Mediated amperometric immunosensing using single walled carbon nanotube forests

O'Connor, Máire B.; Kim, Sang Nyon; Killard, Anthony J.; Forster, Robert J.; Smyth, Malcolm R.; Papadimitrakopoulos, Fotios; Rusling, James F.

doi:10.1039/b412805b

Cited by 86 publications

(69 citation statements)

References 28 publications

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“…Carbodiimide-based covalent linking of SWNTs to amine-functionalized substrates appears to decrease the SWNT forest coverage by one to two orders of magnitude as compared to the Fe 3+ -assisted electrostatic assembly. Both methodologies have provided significant advances for electrochemical biosensors through: i) Ease of fabrication using straightforward dipping and washing steps; [78] ii) Flexible patterning schemes; [122] iii) Availability of carboxy-functionality for convenient conjugation with a variety of biomolecules; [31,35,75,124] iv) Convenient SWNT length-fractionation to tune forest height and its resistivity; [123] v) Efficient vectorial electron transfer along the nanotube length with nearby cofactors of enzymes; [35,75] and vi) Excellent hydrodynamic stability at spinning speeds in excess of several thousand rpm. [35] On the other hand, the as-grown single-and multi-walled nanotubes, using chemical vapor deposition (CVD), display much lower surface coverage (10 7 −10 9 tubes cm −2 ) and upon drying they may collapse.…”

Section: Amperometric and Voltammetric Biosensorsmentioning

confidence: 99%

“…With the electroactive enzyme tag (i.e., HRP or ALP) catalyzing the redox conversion of a substrate (i.e., H 2 O 2 or α-naphthylphosphate, respectively), the signal produced is proportional to the number of enzyme tags at a fixed substrate concentration. [124] Assuming that the sensing antigen (Ag) has the same binding constant with the electro-active Ag-HRP, the signal reduction from the displacement of Ag-HRP by Ag will be proportional to the concentration of Ag. [134] Competitive assays inherently lack good detection limits owing to the difficulty of accurately measuring the difference between two large signals near the detection limit.…”

Section: Amperometric Immunosensors Using Swnt Forestsmentioning

confidence: 99%

“…[124] Using hydroquinone (H 2 Q) as a soluble mediator, a detection limit of 2.5 pmol mL −1 was reached for HRP-labeled biotin.…”

Section: Amperometric Immunosensors Using Swnt Forestsmentioning

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: Amperometric and Voltammetric Biosensorsmentioning

confidence: 99%

Section: Amperometric Immunosensors Using Swnt Forestsmentioning

confidence: 99%

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Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

2007

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“…Rusling reported amperometric enzyme-linked immunoassays of proteins based on a vertically-aligned array of SWCNT forests [48][49][50]. A prototype amperometric immunosensor was evaluated based on the adsorption of antibodies onto perpendicularly-oriented assemblies of SWCNT forests [48].…”

Section: Cnt-based Immunosensorsmentioning

confidence: 99%

Functionalized carbon nanotubes and nanofibers for biosensing applications

Wang

Lin

2008

TrAC Trends in Analytical Chemistry

264

131

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This review summarizes recent advances in electrochemical biosensors based on carbon nanotubes (CNTs) and carbon nanofibers (CNFs) with an emphasis on applications of CNTs. CNTs and CNFs have unique electric, electrocatalytic and mechanical properties, which make them efficient materials for developing electrochemical biosensors.We discuss functionalizing CNTs for biosensors. We review electrochemical biosensors based on CNTs and their various applications (e.g., measurement of small biological molecules and environmental pollutants, detection of DNA, and immunosensing of disease biomarkers). Moreover, we outline the development of electrochemical biosensors based on CNFs and their applications. Finally, we discuss some future applications of CNTs.

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“…An electrochemical immunosensor using a mediator and single walled carbon nanotube forests as the electrode surface was demonstrated in a competitive immunoassay for detecting biotin-HRP and unlabelled biotin. In this competitive assay, labelled and unlabelled antigens competed for binding sites on the anti-biotin capture Ab [42]. The mediator chosen for this system was hydroquinone, used to facilitate a catalytic reduction of hydrogen peroxide by transferring electrons between HRP and the peroxide.…”

Section: Amperometric Sensorsmentioning

confidence: 99%

Trends and Perspectives in Immunosensors

2012

Antibodies Applications and New Developments

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Immunosensors are devices that comprise both a biomolecular recognition system, such as an antibody and its corresponding antigen, and a transducer to translate the high affinity and specific binding event into a physical signal.Antibodies are produced by an immunological response to the presence of a foreign substance called an antigen. Antibodies may be immobilised onto a variety of platforms including bulk planar surfaces and nanoparticles by either covalent or adsorption strategies. Different interfaces between the bio-components and the detector are available to monitor in 'real-time' the signal generated by biological interactions. The transducers detect, for example, the change in electron transfer, absorbance, fluorescence, refractive index, mass change or heat transfer as the antibody binds to the antigen of interest. Such analytical devices have allowed a wide range of analytes to be identified and quantified such as pathogens, toxins, environmental food contaminants and disease biomarkers.The demand for sensitive, rapid, 'on-site' techniques has taken advantage of the latest advances in microfluidics and nanotechnology. This chapter will highlight current trends in immobilisation, micro/nano-fluidics/ and transducers utilised. A number of examples outlining the exploitation of these elements in immunosensors and their successful applications will be described.

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Mediated amperometric immunosensing using single walled carbon nanotube forests

Cited by 86 publications

References 28 publications

Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

Carbon Nanotubes for Electronic and Electrochemical Detection of Biomolecules

Functionalized carbon nanotubes and nanofibers for biosensing applications

Trends and Perspectives in Immunosensors

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