Gif: ScienceRobotics <\/p>\n
Living things: Theyre mostinspiring, but also difficult things to try to replicate in robotics. With that aim, researchers in Japan have managed to designa tiny robotic system that moves like a living cell. The scientists described the robotlast week in the journal Science Robotics. <\/p>\n
The system, called a molecular robot, is about the size and consistency of an amoeba. It is a fluid-filled sac containingonlybiological and chemical componentsabout 27 of them,says Shin-ichiro Nomura, abioengineer at Tohoku University in Sendai, Japan and one of the robots inventors. The molecular componentswork in concert tostretch and change the shape of the sac, propelling it with cell-like motion through a fluid environment. The motioncan be turned on and off with DNA signals that respond to light. <\/p>\n
Other than puttering around, the amoeba-like robot cant do much. But thats the beauty of the invention, says Nomura. The bot serves as a vehicle to house whatever researchers can dream up: tiny computers, sensors, and even drugs.Outfitted with those tools, the system could then be used to explore the biomolecular environment. It could seekout toxins or check the surface of other cells or the content of a Petri dish. <\/p>\n
Nomura and his colleagues have figured out a way to package and ship the tool as a kit so that other scientists can play with the robots and incorporate their own components, he says. He hopes the platform will be used to build increasingly complex molecular robots with controllable motility. <\/p>\n
Ultimately, Nomura would like to seethe robot function inside a cell. Thats kind of a frontier,says Nomura. A robot that can dive into a cell and itsnucleus can act as a diagnostic, seeking out problems with cellular machinery. Its a little dreamy,Nomura says, but notes that his robot can bereduced in size to less than one micrometersmallenough to fit inside a cell. <\/p>\n
Researchers have developed many proof-of-concept micro- and nanoscale robots that can move and communicate within the body. Many of these tiny robots are made with biodegradable materials and are driven by magnetic, chemical, or ultrasonic forces. <\/p>\n
Nomuras molecular robot differsin that it is composed entirely of biological and chemical components, moves like a cell, and is controlled by DNA. Other molecular robots have been developed, but none with this kind of controllable motility, Nomura says. <\/p>\n
It took about a year and half and 27 different chemical components to make the molecular bot, Nomura says.Alipid membrane serves as a the malleablerobot body. Inside, specialproteins bump into the membrane, causing it to change shapekind of like bagbeing punched from the inside. <\/p>\n
The punchingonly happens when key proteins called kinesins and microtubules connect to the membrane viaanchor units. That connection is provided by light-sensitive DNA. When UV light shines on therobot, the light-sensitive DNA inside cleaves into a single strand. It can then latch onto the anchor units and the kinesin-microtubule structure, forming a bridge between them. <\/p>\n
The microtubules, which are rigid, long structures, slide along the kinesin proteins with the help ofadenosine triphosphate, or ATPthemolecule of intracellular energy transport. As they slide, they punch the bots outermembrane, causing it to change shape. <\/p>\n
With this combination of molecules,Nomura and his colleagues succeeded in mimicking the movement of a cell. But if the thing is assembledsolely withbiological components and chemically powered by ATP,can we really call it a robot?The definition of robot is wide, says Nomura. If something has a body and can sense and process information to carry outa function,its a robot, he says. <\/p>\n
Robot orcell-bot, we look forward to seeing what engineers stick inside it. <\/p>\n
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\nAmoeba-Like Robot Programmed With DNA - IEEE Spectrum<\/a><\/p>\n","protected":false},"excerpt":{"rendered":"