Dynamic reaction cell ICP-MS for determination of total As, Cr, Se and V in complex matrices: Still a challenge? A review

Mass interferences, caused by atomic or polyatomic species and having the same mass/charge ratio of the analyte, can be a severe limit for a reliable assay of trace and ultratrace elements by ICP-MS. The DRC™ technology uses a reaction gas to overcome these interferences. Reactions of charge exchange, atom transfer, adduct formation, condensation and analyte association/condensation are the main mechanisms. Interfering ions tend to react with the gas exothermally, while, the analyte reacts endothermally.Selecting the most appropriate reaction gas in DRC-ICP-MS is the very critical point for the determination of strongly interfered elements. A careful evaluation of the reaction mechanisms and the chemistry involved are required. The DRC allows the use of different gases, among them, ammonia (NH3), methane (CH4), hydrogen (H2) and oxygen (O2) are the most known, but there are other potentially useful gases like nitrous oxide (N2O), nitrogen oxide (NO), carbon dioxide (CO2), fluoromethane (CH3F), sulphur hexafluoride (SF6) and carbon disulfide (CS2).This paper provides a review on the analytical challenges for a reliable assay of As, Cr, Se and V by DRC-ICP-MS and illustrates different approaches and mechanisms involved in the analysis of polymers, biological fluids (serum, urine and whole blood), rock, soil and particulate matter.

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► Trace elements determination may be hampered by atomic or polyatomic species.
► Different interference management systems have been introduced for their removal.
► The DRC™ technology uses a reaction gas to overcome these interferences.
► The paper is a review on analytical challenges for the assay of As, Cr, Se, V.