Open AccessAptamer–field-effect transistors overcome Debye length limitations for small-molecule sensing
Author(s) -
Nako Nakatsuka,
Kyung-Ae Yang,
John M. Abendroth,
Kevin M. Cheung,
Xiaobin Xu,
Hongyan Yang,
Chuanzhen Zhao,
Bowen Zhu,
You Seung Rim,
Yang Yang,
Paul S. Weiss,
Milan N. Stojanović,
Anne M. Andrews
Publication year - 2018
Publication title -
science
Language(s) - Uncategorized
Resource type - Journals
SCImago Journal Rank - 12.556
H-Index - 1186
eISSN - 1095-9203
pISSN - 0036-8075
DOI - 10.1126/science.aao6750
Subject(s) - biomolecule , field effect transistor , debye length , molecule , transistor , transconductance , graphene , nanotechnology , aptamer , small molecule , chemistry , materials science , chemical physics , biophysics , ion , physics , voltage , biology , biochemistry , organic chemistry , quantum mechanics , genetics
Detection of analytes by means of field-effect transistors bearing ligand-specific receptors is fundamentally limited by the shielding created by the electrical double layer (the "Debye length" limitation). We detected small molecules under physiological high-ionic strength conditions by modifying printed ultrathin metal-oxide field-effect transistor arrays with deoxyribonucleotide aptamers selected to bind their targets adaptively. Target-induced conformational changes of negatively charged aptamer phosphodiester backbones in close proximity to semiconductor channels gated conductance in physiological buffers, resulting in highly sensitive detection. Sensing of charged and electroneutral targets (serotonin, dopamine, glucose, and sphingosine-1-phosphate) was enabled by specifically isolated aptameric stem-loop receptors.
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