A portable, heated scent, odor, and/or molecule dispense system is provided, as well as devices and methods for doing the same. The portable systems and methods to dispense molecules may contain a liquid, gel, solid, foam, or other material-based formulation so as to attract, repel, kill, mask, or otherwise use the molecules. The portable system and methods may include a housing; a molecule holding pad in the housing; a first chemical reaction heat source in the housing; and a second chemical reaction heat source in the housing, wherein the molecule holding pad is arranged between the first chemical reaction heat source and the second chemical reaction heat source, and wherein the first chemical reaction heat source and the second chemical reaction heat source are each reactive to oxygen.

Wearable articles, such as adhesive tapes, for prevention of tick and other pest bites includes flexible substrates having first and second opposite sides. The first side includes an adhesive configured to adhere the article to a user's skin, while the second side includes an attractant site configured to attract the pest, and a trap site configured to trap the pest. Methods for making an adhesive tape for the prevention of tick bites include providing such a substrate, placing a skin adhesive on one surface, and placing a chemoattractant and tick or insect adhesive on the second surface.

Bedding material having a bed bug monitor. The bedding material includes at least one bed bug monitoring interface adapted to receive a bed bug monitor, whereby the monitor gathers bed bugs and/or evidence thereof and is subject to visual inspection.

The present invention discloses devices for a durable insect bait station for biting flies in blood-seeking mode and methods therein. The devices include: an elastomeric membrane for providing access to the bait station, the elastomeric membrane adapted to be permeable to volatile components, and the elastomeric membrane configured to allow easy insect-probe penetration for biting flies in blood-seeking mode; a bait core for providing bait to the bait station, the bait core including: at least one blood-feeding stimulant (BFS) for inducing feeding of the biting flies on the bait core; and at least one insect toxin; wherein the bait core is configured to be substantially in direct contact with the elastomeric membrane; and a support element for attaching the elastomeric membrane and the bait core to a fixed structure. Alternatively, the BFS for inducing the feeding is operative at an ambient temperature below an average mammal temperature.

A delivery device and system to supplement CO.sub.2 in an underwater environment without the need for electricity or the use of compressed CO.sub.2. The device consists of a container containing a biological organism such as mycelium and including an exit portal for CO.sub.2 to enter the underwater environment. The device may also incorporate a separation device to delay and control the flow of CO.sub.2. The system requires the device to be held in place through a securing point in the underwater environment. The minimum requirements for the device are described, but in certain instances it will be preferably used with a double-bag or an outer shell housing to protect or aesthetically conceal the placement underwater. The use of this device and system to supplement carbon dioxide in water will span many industries and applications. It will assist with mosquito trapping. It will also supplement CO.sub.2 in underwater growing environments.

A system includes an acoustic lure and a sensor package disposed within an interior volume of an insect trapping container and a computing device in communication with the acoustic lure and the sensor package configured to instruct the acoustic lure to output an acoustic tone. The computer device is further configured to receive sensor data from the sensor package, the sensor data representative of insects within the interior volume. Responsive to receiving the sensor data, the computing device is configured to instruct an imaging device to capture image data representative of the insects within the interior volume or determine insect count data based on the sensor data. The computing device is configured to then transmit output data to a remote computing system, the output data including at least one of a first portion of the image data or a second portion of the insect count data.

An insect trap device and methods of using the device are described herein. In some embodiments, an insect trap includes a light source, a removable enclosure with at least one opening, an adhesive surface at least partially within the enclosure, and optics to redirect light from the light source onto an adhesive trapping surface. The light source may include at least one light emitting diode (LED). The optics may be attached to the removable enclosure, and may be located at least partially within the enclosure. The optics may include optical enhancers such as a reflector, a lens and/or a diffuser. The insect trap may further include an insect attractant that emits sound or scent.

A system and method to detect the presence of bed bugs are disclosed. A system detecting the presence of bed bugs comprises an aptamer solution that includes a base ligand, a fluorophore ligand that includes at least one fluorophore, and a quencher ligand that includes at least one quencher, a liquid application tool, and a fluorescent light source. A method of detecting the presence of bed bugs, comprising providing a liquid application tool that carries an aptamer solution, applying the aptamer solution to a target area, shining fluorescent light on the target area, and observing the target area under the fluorescent light. If there are light spots under the fluorescent light, bed bugs have been present.

An arthropod trap with an aerosol dispenser that is remotely controllable to dispense spray doses of an active ingredient such as a pheromone or other semiochemical. Images are captured of trapping media within the trap and are wirelessly communicated to a remote server or application. The dispenser is preferably upside down with the nozzle near the lower extremity of the inverted dispenser. An actuation mechanism controls the spray dose according to a schedule or according to individual sprays commands, each of which may be received wirelessly by the trap. Images of the trapping media may be used as feedback for verifying or modifying the metered dosing schedule.

An adhesive-type insect trap includes a main body having an adhesive sheet insertion hole; a light source mounting unit disposed on the main body; a cover which is detachably mounted on the main body and has a through-hole in at least a part thereof; an adhesive sheet including a sticky substance and a sheet. The main body includes a guide unit by which the adhesive sheet is guided, and an adhesive sheet support unit for supporting the adhesive sheet.