Thanks to the power of their evolutionary algorithm, the team finally had a winning blueprint for their new life forms all they had to now was create them.Sounds simple? Well, it wasn’t.The team used tiny forceps and a microscope to painstakingly perform microsurgeryon heart and skin cells to create their novel organisms. And voilà! The researchers created their first xenobots.The bio–bots could propel themselves, moving in straight lines or in circles.They could work together, herding loose particles into tiny heaps .And when cut open, the xenobots healed themselves. Understanding exactly how cells do this is ultimately the goal behind this research.Cells are incredibly intelligent and there are so still many things that we don’t know about how they work,like how do they communicate to build complex bodies or even heal? If we could decode those signals, scientists could build smarter robots with pre-programmed tasks that would be biodegradable and biocompatible. And these little xenobots are just the first step in figuring out how to control anatomy on demand. I mean, just imagine all the applications of this type of research. If scaled up, xenobots could be used for regenerative medicine like repairing organs or growing body parts for transplant from the ground up. They could be created using a patient’s own cells,then inserted into their bloodstream and programmed to clear the plaque from clogged arteriesor to detect cancer .But the applications aren’t just limited to the medical field. The team also envisions assigning individual tasks to a swarm of xenobots to collect microplastics from the ocean or search and collect radioactive contaminants. Now, a world full of custom planet-saving xenobots sounds really cool—but you may have already asked yourself about the ethical implications for creating a totally new form of life.And you’re not alone.The team has fully acknowledged that future iterations of xenobots could include nervous systems, blood vessels, or even reproductive parts. And it’s these additions that are prompting many to wonder if xenobots should be considered more than just machines.

There’s also the tiny fact that the research is partially sponsored by DARPA’s lifelong learning machines program. Which again, has left some observers questioning the future direction of this research. However, the research team is open and encouraging of these ethical discussions in the public domain in the hope that policymakers can keep up and implement the right regulations as this science progresses. Right now, the xenobots are still really basic, and currently restricted in their reproductive abilities. And in terms of scalability, as we’ve just learned ,these bots aren’t exactly easy to create, requiring hours of microsurgery just to create one.

The next phase of the research is to develop a xenobot capable of carrying a payload using a patient’s cells to deliver medications deep within the human body without eliciting an immune response. So ultimately, these xenobots are just the first steps in trying to understand how life starts, perhaps one day providing scientists with the ability to control exactly how life forms

SUBHAJIT DAS