Haruthaithanasan, Chantarapanont, D

Haruthaithanasan, Chantarapanont, Dilokkunanant, & Suppakul,
2008). Other authors (Bennis, Chami, Chami, Bouchikhi, &
Remmal, 2004) concluded that antifungal activity of eugenol involves
alterations of both membrane and cell wall of S. cerevisiae.
Darvishi, Omidi, Bushehri, Golshani, and Smith, (2013) reported
that eugenol interferes with transporters responsible for uptake of
aromatic and branched-chain amino acids across the S. cerevisiae
cytoplasmic membrane.
Zinoviadou et al. (2015) informed that the antimicrobial
mechanism of action of UST is based on the formation of reactive
species and free radicals, as well as on cavitation. The cavitation
effect depends on liquid properties (vapour pressure, surface tension,
viscosity) and can be diminished with larger amplitudes
(Ciccolini et al. 1997; Luo et al., 2012; Lopez-Malo et al., 1999
); and
an increase in temperature above 50
C reduces the intensity of
cavitation (Lopez-Malo et al., 1999
) affecting microbial inactivation
(Ferrante et al., 2007). The lethality of UST depends on wave
amplitude, intensity, power and temperature (Guerrero et al.,
2001a; Lopez-Malo et al., 1999; L
opez-Malo et al., 2005b
) and
thermo-UTS provoked wall rupture or fragmentation, and cytological
disruption of organelles (Guerrero et al., 2001a, 2005). The
inactivation effect of UST combined with antimicrobials has been
reported to depend on the nature of antimicrobial agent and its
concentration, culture media, pH, aw, amplitude, UST power and
microorganism (Bevilacqua et al., 2014; Ferrante et al., 2007;
Gastelum et al., 2012; Guerrero, Tognon,
& Alzamora, 2001b;
Guerrero et al., 2005; Lopez-Malo et al., 2005a, 2005b
).
Our results agree with the later authors because when we
combined temperatures close to 50
C, CLEO and UST, we obtained
the highest log reduction in both juices, and we also detected that
the inactivation depended on the composition and physicochemical
properties of both studied juices.