BugDorm-4H3030 Insect Rearing Cage

  • Model:BD4H3030
 
Ordered Quantity 1-5 6-11 12+
 Discount -0% -5% -10%
Price per Unit ¥10,950 JPY ¥10,350 JPY ¥9,900 JPY

The BugDorm-4H3030 insect cage is easy to assemble by connecting plastic poles with connectors.  It features Nylon netting (40×32 mesh/inch, 720 µm aperture) ON ALL SIDES, including the floor, to keep most insects out or from entering the cage while promoting superior ventilation.

The front panel includes an 18-cm sleeve opening for easy access to add or remove insects and replace food.  A thin strip sewn across the ceiling suspends objects such as feeders.

Constructed from lightweight fiberglass, the BugDorm-4H3030's framework is built outside the enclosure, minimizing hiding spots for insects inside the cage.  The sturdy, UV-resistant Nylon mesh also makes this cage suitable for outdoor use.

Pack Contents
x1 Fabric Cage Body
x12 Fiberglass Rods (Ø4 mm, L30 cm)
x4 Webbed Plastic Joints (3-Way)
x4 Plastic Joints (3-Way)

Studies Using This Line of Products
Badenes-Perez et al. (2010). Pest Management Science, 66(8), 832-838.
Hunter et al. (2011). Florida Entomologist, 94(4), 1051-1054.
Petzold-Maxwell et al. (2012). Journal of Economic Entomology, 105(4), 1407-1418.
Machtinger & Geden (2013). Biological Control, 65(1), 130-134.
Badenes-Perez et al. (2014). Phytochemistry, 98, 137-144.
Haye et al. (2014). Journal of Pest Science, 87(3), 407-418.
Manley et al. (2015). PLoS One, 10(8), e0134453.
Bots et al. (2015). American Naturalist, 186(1), 141-150.
Reynolds et al. (2016). Journal of Economic Entomology, 109(3), 1254-1260.
Fraga et al. (2016). Journal of Pest Science, 90(4), 1107-1118.
Chari et al. (2017). PLoS Biology, 12(8), e1001935.
Tigreros et al. (2017). Ecology Letters, 20(4), 487-494.
Veronesi et al. (2018). Parasitology Research, 117(6), 1925-1932.
Moadeli et al. (2018). Journal of Economic Entomology, 111(5), 2288-2297.
Gonzales et al. (2018). Scientific Reports, 8(1), 1-14.
Costi et al. (2019). Journal of Applied Entomology, 143(3), 299-307.
Setti et al. (2019). Waste Management, 95, 278-288.
Biasazin et al. (2019). Ecology Letters, 22(1), 108-118.
Gassmann et al. (2020). Pest Management Science, 76(1), 268-276.
Gutiérrez-López et al. (2020). Parasitology, 147(4), 441-447.
Robinson et al. (2020). PLoS Neglected Tropical Diseases, 14(3), e0007719.
Santosh et al. (2021). Frontiers in Ecology and Evolution, 9, 17.
Tarusikirwa et al. (2021). Pest Management Science, 77(1), 184-193.
Khan et al. (2021). Scientific Reports, 11(1), 1-9.
Jones et al. (2021). Scientific Reports, 11(1), 1-12.
Somers et al. (2022). Science Advances, 8(2), eabl4844.
Bimbilé Somda et al. (2022). Scientific Reports, 12(1), 1-13.
Mutamiswa et al. (2022). Pest Management Science, 78(11), 4446-4457.
Faber et al. (2022). PeerJ, 10, e14247.
Kirkland et al. (2023). Pest Management Science, 79(5), 1851-1859.
Baig et al. (2023). Journal of Economic Entomology, 116(2), 505-512.
Elya et al. (2023). Elife, 12, e85410.
Ogawa et al. (2023). Current Biology, 33(20), 4392-4404.
Soto et al. (2023). PLoS Neglected Tropical Diseases, 17(9), e0011649.
Ward et al. (2023). Pest Management Science, 80(2), 866-873.
Zhang et al. (2024). Nature Communications, 15, 1980.
Dweck & Rutledge (2024). Open Biology, 14(3), 230438.
Hernandes et al. (2024). Pest Management Science, 80(6), 2950-2964.