Label-Free Protein Biosensor Based on Aptamer-Modified Carbon Nanotube Field-Effect Transistors

Maehashi, Kenzo; Katsura, Taiji; Kerman, Kağan; Takamura, Yuzuru; Matsumoto, Kazuhiko; Tamiya, Eiichi

doi:10.1021/ac060830g

Cited by 645 publications

(513 citation statements)

References 43 publications

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“…[23,91] Drop casting, [95] dielectrophoresis, [96] and CVD growth [23,91,92,94,[97][98][99] have been employed for the fabrication of dispersed SWNT networks, although the latter approach is gaining greater acceptance owing to the ease of attaining bundle-free structures. Microlithography [92,94,98] and electron beam (e-beam) lithography [97] are typically employed to pattern source and drain contacts, although shadow mask metal evaporation is also used. [23,91] Figure 3a 4 and a 5 illustrate the typical gate configurations for SWNT-FET biosensors.…”

Section: Cnt Characterizationmentioning

confidence: 99%

“…By integrating divalent cations and large Schottky contact areas, pM detection limits for DNA hybridization [92] and antibody-antigen binding [23,91] have been achieved. Aptamers (synthetic DNA or RNA strands designed to recognize amino acids, drugs, and proteins) were utilized to detect proteins, such as thrombin [94] and immunoglobulin E. [98] Their smaller size, as compared to protein receptors, was proposed to enhance the band structure changes in SWNT channel or Schottky barrier contact upon binding of analytes. A single sem-SWNT integrated FET was also utilized for detecting the pH changes down to a resolution of 0.1.…”

Section: Transistor Based Biosensorsmentioning

confidence: 99%

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Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

2007

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The unique electronic and optical properties of carbon nanotubes, in conjunction with their size and mechanically robust nature, make these nanomaterials crucial to the development of next-generation biosensing platforms. In this Review, we present recent innovations in carbon nanotube-assisted biosensing technologies, such as DNA-hybridization, protein-binding, antibody-antigen and aptamers. Following a brief introduction on the diameter-and chirality-derived electronic characteristics of single-walled carbon nanotubes, the discussion is focused on the two major schemes for electronic biodetection, namely biotransistor-and electrochemistry-based sensors. Key fabrication methodologies are contrasted in light of device operation and performance, along with strategies for amplifying the signal while minimizing nonspecific binding. This Review is concluded with a perspective on future optimization based on array integration as well as exercising a better control in nanotube structure and biomolecular integration.

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Section: Cnt Characterizationmentioning

confidence: 99%

Section: Transistor Based Biosensorsmentioning

confidence: 99%

Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

2007

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“…Maehashi et al reported an aptamer-modified carbon nanotube field-effect transistor (CNT-FET) for the detection of immunoglobulin E (IgE). 36 The introduction of IgE caused a significant I d decrease, whose magnitude was proportional to the concentration of IgE. The LOD achieved by this assay was 250 pM.…”

Section: Aptamer-based Sensing Approachesmentioning

confidence: 80%

A review on electronic bio-sensing approaches based on non-antibody recognition elements

Chen

Huang

Palaniappan³

et al. 2016

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“…Instead of using an antiIgE antibody to recognize the target IgE, an aptamer was chosen with the advantage of being insensitive to temperature and low cost. These interesting features explain the number of publications concerning IgE quantification with aptamers [10][11][12][13]. Other studies were also carried out, making use of surface plasmon resonance spectroscopy [14,15] and quartz crystal microbalance detection [15].…”

Section: Introductionmentioning

confidence: 94%

Total serum IgE quantification by microfluidic ELISA using magnetic beads

2011

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The present work reports on the quantification of total IgE in human serum using a microanalytical device whose fluidics is driven by gravity and capillary forces only. Thanks to the eight parallel microchannels in each microchip, calibration and sample analysis are performed simultaneously. A mixture of magnetic bead/analyte/second antibody is incubated off-line and then percolated through the channels where magnetic beads are trapped, enabling the separation of the solid phase from the excess reagents. The entire assay is performed in less than 1 h, and thanks to the miniaturized format, only a small volume of serum is required. Non-specific adsorption was first investigated and a blocking agent compatible with this allergy-based test was chosen. Then, the assay was optimized by determining the best magnetic bead and labelled antibody concentrations. After achievement of a calibration curve with a reference material, the protocol was applied to total IgE quantification of a patient serum sample that showed results in good accordance with those obtained by ImmunoCap® and Immunoaffinity capillary electrophoresis measurements. A detection limit of 17.5 ng ml −1 was achieved and good reproducibility (RSD<10%) inter-and intra-chip was observed.

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Label-Free Protein Biosensor Based on Aptamer-Modified Carbon Nanotube Field-Effect Transistors

Cited by 645 publications

References 43 publications

Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

A review on electronic bio-sensing approaches based on non-antibody recognition elements

Total serum IgE quantification by microfluidic ELISA using magnetic beads

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