Carbon Nanotubes as Platforms for Biosensors with Electrochemical and Electronic Transduction

@article{PaciosPujad2012CarbonNA,
  title={Carbon Nanotubes as Platforms for Biosensors with Electrochemical and Electronic Transduction},
  author={Merc{\`e} Pacios Pujad{\'o}},
  journal={Carbon Nanotubes as Platforms for Biosensors with Electrochemical and Electronic Transduction},
  year={2012}
}
  • Mercè Pacios Pujadó
  • Published 2012
  • Materials Science
  • Carbon Nanotubes as Platforms for Biosensors with Electrochemical and Electronic Transduction

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References

Aligned carbon nanotube-DNA electrochemical sensors.

  • P. HeL. Dai
  • Chemistry, Materials Science
    Chemical communications
  • 2004
Single-strand DNA chains were chemically grafted onto aligned carbon nanotube electrodes, leading to novel aligned carbon nanotube-DNA sensors of a high sensitivity and selectivity for probing