Issue 2, 2008
From the journal:

Lab on a Chip

Enhancing the stability of kinesin motors for microscale transport applications

Maruti Uppalapati,a   Ying-Ming Huang,b   Thomas Nelson Jacksonb  and  William Olaf Hancock*a  

* Corresponding authors

a Department of Bioengineering, Penn State University, 229 Hallowell Building, University Park, PA, USA
E-mail: wohbio@engr.psu.edu
Fax: +1 814 863 0490

b Department of Electrical Engineering, Penn State University, 218 Electrical Engineering West Building, University Park, PA, USA
E-mail: tnj1@psu.edu
Fax: +1 814 863 8570

Abstract

Biomolecular motors, such as kinesins, have great potential for micro-actuation and micro- or nanoscale active transport when integrated into microscale devices. However, the stability and limited shelf life of these motor proteins and their associated protein filaments is a barrier to their implementation. Here we demonstrate that freeze-drying or critical point-drying kinesins adsorbed to glass surfaces extends their lifetime from days to more than four months. Further, photoresist deposition and removal can be carried out on these motor-adsorbed surfaces without loss of motor function. The methods developed here are an important step towards realizing the integration of biological motors into practical devices, and these approaches can be extended to patterning and preserving other proteins immobilized on surfaces.

Graphical abstract: Enhancing the stability of kinesin motors for microscale transport applications

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Article information

DOI
https://doi.org/10.1039/B714989A
Article type
Technical Note
Submitted
02 Oct 2007
Accepted
21 Nov 2007
First published
06 Dec 2007

Lab Chip, 2008,8, 358-361

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Enhancing the stability of kinesin motors for microscale transport applications

M. Uppalapati, Y. Huang, T. N. Jackson and W. O. Hancock, Lab Chip, 2008, 8, 358 DOI: 10.1039/B714989A

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