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Biosensor enzymatic

This group of methods can be applied to routine quality control analyses or for process control of food additives. Many publications describe new developments but few validated procedures are available in the literature. Some applications used within the food industry remain unpublished but some details are given below. A wide variety of techniques are available including biosensors, enzymatic, pH differential methods, X-ray fluorescence and NIR. [Pg.127]

Biosensors Enzymatic analysis of components and products from bioprocesses is widely utilized because this type of analysis is both selective and sensitive. To use enzymes for the automatic analysis and instrumentation of bioprocesses, various sensors using enzymatic reactions, the so-called "biosensors, have been... [Pg.222]

There are many possibilities that can be implemented in enzymatic amperometric biosensors. Enzymatic schemes including several enzymes in one layer or multiple enzymatic layers in series can be used. If the cosubstrates are involved, it may be possible to oxidize or reduce one of them as well. [Pg.223]

Due to high biocompability and large surface are of cobalt oxide nanoparticles it can be used for immobilization of other biomolecules. Flavin adenine FAD is a flavoprotein coenzyme that plays an important biological role in many oxidoreductase processes and biochemical reactions. The immobilized FAD onto different electrode surfaces provides a basis for fabrication of sensors, biosensors, enzymatic reactors and biomedical devices. The electrocatalytic oxidation of NADH on the surface of graphite electrode modified with immobilization of FAD was investigated [276], Recently we used cyclic voltammetry as simple technique for cobalt-oxide nanoparticles formation and immobilization flavin adenine dinucleotide (FAD) [277], Repeated cyclic voltammograms of GC/ CoOx nanoparticles modified electrode in buffer solution containing FAD is shown in Fig.37A. [Pg.197]

A recent study has demonstrated that new biosensors for the detection of organophosphorus compounds should enable continuous monitoring of water quality. These biosensors, enzymatic field... [Pg.879]

Point Of Care biosensors, enzymatic sensors, www.dropsens.com... [Pg.356]

In addition to the use of amperometric biosensors, enzymatic reactors inserted in the FIA system before the amperometric detector have been reported for the analysis of different analytes such as aspartame [85] in dietary food and AA [86] in multivitamin effervescent tablet and white wines. [Pg.63]

A lot of analytical techniques have been proposed in recent decades and most of them are based on enzymes, called dehydrogenases, which are not sensitive to oxygen and need cofactors such as NAD". The key problems which seriously hamper a wide commercialization of biosensors and enzymatic kits based on NAD-dependent enzymes are necessity to add exogenous cofactor (NAD" ) into the samples to be analyzed to incorporate into the biologically active membrane of sensors covalently bounded NAD" to supply the analytical technique by NAD -regeneration systems. [Pg.303]

Scanning electrochemical microscopy can also be applied to study localized biological activity, as desired, for example, for in-situ characterization of biosensors (59,60). In this mode, the tip is used to probe the biological generation or consumption of electroactive species, for example, the product of an enzymatic surface reaction. The utility of potentiometric (pH-selective) tips has also been... [Pg.50]

Electrogenerated chemiluminescence (ECL) has proved to be useful for analytical applications including organic analysis, ECL-based immunosensors, DNA probe assays, and enzymatic biosensors. In the last few years, the electrochemistry and ECL of compound semiconductor nanocrystallites have attracted much attention due to their potential applications in analytical chemistry (ECL sensors). [Pg.341]

Table 1. H202-generating enzymatic systems for chemiluminescence-based optical fibre biosensors (Abbreviations OX = oxidase, PNPase = purine nucleoside phosphorylase). Table 1. H202-generating enzymatic systems for chemiluminescence-based optical fibre biosensors (Abbreviations OX = oxidase, PNPase = purine nucleoside phosphorylase).
Absorbance- and reflectance-based measurements are widespread, as there are many enzymatic reaction products or intermediates that are colored or if not, can react with the appropriate indicator. Sensors using acetylcholinesterase for carbamate pesticides detection are an example of indirect optical fiber biosensors. This enzyme catalyses the hydrolysis of acetylcholine with concomitant decrease in pH41 ... [Pg.349]

Mainly, two principles are used in electrochemical pesticide biosensor design, either enzyme inhibition or hydrolysis of pesticide. Among these two approaches inhibition-based biosensors have been widely employed in analysis due to the simplicity and wide availability of the enzymes. The direct enzymatic hydrolysis of pesticide is also extremely attractive for biosensing, because the catalytic reaction is superior and faster than the inhibition [27],... [Pg.58]

In AChE-based biosensors acetylthiocholine is commonly used as a substrate. The thiocholine produced during the catalytic reaction can be monitored using spectromet-ric, amperometric [44] (Fig. 2.2) or potentiometric methods. The enzyme activity is indirectly proportional to the pesticide concentration. La Rosa et al. [45] used 4-ami-nophenyl acetate as the enzyme substrate for a cholinesterase sensor for pesticide determination. This system allowed the determination of esterase activities via oxidation of the enzymatic product 4-aminophenol rather than the typical thiocholine. Sulfonylureas are reversible inhibitors of acetolactate synthase (ALS). By taking advantage of this inhibition mechanism ALS has been entrapped in photo cured polymer of polyvinyl alcohol bearing styrylpyridinium groups (PVA-SbQ) to prepare an amperometric biosensor for... [Pg.58]

MWNTs favored the detection of insecticide from 1.5 to 80 nM with a detection limit of InM at an inhibition of 10% (Fig. 2.7). Bucur et al. [58] employed two kinds of AChE, wild type Drosophila melanogaster and a mutant E69W, for the pesticide detection using flow injection analysis. Mutant AChE showed lower detection limit (1 X 10-7 M) than the wild type (1 X 10 6 M) for omethoate. An amperometric FIA biosensor was reported by immobilizing OPH on aminopropyl control pore glass beads [27], The amperometric response of the biosensor was linear up to 120 and 140 pM for paraoxon and methyl-parathion, respectively, with a detection limit of 20 nM (for both the pesticides). Neufeld et al. [59] reported a sensitive, rapid, small, and inexpensive amperometric microflow injection electrochemical biosensor for the identification and quantification of dimethyl 2,2 -dichlorovinyl phosphate (DDVP) on the spot. The electrochemical cell was made up of a screen-printed electrode covered with an enzymatic membrane and combined with a flow cell and computer-controlled potentiostat. Potassium hexacyanoferrate (III) was used as mediator to generate very sharp, rapid, and reproducible electric signals. Other reports on pesticide biosensors could be found in review [17],... [Pg.62]

M. Trojanowicz, Determination of pesticides using electrochemical enzymatic biosensors. [Pg.74]

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See also in sourсe #XX -- [ Pg.148 ]

See also in sourсe #XX -- [ Pg.292 , Pg.302 ]

See also in sourсe #XX -- [ Pg.148 ]

See also in sourсe #XX -- [ Pg.135 ]



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Enzymatic biosensors

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