cob in order to evaluate the rate capture of the preferred device according to the invention. The "Mix" composition in figure 2 is that corresponding to composition 1 of example 2.

The results obtained show that only the device having a support in which the “mix” composition according to the invention has been incorporated makes it possible to obtain significant results on the improvement and increase in the rate of capture of mosquitoes by the trap. On the other hand, the results also show that the support allows stabilization of the mix according to the invention because it is more effective than each of these 5 compounds used alone on a support.

Even if the corn cob support itself contributes to increasing the capture rate, the applicant's device is effective because this capture rate increases significantly when the mix is incorporated into the support. These results also show the importance of the mixture in solution of the 5 compounds of the device according to the invention on the rate of capture of mosquitoes and its contribution to the control of the latter without adding CO2.

[0060] Example 12: Evaluation of different solid supports for the incorporation of the mixture

At T0, Mix 5, or liquid mixture of the 5 compounds hexanoic acid, lactic acid, ammonia, cyclopentanone, and 3-methyl-1-butanol, according to composition 1 of example 2 is formulated then is incorporated into different types of support, Cellulose Acetate, Cork, Sepiolite, and Corn Cob CC. The various devices thus produced are then stored at room temperature, protected from light and humidity, and then tested in the trap.

Figure 3 shows the results obtained in terms of mosquito capture with the different devices.

The best efficiencies of the mixture are obtained when it is incorporated on cellulose acetate or corn cob, respectively 61.1 and 58.6% of mosquito capture. However, there is no significant statistical difference between the different devices tested (T.test, p-value >0.05).

All media show effectiveness in capturing mosquitoes. However, when used according to the present invention, the corncob, in addition to be a support allowing a good efficiency, presents itself as the support best suited, by its particle size, to the use within a trap. [0061] Example 13: Evaluation of various solid supports for the incorporation of the mixture without solvent.

The 2 devices according to compositions 6 and 7 of examples 7 and 8, were produced to compare the effectiveness of the devices with the two different supports, corn cob and cellulose acetate on which the mixture of the 5 hexanoic acid compounds is incorporated, lactic acid, ammonia, cyclopentanone, and 3-methyl-1-butanol.

The test was carried out on a large scale, namely under normal conditions of use in a room of a house. The tests take place in a lighted room of approximately 21.5 m ³ , where the temperature is maintained at 25±3°C and where the relative humidity is between 44 and 75%. The trap is placed in the center of the room on a table (h=74 cm) and 1 gram of device to be tested is placed in the compartment dedicated to receiving captured mosquitoes. The trap is activated then 10 female mosquitoes aged 5 to 15 days, looking for a host and having not had access to food during the 2 hours preceding the test, are then introduced into the room using mouth aspirator. The test is then launched for a period of 8 hours. At the end of the test, the trap is turned off and the uncaptured females are counted and eliminated with an insect vacuum cleaner. The trap tray collecting the insects is then opened and the number of females trapped is in turn noted and the mosquitoes eliminated. Mosquitoes that are dead and/or not found are not counted.

Figure 4 shows the results obtained in terms of mosquito capture with the different devices.

Both devices show similar effectiveness in capturing mosquitoes. There is no significant statistical difference among the different devices tested (T.test, p-value >0.05).

However, when used according to the present invention, the corn cobs, in addition to being a support allowing good efficiency, is presented as the best suited support, by its particle size, for use within a trap. [0062] Example 14: Comparative evaluation of the effectiveness of the device according to the invention with other traps and activators on the market^

The test, the protocol of which was defined in Example 13, was carried out with various market traps and corresponding activators, as well as with the trap containing the device according to the invention.

Figure 5 shows the results obtained in terms of mosquito capture with the different traps. In conclusion, the trap plus the device according to the invention show efficacy results superior to the various traps and activators tested on the market.

Claims

Claims

[Claim 1] Mosquito capture aid device characterized in that it consists of a solid or semi-solid support comprising a composition containing a stable mixture of at least 3 compounds chosen from lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone.

[Claim 2] Device according to Claim 1, characterized in that the solid or semi-solid support is an absorbent material chosen from thermoplastic polymers, plant materials, mineral materials or a gel.

[Claim 3] Device according to Claim 2, characterized in that the solid support is a plant material chosen from corn cob, wood shavings, cork, bamboo fiber or cellulose acetate.

[Claim 4] Device according to Claim 3, characterized in that the plant material is corn cob.

[Claim 5] Device according to Claim 2, characterized in that the solid support is a mineral material chosen from pozzolan, diatomite, sepiolite or slag.

[Claim 6] Device according to one of Claims 1 to 5, characterized in that the composition contains a stable mixture of at least 4 compounds chosen from lactic acid, ammonia, hexanoic acid, 3-Methyl - 1 -Butanol and cyclopentanone.

[Claim 7] Device according to one of Claims 1 to 6, characterized in that the composition contains a stable mixture composed of lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone .

[Claim 8] Device according to Claim 7, characterized in that the composition is a liquid solution comprising, relative to the total weight of the device, a mixture of:

- 0.01 to 10% lactic acid,

- 0.005 to 2% ammonia,

- 0.005 to 10% hexanoic acid,

- 0.005 to 10% of 3 -methyl -1 -butanol,

- 0.01 to 15% cyclopentanone.

[Claim 9] Use of the device according to one of Claims 1 to 8 to aid in the capture of mosquitoes within a trap.

[Claim 10] Use according to Claim 9, characterized in that the solid or semi-solid support stabilizes a liquid solution consisting of lactic acid, ammonia, hexanoic acid, 3-methyl-1-butanol and cyclopentanone .

[Claim 11] Use according to Claim 10, characterized in that the solid or semi-solid support is corn cob.

[Claim 12] Method for assisting in the capture of mosquitoes using a device according to one of Claims 1 to 8, characterized in that it comprises the steps consisting of:

- prepare a liquid solution comprising a mixture of at least 3 compounds from lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone.

- contacting an effective amount of said solution on a solid or semi-solid support.

- place the support in a mosquito trap.

[Claim 13] Process according to claim 12, characterized in that the mixture comprises lactic acid, ammonia, hexanoic acid, 3-Methyl-1-Butanol and cyclopentanone.

[Claim 14] Process according to one of Claims 12 or 13, characterized in that the support is corn cob.