Environmentally persistent free radicals
(EPFRs) have
been linked
to the generation of reactive oxygen species (ROS) and adverse health
effects. However, there remains a knowledge gap regarding the dynamic
changes in reactivity and toxicity during the decay process of EPFRs
emitted from incomplete solid fuel burning, which are identified as
a primary source of EPFRs. Here, we report the decay behavior of EPFRs
in particulate matter (PM) emitted from typical solid fuel burning
and the associated ROS generation and cytotoxic effects. The EPFRs
in freshly produced PM first undergo rapid exponential decay with
lifetimes ranging from 15 to 97 h and are categorized as fast-decay
EPFRs. The relative content of fast-decay EPFRs was 40.5 ± 15.3%,
while
the remaining portion, defined as slow-decay EPFRs, displayed an extremely
slow rate of decay. ROS generation and cytotoxicity decreased by 38.8
± 11.4% and 62.5 ± 12.6%, respectively, following the depletion
of fast-decay EPFRs, which were further demonstrated to be responsible
for the variations in PM reactivity and toxicity. These new findings
underscore the importance of considering the decay process of EPFRs
in assessments of PM toxicity