Document Type
Presentation
Publication Date
4-10-2017
Abstract
A valveless shear-driven micro-fluidic pump design (SDMFP) for hemodynamic applications is presented in this work. One of the possible medical and biomedical applications is in-vivo hemodynamic (human blood circulation) support/assist. One or more SDMFPs can be inserted/implanted into vascular lumens in a form of a stent/duct in series and/or in parallel (bypass duct) to support blood circulation in-vivo. A comprehensive review of various micro-pump designs up to about mid 2000’s is given in [1,2]. Many of micropump designs considered are not suitable for in-vivo or even in-vitro medical/biomedical applications.
Operating principles, design, and SDMFP features are given in [3]. A particular design used in cardiovascular applications has no moving valves. SDMFP with Gourney-flap type valves to support high-pressure applications are developed for other applications. SDMFP could be fully bi-directional and can control its operation on the run using embedded microcontrollers and sensors. Estimated efficiency is high with low leakage resulting in low power consumption. Proprietary “fish-scale” surface coating ShearQ™ designs are implemented to improve unidirectional flow pumping efficiency. Bi-directional feature may be especially critical when clogging of blood vessels is detected. By automatically and temporarily switching into the reverse-mode operation and retrogressive flow, while inducing suction-head for a short time periods it is hoped that possibly blood conduits can be cleared/unclogged and the normal forward-flow operation resumed. Such may be an important feature if SDMFP is used in-vivo, such as, in coronary arteries which are prone to clogging leading to cardiac-arrest.
Department
Aviation
ISBN
9780791840672
Publication Title
Proceedings of the 2017 Design of Medical Devices Conference
Conference Name
2017 Design of Medical Devices Conference
Conference Place
Minneapolis, MN
Recommended Citation
Daidzic, N. E. (2017, April 10-13). Shear driven micro-fluidic pump for cardiovsacular applications [Conference paper]. Proceedings of the 2017 Design of Medical Devices Conference, Article DMD2017-3429. https://doi.org/10.1115/DMD2017-3429
DOI
10.1115/DMD2017-3429
Link to Publisher Version (DOI)
Publisher's Copyright and Source
Copyright © 2017 ASME.
Included in
Biomedical Devices and Instrumentation Commons, Cardiovascular System Commons, Complex Fluids Commons, Numerical Analysis and Computation Commons, Partial Differential Equations Commons, Transport Phenomena Commons
