Wireless Acoustic-Surface Actuators for Miniaturized Endoscopes.
Tian QiuFabian AdamsStefano PalagiKai MeldeAndrew MarkUlrich WetterauerArkadiusz MiernikPeer FischerPublished in: ACS applied materials & interfaces (2017)
Endoscopy enables minimally invasive procedures in many medical fields, such as urology. However, current endoscopes are normally cable-driven, which limits their dexterity and makes them hard to miniaturize. Indeed, current urological endoscopes have an outer diameter of about 3 mm and still only possess one bending degree-of-freedom. In this article, we report a novel wireless actuation mechanism that increases the dexterity and that permits the miniaturization of a urological endoscope. The novel actuator consists of thin active surfaces that can be readily attached to any device and are wirelessly powered by ultrasound. The surfaces consist of two-dimensional arrays of microbubbles, which oscillate under ultrasound excitation and thereby generate an acoustic streaming force. Bubbles of different sizes are addressed by their unique resonance frequency, thus multiple degrees-of-freedom can readily be incorporated. Two active miniaturized devices (with a side length of around 1 mm) are demonstrated: a miniaturized mechanical arm that realizes two degrees-of-freedom, and a flexible endoscope prototype equipped with a camera at the tip. With the flexible endoscope, an active endoscopic examination is successfully performed in a rabbit bladder. The results show the potential medical applicability of surface actuators wirelessly powered by ultrasound penetrating through biological tissues.
Keyphrases
- magnetic resonance imaging
- ultrasound guided
- minimally invasive
- urinary tract
- healthcare
- energy transfer
- contrast enhanced ultrasound
- biofilm formation
- gene expression
- spinal cord injury
- low cost
- machine learning
- single molecule
- escherichia coli
- climate change
- high resolution
- high speed
- deep learning
- solid state
- candida albicans