Title :
Controlled microtubules transport on patterned non-fouling surfaces
Author :
Lipscomb, R.C. ; Clemmens, J. ; Hanein, Y. ; Holl, M.R. ; Voge, V. ; Ratner, B.D. ; Denton, D.D. ; Böhringer, K.F.
Author_Institution :
Dept. of Electr. Eng., Washington Univ., Seattle, WA, USA
fDate :
6/24/1905 12:00:00 AM
Abstract :
Described is a lithographic technique used to realize high resolution tracks of the motor protein kinesin inside flow cells. The process consists of patterns of plasma polymerized PEG-like non-fouling coating on a fouling glass substrate. When in contact with a coated surface, proteins adhere exclusively to the fouling areas, thus forming kinesin tracks suited for microtubule guidance. Parallel transport along smooth kinesin track was observed for over 250 μm. A method has been developed to seal the substrates with molded silicon flow channels in order to allow convenient control of reagent introduction and immobilization processes. Complete kinesin and BSA immobilization protocols, comprised of initial rinse, protein introduction, immobilization and final rinse have been successfully demonstrated
Keywords :
biological techniques; cellular transport; coatings; lithography; microfluidics; proteins; 250 micron; Si; controlled microtubules transport; flow cells; fouling glass substrate; high resolution tracks; immobilization processes; lithographic technique; molded silicon flow channels; motor protein kinesin; parallel transport; patterned nonfouling surfaces; polymerized PEG-like nonfouling coating; reagent introduction; Biomedical engineering; Bovine; Chemical engineering; Coatings; Glass; Lithography; Neurons; Plasma chemistry; Protein engineering; Resists;
Conference_Titel :
Microtechnologies in Medicine & Biology 2nd Annual International IEEE-EMB Special Topic Conference on
Conference_Location :
Madison, WI
Print_ISBN :
0-7803-7480-0
DOI :
10.1109/MMB.2002.1002257
