Peptide−Nanowire Hybrid Materials for Selective Sensing of Small Molecules

The development of a miniaturized sensing platform for the selective detection of chemical odorants could stimulate exciting scientific and technological opportunities. Oligopeptides are robust substrates for the selective recognition of a variety of chemical and biological species. Likewise, semico...

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Bibliographic Details
Published in:Journal of the American Chemical Society 2008-07, Vol.130 (29), p.9583-9589
Main Authors: McAlpine, Michael C, Agnew, Heather D, Rohde, Rosemary D, Blanco, Mario, Ahmad, Habib, Stuparu, Andreea D, Goddard, William A, Heath, James R
Format: Article
Language:English
Subjects:
Acetic Acid - analysis
Acetic Acid - chemistry
Ammonia - analysis
Ammonia - chemistry
Biosensing Techniques - methods
Microfluidic Analytical Techniques - methods
Models, Chemical
Nanowires - chemistry
Oligopeptides - chemistry
Silicon - chemistry
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Summary:The development of a miniaturized sensing platform for the selective detection of chemical odorants could stimulate exciting scientific and technological opportunities. Oligopeptides are robust substrates for the selective recognition of a variety of chemical and biological species. Likewise, semiconducting nanowires are extremely sensitive gas sensors. Here we explore the possibilities and chemistries of linking peptides to silicon nanowire sensors for the selective detection of small molecules. The silica surface of the nanowires is passivated with peptides using amide coupling chemistry. The peptide/nanowire sensors can be designed, through the peptide sequence, to exhibit orthogonal responses to acetic acid and ammonia vapors, and can detect traces of these gases from “chemically camouflaged” mixtures. Through both theory and experiment, we find that this sensing selectivity arises from both acid/base reactivity and from molecular structure. These results provide a model platform for what can be achieved in terms of selective and sensitive “electronic noses.”
ISSN:0002-7863
1272-7863
1520-5126
DOI:10.1021/ja802506d