Mechanism for the primary transformation of acetaminophen in a soil/water system

• New acetaminophen (APAP) degrading bacteria in soil were isolated and identified.
• Barely bound residues generated in the transformation of APAP in soil/water system.
• Polymerization of APAP is the main channel for its transformation at 26.5 μM.
• p-aminophenol and its oxidation oligomers were the main intermediates at 530 μM.
• Light irradiation promoted biotransformation and introduced photosensitized transformation.

The transformation of acetaminophen (APAP) in a soil/water system was systematically investigated by a combination of kinetic studies and a quantitative analysis of the reaction intermediates. Biotransformation was the predominant pathway for the elimination of APAP, whereas hydrolysis or other chemical transformation, and adsorption processes made almost no contribution to the transformation under a dark incubation. Bacillus aryabhattai strain 1-Sj-5-2-5-M, Klebsiella pneumoniae strain S001, and Bacillus subtilis strain HJ5 were the main bacteria identified in the biotransformation of APAP. The soil-to-water ratio and soil preincubation were able to alter the transformation kinetic pattern. Light irradiation promoted the overall transformation kinetics through enhanced biotransformation and extra photosensitized chemical reactions. The transformation pathways were strongly dependent on the initial concentration of APAP. The main primary transformation products were APAP oligomers and p-aminophenol, with the initial addition of 26.5 and 530 μM APAP, respectively. APAP oligomers accounted for more than 95% of transformed APAP, indicating that almost no bound residues were generated through the transformation of APAP in the soil/water system. The potential environmental risks of APAP could increase following the transformation of APAP in the soil/water system because of the higher toxicity of the transformation intermediates.

Figure optionsDownload high-quality image (196 K)Download as PowerPoint slide