BugDorm-6E620 Insect Rearing Cage

Model:BD6E620

Ordered Quantity	1-3	4-7	8+
Discount	-0%	-5%	-10%
Price per Unit	€223,03 EUR	€211,88 EUR	€200,73 EUR

Dimensions: W60 x D60 x H120 cm

Net Weight: 1,600 grams

Main Material: Woven Nylon Netting

Frame: Aluminum Pipes

Mesh Size: 150 x 150 | 160 µm Aperture

Mesh Panel: All Except Floor

Clear Panel: None

Floor: White Polyester (water-repellent)

Sleeve Opening: 2 x Front (Ø18 x L38 cm)

Zippered Opening: 1 x Front (W52 x H100 cm)

Quick Guide - click to download bd6e620-bugdorm-6e620-insect-rearing-cage_manual - 254KB

120-cm tall, BugDorm-6E620 insect cage is suitable for large 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 three openings in the front panel of BugDorm-6E620 insect rearing cage. The zippered opening is large enough to insert large plants. On the zippered opening are two 18-cm sleeve openings for addition or removal of insects and replacement of food without letting insects escape.

The framework of BugDorm-6E620 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
x16 Aluminum Pipes (L59 cm)
x8 Nylon Plastic Joints (3-Way)
x4 Nylon Plastic Joints (2-Way)

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Collection of related articles from the last 10 years:
Screening the primary gene pool of field pea (Pisum sativum L. subsp. sativum) in Ethiopia for resistance against pea weevil (Bruchus pisorum L.). Teshome et al. (2015). Genetic Resources and Crop Evolution, 62(4), 525-538.
Enhancing neoplasm expression in field pea (Pisum sativum) via intercropping and its significance to pea weevil (Bruchus pisorum) management. Teshome et al. (2016). Frontiers in Plant Science, 7, 654.
Filth fly transmission of Escherichia coli O157: H7 and Salmonella enterica to lettuce, Lactuca sativa. Pace et al. (2017). Annals of the Entomological Society of America, 110(1), 83-89.
The reproductive strategy and the vibrational duet of the leafhopper Empoasca vitis. Nieri & Mazzoni (2018). Insect Science, 25(5), 869-882.
Vibrational mating disruption of Empoasca vitis by natural or artificial disturbance noises. Nieri & Mazzoni (2019). Pest Management Science, 75(4), 1065-1073.
Transcriptome analysis of contrasting resistance to herbivory by Empoasca fabae in two shrub willow species and their hybrid progeny. Wang et al. (2020). PLoS One, 15(7), e0236586.
Vibrational communication and mating behavior of the greenhouse whitefly Trialeurodes vaporariorum (Westwood) (Hemiptera: Aleyrodidae). Fattoruso et al. (2021). Scientific Reports, 11(1), 1-11.
Extending the vibroscape to agroecosystems: investigating the influence of abiotic factors and monitoring insect vibrational signaling. Akassou et al. (2022). PeerJ, 10, e14143.
An IoT-based smart mosquito trap system embedded with real-time mosquito image processing by neural networks for mosquito surveillance. Liu et al. (2023). Frontiers in Bioengineering and Biotechnology, 11, 1100968.
Incompatible insect technique: insights on potential outcomes of releasing contaminant females: a proof of concept under semi‐field conditions. Lombardi et al. (2024). Pest Management Science, 8(10), 5342-5352.