A new class of perfluorinated acid contaminants: Primary and secondary substituted perfluoroalkyl sulfonamides are acidic at environmentally and toxicologically relevant pH values

The SPARC software program was validated for nitrogen-hydrogen acidity constant estimation of primary and secondary sulfonamides against a broad suite of substituted derivatives with experimental datasets in water and dimethylsulfoxide solvent systems and across a wide pKa range. Following validation, amidic proton pKa values were estimated for all C1 through C8 congeners of five major perfluoroalkyl sulfonamide classes: unsubstituted sulfonamides, N-methyl and N-ethyl sulfonamides, sulfonamidoethanols, and sulfonamidoacetates. Branching of the perfluoroalkyl chain is expected to have substantial impacts on amide moiety acidity in these contaminant groups, with intrahomologue variability of up to four pKa units and increasing pKa values with both increasing chain branching and greater proximity of the chain branching to the sulfonamide head group. Perfluoroalkyl chain length is not predicted to have a substantial influence on sulfonamide acidity. The predicted pKa values and variability are anticipated to have substantial impacts on the environmental partitioning and degradation of these compounds, as well as the modes and magnitudes of toxicological effects. Substantial pH dependent isomeric fractionation of perfluoroalkyl sulfonamides is expected both in situ and in vivo, necessitating the incorporation of amide group acidities in multimedia environmental models and pharmacokinetic studies.

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