Tech
Futuristic Soft-Shell Micro-Robot Ready to Navigate Insides of Our Body
Staff Reporter
First Posted: Feb 27, 2014 12:10 PM EST
They are half a millimetre in size, have a star-shaped hydrogel shell and open when they are irradiated with laser light in the near-infrared range. The new micro-robots, developed in the laboratory of Professor Brad Nelson at ETH, will potentially aid the precision delivery of drugs.
When closed, they resemble plant seedpods; when rolled open, they look like starfish. Due to their shape, these new micro-robots could well be taken for living creatures. Stefano Fusco, a doctoral student at the Institute of Robotics and Intelligent Systems (IRIS ), looked to nature for inspiration when he developed the movement mechanism that opens and closes the robot. The mechanism by which the Venus flytrap catches its insect prey served as the blueprint for the researcher’s ‘creatures’.
The small robot is not hard, but soft: it consists of two layers of hydrogel, a class of material made up of 90% water and 10% polymers. The arms of the starfish-like shell bend inwards on their own to form a capsule, which contains tiny magnetic beads coated with a cell-friendly alginate. The hydrogel bilayers are impregnated with a model drug and serve as a drug delivery platform. At the same time they protect the magnetic beads, which carry cells to the target zone.
Highly targeted drug delivery
The hydrogel robot has been tested only in-vitro thus far. Using an electromagnetic manipulation system, the researchers are able to steer the capsule towards a specific location. Once there, it is irradiated with laser light in the near-infrared range (785 nm wavelength), which causes the hydrogel to change shape. The capsule opens in just seconds and releases the tiny beads. Using this method, researchers would be able to deliver a drug, for example, to a precise location inside the body and release the drug where it is needed. The change in the shape of the micro-robot is reversible, while the sensitivity to near-infrared radiation is made possible through the use of graphene oxide that Fusco mixes in with the hydrogel “From the very beginning, our goal was to develop a specific application, which is why we chose a soft material for the micro-robot,” says Fusco, who works as a materials scientist with the robotics experts at IRIS. His study, under the direction of senior scientist Selman Sakar in collaboration with other groups at ETH Zurich and Harvard University, appeared as the cover story in the journal Advanced Materials.
The doctoral student did not have to concern himself with the navigation system ; other researchers at IRIS have been working on this topic for about a decade now. It is designed to steer and move tiny magnetic objects that do not have their own drive mechanism or power supply. The sophisticated system has become known in connection with a micro-robot used for minimally invasive eye surgery.
Improving operating depth
However, the hydrogel robot has its limitations. Fusco found out that the near-infrared radiation he uses can penetrate only about 15 mm to 15 cm into the body, depending on the tissues. For procedures in the internal organs, this is probably insufficient. The researchers therefore have developed a different mechanism that allows the capsules to open in tissue that cannot be penetrated by the laser. The ETH doctoral student has designed the hydrogel to change form in response to a magnetic pulse, allowing the micro-robots to be released deep inside the body. “The big advantage of the hydrogel is that it can be modified with various chemical additives, which enables the capsule to respond to different stimuli,” explains the materials researcher.
So far, he has tested the hydrogel capsule only in biological fluids and water and not yet in animal or human tissue. Researchers will begin thinking about applications in living organisms only when they have succeeded in making the capsule even smaller. The current size of half a millimetre prevents the micro-robot from fitting through capillaries, for example. Fusco thinks that it “will have to be shrunk at least by a factor of 10”. Another objective is to make the capsule and its contents biodegradable. The shell and beads must be bioresorbable so that they do not need to be removed from the body after use. Fusco estimates that it will probably take another three to five years of research to achieve these two goals. This second generation of hydrogel micro-robots would then be able to undergo tests on animals.
Reference:
Fusco S et al. An Integrated Microrobotic Platform for On-Demand, Targeted Therapeutic Interventions. Advanced Materials vol. 26 issue 6 February 12, 2014. p. 952-957. DOI: 10.1002/adma.201304098
See Now:
NASA's Juno Spacecraft's Rendezvous With Jupiter's Mammoth Cyclone
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First Posted: Feb 27, 2014 12:10 PM EST
They are half a millimetre in size, have a star-shaped hydrogel shell and open when they are irradiated with laser light in the near-infrared range. The new micro-robots, developed in the laboratory of Professor Brad Nelson at ETH, will potentially aid the precision delivery of drugs.
When closed, they resemble plant seedpods; when rolled open, they look like starfish. Due to their shape, these new micro-robots could well be taken for living creatures. Stefano Fusco, a doctoral student at the Institute of Robotics and Intelligent Systems (IRIS ), looked to nature for inspiration when he developed the movement mechanism that opens and closes the robot. The mechanism by which the Venus flytrap catches its insect prey served as the blueprint for the researcher’s ‘creatures’.
The small robot is not hard, but soft: it consists of two layers of hydrogel, a class of material made up of 90% water and 10% polymers. The arms of the starfish-like shell bend inwards on their own to form a capsule, which contains tiny magnetic beads coated with a cell-friendly alginate. The hydrogel bilayers are impregnated with a model drug and serve as a drug delivery platform. At the same time they protect the magnetic beads, which carry cells to the target zone.
Highly targeted drug delivery
The hydrogel robot has been tested only in-vitro thus far. Using an electromagnetic manipulation system, the researchers are able to steer the capsule towards a specific location. Once there, it is irradiated with laser light in the near-infrared range (785 nm wavelength), which causes the hydrogel to change shape. The capsule opens in just seconds and releases the tiny beads. Using this method, researchers would be able to deliver a drug, for example, to a precise location inside the body and release the drug where it is needed. The change in the shape of the micro-robot is reversible, while the sensitivity to near-infrared radiation is made possible through the use of graphene oxide that Fusco mixes in with the hydrogel “From the very beginning, our goal was to develop a specific application, which is why we chose a soft material for the micro-robot,” says Fusco, who works as a materials scientist with the robotics experts at IRIS. His study, under the direction of senior scientist Selman Sakar in collaboration with other groups at ETH Zurich and Harvard University, appeared as the cover story in the journal Advanced Materials.
The doctoral student did not have to concern himself with the navigation system ; other researchers at IRIS have been working on this topic for about a decade now. It is designed to steer and move tiny magnetic objects that do not have their own drive mechanism or power supply. The sophisticated system has become known in connection with a micro-robot used for minimally invasive eye surgery.
Improving operating depth
However, the hydrogel robot has its limitations. Fusco found out that the near-infrared radiation he uses can penetrate only about 15 mm to 15 cm into the body, depending on the tissues. For procedures in the internal organs, this is probably insufficient. The researchers therefore have developed a different mechanism that allows the capsules to open in tissue that cannot be penetrated by the laser. The ETH doctoral student has designed the hydrogel to change form in response to a magnetic pulse, allowing the micro-robots to be released deep inside the body. “The big advantage of the hydrogel is that it can be modified with various chemical additives, which enables the capsule to respond to different stimuli,” explains the materials researcher.
So far, he has tested the hydrogel capsule only in biological fluids and water and not yet in animal or human tissue. Researchers will begin thinking about applications in living organisms only when they have succeeded in making the capsule even smaller. The current size of half a millimetre prevents the micro-robot from fitting through capillaries, for example. Fusco thinks that it “will have to be shrunk at least by a factor of 10”. Another objective is to make the capsule and its contents biodegradable. The shell and beads must be bioresorbable so that they do not need to be removed from the body after use. Fusco estimates that it will probably take another three to five years of research to achieve these two goals. This second generation of hydrogel micro-robots would then be able to undergo tests on animals.
Reference:
Fusco S et al. An Integrated Microrobotic Platform for On-Demand, Targeted Therapeutic Interventions. Advanced Materials vol. 26 issue 6 February 12, 2014. p. 952-957. DOI: 10.1002/adma.201304098
See Now: NASA's Juno Spacecraft's Rendezvous With Jupiter's Mammoth Cyclone