Ak. Abass et al., Development of an amperometric sulfite biosensor based on sulfite oxidase with cytochrome c, as electron acceptor, and a screen-printed transducer, SENS ACTU-B, 62(2), 2000, pp. 148-153
An amperometric biosensor for sulfite has been developed. The enzyme sulfit
e oxidase (SOD) and electron acceptor cytochrome c are mixed into the carbo
n ink that is deposited onto the working electrode of a screen-printed stri
p. A silver-silver chloride electrode is printed alongside the working elec
trode and serves as reference/counter electrode. The electrochemical behavi
our of the biosensor surface in plain buffer has been investigated by cycli
c voltammetry. In the voltage range - 0.5 to + 0.5 V, a well-defined anodic
peak appeared at - 0.15 V and a less well-defined anodic peak at about + 0
.2 V. In the presence of SO32-, the cyclic voltammogram obtained with the b
iosensor exhibited an increase in magnitude of the more positive peak; this
was considered to result from the electrocatalytic oxidation of SO32- invo
lving SOD and the heme (Fe2+/Fe3+) centre of cytochrome c. Amperometry in s
tirred solution was used to construct a hydrodynamic voltammogram for SO32-
using the biosensor; this exhibited a single wave with a plateau beginning
at + 0.3 V. This wave corresponds to the electrocatalytic response observe
d by cyclic voltammetry. The pH and concentration of buffer components have
been optimised for the determination of SO32- by amperometry in stirred so
lution. Using these conditions, a detection limit of 4 ppm was obtained. Th
e stability of the biosensors was examined after storage in 0.05 M phosphat
e buffer pH 7.4 at 4 degrees C: it was found that the initial response was
retained for at least 45 days. The proposed biosensors were evaluated on sa
mples of unspiked and spiked estuarine, river and tap waters. The recovery
and precision data indicated that the devices could be expected to give rel
iable data in these waters. (C) 2000 Elsevier Science S.A. All rights reser
ved.