But this lamprey-inspired bot won’t merely be another animal-mimicking machine. Instead, it will be a “biohybrid”, a simulated sea lamprey that integrates electronic components with living animal cells. The project team hopes to create a tiny swimming machine, just a millimetre in length, that can respond to environmental cues – navigating using ambient light and following the trail of a chemical compound through the water, for instance. The micro-robot, dubbed “Cyberplasm,” could then perform hazardous underwater tasks, such as looking for submerged mines, and explore worlds inaccessible to humans.
“The idea is to build a part biological, part machine robot,” says Daniel Frankel, a chemical engineer at Newcastle University and one of the lead scientists for the project. “We’re going to do that using genetic engineering – we’re changing the way the cells work so they can be read by electronics.” This ambitious project, which began in 2009 aims to build a swimming robot with cells that have been genetically engineered to act like eyes, cells that detect chemicals, and muscles that contract, says Frankel. “All of these components will eventually work together like an artificial organism.”
Frankel’s job is to design the light- and chemical-sensitive cells that will act as Cyberplasm’s “eyes” and “nose”. To engineer the eye sensors, Frankel started with a supply of Chinese hamster ovary cells, which are commonly used in biological and medical research. Then they modified these cells by inserting a gene that makes plants responsive to light. They linked this plant DNA with another gene – common in mammalian cells –which produces nitric oxide, a gas that acts as an important signaling molecule in the body. These genetic manipulations produced hamster cells that are light-responsive; whenever light hits the cells, they respond by producing a hit of nitric oxide.
Frankel is now using the same approach to build the robot’s chemical sensors, working with Christopher Voigt, a biological engineer at MIT, to engineer hamster cells that give off nitric oxide in the presence of certain chemical compounds.
The release of nitric oxide will allow the modified mammalian cells to communicate with Cyberplasm’s electronic “brain”. When the researchers assemble the final robot, they’ll implant a nitric-oxide-sensitive electrode near the genetically engineered cells. And whenever the electrode detects a nitric oxide plume, it will send a signal to a microprocessor, which will then coordinate the robot’s movement.
To mimic the motion of sea lampreys, which essentially slither through the water like a snake, the researchers will build a robot body by attaching muscle cells from a mouse to a flexible, plastic backbone. And when it’s time for the robot to start swimming, the electronic brain will stimulate the muscle cells on either side of the artificial spine to contract and relax in a rhythmic, alternating pattern. “It will send out signals to the muscles in the same type of patterns that a sea lamprey does when it wants to swim,” Frankel says. The result: waves that propagate through the robot’s body and propel it forward.
By programming Cyberplasm to swim toward chemicals of interest, the researchers hope to create an artificial organism capable of performing remote-sensing tasks underwater – wriggling through seaweed and sniffing out pollutants, for example, or hunting down the explosives contained in sea mines.
Some journalists have trumpeted an even more a sci-fi application: the possibility that we could let these tiny, artificial eels loose inside our veins, where they’d seek out the chemical signatures of disease. Cyberplasm could eventually be used this way, the researchers say –it just won’t be anytime soon. “People start talking about applications before you actually get it working,” says Joseph Ayers, a neurophysiologist at Northeastern University who is working on the project. “The assumption that in three years we were going to build a bio-hybrid robot and have it go out and swim through your veins is not based on the reality of what it’s like to do this research.”
The research team– which includes Frankel; Voigt; Ayers; and Vladimir Parpura, a neurobiologist at the University of Alabama at Birmingham – is still working to refine the robot’s individual components. The next step is to integrate all the pieces into a single, seamless machine. It could take five years to “optimise and assemble” the robot, Frankel says.
What makes Cyberplasm so exciting, Ayers says, is that it’s “high-risk research”, a difficult project with no guarantee of success. But by seeking to create an artificial organism that seamlessly merges biological and electronic parts, the team is creating an entirely new model of what a robot can be. And they’re making those plain, old moving hunks of metal look distinctly out of date.