Science
Related: About this forumUnderwater Suit-Wearing Cyborg Insect Capable of Hours-Long Diving and Terra-Aqua Travel
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Cyborg insects are hybrid systems that integrate living insects with electronic components1,2,3,4,5, combining the biological capabilities of insects with the technological functions of electromechanical devices to remotely induce their movements. Current cyborg insects are envisioned for use in complex tasks such as search-and-rescue missions6, pipeline inspection7 and object transportation8, with cockroach-based ones considered the most promising owing to their robustness and ease of locomotion control. Unlike conventional artificial small robots which consume substantial power to drive actuators, draining the energy stored in their onboard batteries, cyborg insects locomote with the insects own muscles, requiring no electrical actuation and achieving minimal power consumption9,10. Their compact size, adaptability, and robustness allow them to traverse cluttered environments and enter into confined spaces inaccessible to larger robots11.
However, their operation is constrained by the hosts physiological requirements, such as optimal oxygen and temperature levels. Naturally, the inability of terrestrial hosts like cockroaches to absorb aquatic oxygen prevents underwater functions12. Given that real-world search-and-rescue or infrastructure inspection terrains often include puddles, flooded zones, or other partially submerged areas, continuous operation requires developing cyborg insects capable of temporary submersion and locomotion underwater while maintaining normal metabolic activity.
If a miniature unit capable of supplying oxygen could be mounted onto a cockroachs body, it might be possible to realise a cyborg cockroach that operates both on land and underwater. Cockroaches, like most terrestrial insects, breathe through thoracic spiracles that take in oxygen directly from the air13,14. If oxygen could be supplied to these spiracles while preventing water entry, cyborg insects might be able to operate underwater as well as on land. To realise this concept, we designed a compact and self-contained oxygen supply system, referred to as a diving suit, based on a controlled chemical reaction that gradually releases oxygen without requiring electronic components. Utilising the Madagascar hissing cockroach (Gromphadorhina portentosa) as the biological platform, a wearable diving suit comprising a flexible shell, an oxygen generator and oxygen delivery tubes was designed enabling survival and task execution during prolonged submersion (Fig. 1A). The flexible abdominal shell insulates the abdominal spiracles from surrounding water and acts as an oxygen storage and transport tank (Fig. 1B, i). The oxygen generator is a sealed chamber containing a hydrogen peroxide (H2O2) solution and a manganese dioxide (MnO2) catalyst. Under catalytic action, the H2O2 decomposes to produce oxygen (Fig. 1B, ii) to maintain the insects normal respiratory function. The oxygen delivery tubes connect the flexible shell to the cockroachs thoracic spiracles (Fig. 1B, iii), transporting the generated oxygen to the tracheae. Together, these components enable cockroaches to achieve amphibious locomotion (Fig. 1C). This study presents an amphibious cyborg insect capable of user-induced locomotion with a low-power, compact design, that enables long-duration operation in confined and cluttered terrestrialaquatic environments.
https://www.nature.com/articles/s41467-026-74235-1
It all makes sense. And it all also makes sense for a spy film, a horror film ...
eppur_se_muova
(42,985 posts)Maybe try a cybercaddisfly larva next. Or, heck, cybercrabs.
muriel_volestrangler
(107,044 posts)It's not just "can we keep an air-breathing insect alive underwater?", it's "can we direct this insect carrying our camera or other equipment in both environments?"
mike_c
(37,218 posts)...between terrestrial and freshwater environments, for example, to disperse over land before reproducing in a different body of water. Some of those have a specialized exoskeleton that holds a persistent bubble of air against the body, called a plastron. It serves as a functional gill, exchanging metabolic CO2 for O2 dissolved in the surrounding water. These also have some environmental restrictions, like needing reasonably well oxygenated water, but I wonder whether such a species pre-adapted to both terrestrial and aquatic habitats might be a natural choice for this sort of thing.
In practice, well studied systems tend to become entrenched, so since manipulating the behavior of large large terrestrial cockroaches is already understood, those roaches are more likely to be re-adapted to aquatic systems instead of using an aquatic taxon to begin with.
eppur_se_muova
(42,985 posts)Last edited Thu Jul 9, 2026, 12:49 AM - Edit history (1)
Although prey is usually consumed underwater in the diving bell, it is occasionally brought to the surface.
A. aquatica is the only known species of spider that spends almost all its life underwater, including resting, catching and eating prey, mating, egg laying, and overwintering. It only briefly surfaces to replenish its oxygen supply and occasionally will bring prey to the surface.[9][10][11][12]
https://en.wikipedia.org/wiki/Diving_bell_spider

The diving bell spider Argyroneta aquatica having just left its diving bell bubble. Credit: Geoff Oxford
Note the bubble of trapped air around its abdomen -- its own 'aqualung'.
Natural selection beat them to it by a couple of million years. And no, spiders aren't insects, but the same principles should apply.
mike_c
(37,218 posts)I was wondering what they did about the thoracic spiracles. It appears they insert auxiliary O2 tubes directly into the spiracles. I wonder whether they tried closing them off entirely? Since the whole tracheal system is internally contiguous, I think it would be simpler to just seal the thoracic spiracles and rely on the abdominal ones.
slightlv
(8,274 posts)gods knows what he could do with it... or blame on it!