Stripping voltammetric techniques a

Stripping voltammetric techniques are an interesting alter-native for the detection of trace levels of heavy metals in
high saline matrices. These techniques present a significant
sensitivity due to their unique ability to preconcentrate tar-get species during the accumulation step on the working
electrode, next to its combination with pulse measurement
techniques that generate a highly favourable signal-to-background ratio. Mercury-based electrodes, such as mercury
film electrodes (MFE), and hanging mercury drop electrodes
(HMDE), have traditionally been used in stripping techniques
because of their advantages, such as high sensitivity, repro-ducibility, purity of the surface, high hydrogen overpotential,
and possibility of amalgam formation. Therefore, they have
been recognized as the most sensitive electrodes for the deter-mination of heavy metals[5]. In particular, the HMDE has
successfully been used for the determination of Pb and Cd in
seawater samples[6,7]. More recently, Süren et al. introduced
a modification in the system by preceding the differential
pulse stripping voltammetry (DPSV) by adsorptive collection
of complexes with 8-hydroxyquinoline (oxine) on to the mer-cury electrode[2]. On the other hand, several studieswith MFE
are reported[8–13]. For example, Khoo and Guo investigated
various mercury(I)/(II) salts as modifiers for carbon paste elec-trodes[8]. Inanattempt toworkwithenvironmentally friendly
metals, a comparative study of the simultaneous determina-tion of heavy metals in highly saline samples by ASV using
both mercury and bismuth film electrodes as working elec-trodes was carried out[9].
Various designs based on graphite–epoxy composite elec-trodes (GECE) for electrochemical stripping analysis of metals
have been used in our laboratories. GECE without any modi-fication have firstly been applied in metal analysis[14–16].A
GECE in the presence of bismuth in the measuring solution
[17] as well as a Bi(NO3)3–GECE[18] that represents a GECE
modified internally with bismuth nitrate salt have also been
studied and applied[19].
The couplingof disposable screen-printedelectrodes (SPEs)
with stripping techniques presents an attractive alternative to
conventional stripping analysis. SPE is related to a mass pro-duction technology based on screening of electroconductive
and insulating inks onto planar substrates (plastic, ceramic,
etc.) at a controlled thickness. The use of stripping analy-sis based SPEs eliminates the problems related to the use
of conventional electrochemical cells: the associated cum-bersome handling, the lengthy cleaning procedures and the
need for a de-aeration step, using electrochemical techniques
less influenced by oxygen interference. Moreover, SPEs related
instruments can be portable by including a compact battery
achieving a user friendly field-deployable device that allows
thedirectmonitoring of heavymetal traces inanin situcontrol
of pollution[20–23].
ASV coupled to SPEs using a variety of electrode designs
and experimental protocols were used for the detection of
Pb and Cd contained in different matrices such as natural
waters[21–27], soil extracts [21,22,27], wastewater [21,26]and
drinking waters[23,25]. On the other hand, Zen et al. devel-oped a Cu/Hg-plated screen-printed electrode for single Pb
determination contained in various waters samples, includ-ing seawater, by square wave anodic stripping voltammetry
[28]. To the best of our knowledge, simultaneous determina-tion of Cd and Pb in seawater has not been reported up to
date.
The present study focuses on the evaluation of the feasi-bility of using SPEs for the simultaneous determination of Pb
and Cd in seawater. Several parameters affecting the system,
such as the matrix effect upon the SPE response and the sta-bility of the measuring system have been studied. The results
obtained for the determination of the metal contents in real
and spiked seawater samples will be shown.
2. Experimental
2.1. Chemicals and apparatus
Heavy metals solutions were prepared by diluting AAS grade
(Panreac) Pb, Cd, Cu and Zn standard solutions. HCl (32%) was
obtained from Fluka. NaCl (99.5%) was purchased from Pan-reac. The pH was adjusted by using CaCO3(99%) (Merck).
A certified reference material (LGC6016) consisting of
estuarine water was used for validation purposes. The
certified metal values: 101±2g/kgCd, 190±4g/kgCu,
196±3g/kgPb, and 976±31g/kgMn.
The SPE sensors (from University of Florence—available
from PalmInstruments,http://www.palmsens.com) consisted
of a screen-printed electrochemical cell with three electrodes
in one single strip: a graphite working electrode modified with
a plasticizer mixed with mercury acetate, a graphite counter
electrode and a silver pseudo-reference electrode[21].
A computer-controlled Autolab PGSTAT-12 (302N-High per-formance) (potentiostat/galvanostat) with general-purposes
electrochemical software operating system (GPES version
4.9.007) from Eco Chemie B.V., The Netherlands, was used