posted on 2015-08-18, 00:00authored bySusana Y. Kimura, Trang Nha Vu, Yukako Komaki, Michael
J. Plewa, Benito J. Mariñas
Nitriles and amides
are two classes of nitrogenous disinfection
byproducts (DBPs) associated with chloramination that are more cytotoxic
and genotoxic than regulated DBPs. Monochloramine reacts with acetaldehyde,
a common ozone and free chlorine disinfection byproduct, to form 1-(chloroamino)ethanol.
Equilibrium (K1) and forward and reverse
rate (k1,k–1) constants for the reaction between initial reactants and 1-(chloroamino)ethanol
were determined between 2 and 30 °C. Activation energies for k1 and k–1 were 3.04 and 45.2 kJ·mol–1, respectively,
and enthalpy change for K1 was −42.1
kJ·mol–1. In parallel reactions, 1-(chloroamino)ethanol
(1) slowly dehydrated (k2) to (chloroimino)ethane
that further decomposed to acetonitrile and (2) was oxidized (k3) by monochloramine to produce N-chloroacetamide. Both reactions were acid/base catalyzed, and rate
constants were characterized at 10, 18, and 25 °C. Modeling for
drinking water distribution system conditions showed that N-chloroacetamide and acetonitrile concentrations were 5–9
times higher at pH 9.0 compared to 7.8. Furthermore, acetonitrile
concentration was found to form 7–10 times higher than N-chloroacetamide under typical monochloramine and acetaldehyde
concentrations. N-chloroacetamide cytotoxicity (LC50 = 1.78 × 10–3 M) was comparable to
dichloroacetamide and trichloroacetamide, but less potent than N,2-dichloroacetamide and chloroacetamide. While N-chloroacetamide was not found to be genotoxic, N,2-dichloroacetamide genotoxic potency (5.19 × 10–3 M) was on the same order of magnitude as chloroacetamide
and trichloroacetamide.