BugDorm-6E610 Insect Rearing Cage

  • Model:BD6E610
 
Ordered Quantity 1-3 4-7 8+
 Discount -0% -5% -10%
Price per Unit ¥23,850 JPY ¥22,650 JPY ¥21,450 JPY
  • Out of Stock
     Restock: 03 January 

A 60-cm cube, BugDorm-6E610 insect cage is suitable for small potted plants.  All panels except the floor are of fine Nylon netting (150 x 150 mesh) for ventilation.  A thin strip is sewn across the ceiling from which to suspend objects such as feeders.

There are two openings in the front panel of BugDorm-6E610 insect rearing cage.  The zippered opening is large enough to insert potted plants.  On the zippered opening is a 18-cm sleeve opening for addition or removal of insects and replacement of food without letting insects escape.

The framework of BugDorm-6E610 insect cage is of durable aluminum and constructed outside the enclosure.  There are no places for insects to hide inside the cage.

Pack Contents
x1 Fabric Cage Body
x12 Aluminum Pipes (L59 cm)
x8 Nylon Plastic Joints (3-Way)

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Host range testing of Diaphorencyrtus aligarhensis (Hymenoptera: Encyrtidae) for use in classical biological control of Diaphorina citri (Hemiptera: Liviidae) in California. Bistline-East et al. (2015). Journal of Economic Entomology, 108(3), 940-950.
Behavioral responses of predaceous minute pirate bugs to tridecane, a volatile emitted by the brown marmorated stink bug. Fraga et al. (2016). Journal of Pest Science, 90(4), 1107-1118.
Knock down of whitefly gut gene expression and mortality by orally delivered gut gene-specific dsRNAs. Vyas et al. (2017). PLoS One, 12(1), e0168921.
Dehydration prompts increased activity and blood feeding by mosquitoes. Hagan et al. (2018). Scientific Reports, 8(1), 1-12.
First laboratory evaluation of Gryon gonikopalense (Hymenoptera: Scelionidae), as potential biological control agent of Bagrada hilaris (Hemiptera: Pentatomidae). Martel et al. (2019). Biological Control, 135, 48-56.
Efficient production of male Wolbachia-infected Aedes aegypti mosquitoes enables large-scale uppression of wild populations. Crawford et al. (2020). Nature Biotechnology, 38(4), 482-492.
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Rethinking trophic interactions in agricultural landscapes through tracking secondary feeding. Kheirodin et al. (2023). Environmental DNA, 6(1), e495.
Timing matters: remotely sensed vegetation greenness can predict insect vector migration and therefore outbreaks of curly top disease. Lee et al. (2024). Journal of Pest Science, 1-11.