TWI484911B - Lure formulation for flies with reduced active ingredient amount - Google Patents

Description

Fly entrapment formula using reduced amount of attractant

The invention relates to a novel use of castor oil for stabilizing substances of flies insects and reducing the dosage.

The fruit flies (tephritid flies) belong to the Diptera and Tephritidae insects. There are 4,800 species in the world, and nearly 90 kinds of hazards are economically important. Among them, the Dacinae subfamily (Dacinae) The genus Bactrocera and the genus Dacine flies of the genus Dacus are more harmful. At present, the main fruit fly ( Bactrocera dorsalis ), B. cucurbitae and Bactrocera ta u are the most important melon and fruit pests. These insects are distributed in Central Asia, Southeast Asia, Oceania and some African countries. Farmers call it "bee" or "melon bee" (for fruit fly and pumpkin fruit fly). There are 173 kinds of fruit species in the oriental fruit fly, and there are 89 species in 32 families in China; the fruit fly is the main economic pest of the cucurbit crop, which has more than 80 host plants, and 41 species of pumpkin fruit fly, such as melon. Melon, melon, courgette, bitter gourd, mountain bitter gourd, loofah, angular loofah, watermelon, melon, pumpkin, zucchini, flat-boiled, melon and other melon crops, when the situation is serious, the fruit can not be harvested completely. In Taiwan, due to the temperate climate, the host is indispensable, causing melons and fruit flies to occur all year round. It is difficult to control, often causing serious loss of fruits and fruits. Melons and fruit flies lay eggs under the peel, and the hatching larvae feed on the fruit. The mature larvae will leave the victim and sneak into the soil to dissipate the mites. Therefore, the eggs are not easy to control during the pupa period, and the control targets are mainly adult worms.

Agricultural pest control can be generally divided into three categories: physical control, biological control and chemical control. Nowadays, farmers mainly use chemical control for pest control, that is, chemical agents are applied. However, according to research reports, many chemical agents have reduced or even failed the efficacy of harmful insects. Farmers keep the beautiful appearance of crops to cater to consumers. Demand, has to increase the number of chemical sprays and drug concentrations, and even mixed a variety of agents, but this will not only achieve the effect of prevention and control, but also increase production costs, but also cause pesticide residues.

Furthermore, due to the rising awareness of environmental protection and health care, organic vegetables and fruits that emphasize the non-spraying of pesticides are becoming popular and become the first choice for consumption. However, organic fruits and vegetables are susceptible to insect erosion and affect the economic benefits of products. However, because the current biological control methods still have some shortcomings that are difficult to overcome, for example, there is a high degree of specificity between the control object and the natural enemies. It is necessary to individually identify the species, the species that cannot be completely eliminated, and the natural enemies used are extremely vulnerable to environmental factors. However, how to reduce the effect, etc., how to prevent crops from being harmed by insects by physical control methods, is a research topic for the industry; among them, the use of insect-adhesive paper has been widely used in the industry, and it is also one of the most convenient physical control methods. .

Another current chemical control method is to use many volatile substances in the natural environment, some of which can induce and assist insects to find habitats, food, spawning places, mating objects, etc., in order to maintain their lives or to progeny. Insects sense these "odors" through the olfactory function, allowing the same species or different species to communicate with each other and initiate specific behavioral responses. Such volatile substances are collectively referred to as semiochemicals, including pheromone, kairomone, spawning primers, repellents, and many other compounds (Nordlund, 1981; Howse et Al., 1998). The application of chemical communication materials in the field can change the behavior of pests, thereby controlling the development of their populations, achieving the purpose of pest management and reducing crop damage. A variety of chemical signaling materials can be used together to increase the trapping effect. For example, a feeding enhancer, a male attractant, a female pheromone and a quick-acting insecticide are added to a slime plate for use in the field control of the fruit fly ( Bactrocera oleae ), and the results are required for each olive tree control. The amount of pesticides has been reduced by one percent (Haniotakis et al., 1991).

In addition to detecting sensational sensation materials, insects also visually recognize different colors (Prokopy and Owens, 1983; Oseto, 2000). Different insects tend to prefer a particular preferred color, so the color itself is an insect attractant. Specific colors with insecticidal traps such as sticky paper, water trays, etc., can be used to trap insects to trap pests (Sivinski, 1990). The colors commonly used for testing in pest control research are white, blue, green, yellow, etc., all related to the reflection spectrum or wavelength of the host plant. There are many experimental results on the color of pest preference. For example, the peach aphid prefers yellow, the aster leafhopper prefers orange, the flower hummus prefers white or blue, and the apple fruit fly (Rhagoletis pomonella) tends to tend to red or yellow. In the field, the intensity of insects' color is affected by the position of the insect trap, the composition of the ground (background), the physiological state of the insect, and the wavelength of light projected on the trap (Robacker et al., 1990).

At present, more than 90% of the Dacine flies of the genus Bactrocera and Dacus are found to be methyl eugenol in the Dacliae subfamily (Dacinae). (ME)) or cue-lure (CL), a derivative of raspberry ketone. At least 176 males of this type of fruit fly are attracted to flies or raspberry ketones, while 58 are attracted to methyl clove oil. Among them, there are 73 species of agricultural pests recorded above, 41 species will be attracted to flies or raspberry ketones, and 22 species will be attracted to methyl clove oil.

At present, the control methods for cucurbit flies and pumpkin fruit flies mainly use a sex pheromones known as Cuelure to trap the males of these cucurbit flies, which are produced by hydrolysis to produce acetic acid and raspberry ketone. Producing attractiveness, the structure is as follows: In addition, there are also methods for controlling pesticides such as direct spraying of pesticides and spraying of toxic protein hydrolysates. However, when the fly itself is used in the field, the killing effect on the fruit fly population is not satisfactory. The relevant literature indicates that the fly fly has only 20% replacement rate for the labeled fruit fly, while the methyl clove oil is for the oriental fruit fly. There is an 85% re-catch rate. Another literature pointed out that the fly has no effect on the attracting of males who have not yet matured, and the effective attracting distance and sensitivity of ethnic detection have room for improvement, and the lure efficiency of the trapping material should be improved. Based on this, domestic products added methyl clove oil to reduce the concentration of the fly to 10% (fly scent), although it can effectively increase the stability of the product, but because of the two attractants of different standard pests, the cost It has not been reduced; and if it is only used as a control object in the field, in addition to increasing the cost of prevention, high concentration of methyl clove oil is also carcinogenic, which will increase the exposure risk of farmers.

Raspberry ketone is a stimulant of 176 species of Dacine flies, such as cucurbit flies, which is a kind of pheromone precursor of melon flies. Its structure is as follows: However, raspberry ketone has no field attracting effect in the solid state (because its volatility is extremely poor, it only has a attracting effect in a very short distance, about 10-20 cm). In recent years, the literature mentions a new raspberry ketone formate, 4-(3-Oxobutyl)phenyl formate or 4- (4) -(Formyloxyphenyl)-2-butanone (4-(4-formyloxyphenyl)-2-butanone): It can be used as a component to induce males of the fruit fly, which has a better attracting effect than the fly. However, because it is easier to decompose and produce crystals than the flies, it is not easy to preserve and the effect in the field is unstable, and it is not easy to promote. The raspberry ketone derivative and the aforementioned gram fly mainly undergo a hydrolysis process (the hydrolysis of the raspberry ketone derivative to produce formic acid and raspberry ketone, and the fly is hydrolyzed to produce acetic acid and raspberry ketone) to simultaneously volatilize and release the raspberry ketone, thereby Long-distance lure effect. However, if the hydrolysis rate is too fast, crystallization will not be formed. If the raspberry ketone crystals are formed on the carrier (the crystal is not equal to the complete decomposition of the raspberry ketone derivative, but the phenomenon of supersaturation after decomposition, ie, the decomposition of raspberry ketone If the amount is not saturated, it will not crystallize when dissolved in a raspberry derivative or other solvent, and the relative long-range attracting efficacy is lost.

Compared with the prior case WO 2005/015993 A1, castor oil is mainly used to stabilize the attractant of the eye and the decomposition of the insecticide by ultraviolet light, and the use effect of castor oil in the present invention is to stabilize the diptera attractant. The rate of hydrolysis, while reducing the amount of attractant used while maintaining the same attractive effect. It is well known in the art that UV photolysis and hydrolysis are two different chemical mechanisms, and therefore it is not possible to easily derive the technical feature of the present invention to stabilize hydrolysis by castor oil according to the previous case.

The invention provides a use of castor oil for stabilizing a formulation of a dipteran insect attractant, wherein the content of the dipteran insect attractant in the formula is 0.1-95%, and the content of the castor oil in the formula It is 5-99.9%, wherein the castor oil can reduce the amount of the attractant used, and can slow down the hydrolysis rate of the attractant. In a preferred embodiment, the Diptera insect belongs to the fruit fly family (Tephritidae). In still another preferred embodiment, the fruit fly insect (Tephritidae) is an insect of the family Dacinae. In a further embodiment, the insect line of the subfamily of the genus Bactrocera is Bactrocera cucurbitae and the Dacine flies of the genus Dacus . . In a preferred embodiment, the fruit fly and the fruit fly are referred to as flax or raspberry ketone, 4-(3-oxobutyl)phenyl formate. (Synonym: 4-(3-oxobutyl)phenylcarboxylic acid), 4-(4-formyloxyphenyl)-2-butanone (4-(4-formyloxyphenyl)-2-butanone) or Raspberry ketone derivatives attract Bactrocera cucurbitae , Bactrocera tau and fruit fly insects.

In another preferred embodiment of the use provided by the present invention, the attractant is a chemical pheromone, a pheromone, a pheromone precursor, a food or any of the above-mentioned dipteran insects. combination. In still another preferred embodiment, the chemical pheromone or pheromone or pheromone precursor is Cuelure, Raspberry Ketone, 4-(3-oxobutyl)phenyl 4-(3-Oxobutyl)phenyl formate or a raspberry derivative. In another more preferred embodiment, the raspberry derivative is of the formula: Wherein R is hydrogen or a linear or branched C _1-5 alkyl group. In still another preferred embodiment, the castor oil may be polyethylene oxide castor oil, polyethylene oxide hardened castor oil, polyoxyethylidene hydrogenated castor oil, ethoxylated castor oil or the like. Castor oil derivatives. In another more preferred embodiment, the formulation further comprises one or more insecticides. In yet another preferred embodiment, the formulation can be further formulated as a glue, a spray, a viscous spray or a similarly functional physical adsorbent. In a preferred embodiment, the formulation is further fabricated as a glue. In another more preferred embodiment, the formulation can be further combined with a color suitable for attracting insects.

The present invention further provides an adsorptive porous material comprising a plurality of interconnected pore structures, wherein the pore structure adsorbs an attractant formulation, wherein the formulation comprises a diptera insect having an attractant content of 0.1-95% and a castor oil content of 5 -99.9%, wherein the castor oil reduces the amount of the attractant used and slows down the rate of hydrolysis of the attractant. In a preferred embodiment, the Diptera insect belongs to the fruit fly family (Tephritidae). In still another preferred embodiment, the fruit fly insect (Tephritidae) is an insect of the family Dacinae. In a further embodiment, the insect line of the subfamily of the genus Bactrocera is Bactrocera cucurbitae and the Dacine flies of the genus Dacus . . In a preferred embodiment, the fruit fly and the fruit fly are referred to as flax or raspberry ketone, 4-(3-oxobutyl)phenyl formate. (Synonym: 4-(3-oxobutyl)phenylcarboxylic acid), 4-(4-formyloxyphenyl)-2-butanone (4-(4-formyloxyphenyl)-2-butanone) or Raspberry ketone derivatives attract Bactrocera cucurbitae , Bactrocera tau and fruit fly insects.

In another preferred embodiment of the adsorptive porous material provided by the present invention, the attractant is a chemical pheromone, a pheromone, a pheromone precursor, a food or a reaction of a diptera insect. Any combination of the above. In still another preferred embodiment, the chemical pheromone or pheromone or pheromone precursor is Cuelure, Raspberry Ketone, 4-(3-oxobutyl)phenyl 4-(3-Oxobutyl)phenyl formate or a raspberry derivative. In another more preferred embodiment, the raspberry derivative is of the formula: Wherein R is hydrogen or a linear or branched C _1-5 alkyl group. In still another preferred embodiment, the castor oil may be polyethylene oxide castor oil, polyethylene oxide hardened castor oil, polyoxyethylidene hydrogenated castor oil, ethoxylated castor oil or the like. Castor oil derivatives. In another more preferred embodiment, the formulation further comprises one or more suitable insecticides.

It will be appreciated that the concentration of the active substance: chemical pheromone, pheromone or pheromone precursor of the present invention will depend on the type of equipment used, application, when formulating the attractant formulation of the invention with the carrier. The method, the area to be treated, the type of pest to be controlled, and the degree of disturbance are determined. Therefore, an appropriate amount of the active substance which may be higher or lower than the aforementioned concentration range is selected depending on the particular circumstances.

The invention also encompasses dispersing the attractant of the invention in the flies-infested area to attract the flies. The insect-infested areas include areas where flies live or feed (plants, fields, forests, orchards, street trees, landscape plants, waterways, soil, plant products, etc.) or areas that are vulnerable to flies in the future. Thus, the invention is useful in practical applications such as parks, campuses, agriculture, horticultural crops, forests, veterinary medicine or animal husbandry or public health.

The formulations of the present invention may also contain more solid or liquid adjuvants such as stabilizers, antifoaming agents, preservatives, viscosity modifiers, binding agents and/or tackifiers, or other active ingredients which achieve particular effects. In a preferred embodiment, the formulation of the present invention can be combined to produce a smear paper. A substrate is dyed with a preferred color to trap insects, and a glue containing the appropriate amount of the formulation of the invention is applied thereto, and the insect-adhesive paper is placed in a place where insect activity is frequent, by combining color and The induced formula of the invention enhances the effects of attracting insects, catching insects and inhibiting pests.

The formulations of the present invention may additionally, but not limited to, be applied in the form of sprays, powders, granules, flowable emulsified concentrates or foams, applied to the crops exposed to the fly; in such formulations A suitable surfactant may be included if desired.

The formulation of the present invention may further comprise an insect control agent having no adverse interaction between the following active substances and the present invention, but is not limited to the following: clorantraniliprole, spinetoram, Aba Aba (abmectin), acephate, acetamiprid, acrinathrin, alanycrb, aldicarb, allethrin, arsenic (alpha) -cypermethrin), aluminium phosphide, amitraz, azadirachtin, azamethiphos, azinphos-ethyl, azinphos -methyl), bendiocarb, benfuracarb, bensultap, beta-cyfluthrin, beta-cypermethrin, bifenthrin, hundred Bioallethrin, S-cyclopentenyl isomer, bioresmethrin, bisatrifluron, borax, buprofezin, butocarboxim, Butoxycarboxim, cadusafos, calcium cyanide, calcium polyether, Carbaryl, carbofuran, carbosulfan, cartap, chlosdane, chlorethoxyfos, chlorfenapyr, ketone Chlosfenvinphos, chlorfluazuron, chlormephos, chloropicrin, chlorpyrifos, methyl Chlorpyrifos-methyl, chromafenozide, clothianidin, coumaphos, cryolite, cyanophos, cycloprothrin, Cyfluthrin, cyhalothrin, cypermethrin, cyphenothrin, cyromazine, dazomet, deltamethrin, annihilation Demeton-S-methyl, diafenthiuron, diazinon, dichlorvos, dicrotophos, dicyclanil, diflubenzuron , dimethoate, dimethylvinphos, dinotefuran, disulfoton, emamectin, emamectin benzoate, Yixuning (empenthrin), endosulfan, esfenvalerate, ethiofencarb, ethion, ethiprole, ethoprophos, dibromoethylene (ethylene dibromide), etofenprox, etoxazole, famphur, fensone (feni) Trothion), fenobucarb, fenoxycarb, fenpropathrin, fenthion, fenvalerate, fipronil, flufenidazole Melamine (flonicamid), flucycloxuron, flucythrinate, flufenoxuron, flumethrin, formetanate, formetanate hydrochloride , fosthiazate, furathiocarb, halofenozide, heptachlor, heptenophos, hexaflumuron, hydramethylnon, alkene Hydroprene, imidacloprid, imiprothrin, indoxacarb, isofenphos, isoprocarb, O-(methoxyamine-based sulfur Phosphonic acid Isopropyl ester, isoxathion, lambda-cyhalothrin, PFOS, lufenuron, magnesium phosphide, malathion, mecarbam, chlorine Mercury, metam, tamtan sodium, methamidophos, methidathion, metiocarb, methodyl, metheprene, methyl ether Methothrin, methoxychlor, methoxyfenozide, methyl isothiocyanate, metolcarb, mevinphos, milbemectin, sub Monocrotophos, naled, naphthalenic compounds, nicotine, nitenpyram, nithiazine, novaluron, noififlumuron , omethoate, oxamyl, oxydemeton-methyl, parathion, methyl balazon, pentachlorophenol, pentachlorophenyl laurate, hunter Permethrin, petroleum oils, phenothrin, phenthoate, phorate, yubi ( Phosalone), phosmet, phosphamidon, phosphine, phoxim, pirimicarb, pirimiphos-methyl, prallethrin , profenofos, propaphos, propetamphos, propoxur, prothiofos, pymetrozine, pyraclofos, pyrethrin , pyridaben, pyridaphenthion, pyrimidifen, pyriproxyfen, quinalphos, resmethrin, rotenone, alfalfa Sabadilla, silafluofen, sodium cyanide, sodium pentachlorobenzene, spinosad, sulcofuron, sulcofuron-sodium, flubendiamide (sulfluramid), sulfodep, sulfonium fluoride Sulfuryl fluoride, sulprofos, tau-fluvalinate, tebufenozide, tebupirimfos, teblubenzuron, tefluthrin ), temephos, terbufos, tetrachlorvinphos, tetramethrin, theta-cypermethrin, thiacloprid, Thiamethoxam, thiodicarb, thiofanox, thiometon, thiosultap-sodium, tolfenpyrad, tylomethrin ), transfluthrin, triazamate, triazophos, trichlorfon, triflumuron, trimethacarb, vamidothion, Xylylcarb, zeta-cypermethrin, and zinc phosphide.

10‧‧‧Polyporous materials for adsorption attractant formulations

101‧‧‧Porous structure

103‧‧‧Inducing agent formula

Figure 1. Raspberry ketone (RK) content after decomposing raspberry ketone derivative (RKF) and raspberry ketone derivative after 7 days of room temperature after adding different amounts of pure water to raspberry ketone derivative. Variety.

Figure 2. Using polyethylene glycol as a control control solvent, different concentrations of raspberry ketone derivatives were formulated for outdoor open bottle regression test to test the hydrolysis rate.

Figure 3. Using castor oil as a blending solvent, various concentrations of raspberry ketone derivatives were formulated and tested for hydrolysis rate after 1 week of open bottle opening.

Figure 4. Net cage induction test using raspberry ketone derivatives of different blending concentrations, each value being the average of 5 replicates.

Figure 5. The total number of traps of the fruit fly males after 5 weeks of hanging with 5 ml of different proportions of the trap or single castor oil (containing 5% of the insecticide) in the field.

Figure 6. Number of fruit flies captured by different proportions of flies or raspberry ketone derivative solutions (counted every seven days).

Figure 7. Proportion of various fly males after 5 weeks of hanging in a field with 5 ml of different proportions of the decoy (containing 5% of the pesticide).

Figure 8. Schematic diagram of a porous material adsorbing the attractant.

Example 1 Relationship between moisture and decomposition rate of raspberry ketone derivatives

After adding different amounts of pure water to the quantitative raspberry ketone derivative, the content was determined by high performance liquid chromatography (HPLC) after standing at room temperature for 7 days. Figure 1 shows the rate of hydrolysis of raspberry ketone derivatives and the rate of formation of raspberry ketone. The higher the amount of water added, the higher the decomposition rate of the raspberry ketone derivative and the higher the amount of raspberry ketone. Therefore, it is known that hydrolysis is The reason why the raspberry ketone derivative is mainly decomposed and crystallized into raspberry ketone. The analysis of moisture is a Karl Fischer moisture titrator.

Example 2 Decomposition rate of raspberry ketone derivatives at different compounding concentrations

When polyethylene glycol (PEG) was used as a solvent control (Fig. 2), the raspberry ketone derivatives of different concentrations were analyzed by HPLC for one week after opening to calculate the decomposition rate, and the decomposition rate was obtained. Both are more than 45%, and crystals will form after one week.

If castor oil is used as a solvent (mixing raspberry derivatives with castor oil in a container and then uniformly mixing with ultrasonic waves for 15 minutes), it can significantly delay the decomposition rate of raspberry derivatives and delay The time at which crystallization occurs. In this formulation, the more the castor oil is added, the slower the decomposition rate of the raspberry ketone derivative is, and there is no crystallization in the bottle or in the carrier. This material can also be used for field attraction (Fig. 3). . One week after opening the bottle, it is derived from raspberry ketone. When the concentration is 50 and 30%, the hydrolysis rate will drop below 40%, and the crystallization will be significantly better after the second week than the unrefueled 100% and 85% (the hydrolysis rate is greater than 50%). At 5 and 10% raspberry ketone derivative concentration, the hydrolysis rate is less than 20%, although the content will continue to decrease, but raspberry ketone is soluble in the formula and will not crystallize until the 8th week. A decoy experiment was performed.

Example 3 Net cage induction efficiency of raspberry ketone derivatives at different blending concentrations

4 μl of 100, 50, 10 and 5% raspberry derivatives, and 2 μl of 100% raspberry derivative (half the amount) for close-range inducing tests, cage test at 40 x 20 x 16 cm ^{In the} cage, 20 males of 1, 5, 10 and 20 days old were placed in the cage, and water and artificial feed were given at the same time. The inducer is a plastic cup with a capacity of 250 ml. In the 1/3 and 2/3 heights of the cup wall, 0.7 ml microcentrifuge tubes are inserted upside down in three directions of the circumference of the circumference, and the tip is cut open to a width of 0.3 cm. The lid of the cup hangs a circular cotton piece with a diameter of 0.6 cm in the center with a cotton thread. During the experiment, 4 μl of flies or raspberry ketone derivatives were added to the cotton pads, and the inducer and the lid were combined and placed in the center of the cage to record the number of males trapped within 72 hours, and each treatment was repeated 5 times.

The results showed that the 50% raspberry ketone derivative had a higher extraction rate than the 100% raspberry derivative and half of the 100% raspberry derivative (Fig. 4). Therefore, the 50% formulation concentration has a good effect; while the 10 and 5% raspberry ketone derivatives have a slightly less attractive effect than the 100% raspberry derivative, but there is no significant difference. The use of different concentrations of raspberry ketone derivatives at close range does not have a significant negative impact on males and has the potential to increase the rate of attraction at 50% concentration. Further testing over long distances is needed to compare the differences.

Example 4 Field Inducing Test

Phytophthora attractants (such as raspberry ketone, flies and raspberry derivatives), castor oil and insecticide 5% (malathion, fipronil or spinosad) 5 mL of the mixture is adsorbed on the adsorbent porous material (cane board, non-woven fabric, foam and cotton sheet, etc.), and placed in a modified fly trap, such as a modified Mai's trap, every 20 meters in the shade. Hang one at a height of 1-1.5 meters, and cover it in the field. After 5 weeks, count the number of insects in the fruit fly. However, if the trapping device (such as the trap) is not allowed to escape, it is not necessary to add an insecticide.

As shown in Figure 5, when the raspberry ketone derivative is used in the field, its attracting effect is better than that of the currently used flies (CL), and when the raspberry ketone derivative is formulated to 50% concentration, its attracting effect and 100%. The raspberry ketone derivative is equivalent and superior to the currently used gram fly. If it is formulated to a concentration of 10%, its attracting effect is slightly better than 100% raspberry ketone derivative; while castor oil (oil) and its decomposition products are used alone. When raspberry ketone (dissolved in castor oil), its attracting effect is not good.

Example 5 Field Inducing Different Fly Tests

In the field, the experiment was carried out with castor oil formula to mix different concentrations of flies. The experiment was carried out by cultivating melons and fruit flies for every 20 meters. The maiden traps were repeated four times every 20 meters, containing 5% of the promises and different proportions of attractants. 5 mL was adsorbed on cotton sheets and the number of induced insects was counted every seven days. The results are shown in Figure 6. The number of insects in the different proportions of the flies solution was comparable to that of the unmixed flies (the standard deviation of the 100% flies group was 29 and 25). And count the number of melons and fruit flies in each attractant, there are more than three kinds (Figure 7), among which the number of fruit fly and pumpkin fruit fly is a large proportion, and the fruit flies account for 50-75%, pumpkin fruit fly 20-50%.

Example 6 Inducing agent formula (including adhesive or insecticide) with different adsorbent materials material

(1) Inducant formulation containing adhesive with adsorbent material

After mixing the attractant (0.1-30% raspberry derivative) and castor oil (5-30%), add appropriate amount of other solvent (0-30%), dye (<0.2%) and adhesive. Material (40-70%), such as pressure sensitive adhesive, rubber, resin, hot melt adhesive, etc., can be blended into 5 mL of attractant formulation 103, then the attractant formulation 103 can be coated or sprayed (filled in plus In a pressure bottle, or with propane or butane added to the spray can) in a porous absorbent material (or adhesive material) 10, such as flat paper, sugar cane or fiberboard (cut to a fixed size, such as 23 * 12 cm ² Above, etc., the porous structure 101 in the porous adsorbent material 10 can adsorb the above-described attractant formulation 103 (see FIG. 8).

(2) Inducing agent formulation containing insecticide with adsorbent material

Mix the attractant (0.1-95% raspberry ketone derivative) and castor oil (5-99.9%), then add the appropriate amount of pesticide (Xenox or Nai Lisong, 0.1-5%) to make 5mL. The attractant formulation 103; and the porous adsorbent material 10, such as a sponge, a non-woven fabric, etc., is cut to a fixed size, such as 4*4*0.8 cm ³ ; the porous adsorbent 10 is wetted with the attractant formulation 103, The porous structure 101 in the porous adsorbent material 10 is allowed to adsorb the above-described attractant formulation 103 (see Fig. 8).

The above description is only a preferred embodiment of the present invention, and is not intended to limit the present invention in any way. Anyone having ordinary knowledge in the technical field may use the present invention without departing from the technical features of the present invention. Equivalent embodiments of the local changes or modifications made by the technical content disclosed herein are still within the scope of the features of the present invention.

Claims (16)

A use of castor oil for stabilizing a formulation of a dipteran insect attractant, wherein the dipteran insect attractant is present in the formulation in an amount of from 0.1 to 95%, and the castor oil is present in the formulation in an amount of from 5 to 5 99.9%, wherein the castor oil can reduce the use amount of the attractant, and can slow down the hydrolysis rate of the attractant, wherein the attractant is a chemical pheromone, a sexual pheromones, and a sexual fee which are reactive by the diptera insects. Lomon precursor or any combination thereof, wherein the chemical pheromone, sexual pheromones or pheromone precursors are Cuelure, Raspberry Ketone, 4-(3-oxobutyl) 4-(3-Oxobutyl)phenyl formate or a raspberry derivative. According to the use of the first aspect of the patent application, the Diptera insect belongs to the insect of the family Muscidae (Tephritidae). According to the use of the second aspect of the patent application, the insect of the fruit family (Tephritidae) is an insect of the family Dacinae. For example, in the application of the third aspect of the patent application, the insect line of the subfamily of the genus Bactrocera is Bactrocera cucurbitae and the fruit fly of the genus Dacus . (Dacine flies). For example, the application of the scope of claim 4, wherein the fruit fly and the fruit fly are referred to as flies or raspberry ketone, 4-(3-oxobutyl)phenylcarboxylic acid (4-(3-Oxobutyl) Phenyl formate) (synonym: 4-(3-oxobutyl)phenylcarboxylic acid), 4-(4-formyloxyphenyl)-2-butanone (4-(4-formyloxyphenyl)-2- Butanone) or Bactrocera cucurbitae , Bactrocera tau and fruit fly insects attracted by raspberry ketone derivatives. The use of the first aspect of the patent application, wherein the raspberry derivative is of the following formula: Wherein R is hydrogen or a linear or branched C _1-5 alkyl group. The use of the first aspect of the patent application, wherein the castor oil may be polyethylene oxide castor oil, polyethylene oxide hardened castor oil, polyoxyethylene ethyl hydrogenated castor oil, ethoxylated castor oil or the like. Castor oil derivative. The use of claim 1 wherein the formulation further comprises one or more insecticides. For example, the use of the scope of claim 1 may further be made into a glue, a spray, a viscous spray or a similar physical sorbent. For example, the use of the scope of claim 1 wherein the formulation is further compatible with a color suitable for attracting insects. An adsorptive porous material comprising a plurality of interconnected pore structures, wherein the pore structure adsorbs an attractant formulation, wherein the formulation comprises a diptera insect having an attractant content of 0.1-95% and a castor oil content of 5-99.9%, Wherein the castor oil reduces the amount of the attractant used, and slows down the rate of hydrolysis of the attractant, wherein the attractant is a chemical pheromone of a Diptera insect, a pheromone, a pheromone precursor or In any combination of the above, the chemical pheromone, pheromones or pheromone precursors are Cuelure, Raspberry Ketone, 4-(3-oxobutyl)phenylcarboxylic acid (4) -(3-Oxobutyl)phenyl formate) or a raspberry derivative. The adsorptive porous material according to claim 11, wherein the Diptera insect belongs to the insect of the family Dacinae. An adsorbent porous material according to claim 12, wherein the insect line of the subfamily of the genus Eriocheir sinensis is Cuelure, Raspberry Ketone, 4-(3-oxobutyl)phenylcarboxylic acid ( 4-(3-Oxobutyl)phenyl formate) or Bactrocera cucurbitae , Bactrocera tau and fruit fly insects attracted by raspberry ketone derivatives. The adsorbent porous material according to claim 11, wherein the raspberry derivative has the structure of the following formula: Wherein R is hydrogen or a linear or branched C _1-5 alkyl group. An adsorbent porous material according to claim 11 which may additionally adsorb one or more insecticides. The adsorbent porous material according to claim 11, wherein the castor oil is polyethylene oxide castor oil, polyethylene oxide hardened castor oil, polyoxyethylene ethyl hydrogenated castor oil, and ethoxylated cerium oxide. Sesame oil or similar castor oil derivatives.