Visual offline sample stacking via moving neutralization boundary electrophoresis for analysis of heavy metal ion

In this paper, a moving neutralization boundary (MNB) electrophoresis is developed as a novel model of visual offline sample stacking for the trace analysis of heavy metal ions (HMIs). In the stacking system, the cathodic-direction motion MNB is designed with 1.95–2.8 mM HCl + 98 mM KCl in phase alfa and 4.0 mM NaOH + 96 mM KCl in phase beta. If a little of HMI is present in phase alfa, the metal ion electrically migrates towards the MNB and react with hydroxyl ion, producing precipitation and moving precipitation boundary (MPB). The alkaline precipitation is neutralized by hydrogen ion, leading to a moving eluting boundary (MEB), release of HMI from its precipitation, circle of HMI from the MEB to the MPB, and highly efficient visual stacking. As a proof of concept, a set of metal ions (Cu(II), Co(II), Mn(II), Pb(II) and Cr(III)) were chosen as the model HMIs and capillary electrophoresis (CE) was selected as an analytical tool for the experiments demonstrating the feasibility of MNB-based stacking. As shown in this paper, (i) the visual stacking model was manifested by the experiments; (ii) there was a controllable stacking of HMI in the MNB system; (iii) the offline stacking could achieve higher than 123 fold preconcentration; and (iv) the five HMIs were simultaneously stacked via the developed stacking technique for the trace analyses with the limits of detection (LOD): 3.67 × 10−3 (Cu(II)), 1.67 × 10−3 (Co(II), 4.17 × 10−3 (Mn(II)), 4.6 × 10−4 (Pb(II)) and 8.40 × 10−4 mM (Cr(III)). Even the off-line stacking was demonstrated for the use of CE-based HMI analysis, it has potential applications in atomic absorption spectroscopy (AAS), inductively coupled plasma-mass spectrometry (ICP-MS) and ion chromatography (IC) etc.

► Novel model of offline HMI stacking via moving nuetralization boundary.
► Demonstration of novel model and its relevant mechanism.
► Vivid display of visual highly efficient stacking.
► Potential uses of MNB-based stacking in CE, AAS, AFS and ICP-MS.