INTRODUCTION

Complex multicomponent microrobots, such as microswimmers, have potential applications in electronics, microfluidic mixing, and targeted drug delivery [1]-[2]. To realize the potential of this technology, fabrication methods must be capable of making large, monodisperse populations of robots. One example of a process to fabricate microswimmers is a hybrid top-down/bottom-up manufacturing process that combines templated assembly by selective removal (TASR) with DNA nanotechnology [3]. In this process, hydrophobic interactions drive the deposition of polystyrene microspheres into size-matched, hemispherical pockets constructed from Polydimethylsiloxane (PDMS). Sonication removes improperly matched particles and DNA nanotubes connect the spheres via biotin-streptavidin binding [3]. Previously, microsphere-based robots were made from random arrangements of particles assembled via one-pot reactions or magnetic manipulation [4]-[5]. TASR improves on these methods by controlling both the size and placement of components during fabrication, resulting in precise assembly of complex, multi-component structures.