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Towards Low Cost Disposable High Throughput Screening Devices

Published online by Cambridge University Press:  26 February 2011

Gerardo Antonio Diaz-Quijada ,
Regis Peytavi ,
André Nantel ,
Emmanuel Roy ,
Michel G. Bergeron ,
Michel M. Dumoulin  and
Teodor Veres
Gerardo Antonio Diaz-Quijada
Affiliation:
gerardo.diaz@nrc.ca, National Research Council of Canada, Industrial Materials Institute, 75 de Mortagne, Boucherville, Quebec, J4B 6Y4, Canada, 450-641-5023, 450-641-5105
Regis Peytavi
Affiliation:
regis.peytavi@crchul.ulaval.ca, Université Laval, Centre de recherche en infectiologie, Canada
André Nantel
Affiliation:
Andre.Nantel@nrc.ca, National Research Council of Canada, Biotechnology Research Institute, Canada
Emmanuel Roy
Affiliation:
Emmanuel.Roy@nrc.ca, National Research Council of Canada, Industrial Materials Institute, Canada
Michel G. Bergeron
Affiliation:
michel.g.bergeron@crchul.ulaval.ca, Université Laval, Centre de recherche en infectiologie, Canada
Michel M. Dumoulin
Affiliation:
Michel.Dumoulin@nrc.ca, National Research Council of Canada, Industrial Materials Institute, Canada
Teodor Veres
Affiliation:
Teodor.Veres@nrc.ca, National Research Council of Canada, Industrial Materials Institute, Canada
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Abstract

Microarrays have become one of the most convenient tools for high throughput screening, supporting major advances in genomics and proteomics. Other important applications can be found in medical diagnostics, detection of biothreats, drug discovery, etc. Integration of microarrays with microfluidic devices can be highly advantageous in terms of portability, shorter analysis time and lower consumption of expensive biological analytes. Since fabrication of microfluidic devices using traditional materials such as glass is rather expensive, there is a high interest in employing polymeric materials as a low cost alternative that is suitable for mass production. A number of commercially available plastic materials were reviewed for this purpose and poly(methylmethacrylate) and Zeonor™ 1060R were identified as promising candidates, for which methods for surface modification and covalent immobilization of DNA oligonucleotide were developed. In addition, we present proof-of-concept plastic-based microarrays with and without integration with microfluidics.

Keywords

biomedicalsurface chemistrypolymer
Type
Research Article
Information
MRS Online Proceedings Library (OPL) , Volume 897: Symposium J – Biomemetic Polymers and Gels , 2005 , 0897-J03-03
Copyright
Copyright © Materials Research Society 2006

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