Scholarly Work - Center for Biofilm Engineering
Permanent URI for this collectionhttps://scholarworks.montana.edu/handle/1/9335
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Item Symmetry breaking propulsion of magnetic microspheres in nonlinearly viscoelastic fluids(Springer Nature, 2021-02) Rogowski, Louis William; Ali, Jamel; Zhang, Xiao; Wilking, James N.; Fu, Henry C.; Kim, Min JunMicroscale propulsion impacts a diverse array of fields ranging from biology and ecology to health applications, such as infection, fertility, drug delivery, and microsurgery. However, propulsion in such viscous drag-dominated fluid environments is highly constrained, with time-reversal and geometric symmetries ruling out entire classes of propulsion. Here, we report the spontaneous symmetry-breaking propulsion of rotating spherical microparticles within non-Newtonian fluids. While symmetry analysis suggests that propulsion is not possible along the fore-aft directions, we demonstrate the existence of two equal and opposite propulsion states along the sphere’s rotation axis. We propose and experimentally corroborate a propulsion mechanism for these spherical microparticles, the simplest microswimmers to date, arising from nonlinear viscoelastic effects in rotating flows similar to the rod-climbing effect. Similar possibilities of spontaneous symmetry-breaking could be used to circumvent other restrictions on propulsion, revising notions of microrobotic design and control, drug delivery, microscale pumping, and locomotion of microorganisms.Item Coupling fluid flow to hydrogel fluidic devices with reversible “pop-it” connections(Royal Society of Chemistry, 2021-01) Abbasi, Reha; LeFevre, Thomas B.; Benjamin, Aaron D.; Thornton, Isaak J.; Wilking, James N.Here, we describe a simple, reversible, plug-based connector designed to couple microfluidic tubing to a hydrogel-based fluidic device, to allow for pressurized liquid flow through the system.Item Light-Based 3D Printing of Hydrogels with High-Resolution Channels(2019-01) Benjamin, Aaron D.; Abbasi, Reha; Owens, Madison; Olsen, Robert J.; Walsh, Danica J.; LeFevre, Thomas B.; Wilking, James N.Hydrogels are soft, water-based gels with widespread applications in personal care products, medicine and biomedical engineering. Many applications require structuring the hydrogel into complex three-dimensional (3D) shapes. For these applications, light-based 3D printing methods offer exquisite control over material structure. However, the use of these methods for structuring hydrogels is underdeveloped. In particular, the ability to print hydrogel objects containing internal voids and channels is limited by the lack of well-characterized formulations that strongly attenuate light and the lack of a theoretical framework for predicting and mitigating channel occlusion. Here we present a combined experimental and theoretical approach for creating well-defined channels with any orientation in hydrogels using light-based 3D printing. This is achieved by the incorporation of photoblocker and the optimization of print conditions to ensure layer-layer adhesion while minimizing channel occlusion. To demonstrate the value of this approach we print hydrogels containing individual spiral channels with centimeter-scale length and submillimeter-scale cross-section. While the channels presented here are relatively simple, this same approach could be used to achieve more complex channel designs mimicking, for example, the complex vasculature of living organisms. The low cytotoxicity of the gel makes the formulation a promising candidate for biological applications.