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Glucose electrode second generation

Enzyme sensors are based primarily on the immobilization of an enzyme onto an electrode, either a metallic electrode used in amperometry (e.g., detection of the enzyme-catalyzed oxidation of glucose) or an ISE employed in potentiometry (e.g., detection of the enzyme-catalyzed liberation of hydronium or ammonium ions). The first potentiometric enzyme electrode, which appeared in 1969 due to Guilbault and Montalvo [140], was a probe for urea with immobilized urease on a glass electrode. Hill and co-workers [141] described in 1986 the second-generation biosensor using ferrocene as a mediator. This device was later marketed as the glucose pen . The development of enzyme-based sensors for the detection of glucose in blood represents a major area of biosensor research. [Pg.340]

Fig. 5. Schematic illustration of the three generations of glucose electrodes (A) first generation, (B) second generation, (C) third generation. E, enzyme. Fig. 5. Schematic illustration of the three generations of glucose electrodes (A) first generation, (B) second generation, (C) third generation. E, enzyme.
Recently, the first second-generation commercial glucose sensor has been introduced by Britain s Genetics International (McCann, 1987). The sensor is based on a ferrocene-modified GOD electrode strip (see Section 3.1.1.3). For glucose determination a drop of blood is transferred to the strip which is then inserted into a pen-sized readout instrument. The response time is only 30 s and thus much more rapid than that of... [Pg.302]

Chronoamperometry is often used for measuring the diffusion coefficient of electroactive species or the surface area of the working electrode. Some analytical applications of chronoamperometry (e.g., in vivo bioanalysis) rely on pulsing of the potential of the working electrode repetitively at fixed time intervals. Some popular test strips for blood glucose (discussed in Chapter 6) involve potential-step measurements of an enzymatically liberated product (in connection with a preceding incubation reaction). Chronoamperometry can also be applied to the study of mechanisms of electrode processes. Particularly attractive for this task are reversal double-step chronoamperometric experiments (where the second step is used to probe the fate of a species generated in the first one). [Pg.69]

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Second-generation glucose biosensors GOx and electrode surfaces

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