Non-linear multivariate curve resolution analysis of voltammetric pH titrations.

A new chemometric approach is put forward, dealing with the non-linear behaviour observed in the multivariate curve resolution (MCR) analysis of certain overlapping voltammetric signals obtained in titrations of metal complexes where pH is progressively changed. In such cases, non-reversible reduction signals move along the potential axis as a consequence of the involvement of H(+)-ions in the electrochemical process and cause a dramatic loss of linearity, which hinders accurate MCR analysis. The method proposed is based on the least-squares fitting of peak potential vs. pH datasets to parametric linear and sigmoid functions through the decomposition of the data matrix into both a concentration profile matrix and a unit signal matrix, in a similar way as in the alternating least-squares algorithm of MCR (ALS). Such calculations are carried out through several home-made Matlab programs which are freely available as Supplementary Material of the present work. The fitted parameters, along with the evolution of resolved concentrations and potential shifts with pH, provide valuable information on the complexation/reduction processes. The method is tested first on the relatively simple Cd(II)-NTA system and then applied to the study of the binding of Cd(II)-ions by glutathione (gamma-Glu-Cys-Gly, GSH) and the phytochelatin PC(2) ((gamma-Glu-Cys)(2)-Gly).

[1]  C. Bessant,et al.  Multivariate Data Analysis in Electroanalytical Chemistry , 2002 .

[2]  B. Kowalski,et al.  Selectivity, local rank, three‐way data analysis and ambiguity in multivariate curve resolution , 1995 .

[3]  M. Esteban,et al.  Combined use of the potential shift correction and the simultaneous treatment of spectroscopic and electrochemical data by multivariate curve resolution: analysis of a Pb(II)-phytochelatin system. , 2008, The Analyst.

[4]  Miquel Esteban,et al.  Multivariate curve resolution with alternating least squares optimisation: a soft-modelling approach to metal complexation studies by voltammetric techniques , 2000 .

[5]  M. Esteban,et al.  Chemometrics for the analysis of voltammetric data , 2006 .

[6]  J. Koryta Kinetik der elektrodenvorgänge von komplexen in der polarographie III. Durchtritts- und dissoziationsreaktion des komplexes , 1959 .

[7]  R. Tauler,et al.  Study of Cd2+ complexation by the glutathione fragments Cys–Gly (CG) and γ-Glu–Cys (γ-EC) by differential pulse polarography , 2002 .

[8]  R. D. Boss,et al.  On the role of solvent in complexation equilibiria. II. The acid-base chemistry of some sulfhydryl and ammonium-containing amino acids in water—acetonitrile mixed solvents , 1979 .

[9]  I. Cukrowski Experimental and calculated complex formation curves for mixed, dynamic and semi-dynamic, metal–ligand systems. , 1999 .

[10]  R. Tauler,et al.  Complexation of cadmium by the C-terminal hexapeptide Lys-Cys-Thr-Cys-Cys-Ala from mouse metallothionein: study by differential pulse polarography and circular dichroism spectroscopy with multivariate curve resolution analysis , 1999 .

[11]  J. Heyrovský Principles of polarography , 1966 .

[12]  J. Koryta Kinetik der elektodenvorgänge von komplexen in der polarographie II. Bestimmung der komplexbildungskonstanten aus den halbstufenpotentialen kinetischer ströme , 1959 .

[13]  R. Tauler,et al.  Multivariate curve resolution analysis of voltammetric data obtained at different time windows: study of the system Cd2+–nitrilotriacetic acid , 1998 .

[14]  M. Esteban,et al.  Differential pulse voltammetric study of the complexation of Cd(II) by the phytochelatin (γ-GluCys)2Gly assisted by multivariate curve resolution , 2002 .

[15]  B. Chandravanshi,et al.  Electrochemical Behavior of N-Phenylcinnamohydroxamic Acid Incorporated into Carbon Paste Electrode and Adsorbed Metal Ions , 1998 .

[16]  Philip H. Ramsey Data Fitting in the Chemical Sciences , 1994 .

[17]  W. Heineman,et al.  An Analytical Study of the Redox Behavior of 1,10‐Phenanthroline‐5,6‐dione, its Transition‐Metal Complexes, and its N‐Monomethylated Derivative with regard to their Efficiency as Mediators of NAD(P)+ Regeneration , 1997 .

[18]  R. Tauler,et al.  CADMIUM-BINDING PROPERTIES OF GLUTATHIONE: A CHEMOMETRICAL ANALYSIS OF VOLTAMMETRIC DATA , 1997 .

[19]  Steven D. Brown,et al.  Chemometric Techniques in Electrochemistry: A Critical Review , 1993 .

[20]  H. Strasdeit,et al.  A Coordination-Chemical Basis for the Biological Function of the Phytochelatins. , 1998, Angewandte Chemie.

[21]  G. Anderegg Critical survey of stability constants of NTA complexes , 1982 .

[22]  H. Zahn,et al.  Polarographic investigations on the complexation of cadmium and zinc by thiol peptides , 1989 .

[23]  R. Tauler,et al.  Application of multivariate curve resolution to voltammetric data. Part 1. Study of Zn(II) complexation with some polyelectrolytes , 1995 .

[24]  J. Blaho,et al.  pH-Dependent metal-based redox couples as models for proton-coupled electron transfer reactions , 1998 .

[25]  M. Esteban,et al.  Potential shift correction in multivariate curve resolution of voltammetric data. General formulation and application to some experimental systems. , 2008, The Analyst.

[26]  M. Esteban,et al.  Identification of heavy metal complexes of a hexapeptide inhibitor of the human immunodeficiency virus integrase protein by using a voltammetric approach. , 2006, Analytical biochemistry.

[27]  R. Tauler,et al.  Implementation of a chemical equilibrium constraint in the multivariate curve resolution of voltammograms from systems with successive metal complexes. , 2001, The Analyst.