Advances in carbon nanotube based electrochemical sensors for bioanalytical applications

Electrochemical (EC) sensing approaches have exploited the use of carbon nanotubes (CNTs) as electrode materials owing to their unique structures and properties to provide strong electrocatalytic activity with minimal surface fouling. Nanofabrication and device integration technologies have emerged...

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Bibliographic Details
Published in:Biotechnology advances 2011-03, Vol.29 (2), p.169-188
Main Authors: Vashist, Sandeep Kumar, Zheng, Dan, Al-Rubeaan, Khalid, Luong, John H.T., Sheu, Fwu-Shan
Format: Article
Language:English
Subjects:
Bioanalytical applications
Biological and medical sciences
Biomarkers - analysis
Biomolecular sensing
bioprocessing
Biosensing Techniques
Biosensors
Biotechnology
Byproducts
carbon nanotubes
CNT based electrodes
CNTs
Electrochemical sensor
Electrochemical Techniques - instrumentation
Electrochemical Techniques - methods
electrochemistry
Electrodes
electron transfer
Electron Transport
enzymatic reactions
food quality
Fouling
Fundamental and applied biological sciences. Psychology
Hydrogen peroxide
Hydrogen Peroxide - analysis
Monosaccharides - analysis
NAD (coenzyme)
NAD - analysis
Nanostructure
Nanotubes, Carbon - chemistry
oxidation
Pharmaceutical applications
Proteins - analysis
quality control
Selectivity
Sensors
thiols
wastewater treatment
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Summary:Electrochemical (EC) sensing approaches have exploited the use of carbon nanotubes (CNTs) as electrode materials owing to their unique structures and properties to provide strong electrocatalytic activity with minimal surface fouling. Nanofabrication and device integration technologies have emerged along with significant advances in the synthesis, purification, conjugation and biofunctionalization of CNTs. Such combined efforts have contributed towards the rapid development of CNT-based sensors for a plethora of important analytes with improved detection sensitivity and selectivity. The use of CNTs opens an opportunity for the direct electron transfer between the enzyme and the active electrode area. Of particular interest are also excellent electrocatalytic activities of CNTs on the redox reaction of hydrogen peroxide and nicotinamide adenine dinucleotide, two major by-products of enzymatic reactions. This excellent electrocatalysis holds a promising future for the simple design and implementation of on-site biosensors for oxidases and dehydrogenases with enhanced selectivity. To date, the use of an anti-interference layer or an artificial electron mediator is critically needed to circumvent unwanted endogenous electroactive species. Such interfering species are effectively suppressed by using CNT based electrodes since the oxidation of NADH, thiols, hydrogen peroxide, etc. by CNTs can be performed at low potentials. Nevertheless, the major future challenges for the development of CNT-EC sensors include miniaturization, optimization and simplification of the procedure for fabricating CNT based electrodes with minimal non-specific binding, high sensitivity and rapid response followed by their extensive validation using “real world” samples. A high resistance to electrode fouling and selectivity are the two key pending issues for the application of CNT-based biosensors in clinical chemistry, food quality and control, waste water treatment and bioprocessing.
ISSN:0734-9750
1873-1899
DOI:10.1016/j.biotechadv.2010.10.002