oils were also tested during a 4-we

oils were also tested during a 4-week trial under sealed condition
and its MIC was recorded at 400 mg/l (Table 1). To the contrary, the
essential oils did not cause full fungal inhibition under non-sealed
conditions even at concentrations as high as 1000 mg/l (Fig. 4AeD).
Previous studies also showed that only high concentrations of
Thyme essential oils ranging from 1000 to 5000 mg/l led to complete
inhibition against different funga species (Beygi, Barzegar,
Hamidi, & Naghdibadi, 2007; Klaric, Kosalec, Mastelic, Pieckova,
& Pepeljnak, 2007; Pina-Vaz et al., 2004).
In this study, sonication was applied for encapsulating the
essential oils by the produced nanogel. In fact, sonication fragmentized
the structure of CS-BA nanogel, and based on the selfassembly
method, and since the internal space of the nanogel
was hydrophobe, the oils was trapped in the CS-BA nanogel. The
encapsulation efficiency was measured at 87% based on the optical
density spectra of the essential oils. Based on the results obtained in
the present study, the CS-BA nanogel encapsulation significantly
improved the overall anti-fungal properties of the Thyme essential
oils as the MIC values recorded were at 300 and 500 mg/l under
sealed and non-sealed conditions, respectively (Fig. 4AeD)
(Table 1). This findingwas in line with those of several other studies
in which CS polymers were used for encapsulating essential oils in
order to enhance their antimicrobial properties (Gutierrez, Barry-
Ryan, & Bourke, 2008; Zivanovic & Chi, 2005).
The results obtained under non-sealed conditions showed that
different concentrations of free Thyme essential oils were able to
delay the growth of the fungi within a short period of time but could
not completely inhibit it. The volatility of oils and exposure to air
and other environmental factors must have affected the biological
activity of the investigated essential oils. On the other hand, the
application of encapsulating nanogels with the Thyme essential oils
led to a complete inhibition at 500 mg/l concentration. This proves
that the encapsulation had significant effects on the half-life of the
essential oils and could protect it against the environmental conditions
and mainly evaporation. Moreover, the concurrent use of
essential oils and nanogel could have resulted in controlled release
of the investigated essential oils from nanogel during the experimental
period which this in turn enhanced the antifungal effects of
the oils. On the other hand, the results of the in vivo application of
the CS-BA nanogel-encapsulated oils on tomato samples within one
month were found promising as full preservation of the samples at
concentrations above 700 mg/l was achieved