Tag Archives: dexterous

#439224 Mobile dexterous robots: a key element ...

Kinova robotic arms, from left to right: Gen2, Gen3 lite, Gen3

Multiple companies turned to Kinova® robotic arms to create mobile platforms with manipulation capabilities to tackle many aspects of the sanitary crisis. The addition of a dexterous manipulator to mobile platforms opens the door to applications such as patient care disinfection and cleaning — critical to the fight against the virus.

Ever since the pandemic hit at the beginning of 2020, it became clear that the human resources available to address all the different fronts in the fight against the virus would be thinly stretched — especially considering the fact that these people are subject to falling ill. Mobile robots with manipulation capabilities were quickly identified as a solution to alleviate this problem by freeing skilled people from menial tasks and by allowing remote or automated work which keeps exposure to the virus to a minimum.
Multiple companies turned to Kinova robotic arms for an off-the-shelf manipulation solution suitable for mobile platforms. The history Kinova has with the assistive market is now at the core of the technology — assistive products such as motorized wheelchair-mounted robots like Jaco® were designed from the beginning to be extremely safe, user-friendly, ultra-lightweight, and power-efficient. This experience has transpired into more recent products as well. All these features do not come at the expense of performance, in fact, Kinova robots boast some of the highest payload-to-weight ratios in the industry. It does make sense that robots like these are ideal for applications involving mobile platforms and integration into products that are meant to be interacted with in non-industrial settings.
One of the companies that successfully made such an integration is Diligent, who developed a patient care robot called Moxi by integrating a Kinova Gen2 robot to a mobile platform powered by cloud-based software and artificial intelligence. Moxi is designed to help clinical staff with menial tasks that do not involve the patients, like fetching supplies, delivering samples, and distributing equipment, thus freeing skilled staff like nurses to perform more value-added tasks. Its rounded design and friendly face make interactions with it feel more natural for both the public and the hospital staff who otherwise may not be used to interacting with robots. In the current pandemic, one can easily understand how a robot such as Moxi can find its uses to alleviate the workload of healthcare workers and prove to quickly provide a return on investment for healthcare institutions.
Another type of menial task that became surprisingly important in the context of the sanitary crisis is that of cleaning. Prior to the crisis, Peanut Robotics, a startup from California that raised $2 million in 2019 was already developing a mobile platform carrying a Kinova Gen3 for cleaning commercial spaces such as restaurants, offices, hotels, and even airports. By coupling the 7 degrees of freedom robot to a vertical rail, their system can reach even the most inconvenient places. Rather than using specialized robot end-effectors to work, they take advantage of the flexibility of the robot gripper to grab tools similar to what a human would use, thus making it possible to clean an entire room with a single system, including spraying disinfectant, scrubbing, and wiping — and all that autonomously! With the current context where more surfaces need more frequent cleaning and where being in contact with objects comes with a higher risk of infection, surely we will see this kind of robot increasingly frequently.
However, not all environments are suitable for such a deep cleaning. Common areas in malls or airports for example are simply too large and possibly too crowded for such operations. It is these kinds of cases that A&K Robotics are tackling with their Autonomous Mobile Robotic UV Disinfector (Amrud) — a project selected for funding by Canada’s Advanced Manufacturing Supercluster. They combined their expertise in navigation and mobile platforms with the capabilities of a Kinova Gen3 lite robot. The compact and extremely light (less than 6 kg) robot is carried around wielding a UV light source to disinfect surfaces. Its 6 degrees of freedom allow for more than enough flexibility to waive the light source around even the most complex surfaces. A&K already made the news a few times in 2020 by deploying their solution to assist in the disinfection of floors and high-touch surfaces. Whereas when they started the project back in 2017 they did not get much traction, it is clear that the recent needs got them much deserved attention.
As the pandemic settles, an always-increasing number of applications for robots are found. Be it traditionally non-industrialized industries looking to be more resilient to staff shortages or due to the democratization of working from home, robots are becoming more commonplace than ever. Kinova, with its wide range of robot type offers, is there to assist developers and integrators accomplish their tasks and contribute to the growth of the collaboration of robots in our daily lives.

To learn more about Kinova click here. Continue reading

Posted in Human Robots

#439211 A highly dexterous robot hand with a ...

A team of researchers at Yale University's Department of Mechanical Engineering and Materials Science, has developed a robot hand that employs a caging mechanism. In their paper published in the journal Science Robotics, the group describes their research into applying a caging mechanism to robot hands and how well their demonstration models worked. Continue reading

Posted in Human Robots

#437957 Meet Assembloids, Mini Human Brains With ...

It’s not often that a twitching, snowman-shaped blob of 3D human tissue makes someone’s day.

But when Dr. Sergiu Pasca at Stanford University witnessed the tiny movement, he knew his lab had achieved something special. You see, the blob was evolved from three lab-grown chunks of human tissue: a mini-brain, mini-spinal cord, and mini-muscle. Each individual component, churned to eerie humanoid perfection inside bubbling incubators, is already a work of scientific genius. But Pasca took the extra step, marinating the three components together inside a soup of nutrients.

The result was a bizarre, Lego-like human tissue that replicates the basic circuits behind how we decide to move. Without external prompting, when churned together like ice cream, the three ingredients physically linked up into a fully functional circuit. The 3D mini-brain, through the information highway formed by the artificial spinal cord, was able to make the lab-grown muscle twitch on demand.

In other words, if you think isolated mini-brains—known formally as brain organoids—floating in a jar is creepy, upgrade your nightmares. The next big thing in probing the brain is assembloids—free-floating brain circuits—that now combine brain tissue with an external output.

The end goal isn’t to freak people out. Rather, it’s to recapitulate our nervous system, from input to output, inside the controlled environment of a Petri dish. An autonomous, living brain-spinal cord-muscle entity is an invaluable model for figuring out how our own brains direct the intricate muscle movements that allow us stay upright, walk, or type on a keyboard.

It’s the nexus toward more dexterous brain-machine interfaces, and a model to understand when brain-muscle connections fail—as in devastating conditions like Lou Gehrig’s disease or Parkinson’s, where people slowly lose muscle control due to the gradual death of neurons that control muscle function. Assembloids are a sort of “mini-me,” a workaround for testing potential treatments on a simple “replica” of a person rather than directly on a human.

From Organoids to Assembloids
The miniature snippet of the human nervous system has been a long time in the making.

It all started in 2014, when Dr. Madeleine Lancaster, then a post-doc at Stanford, grew a shockingly intricate 3D replica of human brain tissue inside a whirling incubator. Revolutionarily different than standard cell cultures, which grind up brain tissue to reconstruct as a flat network of cells, Lancaster’s 3D brain organoids were incredibly sophisticated in their recapitulation of the human brain during development. Subsequent studies further solidified their similarity to the developing brain of a fetus—not just in terms of neuron types, but also their connections and structure.

With the finding that these mini-brains sparked with electrical activity, bioethicists increasingly raised red flags that the blobs of human brain tissue—no larger than the size of a pea at most—could harbor the potential to develop a sense of awareness if further matured and with external input and output.

Despite these concerns, brain organoids became an instant hit. Because they’re made of human tissue—often taken from actual human patients and converted into stem-cell-like states—organoids harbor the same genetic makeup as their donors. This makes it possible to study perplexing conditions such as autism, schizophrenia, or other brain disorders in a dish. What’s more, because they’re grown in the lab, it’s possible to genetically edit the mini-brains to test potential genetic culprits in the search for a cure.

Yet mini-brains had an Achilles’ heel: not all were made the same. Rather, depending on the region of the brain that was reverse engineered, the cells had to be persuaded by different cocktails of chemical soups and maintained in isolation. It was a stark contrast to our own developing brains, where regions are connected through highways of neural networks and work in tandem.

Pasca faced the problem head-on. Betting on the brain’s self-assembling capacity, his team hypothesized that it might be possible to grow different mini-brains, each reflecting a different brain region, and have them fuse together into a synchronized band of neuron circuits to process information. Last year, his idea paid off.

In one mind-blowing study, his team grew two separate portions of the brain into blobs, one representing the cortex, the other a deeper part of the brain known to control reward and movement, called the striatum. Shockingly, when put together, the two blobs of human brain tissue fused into a functional couple, automatically establishing neural highways that resulted in one of the most sophisticated recapitulations of a human brain. Pasca crowned this tissue engineering crème-de-la-crème “assembloids,” a portmanteau between “assemble” and “organoids.”

“We have demonstrated that regionalized brain spheroids can be put together to form fused structures called brain assembloids,” said Pasca at the time.” [They] can then be used to investigate developmental processes that were previously inaccessible.”

And if that’s possible for wiring up a lab-grown brain, why wouldn’t it work for larger neural circuits?

Assembloids, Assemble
The new study is the fruition of that idea.

The team started with human skin cells, scraped off of eight healthy people, and transformed them into a stem-cell-like state, called iPSCs. These cells have long been touted as the breakthrough for personalized medical treatment, before each reflects the genetic makeup of its original host.

Using two separate cocktails, the team then generated mini-brains and mini-spinal cords using these iPSCs. The two components were placed together “in close proximity” for three days inside a lab incubator, gently floating around each other in an intricate dance. To the team’s surprise, under the microscope using tracers that glow in the dark, they saw highways of branches extending from one organoid to the other like arms in a tight embrace. When stimulated with electricity, the links fired up, suggesting that the connections weren’t just for show—they’re capable of transmitting information.

“We made the parts,” said Pasca, “but they knew how to put themselves together.”

Then came the ménage à trois. Once the mini-brain and spinal cord formed their double-decker ice cream scoop, the team overlaid them onto a layer of muscle cells—cultured separately into a human-like muscular structure. The end result was a somewhat bizarre and silly-looking snowman, made of three oddly-shaped spherical balls.

Yet against all odds, the brain-spinal cord assembly reached out to the lab-grown muscle. Using a variety of tools, including measuring muscle contraction, the team found that this utterly Frankenstein-like snowman was able to make the muscle component contract—in a way similar to how our muscles twitch when needed.

“Skeletal muscle doesn’t usually contract on its own,” said Pasca. “Seeing that first twitch in a lab dish immediately after cortical stimulation is something that’s not soon forgotten.”

When tested for longevity, the contraption lasted for up to 10 weeks without any sort of breakdown. Far from a one-shot wonder, the isolated circuit worked even better the longer each component was connected.

Pasca isn’t the first to give mini-brains an output channel. Last year, the queen of brain organoids, Lancaster, chopped up mature mini-brains into slices, which were then linked to muscle tissue through a cultured spinal cord. Assembloids are a step up, showing that it’s possible to automatically sew multiple nerve-linked structures together, such as brain and muscle, sans slicing.

The question is what happens when these assembloids become more sophisticated, edging ever closer to the inherent wiring that powers our movements. Pasca’s study targets outputs, but what about inputs? Can we wire input channels, such as retinal cells, to mini-brains that have a rudimentary visual cortex to process those examples? Learning, after all, depends on examples of our world, which are processed inside computational circuits and delivered as outputs—potentially, muscle contractions.

To be clear, few would argue that today’s mini-brains are capable of any sort of consciousness or awareness. But as mini-brains get increasingly more sophisticated, at what point can we consider them a sort of AI, capable of computation or even something that mimics thought? We don’t yet have an answer—but the debates are on.

Image Credit: christitzeimaging.com / Shutterstock.com Continue reading

Posted in Human Robots

#437946 Video Friday: These Robots Are Ready for ...

Video Friday is your weekly selection of awesome robotics videos, collected by your Automaton bloggers. We’ll also be posting a weekly calendar of upcoming robotics events for the next few months; here's what we have so far (send us your events!):

HRI 2021 – March 8-11, 2021 – [Online]
RoboSoft 2021 – April 12-16, 2021 – [Online]
Let us know if you have suggestions for next week, and enjoy today’s videos.

Is it too late to say, “Happy Holidays”? Yes! Is it too late for a post packed with holiday robot videos? Never!

The Autonomous Systems Lab at ETH Zurich wishes everyone a Merry Christmas and a Happy 2021!

Now you know the best kept secret in robotics- the ETH Zurich Autonomous Systems Lab is a shack in the woods. With an elevator.

[ ASL ]

We have had to do things differently this year, and the holiday season is no exception. But through it all, we still found ways to be together. From all of us at NATO, Happy Holidays. After training in the snow and mountains of Iceland, an EOD team returns to base. Passing signs reminding them to ‘Keep your distance’ due to COVID-19, they return to their office a little dejected, unsure how they can safely enjoy the holidays. But the EOD robot saves the day and finds a unique way to spread the holiday cheer – socially distanced, of course.

[ EATA ]

Season's Greetings from Voliro!

[ Voliro ]

Thanks Daniel!

Even if you don't have a robot at home, you can still make Halodi Robotics's gingerbread cookies the old fashioned way.

[ Halodi Robotics ]

Thanks Jesper!

We wish you all a Merry Christmas in this very different 2020. This year has truly changed the world and our way of living. We, Energy Robotics, like to say thank you to all our customers, partners, supporters, friends and family.

An Aibo ERS-7? Sweet!

[ Energy Robotics ]

Thanks Stefan!

The nickname for this drone should be “The Grinch.”

As it turns out, in real life taking samples of trees to determine how healthy they are is best done from the top.

[ DeLeaves ]

Thanks Alexis!

ETH Zurich would like to wish you happy holidays and a successful 2021 full of energy and health!

[ ETH Zurich ]

The QBrobotics Team wishes you all a Merry Christmas and a Happy New Year!

[ QBrobotics ]

Extend Robotics avatar twin got so excited opening a Christmas gift, using two arms coordinating, showing the dexterity and speed.

[ Extend Robotics ]

HEBI Robotics wishes everyone a great holiday season! Onto 2021!

[ HEBI Robotics ]

Christmas at the Mobile Robots Lab at Poznan Polytechnic.

[ Poznan ]

SWarm Holiday Wishes from the Hauert Lab!

[ Hauert Lab ]

Brubotics-VUB SMART and SHERO team wishes you a Merry Christmas and Happy 2021!

[ SMART ]

Success is all about teamwork! Thank you for supporting PAL Robotics. This festive season enjoy and stay safe!

[ PAL Robotics ]

Our robots wish you Happy Holidays! Starring world's first robot slackliner (Leonardo)!

[ Caltech ]

Happy Holidays and a Prosperous New Year from ZenRobotics!

[ ZenRobotics ]

Our Highly Dexterous Manipulation System (HDMS) dual-arm robot is ringing in the new year with good cheer!

[ RE2 Robotics ]

Happy Holidays 2020 from NAO!

[ SoftBank Robotics ]

Happy Holidays from DENSO Robotics!

[ DENSO ] Continue reading

Posted in Human Robots

#437901 How computer simulation will accelerate ...

Jeffrey C. Trinkle has always had a keen interest in robot hands. And, though it may be a long way off, Trinkle, who has studied robotics for more than thirty years, says he's most compelled by the prospect of robots performing “dexterous manipulation” at the level of a human “or beyond.” Continue reading

Posted in Human Robots