Alphabet's rebooted robotics program starts with trash-sorting machines
For all the advances made by robot companies like Boston Dynamics, we're still a long way from having robots living among humans and performing assistive tasks in our day-to-day lives. Google's parent company, Alphabet, is taking on the this challenge through its experimental X Lab, where engineers are working on The Everyday Robot Project. Alphabet's previous robotics venture was Boston Dynamics, famous for its humanoid bipeds and scary metal dogs. However, the company sold the division to Softbank in 2017.
- Scientists from Tufts University, the University of Vermont, and the Wyss Institute at Harvard have developed tiny, living organisms that can be programmed. Called "xenobots," these were made with frog stem cells.
- The , published in the scientific journal Proceedings of the National Academy of Sciences, is meant to aid development of soft robots that can repair themselves when damaged.
- Ultimately, the hope is these xenobots will be useful in , digesting toxic materials, or even delivering drugs inside our bodies.
What happens when you cross stem cells from a frog heart and frog skin? Not much—that is, until you program those cells to move. In that case, you've created a xenobot, a new type of organism that's part robot, part living thing.
High school unveils synthetic frogs for dissection in biology class
The smell of formaldehyde in classrooms may soon be a thing of the past as high schools begin to introduce synthetic animals for dissection. Students used their scalpels to dissect nearly 100 "realistic man-made" frogs for the first time last week at the J.W. Mitchell High School in New Port Richey, Florida, according to Syndaver, the Tampa-based company that manufactures human and animal models for medical simulation, education and medical device development.
And we've never seen anything like it before.
Researchers from Tufts University, the University of Vermont, and Harvard University have created the first xenobots from frog embryos after designing them with computer algorithms and physically shaping them with surgical precision. The skin-heart embryos are just one millimeter in size, but can accomplish some remarkable things for what they are, like physically squirming toward targets.
"These are novel living machines," Joshua Bongard, a computer scientist and robotics expert at the University of Vermont who co-led the new research, said in a"They're neither a traditional robot nor a known species of animal. It's a new class of artifact: a living, programmable organism."
Florida school uses synthetic frogs for science class dissection
The synthetic frogs can be reused again and again, unlike the frogs currently killed every year for dissection. "We're proud to have found a partner in SynDaver to bring this revolutionary new educational tool to life, replacing the outdated use of once-living frogs forever," said Shalin G. Gala, PETA's vice president of International Laboratory Methods. PETA estimates that millions of frogs are killed each year due to school dissections.
By studying these curious organisms, researchers hope to learn more about the mysterious world of cellular communication. Plus, these kinds of robo-organisms could possibly be the key to drug delivery in the body or greener environmental cleanup techniques.
"Most technologies are made from steel, concrete, chemicals, and plastics, which degrade over time and can produce harmful ecological and health side effects," the authors note in apublished in the scientific journal Proceedings of the National Academy of Sciences. "It would thus be useful to build technologies using self-renewing and biocompatible materials, of which the ideal candidates are living systems themselves."
Xenobots borrow their name from Xenopus laevis, the scientific name for the African clawed frog from which the researchers harvested the stem cells. To create the little organisms, which scoot around a petri dish a bit like—those tiny microorganisms that are pretty much impossible to kill—the researchers scraped living stem cells from frog embryos. These were separated into single cells and left to incubate.
The artificial skin that allows robots to feel
Robots are one step closer to gaining a human sense that has so far eluded them: Touch. © Astrid Eckert / TUM With a sense of touch robots would be able to respond to physical contact, and could work more closely with humans Scientists last month unveiled an artificial skin that enables robots to feel and respond to physical contact, a skill that will be needed as they come in increasingly close contact with people.In 2017, manufacturers worldwide used roughly 85 industrial robots per 10,000 employees, according to a report by the International Federation of Robotics.
They differentiated the stem cells into two different kinds: heart and skin cells. The heart cells are capable of expanding and contracting, which ultimately aids the xenobot in locomotion, and the skin cells provideNext, using tiny forceps and an even smaller electrode, the scientists cut the cells and joined them together under a microscope in designs that were specified by a computer algorithm.
Interestingly, the two different kinds of cells did merge together well and created xenobots that could explore their watery environment for days or weeks. When flipped like a turtle on its shell, though, they could no longer move.
Other tests showed whole groups of xenobots are capable of moving in circles and pushing small items to a central location all on their own, without intervention. Some were built with holes in the center to reduce drag and the researchers even tried using the hole as a pouch to let the xenobots carry objects. Bongard said it's a step in the right direction for computer-designed organisms that can intelligently deliver drugs in the body.
Two Pigs with Monkey Cells Born in China
They only lived for a week, but they mark another step toward growing human organs in animals."This is the first report of full-term pig-monkey chimeras,” Tang Hai, one of the researchers who worked on the pigs at the State Key Laboratory of Stem Cell and Reproductive Biology in Beijing, told New Scientist.
While these xenobots are capable of some spontaneous movement, they can't accomplish any coordinated efforts without the help of computers. Really, xenobots couldn't fundamentally exist without designs created through evolutionary algorithms.
Just as natural selection dictates which members of a species live and which die off—based on certain favorable or unfavorable attributes and ultimately influencing the species' characteristics—evolutionary algorithms can help find beneficial structures for the xenobots.
A team of computer scientists created a virtual world for the xenobots and then ran evolutionary algorithms to see which potential designs for the xenobots could help them move or accomplish some other goal. The algorithm looked for xenobots that performed well at those particular tasks while in a given configuration, and then bred those microorganisms with other xenobots that were consideredto survive this simulated natural selection.
Xenobots: First living robots created from stem cells
Scientists have created the world's first living, self-healing robots using stem cells from frogs. © Douglas Blackiston, Sam Kriegman A four-legged xenobot, less than a millimeter (0.04 inches) wide, built from frog stem cells. Named xenobots after the African clawed frog (Xenopus laevis) from which they take their stem cells, the machines are less than a millimeter (0.04 inches) wide -- small enough to travel inside human bodies. They can walk and swim, survive for weeks without food, and work together in groups.
In the video above, for example, you can see a simulated version of the xenobot, which is capable of forward movement. The final organism takes on a similar shape to this design and is capable of (slowly) getting around. The red and green squares at the bottom of the structure are active cells, in this case the heart stem cells, while the blueish squares represent the passive skin stem cells.
All of this design work was completed over the course of a few months on the Deep Green supercomputer cluster at the University of Vermont. After a few hundred runs of the evolutionary algorithm, the researchers filtered out the most promising designs. Then, biologists at Tufts University assembled the real xenobots in vitro.
What's the Controversy?
Anything dealing with stem cells is bound to meet at least some flack because detractors take issue with the entire premise of using, which are harvested from developing embryos.
That's compounded with other practical ethics questions, especially relating to safety and testing. For instance, should the organisms have protections similar to animals or humans when we experiment on them? Could we, ourselves, eventually require protection from the artificially produced creatures?
"When you’re creating life, you don’t have a good sense of what direction it’s going to take," Nita Farahany, who studies the ethical ramifications of new technologies at Duke University and was not involved in the study, told. "Any time we try to harness life … [we should] recognize its potential to go really poorly."
Michael Levin, a biophysicist and co-author of the study from Tufts University, said that fear of the unknown in this case is not reasonable:
"When we start to mess around with complex systems that we don't understand, we're going to get unintended consequences," he said in a press statement. "If humanity is going to survive into the future, we need to better understand how complex properties, somehow, emerge from simple rules."
At its heart, the study is a "direct contribution to getting a handle on what people are afraid of, which is unintended consequences," Levin said.
Living robots made from frog embryo cells could swim inside your body .
The tiny xenobots aren't quite an animal, and they're not a traditional robot, but they are both awesome and terrifying.Researchers from the University of Vermont and Tufts University used a supercomputer to design new life-forms using skin and heart cells from frogs. Once they had a design they thought would achieve a goal like moving forward in one direction, they harvested stem cells from frog embryos, incubated mature cells from them and then cut and joined them to create a biological model of what the supercomputer drew up.