Six-Helix Bundle and Triangle DNA Origami Insulator-Based
Dielectrophoresis
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Abstract
Self-assembled DNA nanostructures
have large potential for nanoelectronic
circuitry, targeted drug delivery, and intelligent sensing. Their
applications require suitable methods for manipulation and nanoscale
assembly as well as adequate concentration, purification, and separation
methods. Insulator-based dielectrophoresis (iDEP) provides an efficient
and matrix-free approach for manipulation of micro- and nanometer-sized
objects. In order to exploit iDEP for DNA nanoassemblies, a detailed
understanding of the underlying polarization and dielectrophoretic
migration is essential. Here, we explore the dielectrophoretic behavior
of six-helix bundle and triangle DNA origamis with identical sequence
but large topological difference and reveal a characteristic frequency
range of iDEP trapping. Moreover, the confinement of triangle origami
in the iDEP trap required larger applied electric fields. To elucidate
the observed DEP migration and trapping, we discuss polarizability
models for the two species according to their structural difference
complemented by numerical simulations, revealing a contribution of
the electrophoretic transport of the DNA origami species in the iDEP
trapping regions. The numerical model showed reasonable agreement
with experiments at lower frequency. However, the extension of the
iDEP trapping regions observed experimentally deviated considerably
at higher frequencies. Our study demonstrates for the first time that
DNA origami species can be successfully trapped and manipulated by
iDEP and reveals distinctive iDEP behavior of the two DNA origamis.
The experimentally observed trapping regimes will facilitate future
exploration of DNA origami manipulation and assembly at the nano-
and microscale as well as other applications of these nanoassemblies
with iDEP