Title :
Unidirectional movement of myosin-driven beads on immobilized F-actin arrays in a microfluidic channel
Author :
Lee, Y. ; Carroll, L. ; Holland, L. ; Famouri, P.
Author_Institution :
Lane Dept. of Comput. Sci. & Electr. Eng., West Virginia Univ., Morgantown, WV, USA
Abstract :
Actin-myosin system is a basic component to perform nanoscale biological transport in cells. Myosin walks along actin filament using chemical fuel, ATP, and the polarity of F-actin decides the direction of myosin movement. The present paper demonstrates unidirectional transport of microbeads along immobilized F-actin arrays in a microchannel. To transport myosin coated microbeads to the desired direction, polarity of F-actin is oriented using biotinylated actin-capping proteins and a flow field. Streptavidin coated microfluidic channel defines the direction of the flow field and biotinylated F-actin is oriented along the flow field. This technique will lay foundation for the future applications of autonomous transport and actuation systems, whether biological or synthetic in nature at nanoscale.
Keywords :
biotransport; intelligent materials; microfluidics; molecular biophysics; molecular moments; proteins; ATP; F actin polarity; actin filament; actin-myosin system; autonomous actuation systems; autonomous transport systems; biotinylated actin capping proteins; chemical fuel; immobilized F actin arrays; myosin coated microbead transport; myosin driven bead unidirectional movement; myosin dynamics; myosin motion direction; nanoscale cellular transport; streptavidin coated microfluidic channel; Buffer storage; Cells (biology); Chemicals; Fuels; Glass; Microchannel; Microfluidics; Muscles; Nanobioscience; Proteins; actin; array; microfluidic; myosin; structural polarity; transport;
Conference_Titel :
Nanotechnology Materials and Devices Conference, 2009. NMDC '09. IEEE
Conference_Location :
Traverse City, MI
Print_ISBN :
978-1-4244-4695-7
Electronic_ISBN :
978-1-4244-4696-4
DOI :
10.1109/NMDC.2009.5167568
