A group of College of Waterloo researchers has created sensible, superior supplies that would be the constructing blocks for a future technology of sentimental medical microrobots.
These tiny robots have the potential to conduct medical procedures, equivalent to biopsy, and cell and tissue transport, in a minimally invasive trend. They’ll transfer by way of confined and flooded environments, just like the human physique, and ship delicate and lightweight cargo, equivalent to cells or tissues, to a goal place.
The tiny smooth robots are a most of 1 centimetre lengthy and are bio-compatible and non-toxic. The robots are fabricated from superior hydrogel composites that embody sustainable cellulose nanoparticles derived from vegetation.
This analysis, led by Hamed Shahsavan, a professor within the Division of Chemical Engineering, portrays a holistic method to the design, synthesis, fabrication, and manipulation of microrobots. The hydrogel used on this work modifications its form when uncovered to exterior chemical stimulation. The power to orient cellulose nanoparticles at will allows researchers to program such shape-change, which is essential for the fabrication of practical smooth robots.
“In my analysis group, we’re bridging the previous and new,” stated Shahsavan, director of the Sensible Supplies for Superior Robotic Applied sciences (SMART-Lab). “We introduce rising microrobots by leveraging conventional smooth matter like hydrogels, liquid crystals, and colloids.”
The opposite distinctive part of this superior sensible materials is that it’s self-healing, which permits for programming a variety within the form of the robots. Researchers can reduce the fabric and paste it again collectively with out utilizing glue or different adhesives to kind totally different shapes for various procedures.
The fabric will be additional modified with a magnetism that facilitates the motion of sentimental robots by way of the human physique. As proof of idea of how the robotic would maneuver by way of the physique, the tiny robotic was moved by way of a maze by researchers controlling its motion utilizing a magnetic area.
“Chemical engineers play a crucial function in pushing the frontiers of medical microrobotics analysis,” Shahsavan stated. “Apparently, tackling the various grand challenges in microrobotics requires the skillset and data chemical engineers possess, together with warmth and mass switch, fluid mechanics, response engineering, polymers, smooth matter science, and biochemical methods. So, we’re uniquely positioned to introduce revolutionary avenues on this rising area.”
The following step on this analysis is to scale the robotic right down to submillimeter scales.
Shahsavan’s analysis group collaborated with Waterloo’s Tizazu Mekonnen, a professor from the Division of Chemical Engineering, Professor Shirley Tang, Affiliate Dean of Science (Analysis), and Amirreza Aghakhani, a professor from the College of Stuttgart in Germany.
