posted on 2023-11-02, 21:29authored byPaul Wrede, Amirreza Aghakhani, Ugur Bozuyuk, Erdost Yildiz, Metin Sitti
Microparticle manipulation
and trapping play pivotal roles in
biotechnology. To achieve effective manipulation within fluidic flow
conditions and confined spaces, it is necessary to consider the physical
properties of microparticles and the types of trapping forces applied.
While acoustic waves have shown potential for manipulating microparticles,
the existing setups involve complex actuation mechanisms and unstable
microbubbles. Consequently, the need persists for an easily deployable
acoustic actuation setup with stable microparticles. Here, we propose
the use of hollow borosilicate microparticles possessing a rigid thin
shell, which can be efficiently trapped and manipulated using a single-lens
focused ultrasound (FUS) transducer under physiologically relevant
flow conditions. These hollow microparticles offer stability and advantageous
acoustic properties. They can be scaled up and mass-produced, making
them suitable for systemic delivery. Our research demonstrates the
successful trapping dynamics of FUS within circular tubings of varying
diameters, validating the effectiveness of the method under realistic
flow rates and ultrasound amplitudes. We also showcase the ability
to remove hollow microparticles by steering the FUS transducer against
the flow. Furthermore, we present potential biomedical applications,
such as active cell tagging and navigation in bifurcated channels
as well as ultrasound imaging in mouse cadaver liver tissue.