The present disclosure is generally related to mosquito attractant compositions, and more particularly, to mosquito attractant compositions, cartridges, and inserts that can be used to attract mosquitoes to an insect trapping device over an extended period of time.
Certain insects, such as mosquitoes, can be both a nuisance and a health risk to humans. For example, mosquito bites can cause painful irritation at bite locations and can infect humans with a variety of diseases including yellow fever, dengue fever, malaria, chikungunya, elephantiasis, west nile, zika, tularemia, and other debilitating diseases which can be difficult to treat. Some have estimated that mosquitoes may be responsible for more than 750,000 deaths per year. Bill Gates, The Deadliest Animal in the World, Gatesnotes (2014). The World Health Organization (“WHO”) has estimated that Yellow Fever infects 84,000 to 170,000 people per year and results in 29,000 to 60,000 deaths. WHO FactSheet (2016). The WHO has also stated that there are an estimated 390 million dengue infections per year, with an estimated 500,000 requiring hospitalization. WHO FactSheet (2016). More recently, the WHO has labeled Zika as a public health emergency due to Zika's causal relationship with microcephaly and other neurological disorders. The Aedes aegypti mosquito is a known vector for yellow fever, dengue fever, and zika. Other mosquito species believed to be carriers of human disease include Aedes albopictus, Aedes canadensis, Anopheles gambiae, Anopheles funestus, Culex annulirostris, Culex annulus and Culex pipiens. Other insects can also spread disease and inflict painful and irritating bites.
Insect trapping devices are known. Some examples are described in U.S. Pat. Nos. 4,907,366; 6,920,716; 7,074,830; U.S. Patent App. Publication No. 2006/0188540; U.S. Patent App. Publication No. 2010/0287816; U.S. Patent App. Publication No. 2012/291337; U.S. Patent App. Publication No. 2014/0311016; KR Publication No. 2012/0132132; PCT Patent App. Publication No. WO 2015/081033; and PCT Patent App. Publication No. WO 2015/164849. Although insect trapping devices are generally known in the art, there are opportunities to improve insect trapping devices by improving chemical attraction mechanisms which draw insects, such as the disease spreading Aedes aegypti mosquito, to the device. For instance, it would be advantageous to provide mosquito attractant compositions that are safe and effective for use in rooms occupied by pets, children, and/or adults.
It would be further advantageous to formulate a mosquito attractant composition having dual-attraction mechanisms that attract mosquitoes using two different chemical attractants. Advantageously, dual-attraction compositions may improve the attractiveness of the composition and attract mosquitoes for at least 7 days, at least 14 days, at least 21 days, at least 28 days or more, before needing replacement. This in turn improves the convenience and effectiveness of an insect trapping device. Further, it would be advantageous to provide mosquito attractant compositions that are stable so that they are safe for use in an electrical insect trapping device. It would still further be advantageous to provide water containing mosquito attractant compositions that are formulated at a low pH in order to retard the growth of mold during shipment, storage and/or use. While numerous opportunities for improvement are described above, it will be appreciated that the disclosure hereafter is not limited to mosquito attractant compositions that provide any or all such improvements.
According to one example, a method of using a mosquito attractant composition includes exposing a mosquito attractant composition to air for a period of at least 7 days. The mosquito attractant composition has a pH from 2.5 to about 5 and includes, by weight, from about 3.5% to about 30% lactic acid, from about 0.5% to about 5% of a gelling agent, from about 0.5% to about 50% of a humectant other than lactic acid, and from about 45% to about 95% water. The gelling agent includes a gellan gum or agar. The mosquito attractant composition attracts mosquitoes when exposed to air.
The above-mentioned and other features and advantages of the present disclosure, and the manner of attaining them, will become more apparent and the disclosure itself will be better understood by reference to the following description of non-limiting embodiments of the disclosure taken in conjunction with the accompanying drawings, wherein:
Unless otherwise defined, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Although methods and materials similar or equivalent to those described herein can be used in the practice or testing of the present invention, suitable methods and materials are described below. All publications, patent applications, patents, and other references mentioned herein are incorporated by reference in their entirety. In case of conflict, the present specification, including definitions, will control. In addition, the materials, methods, and examples are illustrative only and not intended to be limiting.
Other features and advantages of the disclosure will be apparent from the following detailed description, and from the claims.
As used herein, “gel” means any composition comprising a liquid and having a three-dimensional, cross-linked, network.
As used herein, “gelling agent” means any material, or combination of materials, that facilitate the formation of the three-dimensional, cross-linked, network of a gel.
As used herein, “high acyl” means a gellan gum that has two acyl substituents: acetate and glycerate. Both substituents are located on the same glucose unit, and on average, there is one glycerate per repeat and one acetate per every two repeats.
As used herein, “low acyl” refers to a gellan gum having no acyl groups.
As used herein, “lactic acid” refers to monomeric lactic acid molecules as well as related lactic acid species including the anhydride, lactide, and other oligomeric lactic acid species. The monomeric lactic acid molecule CH3CH(OH)COOH is depicted below as Formula I:
Lactic acid is a chiral molecule having an L(+) or (S) isomeric form and a D(−) or (R) isomeric form. Many commercially available aqueous solutions of lactic acid comprise lactic acid, lactide and possibly other oligomeric lactic acid species. The amount of lactic acid in such solutions is typically assayed according to a USP titration specification, which converts the oligomeric lactic acid species to lactic acid to determine a total titratable lactic acid concentration for the aqueous solution. Lactic acid concentrations can also be determined by the Lactic Acid Equivalents HPLC Method described hereinafter in Section X.
As used herein, “oligomeric lactic acid species” means lactyl lactate (C6H10O5), which is the anhydride of lactic acid; lactide (C6H8O4), which is the cyclic di-ester of lactic acid; and other oligomers of lactic acid.
As used herein, “mosquito” means any species of mosquito that is human host seeking. In certain instances, mosquito refers to any species of the genus Aedes, Culex or Anopheles. In certain instances, mosquito refers to any species of the subgenus Stegomyia of the genus Aedes. In some instances, mosquito refers to the species Aedes aegypti (Ae. aegypti).
As used herein, “package” refers to any article of manufacture that functions as a primary package during storage, shipment or display at the point of sale to an end user that encloses a mosquito attractant composition, or an insect trap portion (e.g., a cartridge or insert) comprising a mosquito attractant composition.
The present disclosure provides for mosquito attractant compositions and insect trapping devices, including components thereof such as cartridges and inserts, which contain a mosquito attractant composition. Methods of making and using the mosquito attractant compositions are further disclosed. The mosquito attractant compositions comprise a gelling agent, a humectant, water and lactic acid.
Advantageously, it is believed that a mosquito attractant composition in the form of a gel comprising a gelling agent and humectant can (a) be formulated at a low pH to retard mold growth in the package or during use and accommodate lactic acid, and/or (b) be provided in stable form that resists liquid flow and/or syneresis so that the mosquito attractant composition can be safely used in combination with an electrically powered insect trapping device. Further, it is believed that compositions comprising lactic acid, a gelling agent, a humectant, and water are effective at attracting mosquitoes for an extended duration, including for a period of time after which the majority of the water has evaporated. Without intending to be bound by any theory, it is presently believed that such an extended insect attraction occurs due to the described compositions having a “dual-attraction” mechanism. Specifically, it is theorized that water may be the dominant attraction mechanism over a period of 7 to 14 days (when combined with a humectant) after which the lactic acid may become the dominant attraction mechanism that continues for a period of time after which the majority of the water has evaporated. In certain embodiments, the mosquito attractant composition is homogenous with the various ingredients dispersed throughout a single composition.
Various non-limiting examples of the present disclosure will now be described to provide an overall understanding of the principles of the function, design, and use of mosquito attractant compositions, and insect trapping devices (and components thereof) described herein. Those of ordinary skill in the art will understand that the examples described herein are non-limiting and that the scope of the various non-limiting examples of the present disclosure are defined solely by the claims. The features illustrated or described in connection with one non-limiting example can be combined with the features of other non-limiting examples. Such modifications and variations are intended to be included within the scope of the present disclosure.
The mosquito attractant compositions described herein include lactic acid and water as mosquito attractant actives. Certain insects (e.g., Ae. aegypti) may be attracted to lactic acid, although some commentators have characterized lactic acid by itself as a weak mosquito attractant. See, e.g., Tauxe et al., Targeting a Dual Detector of Skin and CO2 to Modify Mosquito Host Seeking, Cell 155(6): 1366 (2013) (stating that, “lactic acid, ammonia, carboxylic acids, 1-octen-3-ol, and nonanal, increase mosquito attraction when presented together with CO2, but these are poor attractants by themselves”). Others have noted that mosquito attraction to humans appears driven by multimodal integration of host sensory cues. See, e.g., McMeniman et al., Multimodal Integration of Carbon Dioxide and Other Sensory Cues Drives Mosquito Attraction to Humans, Cell 156: 1060-1071 (2014) (revealing “a networked series of interactions by which multimodal integration of CO2, human odor and heat orchestrates mosquito attraction to humans”). It is presently believed, however, that compositions which release lactic acid molecules, preferably in combination with water vapor, over time can function as effective mosquito attractant compositions and may attract mosquitoes over at least short distances (e.g., 1.5 meters or less) even in the absence of CO2 emission. Further, since CO2 is known to attract mosquitoes over large distances, the absence of CO2 may have the benefit of not attracting mosquitoes from the outside into a dwelling.
The compositions described herein can emit lactic acid and water to attract insects to the composition or an insect trapping device containing the same. Lactic acid raw material sources suitable for making the mosquito attractant compositions herein can generally include any lactic acid raw material source which predominantly consists of lactic acid or related lactic acid species such as oligomeric lactic acid species. For example, lactic acid raw materials are typically provided as an aqueous solution (e.g., CAS#79-33-4, 50-21-5) comprising concentrated L(+)-lactic acid, lactide (dilactide), lactyl lactate, and other oligomeric lactic acid species. An example of a commercially supplied lactic acid source is Purac FC 88 available from Corbion N.V. including approximately 88.0%% (w/w) of lactic acid by weight of the aqueous solution according to the manufacturer's certificate (typically being assayed by the USP methodology that converts most of the oligomeric lactic species to lactic acid). Other suppliers of suitable lactic acid aqueous solutions include Jungbunzlauer A.G., Merck KGaA, Daiichi Sankyo Co., and Cargill Inc.
Lactic acid raw materials are typically both strongly concentrated and acidic. While these aqueous lactic acid solutions are suitable as a raw material source, in certain embodiments it is believed desirable to control the concentration of lactic acid present in the final mosquito attractant composition together with the concentration of other components to maximize insect capture while balancing stability. In some instances, it is presently believed desirable for the mosquito attractant composition to comprise from about 1% to about 40%, or about 10% to about 40%, or about 10% to about 30%, or about 13% to about 20% of lactic acid by weight of the mosquito attractant composition.
For compositions and products having concentrated lactic acid, adjustment of the pH to an appropriate acidic pH value is desirable for safety reasons (e.g., to prevent harm from incidental contact and inhibition of mold growth) as well as to maximize mosquito capture. In certain examples, suitable pH values for a mosquito attractant composition can be between about 1.5 and about 5, or between about 1.5 and about 3, or between about 2 and about 3, or be about 2.5.
The pH of a mosquito attractant composition can also influence a mosquito attractant composition's stability. For example, mosquito attractant compositions gelled with certain gelling agents may breakdown and/or exhibit water flow (syneresis) under certain pH conditions. The stability of mosquito attractant compositions can be evaluated using the Open Container Closed Container Stability Test Method described hereinafter in Section X. Resistance to syneresis can be evaluated using the Closed Container Test Method described in Section X. As illustration of this stability, mosquito attractant compositions gelled with agar may be unstable at a pH of about 4 or less when observed for 30 days or more.
In certain embodiments, the pH of an insect attract composition can be adjusted through the addition of a pH adjustment agent, such as an acid or base and the use of a pH probe or an appropriate titration method to measure the pH value as known in the art. For commercial lactic acid raw materials which can be strongly acidic, a strong base such as sodium hydroxide can be used to raise the pH to a value of about 2.5 or greater. In certain examples, the step of diluting a concentrated lactic acid raw material can be performed concurrently with the step of adjusting the pH. In other certain examples, the pH can alternatively be adjusted after dilution of the concentrated lactic acid raw material of after addition of a gelling agent and heating. As can be appreciated, the pH of a gel can be determined by diluting the gel with excess distilled water to form a 10% aqueous solution.
In certain instances, it can be desirable to dilute a concentrated lactic acid source with water. As can be appreciated, lactic acid raw materials are typically supplied as a concentrated aqueous solution. It is presently believed that dilution to modify the water concentration of the mosquito attractant composition may affect mosquito capture, since moisture is also a known attractant for mosquitoes. In combination, lactic acid and water vapor can act as a dual-attraction mechanism to attract insects. In certain examples, the lactic acid raw material is diluted with water sufficiently to achieve a weight concentration of water between about 50% and about 85%, or between about 60% and about 80%, or between about 70% and about 75% in the mosquito attractant composition.
The mosquito attractant compositions comprise water, which advantageously is released from the composition over time during use and may attract mosquitoes. In addition, water may function as a solvent and carrier upon evaporation for the lactic acid. The mosquito attractant composition comprises water in an amount, by weight, from about 45% to 99%, or from about 70% to about 95% or from about 75% to about 85%, which are believed to be sufficient amounts to evaporate and attract mosquitoes, over at least 7 days, 14 days or more.
The mosquito attractant compositions described herein can be gelled through inclusion of agar or a gellan gum. Gelling of a mosquito attractant composition may confer a number of benefits over non-gelled mosquito attractant compositions. For example, gelled compositions may exhibit a longer effective life, can resist spilling, and can provide increased consumer flexibility by simplifying handling, disposal, and use. Additionally, gelling of the mosquito attractant compositions described herein, in combination with an appropriate concentration of a humectant, can allow for controlled evaporation of water vapor when compared to non-gelled compositions. In the form of a gel, the mosquito attractant compositions described herein can effectively operate for an extended duration of about 7 days, or more. In certain examples, the mosquito attractant compositions described herein can effectively operate for about 7 days, 14 days, 21 days, 28 days, or more.
While there are advantages to a gelled mosquito attractant composition, there are also challenges with formulating such compositions. For example, it is desirable to include a sufficient amount of water in the composition to: (a) attract mosquitoes, and (b) volatize the lactic acid over a sufficient period of time. However, in compositions formulated with high concentrations of water, a gelling agent and a humectant may lead to mold formation over time, which is undesirable in a consumer product. Additionally, formulating a mosquito attractant composition at a low pH, can also introduce added challenges such as the ability to form a stable composition that resists flowing and syneresis at elevated temperatures so that the composition is safe for use in connection with an electrical insect trapping device. Furthermore, in certain embodiments, it is desirable for the composition to be manufactured and deposited in a reservoir or cartridge in a flowable form and yet form a gel within an acceptable period of time (e.g., the time to form a gel is not excessive). While agar may also be used to form mosquito attractant compositions at pHs about 4 or greater that are stable for time periods greater than 14 days, it is believed that gellan gum is more preferred for addressing the foregoing challenges. For example, agar compositions formulated at low pHs (e.g., pH of 2.5) are less stable than gellan gum compositions formulated at the same pH (see, e.g., Table 2).
Gellan gum and agar are cold set gelling agents. Cold set gelling agents are gelling agents that form a gel after heating of a liquid composition containing the gelling agent and subsequent cooling of the liquid composition. For example, mosquito attractant compositions described herein can be gelled by heating a liquid attractant composition to a temperature of about 60° C. to about 80° C. and then allowing the liquid attractant composition to cool to a temperature about 60° C. or less.
Gellan gum and agar also exhibit a number of other advantageous properties. For example, gellan gum and agar provide for manufacturing flexibility by exhibiting a large temperature spread between the melting temperature and the set temperature. This temperature spread provides for a relatively large amount of work time to, for example, form a heated liquid attractant mixture and then store and deliver the heated liquid mixture before formation of the gel. This work time can facilitate dispensing of the liquid mosquito attractant composition into a package, insert, or cartridge and then cooling the liquid composition to form a gel.
In certain examples, a liquid attractant composition can be gelled to form a mosquito attractant composition through inclusion of about 0.5% to about 5%, by weight, of agar or a gellan gum. For example, in certain examples, a mosquito attractant composition can include about 1% to about 3%, by weight, gellan gum or can include about 1% to about 2%, by weight, gellan gum. In certain embodiments, the mosquito attractant composition may comprise from about 2% to about 6%, by weight, or from about 2% to about 4%, by weight, of agar. It has been generally found that a higher concentration of agar than gellan gum is desirable to achieve stable compositions at pHs greater than 4. Insufficient quantities of a gelling agent can form gels having insufficient strength, or resistance to flow, while excess quantities of gellan gum (e.g., greater than 5 wt %) or agar (e.g., greater than 20 wt %) can form viscous gels of unworkable strength or which are difficult to process.
Gellan gum is a water-soluble anionic polysaccharide, typically produced by fermentation using the bacterium Spingomonas elodea. Generally, gellan gum is available in a variety of grades including low acyl, high acyl, and food grade forms. Suitable gellan gums can be selected from any such grade or form. For example, a blend of both high acyl gellan gum and low acyl gellan gum can be included in a mosquito attractant composition. In other certain examples, only one gellan gum, such as a low acyl gellan cum, can be selected.
Additionally, suitable gellan gums can also be of any known grade of gellan gum including low-purity commercial gellan gum grades and high-purity food grade gellan gums. For example, it can be useful in certain examples to select a food grade gellan gum to minimize any health consequences if the mosquito attractant composition is swallowed by a human or animal. Selection of a food grade gellan gum in combination with a food grade humectant can allow certain mosquito attractant compositions described herein to advantageously be entirely formed from food grade components.
In certain examples, supplemental gelling agents can also be included in a mosquito attractant composition. For example, one or more of gelatin, carrageenan, starch, alginate, xanthan, gum Arabic, guar, locust bean gum, tara, konjac, tragacanth, cellulose, modified cellulose, and clay can supplement the gellan gum or agar used to gel a mosquito attractant composition. In certain such examples, a supplemental gelling agent may be included in relatively smaller quantities than the gellan gum or agar.
One or more humectants may be included in a mosquito attractant composition in certain examples to lower the evaporation rate of water and improve the effective lifespan of the mosquito attractant composition. The lifespan of a mosquito attractant composition may depend, in part, on the amount of moisture present in the gel with complete evaporation of the water diminishing, or preventing, the further attraction of mosquitoes (assuming no other volatile insect attractants are present in the composition). Non-limiting examples of humectants suitable for the mosquito attractant compositions described herein can include glycerol, sorbitol, xylitol, ethylene glycol, diethylene glycol, polyethylene glycol, propanediol, and mixtures thereof. In certain examples, it can be preferable to use a natural humectant such as glycerol to improve the safety and effectiveness of a mosquito attractant composition. Examples 1, 2 and 3 illustrate that various humectants may be utilized in a mosquito attractant composition that attracts mosquitoes.
A suitable humectant can be included at about 0.5% to about 50%, by weight, or about 1% to about 40%, by weight, or about 5% to about 30%, by weight, or about 5% to about 15%, by weight of the mosquito attractant composition. Generally, suitable levels of humectants will produce mosquito attractant compositions which confer a longer lifespan for the mosquito attractant composition without lowering the evaporation rate of water to a level below the rate at which mosquitoes are attracted.
In certain examples, the pH of a mosquito attractant composition can be adjusted through the addition of a pH adjusting agent, such as an acid or a base. The use of a pH probe, or an appropriate titration method, can allow for precise measurement, and adjustment, of the pH value as known in the art during formation of the mosquito attractant composition. Generally, the pH of a mosquito attractant composition can be lowered through the addition of an acid such as hydrochloric acid (“HCl”) or increased through the addition of a base such as sodium hydroxide (“NaOH”) or ammonium hydroxide. The pH of the mosquito attractant composition can also be influenced by any optional components included in the composition such as, for example, any optional additional insect attractant additives. Lactic acid raw material sources are also typically strongly acidic.
The pH of a gel can be determined by diluting the gel with excess distilled water to form a 10% aqueous solution. In certain embodiments, the pH of the mosquito attractant composition may be adjusted during formulation to achieve a target pH from about 2 to about 4 or from about 2 to about 3. In certain embodiments, the pH of the mosquito attractant composition may be adjusted during formulation to achieve a pH from about 8 to about 12 or from about 10 to about 12. The pH of the mosquito attractant composition may be measured using the pH Test Method described in Section X.
As can be appreciated, a variety of additional components can optionally be included in certain mosquito attractant compositions described herein to further improve, or tailor, the properties of the compositions. For example, in certain examples, a preservative can optionally be included in a mosquito attractant composition to prevent degradation of the composition. In certain examples, the preservative can also, or alternatively, be a biocide which prevents the growth of bacteria and fungi. Suitable preservatives can include one or more of 1,2-benzisothiazolin-3-one (“BIT”), benzoic acid, benzoate salts, hydroxy benzoate salts, nitrate, nitrite salts, propionic acid, propionate salts, sorbic acid, and sorbate salts. Other suitable preservatives are known in the art.
A fragrance can optionally be included in certain examples. As can be appreciated however, in certain examples, a mosquito attractant composition can be odorless when formed from odorless components. For example, a mosquito attractant composition formed of gellan gum, glycerol, and water can be odorless to humans as each of the components in the composition are odorless to humans. Odorless compositions may be preferred for increased consumer acceptance.
In certain examples, the mosquito attractant compositions described herein can also, or alternatively, be substantially free of certain components. For example, the compositions can be substantially free of oils, essential oils, insecticides, biocides, repellants, and perfumes which may adversely affect the attraction of mosquitoes. Excluded biocides can include bacteria or virus harmful to an insect. In certain examples, the compositions can be essentially free of oils, essential oils, insecticides, biocides, repellants, and perfumes. In certain examples, the compositions can be free of oils, essential oils, insecticides, biocides, repellants, and perfumes. In certain embodiments, the mosquito attractant composition may consist essentially of or consist of lactic acid, water, one or more gellan gums, one or more humectants and optionally one or more pH adjusting agents.
Additional components can generally be added at any step before final cooling of the mosquito attractant composition. If the additional component is acidic or alkaline, it may be desirable in certain instances to add the component just before cooling into a gel to mitigate any hydrolysis concerns.
In certain embodiments, it is desirable for the mosquito attractant composition to be stable at elevated temperatures over extended periods of time (e.g., greater than 14 days, preferably at least 30 days). Still further, in certain embodiments, it may be desirable for the mosquito attractant composition to be resistant to syneresis at elevated temperatures. For example, the mosquito attractant compositions may be exposed to elevated temperatures during storage, shipping, or usage. Compositions that undergo hydrolysis, become flowable or which undergo syneresis (release of liquid water) may impact efficacy or present an unsafe condition when used in combination with an electrical insect trapping device. Stability is evaluated using the Open Container Test Method described in Section X, and resistance to syneresis is evaluated using the Closed Container Test Method described in Section X.
It has found that mosquito attractant compositions comprising a gellan gum have better stability at lower pHs (e.g., about 2 to about 3) over extended time periods (e.g., at least 30 days) than agar and can be formulated into compositions that can attract mosquitoes. In certain embodiments, mosquito attractant compositions comprising agar, water, a humectant and lactic acid may be suitable for use at a pH greater than 4, preferably greater than 4.5 and less than about 5 if stability at greater than 14 days, preferably at least 30 days is desired. Mosquito attractant compositions may be formulated using agar at pHs less than 4 if stability for 14 days or less is desired or acceptable.
Mosquito attractant compositions can be manufactured in a variety of ways. Certain examples of making of a mosquito attractant composition are provided for reference:
A. Mosquito attractant composition gelled with gellan gum (pH 2.5)
In an example mosquito attractant composition including, by weight, 17.38% lactic acid, 6.25% glycerol, 1% gellan gum and having a pH of 2.5, the weight percentage of each component is provided below:
Lactic Acid premix: 8.025% distilled water (Crystal Springs), 21.725% (17.380% active) lactic acid (Sanilac® (Corbion Purac)), and 1.450% sodium hydroxide (0.725% active) (P&G Chemical).
Humectant Premix: 61.55% distilled water (Crystal Springs), 6.25% glycerol (P&G Chemical).
B. Mosquito Attractant Composition Gelled with Agar (pH 2.5)
In an example mosquito attractant composition including, by weight, 17.38% lactic acid, 6.25% glycerol, 1% agar and having a pH of 2.5, the weight percentage of each component is provided below:
Lactic Acid premix: 8.025% distilled water (Crystal Springs), 21.725% (17.380% active) lactic acid (Sanilac® (Corbion Purac)), and 1.450% sodium hydroxide (0.725% active) (P&G Chemical).
Humectant Premix: 58.55% distilled water (Crystal Springs), 6.25% glycerol (P&G Chemical).
Mosquito Attractant Composition Gelled with Agar (pH 4)
In an example mosquito attractant composition including, by weight, 17.38% lactic acid, 6.25% glycerol, 4% agar and having a pH of 2.5, the weight percentage of each component is provided below:
Lactic Acid premix: 8.025% distilled water (Crystal Springs), 21.725% (17.380% active) lactic acid (Sanilac® (Corbion Purac)), and 9.430% sodium hydroxide (4.715% active) (P&G Chemical).
Humectant Premix: 50.07% distilled water (Crystal Springs), 6.25% glycerol (P&G Chemical).
As can be appreciated, many variations to the above processes are possible. For example, the step of adding a pH modifier can occur at a different stage in the process before the gel begins to solidify (e.g., added with the gelling agent). Additional components can be added at any point before cooling. Acidic or alkaline additional components can be added to a heated liquid attractant mixture. Laboratory equipment can be substituted for similar machines from other manufacturers.
The mosquito attractant compositions may be packaged prior to use. Any suitable type of package may be utilized. Some non-limiting examples of packages include boxes, cartons, clam-shell containers, bags, pouches and the like. In certain embodiments, a package may be formed from a paper material, a plastic material and combinations thereof.
The mosquito attractant compositions disclosed herein can beneficially be used in combination with a wide variety of insect trapping devices to attract and remove insects, such as mosquitoes, from a space, such as a room in a residence or building. In certain examples, the mosquito attractant composition is effective enough that the devices preferably do not incorporate a CO2 generating means or emitter as an additional mosquito attractant the insect trapping device does not rely on a mechanism, such as electric fan, to induce an airflow over the mosquito attractant composition to enhance evaporation. The insect trapping devices may attract mosquitoes as well as other flying or crawling insects, such as flies, moths and gnats, for example. In this sense, the insect trapping device may be a broad spectrum insect trap. In certain examples, the insect trapping devices can be enhanced by incorporating one or more broad spectrum one or more lights. The mosquito attractant compositions can help attract insects to an insect trapping device which permanently traps and removes the mosquitoes and other insects. A wide variety of insect trapping devices are generally known in the art and suitable for use with the compositions described herein. Some non-limiting examples are disclosed in U.S. Pat. Nos. 6,108,965; 7,191,560; PCT Patent App. No. WO 2014/134,371; PCT Patent App. No. WO 2015/081,033; and PCT Patent App. No. WO 2015/164,849, each of which is incorporated herein by reference.
Insect trapping devices may generally share a number of similar features. For example, insect trapping devices can include one or more attraction mechanisms to attract insects to the device. Examples of such insect attraction mechanisms can include a mosquito attractant composition such as the compositions disclosed herein as well as heat, light, and/or food. In certain embodiments, the insect trapping device is an electrical device, meaning it utilizes electricity to power one or more elements such as a light or heating element. Once an insect is attracted to an insect trapping device, one or more trapping mechanisms can prevent an insect from leaving the device. For example, an insect may be trapped on an adhesive sheet, enter into a chamber that is difficult to exit, or be killed (for example by electrocution).
In certain examples, an exemplary insect trapping device comprises a base unit and a disposable insect trapping portion, such as either a disposable cartridge or a disposable insert which may be inserted into a shell as illustrated by, for example, the insect trapping device depicted in
In certain examples, the disposable cartridge and the disposable insert comprise an adhesive portion for trapping insects, which may be in the form of an adhesive sheet. The adhesive portion may comprise a substrate having an adhesive composition coated thereon. In certain such examples, the adhesive portion can divide the housing into a front enclosure and a rear enclosure. A mosquito attractant composition can be included in one, or both, of such enclosures to attract insects. The enclosures can have one or more openings to allow insects to enter. Alternatively, in certain examples, insects can be mechanically trapped within the housing through a substantially one-way opening.
Additionally, or alternatively, an insect trapping device can include additional features to attract insects. For example, in certain examples, an insect trapping device can include one or more lights to attract a variety of insects. In certain such examples, the lights can comprise a plurality of light emitting diodes (“LEDs”) and can emit light at a spectrum attractive to insects such as a substantially blue light and/or ultraviolet light. In such examples, a suitable power source such as batteries, solar panels, or connections to wired power sources or the like can be included. For example, prongs for an AC power outlet can be included in certain examples. Certain insect trapping devices can also emit heat to attractant insects. As can be appreciated, heat can be generated through an electric heating element, a chemical reaction or the like.
Some have speculated that carbon dioxide is a long distance attractant for at least certain mosquito species. See, e.g., Carde et al., Olfaction in Vector-Host Interactions, Ecology and Control of Vector Borne Diseases, Vol. 2, pg. 128 (2010) (speculating that “[t]his finding could mean that for Ae. aegypti the ‘long distance’ attractant is carbon dioxide and not human skin odor, and/or that carbon dioxide lowers the threshold for attraction to a human skin odor, acting at some distance from the host”). Since carbon dioxide is thought by at least some to be a long range mosquito attractant, insect trapping devices of the present disclosure can be devoid of a carbon dioxide generating means or emitter so as to reduce the possibility of the insect trapping device drawing mosquitoes into an enclosed space, such as a room, from outside of the building.
Examples of carbon dioxide generating means which are preferably excluded from the devices described herein include the burning or catalytic conversion of a fuel source, chemical reactions between certain components such as a carbonate salt and an acid, the evaporation of dry ice, fermentation, or the use pressurized carbon dioxide cartridges. Additional details of these, and other excluded carbon dioxide means, are described in U.S. Pat. Nos. 7,074,830; 6,209,256; 4,907,366, U.S. Patent App. Publication No 2013/142753; U.S. Patent App. Publication No. 2010/0287816; U.S. Patent App. Publication No. 2004/128902; and U.S. Patent App. Publication No. 2004/025412.
In certain examples, an insect trapping device can be formed of multiple parts. For example, in certain examples, an insect trapping device comprises a plug-in unit that may engage an electrical wall outlet and a disposable insect trapping cartridge. In such examples, a plug-in unit may provide structural stability, lighting, and heating elements while an insect trapping cartridge comprises a mosquito attractant composition and an adhesive portion to capture mosquitoes and other insects. In certain examples, the insect trapping device can emit heat or activate the one or more lighting elements when the insect trapping cartridge is inserted into the plug-in unit. The cartridge comprising the adhesive portion and the mosquito attractant composition may be removed from the plug-in unit and disposed of when the mosquito attractant composition is exhausted and/or when the adhesive portion is filled with insects. The spent cartridge is then replaced by a fresh, new cartridge. A kit including the plug-in unit and the insect trapping cartridge can be sold together with further replaceable insect trapping cartridges sold separately. In certain examples, the insect trapping device can be a single, disposable, item and can be sold without a separate plug-in unit.
Many additional variations are possible. For example, in certain examples, the housing of an insect trapping device or cartridge can be reused by providing a releasable, replaceable insert comprising the mosquito attractant composition and/or an adhesive portion for trapping mosquitoes and insects. When the adhesive portion is full of insects and/or the mosquito attractant composition is effectively exhausted, then the spent insert can be disposed of and a new, fresh insert can be inserted into the cartridge without necessitating disposal of the functional housing. In certain examples, the releasable insert comprises a reservoir containing a mosquito attractant composition described herein. Some non-limiting examples of the previously described inserts, reservoirs, cartridges and insect trapping devices utilizing the same are described in PCT Patent Application Serial No. PCT/US16/41812, entitled INSECT TRAPPING DEVICE AND METHODS THEREOF, and filed on Jul. 11, 2016, the disclosure of which is incorporated herein by reference.
As can be appreciated, the exact dimensions of the reservoir can be varied depending upon the design on the mosquito attractant composition. For example, in certain examples, the reservoir can include a front wall and a substantially planar rear wall. In certain such examples, the insert can comprise the adhesive portion so that replacement of the insert provides a fresh adhesive portion. In certain such examples, the insert can comprise a frame at least partially surrounding the adhesive portion. The frame may be integrally formed or integrated with the reservoir. For example, in examples including a reservoir having a front wall and rear wall, the front wall and the rear wall can be integrally formed with the frame. The adhesive portion can be transparent or translucent. Other non-limiting examples of reservoirs suitable for use with the mosquito attractant compositions described herein are described in PCT Patent App. Publication No. WO 2015/081033 and PCT Patent App. Publication No. WO 2015/164849, the disclosures of which are incorporated herein by reference.
One non-limiting example of an exemplary insect trapping device is depicted in
The mosquito attractant compositions can be utilized with an insect trapping device in multiple ways. For example, a packaged mosquito attractant composition can be removed from a package by a user by opening the package and removing the mosquito attractant composition disposed therein, which may include removing the composition itself, removing an insert having the mosquito attractant composition disposed therein or thereon, or removing a cartridge having the mosquito attractant composition disposed therein. The composition, insert or cartridge may then be utilized with an insect trapping device by exposing the mosquito attractant composition to air. The air may be within a space, such as a room of a residence of building. The mosquito attractant composition may be exposed to the air for a period of 7 days, 14 days, 21 days, 28 days, or more, during which time the mosquito attractant composition attracts mosquitoes to the insect trapping device. In certain embodiments, the mosquito attractant composition, upon removal from the package, is placed in the reservoir of an appropriate insect trap device or insect trapping cartridge or the like, such as for example reservoir 176 defined in part by a front wall 180 as depicted in
Alternatively, the mosquito attractant composition may be pre-disposed within the reservoir 276 of an insert 218, as depicted by way of example in
The cartridge 218 can include a reservoir 276 for a mosquito attractant composition, a front housing 224 and rear housing 228. The front housing 224 can include one or more openings 232 for receiving a flying or crawling insect such that they will come in contract with an adhesive portion 252. The rear housing can include a bottom opening 234. The front housing 224 and the rear housing 228 and, optionally, the adhesive portion 252, can be coupled using any suitable technique, such as ultrasonic welding, adhesives, mechanical fasteners, and the like. Alternatively, the front housing 224 and the rear housing 228 can be a unitary structure formed by, for example, injection molding. A downwardly depending tab 264 can be included to engage with an insect trapping device.
In some instances, alternative packages similar in some respects to the insert 218 can alternatively provide a mosquito attractant composition to an insect trapping device. For example, a package including only a reservoir containing the mosquito attractant composition may alternatively be provided. In other examples, a mosquito attractant composition may be provided without a structure similar to the insert 218. In such examples, an isolated mosquito attractant composition can be provided for direct placement in an insect trapping device.
Generally, a mosquito attractant composition can be formed and provided to an insect trapping device or insert in accordance to any method disclosed in Section VII. For example, an insect attractant cartridge including a mosquito attractant composition can be manufactured by forming a lactic acid premix by making water and lactic acid, forming a humectant premix from water and a humectant, introducing gellan gum into the humectant premix to form a gel premix, heating the gel premix to a temperature of about 70° C. to about 80° C., adding the lactic acid premix to the gel premix to form a heated liquid attractant composition, and depositing the heated liquid attractant composition into an insect attractant cartridge and allowing the heated liquid attractant composition to cool to a temperature below about 65° C.
pH Measurement of Mosquito Attractant Compositions
If it is desired to measure the pH of a gelled mosquito attractant composition, the following method may be used. The gelled mosquito attractant composition is removed from the cartridge or insert (in instances where it has been deposited therein). At least a 1 gm sample of the mosquito attractant composition is then, using a spatula or equivalent tool, mashed to a paste-like consistency and then added to distilled water and mixed while stirring (e.g., using a mechanical stirring device) to create a 10% solution of the sample in the distilled water (e.g., 9 gms of water would be added to a 1 gm sample). Following at least 5 minutes of stirring, the pH of the sample solution is measured using a pH meter (e.g., VWR SympHony model SP70P, or equivalent, using VWR probe cat. no. 89231-600, or equivalent) following calibration of the pH meter using several Buffer Reference Standard Solutions (e.g., available from VWR having a pH of 2, 4, and 7 or equivalent), as known in the art.
pH Measurement of Liquids
If it is desired to measure the pH of a liquid or a premix, the pH of the sample solution is measured using a pH meter (e.g., VWR SympHony model SP70P, or equivalent, using VWR probe cat. no. 89231-600, or equivalent) following calibration of the pH meter using several Buffer Reference Standard Solutions (e.g., available from VWR having a pH of 2, 4, and 7 or equivalent), as known in the art.
Mosquito Capture Test
Mosquito capture testing was conducted using an insect trapping device. The insect trapping device comprised a plug-in unit having disposed therein 2 blue LEDs and an ultraviolet LED. A replaceable cartridge comprising an adhesive for trapping the mosquitoes and the described mosquito attractant composition engaged the plug-in unit. A general description of the insect trapping device is provided in PCT Patent App. Publication No. WO 2015/081033 with respect to
The test enclosure within which the insect trapping device was placed consisted of a mesh enclosure 6 feet by 6 feet by 6 feet in size. The enclosures were equipped with a 4 foot high by 3 foot wide section of vertical wallboard placed diagonally across 1 corner of the enclosure on a wooden base. The wallboard section contained a vertically mounted 12 V power strip such that the bottom of the power strip was 8 to 9 inches from the bottom of the wallboard. The test enclosures were placed in windowless rooms and the bottom perimeter was sealed with duct tape. The rooms were continuously measured to have an average temperature of 24° C. and an average relative humidity of 47%. Four vertical floor lamps were placed around the outside of the enclosure to provide lighting with each lamp having a single 800-900 lumen CFL bulb which was kept on for the duration of the test.
Mosquitoes were reared according to protocols known in the art. Specifically, adult Aedes aegypti mosquitoes were held at 27° C. under long day lengths with free access to 10% sucrose and water ad libitum. Females (two weeks after adult emergence) were allowed access to a bloodmeal with a Hemotek blood feeding system. Females were collected two to three days after blood feeding and moved into a small plastic container half filled with water and a small pinch of ground fish food. Eggs were dried for one week before being placing in the small container. After one day, 100-120 larvae were counted and placed into a large plastic container half filled with water. Each day excess ground fish food was added to ensure that the larvae had food for development. Pupae were collected in small emergence cups and placed within 12″ by 12″ by 12″ cages (Bioquip 1450BS). Adults were utilized 12 to 20 days post ecdysis.
After the start of the test, 50 female mosquitoes were released into the tent. At the end of each measured capture period, the percentage of mosquitoes captured by the device was determined by counting them and dividing by the total released. Each test was run at least five times and the results were averaged.
Open Container Stability Test
As used herein, the Open Container Stability Test indicates whether a gel composition sample remains stable when exposed to air. In the Open Container Stability Test, a 25 g±1 g liquid gel composition (prior to forming a gel network) is dispensed into a 2 oz flint glass jar (Qorpak GLA-00843) and allowed to cool and solidify at ambient conditions of 22° C. to 26° C. and 40%-80% relative humidity with the jar open and in an upright, un-tilted orientation (typically at least 60 minutes). The solidified gel and jar are then placed in a constant humidity and constant temperature room maintained at a constant temperature of about 40° C. and about 20% relative humidity. The jar is in the open condition in the test room, and the open jar is oriented at approximately a 45 degree angle within the test room for 30 days. The gel sample integrity is determined at the end of 14 days and/or 30 days by qualitatively assessing the gel sample according to the following criteria:
1. No flowing of the gel sample within the jar.
2. The gel sample has flowed within the jar.
A gel composition is considered to pass the Open Container Stability Test when criteria #1 is satisfied. Shrinkage of the gel sample due to loss of water from the sample is not considered a flow condition satisfying criteria #2.
Closed Container Syneresis Test
As used herein, the Closed Container Syneresis Test indicates whether a gel sample exhibits syneresis when sealed within a closed container. In the Closed Container Syneresis Test, a 25 g±1 g liquid gel composition (prior to forming a gel network) is dispensed into a 2 oz flint glass jar (Qorpak GLA-00843) and allowed to cool and solidify at ambient conditions of 22° C. to 26° C. and 40%-80% relative humidity for 90 minutes with the jar open and in an upright, un-tilted orientation. Once a gel has formed, any existing condensation on the sides of the open jar is removed with an absorbent laboratory wipe and the jar is then closed tightly by a lid. The closed jar with the gel is then placed in a constant humidity and constant temperature room maintained at a constant temperature of about 40° C. and about 20% relative humidity. The closed jar is oriented at approximately a 90 degree angle. The presence of syneresis is determined 24 to 72 hours from placement in the test room. If water is visible within the closed jar, then the jar is opened and an absorbent laboratory wipe is used to remove the water and the amount of water absorbed by the wipe is determined by weighing the wipe and calculating the difference in the weight of the wipe prior to absorption of the water and after. The following criteria are used to qualitatively assess whether the gel sample has undergone syneresis:
1. No condensation visible in jar or slight condensation visible in jar but not enough to form a drop in the tilted orientation (i.e., less than 100 μL of water).
2. More than 100 μL of water has pooled within the jar.
A gel composition is considered to pass the Closed Container Syneresis Test if criteria #1 is satisfied. A gel composition is considered to have failed this test if criteria #2 is satisfied.
High Performance Liquid Chromatography (HPLC)
When it is desired to determine the amount of lactic acid in a composition, the amount/concentration of lactic acid may be determined by either: i) using the lactic acid equivalents in a composition as determined by the Lactic Acid Titration Test USP Method described herein, or equivalent, as an approximation if it is believed the weight fraction of lactic acid in the composition is greater than 90%, or ii) by measuring the lactic acid equivalents in the composition using the HPLC method described below. The HPLC method is preferred, for example, when the sample may contain other chemicals (e.g., acids) that might interfere with a titration.
Lactic Acid Equivalents HPLC Method
HPLC is used to determine the amount of lactic acid equivalents present in a sample, particularly when the sample comprises lactic acid in combination with other acids. For the HPLC method, three blank standards are prepared using a Lactate Standard from Sigma Aldrich sold as TraceCert. The blanks standards are diluted with 0.1 N sulfuric acid to have concentrations of 200 μg/mL, 100 μg/mL, and 50 μg/mL. Samples to be evaluated are prepared by weighing 10-15 mg gel samples into a 2 mL autosampler vial and diluting the samples with 1-1.5 mL of 1 N sulfuric acid. The vials are then heated in a sand bath at 100° C. for 1 hour. The samples are then diluted with water to reach a concentration of 50-200 μg/mL. The samples are then run through a Hamilton PRP-X300 (4.6×250 mm, 7 μm particles) ion exclusion column with an isocratic separation and flow rate of 2 mL/min. The concentration of lactic acid is determined by using a 210 nm UV/vis spectrometer.
Lactic Acid Titration Test USP Method
Lactic acid titration is used to determine the amount of lactic acid equivalents in a sample if no other acids are present in the sample other than lactic acid. The Lactic Acid Titration Test USP Method is well known and described in various USP publications. See, e.g., The Food Chemicals Codex, 7th Ed., Prepared by the Council of Experts, United States Pharmacopeial Convention (2011). A 2.5 mL sample is accurately weighed in a tared 250 mL flask, mixed with 50.0 mL of 1N sodium hydroxide VS, and boiled for 20 minutes. The solution is then titrated using phenolphthalein TS and 1 N sulfuric acid VS. A blank determination is then used to determine the amount of lactic acid equivalents with each mL of 1 N sodium hydroxide equivalent to 90.08 mg of lactic acid. Lactic acid equivalents include all the precursor dimers, oligomers, and other chemical species that are converted into lactic acid under the conditions of the test method.
The following examples are given solely for the purpose of illustration and are not to be construed as limitations of the invention as many variations are possible without departing from the spirit and the scope of the invention. The target pH values provided in the Tables for the following Examples represent the target pH value for the mosquito attractant composition. As provided below, certain combinations of ingredients were adjusted to the desired target pH value by the addition of a pH adjusting agent.
For Examples comprising lactic acid where the target pH of the mosquito attractant composition is between 2.5 and 4, the pH of the humectant, distilled water, lactic acid combination was adjusted by the addition of sodium hydroxide to achieve the target pH of this combination.
While the pHs of the respective mosquito attractant compositions were not measured directly for the following Examples, it is believed the pH of the certain ingredient combinations adjusted using pH adjusting agents as provided above should be result in about the target pH of the mosquito attractant composition, recognizing that it's possible that the actual pH of the mosquito attractant composition may vary slightly from the target pH due to the addition of the gelling agent. Unless noted otherwise, the gellan gum for each example is KELCOGEL® AFT, a low-acyl, low-purity, gellan gum and water is distilled water.
Mosquito capture percentages are measured in accordance with the Mosquito Capture Test of Section X, wherein the sample size of insect trapping device was N=3 for each test and measurements were taken after 24 hours, 14 days, 21 days or 28 days as indicated. Capture data for all three samples of each leg are presented in the Tables. Mosquito capture results at 24 hours are conducted by using a freshly prepared mosquito attractant composition deposited in an insect cartridge and placed into a plastic bag for transportation to a separate laboratory, where the bag was opened and the test was run.
In instances where 14 day, 21 day and/or 28 day mosquito capture data is provided, the test was conducted as follows. The mosquito attractant composition was deposited in an insect cartridge and was thereafter exposed to ambient air under laboratory conditions for 14 days, 21 days and/or 28 days, as applicable. Laboratory conditions were approximately 21° C. to 27° C. temperature and 50% to 60% relative humidity. After 14 days, 21 days or 28 days, as applicable, of exposure to ambient air under laboratory conditions, the cartridge was placed in a plastic bag for preservation and transported to a separate laboratory where the cartridge was unsealed and the Mosquito Capture Test Method was conducted for a period of 24 hours to determine the mosquito capture following the 14 days, 21 days or 28 days of prior exposure to ambient air.
Examples 1 to 12 (set forth in Table 1) are mosquito attractant compositions comprising different humectants (e.g., glycerol, sorbitol or propylene glycol) at different concentrations of lactic acid (8 wt % or 17.38 wt %) and different concentrations of the humectant (6.25 wt % or 30 wt %). Examples 1 to 4 comprised glycerol. Examples 5 to 8 comprised sorbitol. Examples 9 to 12 comprised propylene glycol. Each of examples 1 to 12 further comprised distilled water (q.s.) and sodium hydroxide added as the pH adjusting agent, wherein the target pH of the mosquito attractant compositions was 2.5.
Examples 13 to 17 are comparative examples. Examples 13, 14 and 15 are comparative examples without lactic acid but comprising a humectant (Example 13=glycerol, Example 14=sorbitol, Example 15=propylene glycol), a gellan gum, water and having a target pH of 2.5. Example 16 is a comparative example that comprised 2.5 grams of water on a 37 mm×10 mm cylindrical piece of dental cotton disposed in the insect trapping device. Formulations, target pHs of the mosquito attractant composition, and mosquito capture rates for each sample are set forth in Table 1 (NA=Not Applicable). Example 17 is a comparative example illustrating insect capture after 24 hrs for an insect trapping device without a mosquito attractant composition (but still comprising lights and an adhesive sheet). Since it is believed that insect capture of Example 17 should be the same after 14 days as after 24 hrs, only the insect capture after 24 hours is presented. The 24 hour capture data set forth in Table 1 for Example 17 is for N=99 devices tested and the values for the high/low/average/and 1 std deviation of mosquito capture after 24 hours are presented.
Several conclusions may be drawn from the results presented in Table 1, recognizing there is some variability in the data due to the nature of the test and the biology of attraction. First, at 24 hours, the mosquito capture rate for devices comprising the mosquito attractant compositions were generally the same across humectant concentrations, humectant types and lactic acid concentrations, including the Examples where lactic acid was absent.
Second, the mosquito attractant compositions all improved mosquito capture at 24 hours compared to a device without a mosquito attractant or just water, which might indicate that the combination of water, humectant, gelling agent and/or lactic acid may provide an enhanced benefit for mosquito capture from the outset.
Third, directional differences appear to happen at least by day 14, presumably after a majority of the water has evaporated from the mosquito attractant compositions. The addition of lactic acid in an amount of about 17 wt % appeared to directionally improve capture at 14 days as compared to its comparative example without lactic acid (e.g., Example 3 compared to Example 13; Example 7 compared to Example 14; Example 11 compared to Example 15) even though the water concentration for the lactic acid containing Examples decreased.
Fourth, glycerol appears to be a directionally preferred humectant compared to sorbitol and polyethylene glycol for mosquito capture at 14 days. Generally, compositions comprising a total amount, by weight, of lactic acid and humectant (preferably glycerol) from about 20 wt % to about 40% wt % appear to be preferred. Without intending to be bound by any theory, it is believed that lactic acid may also function as a humectant in addition to a mosquito attractant. Mosquito attractant compositions comprising higher levels of lactic acid may provide a dual benefit of retaining a little more water at 14 days in addition to having more lactic acid available to act as an attractant. Example 3 appeared to be the best and most consistent performing mosquito attractant composition of those tested, followed by Example 2.
Examples 18 to 22 (set forth in Table 2) are mosquito attractant compositions comprising either agar or gellan gum comparing the stability of the mosquito attractant composition at pHs between 2.5 and 4. Example 22 comprised KELCOGEL® AFT Low Purity (a low acyl gellan gum available from CP Kelco, USA) and Examples 18 to 22 comprised agar. The mosquito attractant compositions of Examples 18 to 22 further comprised glycerol at 6.25%, by weight; and distilled water at approximately 70%, by weight. Examples 18, 19 and 20 (agar, target pH of 2.5) failed the Open Container Test at 30 days but passed this test when checked at 14 days. Example 21 (agar, target pH of 2.5) passed the Open Container test at both 14 days and 30 days, as did Example 22 (gellan gum, also target pH of 2.5). These Examples illustrate that gellan gum may be preferred for a target pH less than 4 while both agar and gellan gum may be suitable for use for a pH greater than 4. These agar Examples 18 to 22 also illustrate that in situations where stability for less than 14 days is desired, an agar mosquito attractant composition may be suitable. Open Container Stability was observed at 14 days and at 30 days.
The following numbered paragraphs constitute a further non-limiting description of the disclosure in a form suitable for appending to the claim section if later desired.
A.1. An insert trapping portion for use with an insect trapping device, the insert trapping portion comprising:
from about 10% to about 30% of the lactic acid;
from about 0.5% to about 1.5% of a gelling agent;
from about 5% to about 15% of the humectant; and
from about 50% to about 99% water; and
optionally, a pH adjusting agent; and
wherein the gelling agent comprises a gellan gum.
A.14. An insect trapping portion according to any preceding claim, further comprising a reservoir and the mosquito attractant composition is at least partially disposed within the reservoir.
A.15. An insect trapping portion according to any of claims A.1 to A.13, further comprising at least one housing, wherein the mosquito attractant composition is disposed within the housing.
A.16. An insect trapping portion according to any of the preceding claims, wherein the mosquito attractant composition is disposed within a cartridge comprising an adhesive for trapping insects.
A.17. An insect trapping device, comprising an insect trapping portion according to any preceding claim, and a base unit comprising at least one light for illuminating the adhesive of the insect trapping portion.
A.18. An insect trapping device according to claim A.17, wherein the insect trapping device does not comprise a means for producing carbon dioxide.
A.19. A method for attracting mosquitoes, the method comprising exposing the insect trapping device according to any of paragraphs A.17 or A.18 to air.
A.20. The method according to claim A.19, wherein mosquitoes are attracted for at least 7 days.
A.21. The method according to any of claims A.19 to A.20, wherein mosquitoes are attracted for at least 14 days.
A.22 The method according to any of claims A.19 to A.21, wherein the mosquito attractant composition is homogenous.
B.1. A method of making an insect trapping portion, comprising:
adjusting the pH of a lactic acid source to a pH value of about 1.5 to about 5 to form a lactic acid premix;
forming a humectant premix by mixing water and a humectant;
heating the lactic acid premix and the humectant premix to a temperature of about 80° C. or more;
introducing a gelling agent into the humectant premix to form a gel premix;
incorporating the lactic acid mixture into the gel premix to form a heated liquid attractant composition;
depositing the heated liquid attractant composition into reservoir of an insect trapping portion; and
cooling the heated liquid attractant composition to a temperature below about 65° C. to form a mosquito attractant composition.
C.1. A method of forming a mosquito attractant composition, the method comprising:
adjusting the pH of a lactic acid source to a pH value of about 1.5 to about 5 to form a lactic acid premix;
forming a humectant premix by mixing water and a humectant;
heating the lactic acid premix and the humectant premix to a temperature of about 80° C. or more;
introducing gellan gum into the humectant premix to form a gel premix;
incorporating the lactic acid mixture into the gel premix to form a heated liquid attractant composition; and
cooling the heated liquid attractant composition to a temperature below about 65° C. to form a mosquito attractant composition.
C.2. The method according to claim C.1, wherein the gel premix is mixed with a high shear mixer.
C.3. The method according to claim C.1 or claim C.2, wherein the heated liquid attractant composition is heated for about 1 minute or longer.
C.4. The method according to any of claims C.1 to C.3, wherein the heated liquid attractant is cooled without shear.
C.5. The method according to any of claims C.1 to C.4, wherein the humectant comprises one or more of glycerol, sorbitol, xylitol, ethylene glycol, diethylene glycol, polyethylene glycol, and propanediol.
C.6. The method according to claim C.5, wherein the mosquito attractant composition comprises about 0.5% to about 45%, by weight, of the humectant.
C.7. The method according to any of claims C.1 to C.6, wherein the mosquito attractant composition comprises about 0.5% to about 5%, by weight, of the gellan gum.
C.8. The method according to any of claims C.1 to C.7, wherein the mosquito attractant composition comprises about 1% to about 1.5%, by weight, of the gellan gum.
The dimensions and/or values disclosed herein are not to be understood as being strictly limited to the exact numerical dimension and/or values recited. Instead, unless otherwise specified, each such dimension and/or value is intended to mean both the recited dimension and/or value and a functionally equivalent range surrounding that dimension and/or value. For example, a dimension disclosed as “40 mm” is intended to mean “about 40 mm”.
Every document cited herein, including any cross referenced or related patent or application is hereby incorporated herein by reference in its entirety unless expressly excluded or otherwise limited. The citation of any document is not an admission that it is prior art with respect to any invention disclosed or claimed herein or that it alone, or in any combination with any other reference or references, teaches, suggests or discloses any such invention. Further, to the extent that any meaning or definition of a term in this document conflicts with any meaning or definition of the same term in a document incorporated by reference, the meaning or definition assigned to that term in this document shall govern.
While particular embodiments of the present invention have been illustrated and described, it would be obvious to those skilled in the art that various other changes and modifications can be made without departing from the spirit and scope of the invention. It is therefore intended to cover in the appended claims all such changes and modifications that are within the scope of this invention.
All percentages and ratios used herein are by weight of the total mosquito attractant composition and all measurements made are at 25° C., unless otherwise designated. All measurements used herein are in metric units unless otherwise specified.
Number | Date | Country | |
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62368867 | Jul 2016 | US |
Number | Date | Country | |
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Parent | PCT/US2017/044277 | Jul 2017 | US |
Child | 16253385 | US |