Magnets could guide tiny robots to deliver medicine in the body

Magnets could guide tiny robots to deliver medicine inside the body, improving on IV drug delivery that sends only 0.7% of the drug to the target tissue.
The microrobots are two-sided particles composed of a gel that can carry medicines and magnets that enable their control, measuring about 0.2 millimeters in size.
Researchers demonstrated how the microrobots can be delivered by catheter and directed to a target site with a magnetic field, improving inflammatory bowel disease treatment by delivering multiple drugs to different inflammation sites along the intestine.
The team developed a new fabrication technique that enables the creation of soft robotic systems with remarkable features and motion capabilities, significantly increasing efficiency and decreasing fabrication cost compared to traditional microrobot fabrication.
Future research aims to design new microrobots that can better navigate intricate environments, test different particles in emulsions, and explore a wider design space using computational platforms, potentially leading to more complex microrobot architectures inspired by the PMDM concept.

A blue and red magnet on a white background with magnetic dust.

Researchers have created microrobots that could deliver medicine inside the body.

The microrobots formed in droplets could enable precision-targeted drug delivery, improving on IV drug delivery that sends only 0.7% of the drug to the target tissue, according to a recent Science Advances study.

An experiment mimicking a treatment for inflammatory bowel disease, performed in a pig intestine and supported by simulations, demonstrated how the microrobots can be delivered by catheter and directed to a target site with a magnetic field.

The microrobots are two-sided particles that are composed of a gel that can carry medicines and magnets that enable their control.

In the intestine experiment, when the gel dissolved, it delivered a dye that the team detected to ensure that the chemical cargo arrived at its target site. They also tested delayed release, with some gels dissolving over longer periods of time. After delivery, the magnetic particles were directed back to the catheter and retrieved.

If dispensed at multiple locations, this function could improve inflammatory bowel disease treatment, for instance, delivering multiple drugs such as steroids, immunomodulators, and regenerative agents to different inflammation sites along the intestine.

The team also tested a minimally invasive surgery use case with a model of a human knee. The microrobots were released at an easily accessible area, then maneuvered to a difficult-to-reach target site to dispense a dye before navigating back to the entry site for extraction.

“With this work, we’re moving closer towards very advanced therapeutic delivery. Our advanced fabrication techniques enable the creation of soft robotic systems with remarkable features and motion capabilities,” says Molly Stevens, a professor of bionanoscience at the University of Oxford Institute of Biomedical Engineering and co-senior author of the study.

The particles that compose the microrobots are made by pushing a stream of gel containing magnetic particles through a narrow channel. A stream of oil enters the device and intersects the gel, pinching off evenly sized droplets. Magnetic gel particles sink to the bottom of the droplet and empty gel floats on the top.

The resulting devices, called permanent magnetic droplet-derived microrobots or PMDMs, measure about 0.2 millimeters, or the width of two human hairs.

“Traditional microrobot fabrication has very low throughput. Using microfluidics, we can generate hundreds of microrobots within minutes. It significantly increases efficiency and decreases fabrication cost,” says Yuanxiong Cao, a doctoral student in the Stevens Group at the University of Oxford and co-lead author of the study.

Simulations predicted and then fine-tuned how the microrobots move in response to specific magnetic field frequencies. Simulated obstacle courses served as a proving ground for steering the microrobots through complex environments.

The physical system uses an electromagnet controlled by commercial software, creating magnetic fields that form and move inch-worm-like chains of microrobots. The chains move in three different ways, which the researchers refer to as walking, crawling, or swinging. They can disassemble and reassemble on command, helping them traverse narrow passages or other obstructions.

“I was amazed to see how much control we have over the different particles, especially for the assembly and disassembly cycles, based on the magnetic field frequency,” says Philipp SchxF6nhxF6fer, a co-lead author of the study and research investigator of chemical engineering at the University of Michigan in the group of Sharon Glotzer, a chair of chemical engineering and co-senior author.

As a next step, the research team is designing new microrobots that can better navigate intricate environments. They will test different particles in emulsions to understand how they attract each other and study how larger particle swarms behave under varying magnetic fields.

“With our computational platform, we have now also developed a playground to explore an even wider design space, which has already triggered ideas for more complex microrobot architectures inspired by the PMDM concept,” SchxF6nhxF6fer says.

Additional researchers came from the Imperial College of London also contributed to the study.

Individual researchers were funded by the University of Oxford, China Scholarship Council, Engineering and Physical Sciences Research Council, Rosetrees Trust, British Heart Foundation, UK Research and Innovation, UK Department of Science Innovation and Technology, Royal Academy of Engineering, and US National Science Foundation.

Computations were supported by Anvil at Purdue University and Advanced Research Computing at the University of Michigan.

Source: University of Michigan

The post Magnets could guide tiny robots to deliver medicine in the body appeared first on Futurity.

link

Q. What is the potential application of microrobots in medicine?

A. Microrobots could deliver medicine inside the body, improving precision-targeted drug delivery and potentially treating inflammatory bowel disease.

Q. How do the microrobots work?

A. The microrobots are two-sided particles composed of a gel that can carry medicines and magnets that enable their control.

Q. What is the advantage of using microfluidics in fabricating microrobots?

A. Microfluidics significantly increases efficiency and decreases fabrication cost, allowing for the generation of hundreds of microrobots within minutes.

Q. How do the researchers control the movement of the microrobots?

A. The researchers use magnetic fields to control the movement of the microrobots, which can move in three different ways: walking, crawling, or swinging.

Q. What is the potential benefit of using microrobots for inflammatory bowel disease treatment?

A. Microrobots could deliver multiple drugs to different inflammation sites along the intestine, improving treatment outcomes.

Q. How were the microrobots tested in the experiment?

A. The microrobots were tested by releasing them at an easily accessible area and then maneuvering them to a difficult-to-reach target site to dispense a dye before navigating back to the entry site for extraction.

Q. What is the size of the microrobots?

A. The microrobots measure about 0.2 millimeters, or the width of two human hairs.

Q. Who are the researchers behind this study?

A. The researchers include Molly Stevens, Yuanxiong Cao, Philipp Schnhfer, and others from the University of Oxford and Imperial College of London.

Q. What is the next step for the research team?

A. The research team plans to design new microrobots that can better navigate intricate environments and test different particles in emulsions to understand how they attract each other.