A system for controlling insects, comprising a first lure module for attracting insects to eat a toxicant and a second cooling module for lowing environmental temperature to a temperature lethal to insects but above the ice crystallization of fruit. The lure comprises: wax; oil; ethyl methyl eugenol or other suitable attractant; and spinosad or other suitable toxicant.

Compositions, formulas, methods of making, mixing and applying insecticide formulations to different surfaces such as but not limited to interior surfaces of ovitraps, on walls and on chips and tiles to produce a texturized surface to allow for better transfer of the insecticidal active ingredients to insects, such as mosquitoes and the like, which land on or crawl on the surfaces, resulting in faster insect mortality rates. The texture of the insecticidal residue provides better transfer of the insecticidal active ingredients to insects that land on or crawl on the surface, resulting in faster insect mortality. The textured residue also enhances desirable surface characteristics for landing of mosquitoes and potentially other insects.

An insect trapping system includes an enclosed container having an entrance hole formed in a vertical wall and an acoustic lure device located within the container. The enclosed container may be formed from a transparent material. The system may also include a support stand, formed from a dark-colored material, and used to support the container.

A device for controlling at least one insect bait station, in particular for insects harmful to humans, animals and plants, in which the bait station is provided with: at least one container provided with an insect entrance opening, the container containing bait and being at least partially transparent or translucent, a lighting device lighting the inside of the container but located outside same, a telecommunication module and a printed circuit comprising, inter alia, a memory and a processor connected to said telecommunication means. The device comprises an optical sensor essentially opposite the lighting device, and connected to the printed circuit, which measures the general opacity caused by the insect(s) in the container, the corresponding value being transmitted for processing and analysis of the status of the bait station.

A swaddling blanket and pouch combination (SBPC) (10) that allows an infant to be comfortably and easily swaddled. The blanket (12) is comprised of a right blanket flap (28) and a left blanket flap (46) and includes a designated area to which is removably attached the pouch (70). The pouch features a lower end (78) which includes an opening and closing means that allows an infant's soiled diaper to be easily removed and replaced or to take a rectal temperature. The SBPC (10) is used by first placing the left blanket flap (46) over the pouch (70), which is then followed by placing the right blanket flap (28) over the pouch. The right and left blanket flaps (28,46) as well as the pouch (70) are preferably held in place by hook and loop fasteners (88).

Insecticide dispensing devices and methods of the present technology provide for the prolonged release of insecticide for the eradication of insect populations. Insecticide dispensing devices include an attractive toxic sugar bait, and have a housing configured with at least one aperture to allow a gaseous compound to exit the internal cavity and sized to allow entry of a target insect into the internal cavity. Methods of insecticide dispensing include activating the attractive toxic sugar bait in the device, and placing the activated device in an area where insects are present.

An insect trapping system includes an enclosed container having an entrance hole formed in a vertical wall and an acoustic lure device located within the container. The enclosed container may be formed from a transparent material. The system may also include a support stand, formed from a dark-colored material, and used to support the container.

Insecticide dispensing devices and methods of the present technology provide for the prolonged release of insecticide for the eradication of insect populations. Insecticide dispensing devices include an attractive toxic sugar bait, and have a housing configured with at least one aperture to allow a gaseous compound to exit the internal cavity and sized to allow entry of a target insect into the internal cavity. Methods of insecticide dispensing include activating the attractive toxic sugar bait in the device, and placing the activated device in an area where insects are present.

Insecticide dispensing devices and methods of the present technology provide for the prolonged release of insecticide for the eradication of insect populations. Insecticide dispensing devices include an attractive toxic sugar bait, and have a housing configured with at least one aperture to allow a gaseous compound to exit the internal cavity and sized to allow entry of a target insect into the internal cavity. Methods of insecticide dispensing include activating the attractive toxic sugar bait in the device, and placing the activated device in an area where insects are present.

Methods and systems for counting insects in a container having at least one aperture, by attracting at least one insect into the container, using toxins within the container to kill the at least one insect, measuring signals by at least one sensor coupled to a receiving surface, wherein the receiving surface is configured to vibrate when insects falling through the at least one aperture engage the receiving surface, detecting that at least one measured signal is within a predetermined range, and adding the number of detected signals to an insect counter, wherein the predetermined range is calibrated to correspond to a range of signals associated with impact of a single insect on the receiving surface.