Hence, lipid oxidation or MDA forma

Hence, lipid oxidation or MDA formation could indicate the
damage of cell membranes in a Gþ bacterium or the damage of
both the outer lipid layer and cell membranes in a G
bacterium.
During the photocatalytic treatment, peroxides are generated on
TiO2 surface under UVA irradiation. They then react with some
intermediate compounds and generate new free radicals, such as
hydroxide (Sutherland & Gebicki, 1982; Thomast, Mehl, & Pryor,
1982). These peroxides and radicals are able to effectively
initiate a free-radical-based chain reaction of lipid oxidation in
cell surface or boundary (Maness et al., 1999). In addition, these
free radicals by themselves as well as lipid oxidation process and
products can also penetrate through cell boundary (Chaudhary
et al., 1994) and result in protein denaturation and DNA mutation
inside cells (Burcham & Kuhan, 1996), permanent cell damage,
and subsequently cell death. Maness et al. (1999)
demonstrated the occurrences of lipid oxidation in cells treated
with TiO2 under UVA irradiation. Our results in the present study
showed that nano-TiO2 resulted in significant increases in lipid
oxidation indicated by MDA formation under UVA light in both
Gþ and G
bacteria. In addition, our results also show that more
MDA was formed in M. caseolyticus cells and more reduction in its
populations than those in P. fluorescens cells during the treatment,
and lipid oxidation peaked before the maximal cell death. These
indicate that the lipid oxidation may be involved in TiO2-based
photocatalytic disinfection of bacteria. The lipids of
M. caseolyticus cells suffered more damage than those of
P. fluorescens cells. These also indirectly support the hypothesis
that free radicals generated by TiO2 may penetrate Gþ bacterial
cell walls more easily than the G
bacterial cell boundary and
therefore result in more severe lipid oxidation and cell death.