Author/Authors :
Choi، نويسنده , , HyunMin and Koo، نويسنده , , Kyo-in and Park، نويسنده , , Sunkil and Jeong، نويسنده , , Myoung-Jun and Kim، نويسنده , , GilSub and Park، نويسنده , , Jaehong and Lim، نويسنده , , Jung Min and Chung، نويسنده , , Woo-Jae and Lee، نويسنده , , Seung-Hwan and Jin، نويسنده , , Songwan and Lee، نويسنده , , Yoon-Sik and Park، نويسنده , , Tai Hyun and Yoo، نويسنده , , Jung Yul and Cho، نويسنده , , Dong-il “Dan”، نويسنده ,
Abstract :
This paper reports a physical and chemical surface modification technique to achieve a high tethering efficiency as well as controllability and coordinating bacterial cells. This technique was used to experimentally show multiple spin actuators, using the flagellar motion of AMB-1 bacteria. For physical surface modification, a polydimethylsiloxane (PDMS) pillar array, using a soft-lithography technique, was used. For chemical surface modification, a UV-crosslinked azido benzoic acid (ABA) modified surface was used. A high rate of tethering and adhesion of AMB-1 bacterial cells was achieved on the modified surface, and multiple spin actuation and motoring were observed.
Keywords :
bacterial adhesion , flagellar motor , Microfluidics , surface engineering
