Title :
Low-power, self-contained, reciprocating micropump through electrolysis and catalyst-driven recombination toward drug delivery applications
Author :
Portilla, J.M. ; Unyoung Kim
Author_Institution :
Dept. of Mech. Eng., Santa Clara Univ., Santa Clara, CA, USA
Abstract :
Implantable pumps have allowed for substantial improvements in health and are a developing discipline in biomedical engineering, with applications in drug delivery, fluid removal, and research [1-4]. Towards this end, we here propose a novel electrolytic micropump utilizing a platinum based catalyst for cyclic operation. This pump design offers advantages in terms of low power consumption, high reliability, precise flow rates, and simple addition of external micro-controllers. Our system leverages electrolysis of water followed by catalyst-driven recombination of electrolytic gases to achieve a reciprocating motion of a membrane that leads to cyclic dispensing of drug fluids, with a performance rate of approximately 0.3μL/min per mA.
Keywords :
bioMEMS; biomedical engineering; biomedical equipment; catalysts; drug delivery systems; drugs; electrolysis; health care; microcontrollers; micropumps; power consumption; prosthetics; biomedical engineering; catalyst-driven recombination; cyclic dispensing; cyclic operation; drug delivery applications; drug fluids; electrolytic micropump; external microcontrollers; flow rates; fluid removal; health improvements; implantable pumps; low-power self-contained reciprocating micropump; membrane; platinum based catalyst; power consumption; reciprocating motion; reliability; system leverages electrolysis; Actuators; Drug delivery; Gases; Micropumps; Platinum; Sensors;
Conference_Titel :
Micro Electro Mechanical Systems (MEMS), 2013 IEEE 26th International Conference on
Conference_Location :
Taipei
Print_ISBN :
978-1-4673-5654-1
DOI :
10.1109/MEMSYS.2013.6474436
