EP4307893A1 - Method for producing an attractant composition - Google Patents

Abstract

The invention relates to a method (100) for producing an attractant composition (120) and to an attractant composition (120) for attracting blood-sucking arthropods (31) and/or fruit flies. According to the invention, a porous carrier material is charged with a buffer system, the buffer system being at least largely completely absorbed by the porous carrier material. An attractant is subsequently introduced into the carrier material that is charged with the buffer system.

Description

Process for preparing an attractant composition

The present invention relates to a method for producing an attractant composition and an attractant composition according to the features of the independent claims.

The present invention relates to an attractant composition which is particularly suitable for attracting blood-sucking arthropods and/or fruit flies.

Blood-sucking insects often use olfactory and/or visual stimuli to track down humans or animals. It is particularly problematic that blood-sucking insects often transmit diseases, which is why attempts are made to keep these insects away from human dwellings and/or crowds. You can either rely on defense, for example by using chemical insect repellents. Alternatively, different insect traps are used to capture blood-sucking arthropods. Such insect traps often work with olfactory and/or optical attractants.

For example, carbon dioxide and lactic acid are known to attract a number of blood-sucking insect species. For example, US Patent Publication No. US 4907366 A describes the use of a composition of lactic acid, carbon dioxide, water in conjunction with heat to attract mosquitoes.

The object of the invention is to provide an attractant composition that is easy to handle and, in particular, does not require the use of a plurality of containers or bottles for the preparation of a plurality of attractant components.

The object is achieved by a method for producing an attractant composition for attracting blood-sucking arthropods and/or fruit flies and an attractant composition, which comprise the features of the independent claims. Further advantageous configurations are described by the dependent claims. Furthermore, a method for attracting blood-sucking arthropods and/or fruit flies with an attractant composition according to the invention is described and claimed.

The attractant composition serves to attract blood-sucking arthropods and fruit flies. The arthropods include, among other things, many disease carriers, which are therefore of great medical and veterinary relevance, including mosquitoes, black flies, sand flies, tsetse flies, but also blowflies and house flies, fleas, lice, etc. Mosquitoes include, for example, the genus Anopheles, where many species are responsible for transmission of malaria. Concerning fruit flies, all species of Drosophila are included.

The attractant composition consists of a porous carrier material in which at least effective amounts of at least one attractant are embedded, attached and/or bound. Furthermore, small amounts of water can preferably be present in the porous carrier material. According to the method described here for attracting blood-sucking arthropods and/or fruit flies, the at least one attractant is slowly released from the attractant composition, in particular by evaporation. As a result, the at least one attractant gets into the environment and can thus effectively attract blood-sucking arthropods and/or fruit flies.

For example, synthetic, porous solid bodies in the form of a granular, pourable material can be used as the porous carrier material. Known carrier bodies can be in the form of organic substances (e.g. polymer foams, knitted synthetic fibers, ion exchange resins) or inorganic substances (e.g. sand, aluminum oxide, activated carbon). The synthetic, porous solid bodies used as carrier materials are preferably chemically inert and stable over a longer period of time. This includes adequate chemical and mechanical resistance. Due to the porosity, the carrier material has a large usable surface for the attachment of the buffer system and the attractant described below. The buffer system and the at least one attractant are preferably stored within the pores of the carrier material.

The method for producing the attractant composition for attracting blood-sucking arthropods and/or fruit flies provides that the porous carrier material is mixed with a buffer system, the buffer system being at least largely completely absorbed, in particular absorbed, by the porous carrier material.

For example, porous carrier material is filled into a drum mixer. The buffer system is then added and mixed with the porous carrier material until it has soaked up the buffer system. Excess buffer system can preferably be removed before further processing. In particular, the buffer system is stored in the pores of the carrier material and/or attached to the outer surfaces of the carrier material.

In a subsequent process step, at least one attractant is added to the carrier material loaded with the buffer system and mixed with it. The at least one attractant is absorbed and/or bound within the pores of the carrier material that are filled with the buffer system and/or on the outer surfaces of the carrier material.

The attractant composition produced in this way has the advantage that the at least one attractant contained therein is slowly released from the attractant composition over time and released into the environment or environment through evaporation, whereby the attractant composition has its effect over a longer period of time the blood-sucking arthropods and/or fruit flies. In particular, it is provided that the buffer system supports the absorption of the attractant into the carrier material and/or the release of the attractant from the carrier material. The buffer system particularly preferably supports the slow release of the attractant into the environment.

In particular, the volatility of acidic components of the attractant composition, for example lactic acid and/or hexanoic acid, depends on the pH value. At high pH values, these are all present as salts and are non-volatile. At low pH values, however, these components are highly volatile. By choosing a suitable pH value, the release of the attractant can be specifically influenced and adjusted.

Small amounts of water may be necessary to release the attractant. This is preferably provided by the buffer system. The attractant is released in a way that can be compared to steam distillation. According to one embodiment of the invention, the buffering system consists of or comprises at least one aqueous ammonium salt of a carboxylic acid or at least one aqueous ammonium salt of a fatty acid or at least one aqueous ammonium salt of acetic acid, lactic acid; Propionic acid, butyric acid, valeric acid, caproic acid, enanthic acid or caprylic acid. An embodiment of the invention can provide not to use racemic carboxylic acids, but in each case a pure (D)-carboxylic acid or a pure (L)-carboxylic acid, for example pure (D)-lactic acid or a pure (L)-lactic acid. The buffer system preferably has a substantially neutral pH.

The at least one attractant is preferably selected from a group of at least one C1 to C10 carboxylic acid and/or a corresponding salt thereof, in particular from a group comprising formic acid, acetic acid, lactic acid, propionic acid and caproic acid. Furthermore, the at least one attractant can be selected from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol, glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid, fermenting yeast and/or an extract from fermenting yeast . A compound that is particularly preferred as a further attractant is acetic acid.

The attractant composition produced in this way is available in a form which can be easily portioned and which can now be used directly in a suitable insect trap. For example, a corresponding amount of attractant composition is introduced directly into the insect trap, which can preferably provide a corresponding receiving device for the attractant composition.

A preferred embodiment further provides that the attractant composition is portioned and placed in a packaging consisting of a gas-permeable container. For example, the attractant composition can be placed in a package consisting of packaging bags made of a gas-permeable material, for example porous polyethylene or a fleece or other suitable material.

The attractant composition arranged in a gas-permeable packaging material can be inserted and used directly together with the packaging in a corresponding insect trap. This significantly simplifies handling, since the attractant composition is not available as loose bulk material, but rather in a form that is easy to handle, in particular pre-portioned, thanks to the packaging. in which, in particular, there is no direct contact between the user and the attractant composition.

An alternative embodiment may provide for the attractant composition to be packaged in a container or packaging bag made of a fluid impermeable material. In this context, too, provision can be made for the attractant composition to be pre-portioned in manageable portions and packaged accordingly. In this case, the packaging material must be removed before the attractant composition is used, since the packaging material prevents the at least one attractant from being released.

An embodiment of the invention can provide that the attractant composition is additionally loaded with at least one fragrance. The fragrance can be introduced or applied directly into the carrier material loaded with buffer system and attractant. Alternatively, the carrier material loaded with the buffer system can also first be loaded with the fragrance and then loaded with the at least one attractant. The fragrance can be a fragrance that improves the user's handling of the attractant composition, but does not affect the behavior of the blood-sucking arthropods and/or fruit flies. Particularly preferred is the use of additional fragrances that both improve handling for the user and show a positive attracting effect on the blood-sucking arthropods and/or fruit flies.

According to a further embodiment, the attractant composition, i.e. the carrier material loaded with the buffer system and at least one attractant, can be loaded with at least one further attractant for blood-sucking arthropods and/or fruit flies.

The at least one further attractant is preferably selected from a group of at least one C1 to C10 carboxylic acid and/or a corresponding salt thereof, in particular formic acid, acetic acid, lactic acid, propionic acid and caproic acid. Furthermore, the at least one other attractant can be selected from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol, glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid, fermenting yeast and/or an extract from fermenting yeast will. A compound that is particularly preferred as a further attractant is acetic acid. According to one embodiment it is provided that in addition to the at least one attractant of the attractant composition, components of the buffer system can also pass into the gas phase of the attractant composition and can support or enhance the attracting effect of the at least one attractant component. In particular, in addition to the release of the attractant, there can be a release of ammonia and the corresponding carboxylic acid of the buffer system. These are also released from the attractant composition in gaseous form as a result of slow decomposition and evaporation and pass into the gas phase together with the at least one attractant.

According to one embodiment of the invention, it is provided that the carrier material is formed by an inert matrix. This preferably has a pore size between 2 pm and 100 pm, in particular a pore size between 5 pm and 30 pm. Furthermore, the inert matrix is designed to absorb liquids.

The carrier material preferably has microporous structures that act like small sponges and can absorb other substances, in particular liquids, in which case they can preferably absorb many times their own weight.

The carrier material can, for example, consist of a polymeric plastic material such as PP (polypropylene), LDPE (low density polyethylene), HDPE (high density polyethylene), EVA (ethylene vinyl acetate); PA6 (polyamide 6); PET (polyethylene terephthalate); PC (polycarbonate); PS (polystyrene); PMMA (polymethyl methacrylate) or the like. A carrier material is preferably used that has an open cell structure with gaps that are at least partially interconnected.

When the corresponding liquids or fusible solids are mixed with the carrier material, the microvoids in the polymer material fill up by capillary absorption. When fully loaded, the system remains dry and free-flowing.

It should be noted that the attractant composition of the present invention is not limited in quality and quantity to the above components and their effects. The composition can contain other ingredients, for example fragrances, preservatives, stabilizers, other attractants, etc. Furthermore, the effects of the disclosed attractant composition can be enhanced by combining them with other attractants, in particular with others provided by the corresponding insect trap attractants. These include, for example, optical stimuli, thermal radiation, moisture and air currents.

The attractant composition described herein can be applied in any form to a commercial or home-made insect trap to attract arthropods and/or fruit flies and thereby collect them in the insect trap. The at least one attractant and possibly ammonia and the corresponding carboxylic acid used in the buffer system, and possibly other fragrances and/or attractants are released from the attractant composition and can be released from the insect trap with or without a gas stream as a carrier (e.g. air, carbon dioxide, etc.). or diffuse away from the insect trap. Traps known from the prior art can be used as effective traps, such as are commercially available from various suppliers.

The storage of the attractant in a porous carrier material loaded with a suitable buffer system results in a controlled, time-delayed release of the attractant from the attractant composition, which enables long-term use to effectively attract arthropods (e.g. mosquitoes) over a certain sufficient period of time and for example with an insect trap.

Furthermore, materials which actively attack the arthropod may be placed adjacent to the attractant composition so that preferably no interaction or reaction can occur between the chemicals of the attractant composition and the materials attacking the arthropod. If the attractant composition is combined with insecticides, for example, the result is advantageously that the insecticides can be used in a locally limited manner, so that a broad distribution of the insecticide is not necessary.

It should be expressly mentioned at this point that all aspects and design variants that have been explained in connection with the device according to the invention equally relate to or can be partial aspects of the method according to the invention. Therefore, if certain aspects and/or connections and/or effects are mentioned at one point in the description or also in the definition of claims for the device according to the invention, this applies equally to the method according to the invention. The same applies in reverse, so that all aspects and variants that have been explained in connection with the method according to the invention are equally partial aspects of the relate to the device according to the invention or may be. Therefore, if certain aspects and/or connections and/or effects are mentioned at one point in the description or also in the claim definitions for the method according to the invention, this applies equally to the device according to the invention.

In the following, exemplary embodiments are intended to explain the invention and its advantages in more detail with reference to the attached figures. The proportions of the individual elements to one another in the figures do not always correspond to the real proportions, since some forms are shown in simplified form and other forms are shown enlarged in relation to other elements for better illustration.

FIG. 1 schematically shows the process steps of a first embodiment of a process for producing an attractant composition.

FIG. 2 schematically shows the process steps of a second embodiment of a process for producing an attractant composition.

FIG. 3 shows the use of an attractant composition in a first embodiment of an insect trap.

FIG. 4 shows the use of an attractant composition in a second embodiment of an insect trap.

Identical reference symbols are used for elements of the invention that are the same or have the same effect. Furthermore, for the sake of clarity, only reference symbols are shown in the individual figures that are necessary for the description of the respective figure. The illustrated embodiments only represent examples of how the attractant composition according to the invention or the method according to the invention can be designed and do not represent any final limitation.

Figure 1 shows schematically the process steps of a first embodiment of a process 100, 100a for producing an attractant composition 120 and Figure 2 shows schematically the process steps of a second embodiment of a process 100, 100b for producing an attractant composition 120.

Both methods 100, 100a, 100b provide that, in a first method step 110, a porous carrier material is loaded with a buffer system, the buffer system being at least partially completely absorbed by the porous carrier material. In particular, the porous carrier material is a tumble mixer with a buffer system consisting of or comprising an aqueous ammonium salt of a carboxylic acid.

For example, an excess of buffer system is used. In a second method step 111, excess buffer system is removed, so that a carrier material saturated with buffer system is now present.

In a third method step 112, at least one attractant is now added and mixed with the carrier material loaded or saturated with the buffer system. The attractant accumulates in the pores of the carrier system that are filled with the buffer system and/or attaches itself to the outer surfaces of the carrier material.

The at least one attractant is preferably selected from a group of at least one C1 to C10 carboxylic acid and/or a corresponding salt thereof, in particular from a group comprising formic acid, acetic acid, lactic acid, propionic acid and caproic acid. Furthermore, the at least one attractant can be selected from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol, glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid, fermenting yeast and/or an extract from fermenting yeast . A compound that is particularly preferred as a further attractant is acetic acid.

The carrier material loaded with a buffer system and at least one attractant in this way forms the attractant composition 120.

The method 100b according to the second embodiment shown in Figure 2 also provides that after the loading of the porous carrier material with the buffer system and, if necessary, removal of excess buffer system in an intermediate method step 115, at least one fragrance is added to the carrier material loaded with the buffer system before Subsequently, in a third method step 112 analogous to Figure 1, a corresponding amount of attractant is added and again distributed homogeneously on its surface and/or within the pores by mixing with the carrier material loaded with buffer system and fragrance, resulting in an attractant composition additionally loaded with fragrance 120* is formed. Alternatively, an attractant composition 120 produced according to the method 100a according to FIG. 1 can also be loaded with fragrance in a step following the third method step 112 . The fragrance can be a fragrance that improves the handling of the attractant composition 120, 120* for the user, but has no further, in particular no negative, influence on the behavior of the blood-sucking arthropods and/or fruit flies. Particularly preferred is the use of additional fragrances that both improve handling for the user and have a positive attracting effect on the blood-sucking arthropods and/or fruit flies.

The attractant composition 120, 120* produced in this way has the advantage that the attractant is released slowly over time. This is achieved in particular by the buffer system used, since the volatility of acidic components, for example lactic acid and/or hexanoic acid, depends on the pH value. At high pH values, these are all present as salts and are non-volatile. At low pH values, however, these components are highly volatile. By selecting a suitable pH value for the buffer system, the release of the attractant from the attractant composition 120, 120* can be specifically influenced and adjusted.

In addition, it can be provided that the ammonium salt of the carboxylic acid of the buffer system also slowly decomposes over time, as a result of which ammonia and the corresponding acid are released and released into the environment or the environment through evaporation. The attractant in particular, but also the ammonia and carboxylic acid released from the buffer system, pass into the gas phase of the attractant composition 120 and develop an attracting effect on the blood-sucking arthropods and/or fruit flies.

The incorporation of the attractant in the porous carrier material and/or the binding of the attractant to the porous carrier material results in a controlled, time-delayed release of at least the attractant from the attractant composition 120, 120*, which enables longer-term use in order to to effectively attract blood-sucking arthropods and/or fruit flies for a certain sufficient period of time, e.g. for collecting and/or killing them with an insect trap.

The attractant composition 120, 120* is in a form that can be easily portioned and can now be used directly in a corresponding insect trap. FIG. 2 also shows that the attractant composition 120* is portioned in a fourth method step 117 and placed in a pack 122 and packed. For example, the packaging 122 by a gas-permeable container or packaging bag, which consists, for example, of a porous polyethylene or a fleece or other suitable material. In this case, the attractant composition 120, 120 * packaged in this way can be used directly together with the packaging 122 in an insect trap, since the gas-permeable packaging 122 prevents the release of the attractant and any ammonia and carboxylic acid of the buffer system into a gas phase outside the packaging 122 permitted.

Another embodiment of the invention that is not shown can provide that the attractant composition 120, 120' is loaded with at least one additional attractant in a further method step. The further attractant can be applied before or after the carrier material loaded with the buffer system has been loaded with at least one first attractant.

The at least one further attractant is preferably selected from a group of at least one C1 to C10 carboxylic acid and/or a corresponding salt thereof, in particular formic acid, acetic acid, lactic acid, propionic acid and caproic acid. Furthermore, the at least one other attractant can be selected from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol, glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid, fermenting yeast and/or an extract from fermenting yeast will. A compound that is particularly preferred as a further attractant is acetic acid.

The attractant composition 120 described herein can be applied in any form to a commercial or home-made insect trap to attract arthropods and/or fruit flies and thereby collect them in the insect trap. FIG. 3 shows the use of an attractant composition 120 in a first embodiment of an insect trap 1, 1a and FIG. 4 shows the use of an attractant composition in a second embodiment of an insect trap 1, 1b.

The insect trap 1, 1a according to FIG. 3 comprises an approximately hollow-cylindrical collection container 2 for receiving the attracted and captured insects 30, for example mosquitoes 31. A flat or slightly curved light-colored outflow surface 3 is arranged on the collection container 2 as an upper cover. A weak, uniform, upward air flow 4 proceeds from this. This extensive, weak, uniform air flow 4 attracts many insects 30, in particular mosquitoes 31 or the like. The air flow 4 with a flow rate S4 is generated, for example, by at least one blower 5 arranged below the outflow surface 3 . The effect of the air flow 4 can also be enhanced by heat and/or the addition of other, in particular chemical, attractants.

The outflow surface 3 can additionally be provided with a glue and/or an insecticide, so that insects 30 that land on the outflow surface 3 are held directly and/or killed.

Furthermore, an intake channel 6 is provided. In the exemplary embodiment shown, this intake channel 6 is designed in particular as a dark contrasting point 7 on the outflow surface 3 . For example, ambient air 8 is sucked in at a flow rate S8 via the intake channel 6 . The flow speed S8 of the ambient air 8 that is sucked in is significantly higher than the flow speed S4 of the air flow 4 flowing out via the outflow surface 3. In particular, it can be provided that a single blower 5 is used for the suction of the ambient air 8 and the generation of the air flow 4 that flows out.

To better illustrate the three-dimensionality and in particular the shape of the intake port 6, the upper edge of the intake port 9 has been shown in broken lines. However, the representation gives no indication of the color design of the edge.

This edge is preferably also dark and in particular does not form any contrast to the rest of the intake port 6.

The attractant composition 120 is arranged inside the collection container 2 so that the attractant which has changed into the gas phase flows outwards via the outflow surface 3 together with the air flow 4 . For example, a receiving device 10 for the attractant composition 120 can be formed inside the collection container 2 . When using an attractant composition 120 packaged in gas-permeable packaging bags, a hook or a corresponding hanging device can be provided inside the collection container 2, for example, to which the packaging bag is attached. It is preferably provided for an optimal effect of the attractant composition 120 to be arranged adjacent to the fan 5 and within the weak outflowing air flow 4 .

The at least one attractant contained in the attractant composition 120 and optionally other fragrances and/or attractants and/or ammonia and Carboxylic acids from the buffering system are released from the attractant composition 120 and can diffuse with the weak air flow 4 as a carrier out of and up from the insect trap 1a.

The insect trap 1, 1b according to FIG. 4 shows the essential principles of a possible embodiment variant of an insect trap 1b, which is used in particular to attract and/or catch insects 30, in particular flying and/or pest insects such as mosquitoes, yellow fever mosquitoes, Zika mosquitoes, tiger mosquitoes etc. can serve.

The insect trap 1b has an upper circular suction opening 11, which continues into a cylindrical suction channel 12 leading vertically downwards, in which there is an air flow which acts on the suction opening 11 with negative pressure or with a suction flow 13 and which leads to an interior space 14 of the insect trap 1b or leads into it. In addition, the insect trap 1b is equipped with an outer wall 15 in the shape of a truncated cone, which has a surface that is at least partially permeable to outflowing air 16, formed in particular by a net-like structure 17 whose mesh size is large enough for a sufficient outflowing air flow 16 to be able to pass through there however, reliably prevents the insects 30 trapped in the interior space 14 of the trap 1b from escaping.

The outer wall 15 encloses the intake duct 12 in the vicinity of the intake opening 11 and envelops the intake duct 12 in the further area which continues downwards at a varying radial distance, so that the outer wall 15 widens conically downwards. In addition, the insect trap 1b is equipped with a bottom side 18 that adjoins the outer wall 15 and is largely impermeable to air flowing in or out and is opposite the suction opening 11, which is spaced from an open lower end face 19 of the suction channel that extends into the interior 14 of the insect trap 1b 16. In the exemplary embodiment of the insect trap 1b shown, the bottom side 18 is flat and cylindrical in shape, so that it is aligned perpendicularly to the longitudinal axis of the intake channel 12.

At least one fan 20 generating the suction flow 13 can be arranged inside the intake channel 12 . The suction flow 13 has an air velocity that makes it significantly more difficult for the insects 30 that have been attracted to escape in the vicinity of the suction opening 11 . Rather, they should be sucked into the interior 14 of the trap 1b with the aid of the sufficiently strong suction flow 13 and reliably prevented from flying back out of the interior 14 there. Suitable means for retaining or killing the trapped insects 30 can be arranged inside the trap 1b, but these are not shown here.

The insect trap 1b can be mounted hanging or standing so that the suction opening 11 is directed upwards and the suction channel 12 preferably runs in an approximately vertical direction, and the bottom side 18 forms a lower horizontal end of the trap 1b.

The outflowing air 16 already represents an attraction for the insects. As an additional attraction, an attractant composition 120 produced according to the method 100 according to FIG. 1 or FIG attractant that has passed into the gas phase and, if necessary, the ammonia and the carboxylic acid of the buffer system can flow outwards together with the outflowing air 16 via the frustoconical outer wall 15 of the insect trap 1b and develop its attracting effect. For example, in this embodiment of an insect trap 1b in the interior 14, a receiving device 10 for the attractant composition 120 can be configured analogously to the receiving device 10 described in connection with FIG.

The embodiments, examples and variants of the preceding paragraphs, the claims or the following description and figures, including their different views or respective individual features, can be used independently of one another or in any combination. Features described in connection with one embodiment are applicable to all embodiments unless the features are incompatible.

Although “schematic” representations and views are generally referred to in connection with the figures, this in no way means that the representations in the figures and their description are to be of secondary importance with regard to the disclosure of the invention. The person skilled in the art is quite capable of deriving enough information from the schematic and abstract drawings to make it easier for him to understand the invention, without having to draw from the drawn and possibly not exactly true-to-scale proportions of the insects and/or parts of the insect traps 1 or other drawn elements would be impaired in any way in his understanding. The figures thus enable the person skilled in the art as a reader, on the basis of the more concretely explained implementations of the method according to the invention and the more concrete explained functioning of the device according to the invention to derive a better understanding of the inventive concept formulated more generally and/or more abstractly in the claims and in the general part of the description.

The invention has been described with reference to a preferred embodiment. However, it will be apparent to a person skilled in the art that modifications or variations can be made to the invention without departing from the scope of the following claims.

Reference List

1, 1a, 1b insect trap 2 hollow-cylindrical collection container

3 outflow surface

4 air flow

5 blowers

6 intake duct

7 dark contrast spot

8 ambient air

9 intake port

10 receiving device 11 circular suction opening 12 suction channel

13 suction flow

14 interior

15 frustoconical outer wall

16 outflowing air

17 net-like structure

18 bottom side

19 lower face of the intake port

20 fan

30 insect

31 mosquito

100, 100a, 100b method 110 first method step 111 second process step

112 third process step

115 intermediate process step

117 fourth step 120 attractant composition

120 additionally scented attractant composition 122 packaging S4 flow rate S8 flow rate

Claims

Expectations

A method (100) for producing an attractant composition (120) for attracting blood-sucking arthropods (31) and/or fruit flies, wherein

• a porous carrier material is loaded with a buffer system, the buffer system being at least partially completely absorbed by the porous carrier material and

• wherein at least one attractant is introduced into the carrier material loaded with the buffer system.

2. The method (100) according to claim 1, wherein the buffer system and the attractant are stored in the pores of the carrier material and/or are attached to the outer surfaces of the carrier material.

3. The method (100) of claim 1 or 2, wherein the attractant is released slowly to the environment.

4. The method according to any one of the preceding claims, wherein the buffer system supports the absorption of the attractant into the carrier material and the release of the attractant from the carrier material, in particular wherein the buffer system supports the slow release of the attractant to the environment.

5. The method according to any one of the preceding claims, wherein the buffer system comprises at least one aqueous ammonium salt of a carboxylic acid, in particular wherein the buffer system comprises at least one aqueous ammonium salt of a fatty acid or at least one aqueous ammonium salt of acetic acid, lactic acid; propionic acid, butyric acid, valeric acid, caproic acid, enanthic acid or caprylic acid.

6. The method according to any one of the preceding claims, wherein the at least one attractant is selected from a group comprising at least one C1 to C10 carboxylic acid and/or a corresponding salt, in particular from a group comprising formic acid, acetic acid, lactic acid, propionic acid and caproic acid, or from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol, fermented yeast or an extract from fermented yeast and/or from a group comprising glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid.

7. The method according to any one of the preceding claims, wherein the attractant composition (120) is additionally loaded with at least one fragrance.

8. The method (100) according to any one of the preceding claims, wherein the attractant composition (120) is loaded with at least one further attractant for blood-sucking arthropods (31) and/or fruit flies, the at least one further attractant being selected from a group comprising at least one C1 - C10 carboxylic acid and/or a corresponding salt, in particular from a group comprising formic acid, acetic acid, lactic acid, propionic acid and caproic acid, or from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol Yeast or an extract of fermented yeast and/or from a group comprising glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid.

9. The method (100) according to any one of the preceding claims, wherein the carrier material is formed by an inert matrix, which inert matrix has a pore size between 2 pm and 50 pm, in particular a pore size between 5 pm and 30 pm, and which inert matrix is designed to liquids to suck up.

10. An attractant composition (120) for attracting blood-sucking arthropods (31) and/or fruit flies, comprising a. a porous support material, and b. a buffer system; and c. at least one attractant, in particular wherein the attractant composition (120) is produced by a method (100) according to any one of claims 1 to 10.

11. Attractant composition (120) according to claim 10, wherein the buffer system is formed by aqueous ammonium salts of carboxylic acids, in particular wherein the buffer system is formed by aqueous ammonium salts of fatty acids or aqueous ammonium salts of acetic acid, lactic acid; Propionic acid, butyric acid, valeric acid, caproic acid, enanthic acid or caprylic acid is formed.

12. attractant composition (120) according to claim 10 or 11, wherein the porous carrier material is formed by an inert matrix, which inert matrix has a pore size between 5 pm and 100 pm, in particular a pore size between 5 pm and 30 pm, and which inert matrix designed to suck up liquids.

13. attractant composition (120) according to any one of claims 10 to 12, wherein attractant is selected from a group comprising at least one C1 - C10 carboxylic acid and / or a corresponding salt, in particular from a group comprising formic acid, acetic acid and propionic acid, or from a group comprising dichloromethane, trichloromethane, acetone, phenol, 1-octen-3-ol, fermented yeast or an extract from fermented yeast and/or from a group comprising glycolic acid, thiolactic acid, thiomalic acid, tartaric acid and/or mandelic acid.

14. A method for attracting blood-sucking arthropods (31) and/or fruit flies, wherein an attractant composition (120) according to any one of

Claims 10 to 13 is used, wherein one of the attractant composition (120) at least one attractant for blood-sucking arthropods (31) and / or fruit flies is slowly released and evaporates and thereby released into the environment, wherein the composition released blood-sucking arthropods ( 31) and/or attracts fruit flies.