Kynurenines are formed as part of the tryptophan metabolism and are known to exhibit pro- and anti-oxidant activities in vitro. The mapping of these biological redox-systems and identification of potential in vivo targets are therefore of great interest in cellular physiology. Here the redox-behavior of different kynurenines and anthranilic acids is evaluated electrochemically and compared to that of simple model compounds. Electrochemical results are correlated with the activity of these compounds in redox-bioassays where 3-hydroxyanthranilic acid and 3-hydroxykynurenine have significant redox-activity. The specific electrochemical redox-behavior of these two compounds, indicating a particular redox-mechanism involving the hydroxyl group, can be used to rationalize these findings. The results indicate that tryptophan metabolites can undergo a range of complex redox-reactions in vivo whose precise nature critically depends on structural details. As a consequence, some of the kynurenines have the potential to contribute to neuronal damage in brain disorders and stroke. (C) 2002 Elsevier Science (USA). All rights reserved.