2001
DOI: 10.1016/s0956-5663(01)00115-4
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Electrochemical biosensors: recommended definitions and classification1International Union of Pure and Applied Chemistry: Physical Chemistry Division, Commission I.7 (Biophysical Chemistry); Analytical Chemistry Division, Commission V.5 (Electroanalytical Chemistry).1

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Cited by 1,218 publications
(216 citation statements)
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“…The first one is a biomolecule responsible for recognition of the target substance through specific intermolecular binding or by means of catalytic reactions (D’Orazio, 2003). The second is the transducer that converts the biochemical response into a measurable electric signal, which is mainly proportional to analyte concentration (Higgins and Lowe, 1987; Hulanicki et al, 1991; Thévenot et al, 2001). In addition, diverse transducers can be used for conversion of the biochemical response into a quantifiable analytical signal, being classified according to their physical principles as electrochemical, electrical, optical, piezoelectric, calorimetric, acoustic, and magnetic (Hulanicki et al, 1991; Sethi, 1994; Marco and Barcelo, 1996; Thévenot et al, 2001).…”
Section: Strategies For the Development Of Amp-based Biosensorsmentioning
confidence: 99%
“…The first one is a biomolecule responsible for recognition of the target substance through specific intermolecular binding or by means of catalytic reactions (D’Orazio, 2003). The second is the transducer that converts the biochemical response into a measurable electric signal, which is mainly proportional to analyte concentration (Higgins and Lowe, 1987; Hulanicki et al, 1991; Thévenot et al, 2001). In addition, diverse transducers can be used for conversion of the biochemical response into a quantifiable analytical signal, being classified according to their physical principles as electrochemical, electrical, optical, piezoelectric, calorimetric, acoustic, and magnetic (Hulanicki et al, 1991; Sethi, 1994; Marco and Barcelo, 1996; Thévenot et al, 2001).…”
Section: Strategies For the Development Of Amp-based Biosensorsmentioning
confidence: 99%
“…They made up of a biological factor responsible for sampling, as well as a physical element (often called transducer) transmitting sampling outcome for moreover processing [5][6][7][8]. The biological element of a biosensor contains a biosensitive layer, which can either contain bioreceptors or be made of bioreceptors covalently attached to the transducer.Concerning the biological specificity conferring mechanism used one can distinguish 5 major categories of biosensors 1) Antibody/antigen based, 2) Enzymes based (mono-or multi enzyme systems) [9], 3) Nucleic acids based (DNA, cDNA, RNA) [10] 4) Based on cellular interactions (cellular structures/cells),utilisating the whole cells (microorganisms, such asbacteria, fungi, eukaryotic cells or yeast) or cell organellesor particles (mitochondria, cell walls, tissue slices) [11][12][13][14][15][16] 5) Employing biomimetic materials (e.g., synthetic bioreceptors).…”
Section: Biosensorsmentioning
confidence: 99%
“…recognizes the analyte and catalyzes a reaction leading to consumption of the analyte, while in the bioaffinity system, the bioreceptor (e.g. antibody or aptamer) specifically binds to the analyte and an equilibrium is usually reached [21]. In Table 1, common types of biosensors according to different transduction pathways are listed and the related typical biological recognizing elements which are used for each type is defined.…”
Section: Introductionmentioning
confidence: 99%