These include a glassy carbon electrode (GCE) and a carbon paste

These include a glassy carbon electrode (GCE) and a carbon paste electrode with complexes and organic compounds, such as, Naphthol green B doped in polypyrrole film (Mohadesi & Taher, 2007), cobalt phthalocyanine nanoparticles (Wang, Xu, Tang, & Chen, 2005), poly(caffeic acid) (Li, Ren, & Luo, Atezolizumab 2007)), octacyanomolybdate-doped-poly(4-vinylpyridine) (Thangamuthu, Senthil Kumar, & Chandrasekara Pillai, 2007), ferrocene and its

derivatives (Pournaghi-Azar and Ojani, 1999, Raoof et al., 2006 and Wang and Du, 2004), vanadium oxide polypropylene carbonate (Tian et al., 2006), ruthenium oxide (Shakkthivel & Chen, 2007) and polyaniline film (Mu & Kan, 2002). Enzymes have been used to improve the selectivity of many reactions using the amperometric detection. Due to the enzymes high cost, some strategies have been reported to reduce its consumption. Recently, various ion-exchange resins have gained considerable attention not only for separation purposes but also as carriers of catalytic active substances, as enzymes (Franchini et al., 2008). These resins must meet several requirements as having a porous structure that is strong enough click here to withstand a pressure increase, usually applied in flow bioreactors, and having a chemically and physically resistant membrane material. These requirements

can be met by several aromatic and aliphatic polyamides. Therefore, resin prepared from these polymers is a suitable substrate for the immobilisation of enzymes (Watkins et al., 1995). The covalent binding of the

enzymes to the polymer matrix is one of the most prospective methods for its immobilisation. It is known that the ascorbate oxidase enzyme catalyses fast and selectively the oxidation reaction of ascorbic acid. In this work, we describe a differential amperometric determination of ascorbic acid in honey using a gold electrode modified by electrodeposition with palladium, and a tubular reactor containing the ascorbate oxidase enzyme immobilised on amberlite IRA-743. The concentrations of ascorbic acid in each sample were calculated based on the difference between the current measured before and after the enzymatic treatment. The procedure adopted to immobilise the ascorbate oxidase enzyme was quick and simple (Matos, Pedrotti, & Angnes, 2001). Amberlite IRA-173 resin was selected as support, because it has active amine Sitaxentan groups in its chemical structure. The enzyme immobilisation process begins with the addition of 100 μl of glutaraldehyde 0.1% to 250 mg of resin, and this mixture was stirred for 5 min. Subsequently, 50 units of enzymes were introduced into the mixture and stirred for an additional time of 10 min. In the next step, the resin was transferred to a tygon tubing (2.5 mm of i.d. and 25 mm long) with its extremities closed with a thin layer of glass wool to assemble the reactor. To adapt the enzymatic reactor to a FIA (flow injection analysis) system, the tubing (0.8 mm of i.d.

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