Tag Archives: Microrobot

This Magnet-Driven Microrobot Will Soon Navigate Your Bloodstream

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Researchers have revealed the development of a microrobot capable of utilizing magnets to deliver medications precisely where they are needed, as detailed in recent studies from the Swiss Zurich University of Technology.

This innovative technology has the potential to assist medical professionals in removing clots that lead to strokes, combat infections with antibiotics, and deliver cancer treatments directly to tumors without affecting other areas of the body.

The robot features a small spherical capsule made of a dissolvable gel, with iron oxide nanoparticles added to impart magnetic properties. The researchers can monitor the robots via X-ray technology.

“The blood vessels in the human brain are quite narrow, which limits the capsule’s size,” stated the lead researcher, Dr. Fabian Landers, a postdoctoral researcher at the Institute for Multiscale Robotics, ETH Zurich.

“The technical challenge lies in ensuring that such a tiny capsule possesses adequate magnetic properties.”

Watch microrobots dissolve blood clots, which are obstructions in blood vessels that can lead to strokes.

The following challenge was maneuvering the robot through a complex network of blood vessels, navigating turns, junctions, and rapid blood flow.

“It’s astonishing how much blood travels through our vessels at such high speeds,” Landers remarks. “Our navigation systems must endure all of this.”

They then devised three methods to maneuver microrobots using electromagnets. Depending on the type of magnetic force applied, the scientists could roll the robot along the container’s walls or direct it towards a specific location.

Three distinct modes utilize specific magnetic forces to navigate blood flow, rolling along vessel walls, countering currents, and moving through confluences. – Credit: ETH Zürich

Employing these strategies, microrobots are capable of traveling along or against the current at speeds of up to 4 mm per second (or 1 inch every 6 seconds).

“Magnetic fields and gradients are optimal for minimally invasive approaches as they penetrate deeply into the body without adverse effects, at least at the intensities and frequencies we apply,” noted the last author, Professor Bradley Nelson, a microrobot researcher at ETH Zurich.

Upon reaching their destination, scientists employed a high-frequency magnetic field to heat the microrobot, causing it to melt its shell and release the drug contained within.

This invention was tested using silicon models that mimicked human and animal blood vessels, as well as the brains of pigs and sheep.

The scientists’ next objective is to initiate human clinical trials, paving the way for this technology to be utilized in hospital operating rooms shortly.

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Source: www.sciencefocus.com

Microrobot swarm replicates incredible ant feats

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Robots the size of a grain of sand work together like ants

Jung Jae-wi et al.

Swarms of small robots guided by magnetic fields can coordinate and act like ants, even swarming to form floating rafts or lifting objects hundreds of times their weight. The microrobots, which are about the size of a grain of sand, could one day be able to perform tasks that larger robots cannot, such as unclogging blood vessels or delivering drugs to specific parts of the human body.

Jung Jaewi and his colleagues at South Korea's Hanyang University built the tiny, cubic-shaped robot using a mold and epoxy resin embedded with a magnetic alloy. These tiny magnetic particles allow the microrobot to be “programmed” to form different configurations after being exposed to a strong magnetic field from a specific angle. The bot is controlled by an external magnetic field and can perform rotations and other movements. This approach allowed the team to “efficiently and quickly manufacture hundreds to thousands of microrobots” with magnetic profiles designed for specific missions, Wee said.

The researchers instructed swarms of microrobots to work together to overcome obstacles five times higher than individual microrobots and form floating rafts on water. The bot also punched through a clogged tube and transported tablets weighing 2000 times their individual weight through a liquid, demonstrating potential medical applications.

“These magnetic microrobots hold great promise for minimally invasive drug delivery in confined, confined spaces,” he says. small guangdong from Vanderbilt University in Tennessee was not involved in the study. However, microrobots are not yet capable of autonomously navigating complex and narrow spaces such as arteries.

There are also safety challenges, Dong said, including the need to coat “potentially toxic” magnetic particles with human-friendly materials. Still, he says he's optimistic about future medical applications for such microrobots. When safe, bots can “effectively travel to targeted disease sites and deliver drugs locally,” making treatments more precise and effective.

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Source: www.newscientist.com