From California Institute of Technology 29/02/24
Jellyfish can’t do much besides swim, sting, eat, and breed.
They don’t even have brains.
Yet, these simple creatures can easily journey to the depths of the oceans in a way that humans, despite all our sophistication, cannot.
But what if humans could have jellyfish explore the oceans on our behalf, reporting back what they find?
New research conducted at Caltech aims to make that a reality through the creation of what researchers call biohybrid robotic jellyfish.
These creatures, which can be thought of as ocean-going cyborgs, augment jellyfish with electronics that enhance their swimming and a prosthetic “hat” that can carry a small payload while also making the jellyfish swim in a more streamlined manner.
The work, published in the journal Bioinspiration & Biomimetics, was conducted in the lab of John Dabiri (MS ’03, PhD ’05), the Centennial Professor of Aeronautics and Mechanical Engineering, and builds on his previous work augmenting jellyfish.
Dabiri’s goal with this research is to use jellyfish as robotic data-gatherers, sending them into the oceans to collect information about temperature, salinity, and oxygen levels, all of which are affected by Earth’s changing climate.
“It’s well known that the ocean is critical for determining our present and future climate on land, and yet, we still know surprisingly little about the ocean, especially away from the surface,” Dabiri says.
“Our goal is to finally move that needle by taking an unconventional approach inspired by one of the few animals that already successfully explores the entire ocean.”
Throughout his career, Dabiri has looked to the natural world, jellyfish included, for inspiration in solving engineering challenges.
This work began with early attempts by Dabiri’s lab to develop a mechanical robot that swam like jellyfish, which have the most efficient method for traveling through water of any living creature.
Though his research team succeeded in creating such a robot, that robot was never able to swim as efficiently as a real jellyfish.
At that point, Dabiri asked himself, why not just work with jellyfish themselves?
“Jellyfish are the original ocean explorers, reaching its deepest corners and thriving just as well in tropical or polar waters,” Dabiri says.
“Since they don’t have a brain or the ability to sense pain, we’ve been able to collaborate with bioethicists to develop this biohybrid robotic application in a way that’s ethically principled.”
Previously, Dabiri’s lab implanted jellyfish with a kind of electronic pacemaker that controls the speed at which they swim.
In doing so, they found that if they made jellyfish swim faster than the leisurely pace they normally keep, the animals became even more efficient.
A jellyfish swimming three times faster than it normally would uses only twice as much energy.
This time, the research team went a step further, adding what they call a forebody to the jellies.
These forebodies are like hats that sit atop the jellyfish’s bell (the mushroom-shaped part of the animal).
The devices were designed by graduate student and lead author Simon Anuszczyk (MS ’22), who aimed to make the jellyfish more streamlined while also providing a place where sensors and other electronics can be carried.
“Much like the pointed end of an arrow, we designed 3D-printed forebodies to streamline the bell of the jellyfish robot, reduce drag, and increase swimming performance,” Anuszczyk says.
“At the same time, we experimented with 3D printing until we were able to carefully balance the buoyancy and keep the jellyfish swimming vertically.”
To test the augmented jellies’ swimming abilities, Dabiri’s lab undertook the construction of a massive vertical aquarium inside Caltech’s Guggenheim Laboratory.
Dabiri explains that the three-story tank is tall, rather than wide, because researchers want to gather data on oceanic conditions far below the surface.
“In the ocean, the round trip from the surface down to several thousand meters will take a few days for the jellyfish, so we wanted to develop a facility to study that process in the lab,” Dabiri says.
“Our vertical tank lets the animals swim against a flowing vertical current, like a treadmill for swimmers.”
“We expect the unique scale of the facility—probably the first vertical water treadmill of its kind—to be useful for a variety of other basic and applied research questions.”
Swim tests conducted in the tank show that a jellyfish equipped with a combination of the swimming pacemaker and forebody can swim up to 4.5 times faster than an all-natural jelly while carrying a payload.
The total cost is about $20 per jellyfish, Dabiri says, which makes biohybrid jellies an attractive alternative to renting a research vessel that can cost more than $50,000 a day to run.
“By using the jelly fish’s natural capacity to withstand extreme pressures in the deep ocean and their ability to power themselves by feeding, our engineering challenge is a lot more manageable,” Dabiri adds.
“We still need to design the sensor package to withstand the same crushing pressures, but that device is smaller than a softball, making it much easier to design than a full submarine vehicle operating at those depths.”
“I’m really excited to see what we can learn by simply observing these parts of the ocean for the very first time,” he adds.
Dabiri says future work may focus on further enhancing the bionic jellies’ abilities.
Right now, they can only be made to swim faster in a straight line, such as the vertical paths being designed for deep ocean measurement.
But further research may also make them steerable, so they can be directed horizontally as well as vertically.
The paper describing the work, “Electromechanical enhancement of live jellyfish for ocean exploration,” appears in the XX issue of Bioinspiration & Biomimetics.
Co-authors are Anuszczyk and Dabiri.
Funding for the research was provided by the National Science Foundation and the Charles Lee Powell Foundation.