Toxin Enzyme Inhibition Biosensors

4 Toxin (Enzyme Inhibition) Biosensors Enzyme affectors (inhibitors and activators) that influence the rate of biocatalytic reactions can also be measured. Sensing probes for organophosphate and carbamate pesticides, for the respiratory 

FIGURE 6-11 Urea electrode, based on the immobilization of urease onto an ammonium ion-selective electrode. 

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On the one hand, protein phosphatase and acetylcholinesterase inhibition assays for microcystin and anatoxin-a(s) detection, respectively, are excellent methods for toxin analysis because of the low limits of detection that can be achieved. On the other hand, electrochemical techniques are characterised by the inherent high sensitivities. Moreover, the cost effectiveness and portability of the electrochemical devices make attractive their use in in situ analysis. The combination of enzyme inhibition and electrochemistry results in amperometric biosensors, promising as biotools for routine analysis. 

Enzymes-based biosensors are well reported in the literature for chemical toxicity screening. The sensor devices produced using enzymes are usually simple and easy to fabricate, inexpensive, and sensitive to low levels of toxicants. Immobilization of enzymes on the electrode surface can include adsorption, covalent attachment, or film deposition using a range of procedures [68-70]. The sensor system relies primarily on two enzyme mechanisms catalytic transformation of a pollutant and detection of pollutants that inhibit or mediate the enzyme s activity. In catalytic enzyme biosensor, the enzyme specific for the substrate of interest (toxin in this case)... 

Our research group is working on the development of electrochemical biosensors for the detection of microcystin and anatoxin-a(s), based on the inhibition of protein phosphatase and acetylcholinesterase, respectively. These enzyme biosensors represent useful bioanalytical tools, suitable to be used as screening techniques for the preliminary yes/no detection of the toxicity of a sample. Additionally, due to the versatility of the electrochemical approach, the strategy can be applied to the detection of other cyanobacterial toxins. 

The main drawback of acetylcholinesterase-based biosensors is the lack of selectivity because, as we mentioned, this enzyme is inhibited not only by anatoxin-a(s) but also by insecticides such as organ-ophosphorates and carbamates. This problem can be overcome by the choice of specific mutant enzymes. The combined use of mutants highly sensitive to anatoxin-a(s) and resistant to most insecticides and vice versa allows us to unambiguously discriminate between the cyanobacterial toxin and insecticides. 

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