Abstract: Disclosed are methods for attracting and thereby controlling bedbugs. One volatizes a synthetic pheromone and generates infrared radiation adjacent the location and exposes bedbugs thereto.

Abstract: In one aspect, the present invention is directed to an ampoule for the storage and dispersion of a volatile liquid comprised of (a) an outer shell composed of an impermeable material and defining at least one opening; (b) a porous diffusion member defining an internal reservoir positioned inside said outer shell; (c) a volatile liquid contained within such internal reservoir; and (d) a film member adhered to said outer shell and covering said at least one opening; wherein said film member is disposed such that an air space is present between said porous diffusion member and said film member; and wherein said porous diffusion member is configured such that molecules of the volatile liquid can only enter into said air space via diffusion through said porous diffusion member. Such ampoules are particularly suited for the storage and dispersion of organic chemicals useful as bed bug attractants, especially where such attractants are formulated in a highly volatile liquid, such as a C8-C12 alkane.

Abstract: The present invention relates to a bed bug capturing device comprising: (a) a bed bug attractant element comprising (i) a heavier than air organic chemical which attracts bed bugs; and (ii) a means for producing air flow such that the air movement from the device has a face velocity of between about 5 and about 50 ml/cm2/min; and (b) a trap element. Preferably, such means of producing air flow is a fan.

Abstract: The present invention relates to a bed bug capturing device comprising: (a) a bed bug attractant element; and (b) a deadfall capturing element comprising at least one pathway comprising: (i) an upwardly sloped segment; (ii) a downwardly sloped segment having an outer portion; and (iii) a deadfall trap area: characterized in that the upwardly sloped segment and at least the outer portion of the downwardly sloped segment possesses an average surface roughness of at least about 2.5 micrometers.

Abstract: An device for attracting and capturing an insect is provided. The device includes a housing which defines an interior space and a plurality of entrances in open communication with the interior space, a downwardly sloping panel coupled to and disposed within the housing, and an adhesive attached to at least a portion of the bottom surface of the downwardly sloping panel. The downwardly sloping panel and the housing together define a tapering passageway which leads to a crevice opposite at least one of the plurality of entrances, and the adhesive attached to the bottom surface of the panel is adapted to capture the insect.

Abstract: One nonlimiting variation of a detection arrangement includes one or more sensors each structured to detect at least one biochemical substance indicative of biochemistry of one or more target insect species and provide a corresponding sensor signal, a controller responsive to the sensor signal of each of the one or more sensors to determine if the one or more insect species are present and generate a corresponding output signal, and an indicator responsive to the output signal to indicate the presence of the one or more insect species.

Abstract: A detection device and method for monitoring infestation by insects such as bed bugs is provided. A suitable device comprises a pair of plates separated by an internal spacing sized to permit entry into the detection device by one or more insects. Also disclosed is a method for readily detecting insects such as bed bugs in a multiple areas such as in multiple hotel rooms, areas where animals are housed, or the like.

Abstract: An intercepting device (e.g. a furniture coaster device) is placed under furniture (bed, sofa, chair. etc.), other climbable object, or the floor adjacent an object to intercept crawling arthropods and other crawling pests. The intercepting device can be used to monitor the presence of crawling arthropods and other crawling pests (such as bed bugs, ants, cockroaches, beetles, spiders, etc.), reduce pest numbers, and monitor efficacy of pest control procedures. The intercepting device includes pitfall trap surfaces that form multiple pitfall traps.

Abstract: A trap for ectoparasitic arthropods with cryptic behavior, such as bed bugs, includes one or more dimensions of attractants, as well as the physical attributes of hiding places preferred by bed bugs. The trap may have an adhesive or fabric layer disposed within it, and the adhesive or fabric layer may include a non-volatile attractant such as a fecal matter attractant. With respect to attractants, such a trap may include one or more of a slow CO2 leaker device, one or more temperature gradient generators, one or more heated air generators, one or more cool infra-red (IR) sources, one or more volatile chemical attractants, and one or more non-volatile chemical attractants.

Abstract: An insect monitoring and trapping device is provided according to the invention. The device includes a base and a lid for covering the base, and is constructed to provide a trap interior and an insect opening for insects to access the trap interior. The device includes a heating device provided within the trap interior for attracting insects, and an adhesive surface provided within the trap for trapping insects.

Abstract: A climb-up pitfall trap for attracting and capturing bed bugs and the like comprises a rough exterior surface, a precipice, a smooth interior surface and sensory lures. The sensory lures include heat, carbon dioxide and/or a lure composition. The lure composition comprises a combination of (a) L-lactic acid, and (b) a fatty acid from the group consisting of (1) propionic acid, (2) butyric acid, and (3) valeric acid. The lure composition may also comprise (c) octenol. A method for attracting and capturing bed bugs and the like uses the climb-up pitfall trap in a bed bug infested environment.

Abstract: The present invention is directed to an apparatus for monitoring or abatement of bedbugs, comprising: a base having a mounting portion and a control portion; a heating source positioned on the mounting portion; two capture channels positioned proximate to the heating source and adjacent to the base and each comprising a sloped portion; a horizontal portion connected to the sloped portion, the horizontal portion having a width ranging from about 8 to about 15 millimeters; and a channel portion connected to the horizontal portion by a curved portion having a radius of curvature ranging from about ?th inch to about ½ inch; an insect attractant source positioned on the heating source; a carbon dioxide source attached to the base and capable of emitting carbon dioxide proximate to the heating source, and a control circuit mounted in the control portion and in communication with the heating source and the carbon dioxide source to control operation of the apparatus, wherein the control circuit controls emission of t

Abstract: Methods of assaying insects for pesticide resistance and to identify insect species are based on feeding disruption caused by insecticide such as the biopesticide Bacillius thuringiensis toxin (Bt). Further provided are methods for monitoring insecticide resistance in a population of insects, as well as methods of screening compounds for insecticidal activity. Insecticide resistance can be assessed at the level of an individual insect or at population levels. Apparatus and dehydrated insect meal pads useful in such assays are described.

Abstract: A peripheral termiticide delivery system of flexible apertured tubing is provided for injection under pressure of termiticide between the exterior walls of a building and its exterior coating. The tubing preferably has flanges extending therefrom whereby it is affixed to the walls around the building above ground level, and the apertures are protected from clogging by coating material. Injection ports for injection of termiticide into the tubing are disposed at intervals along the tubing, which ports are adapted to extend outside the exterior surfacing materials. Termiticide is injected under pressure into each port until all sections of tubing are filled to overflowing and termiticide exiting the apertures soaks the adjacent wall surfaces and runs down into the adjacent soil, creating a termite barrier. The system may be installed after construction by cutting a channel through the exterior coating, inserting the tubing into the channel and then reapplying exterior coating.