216
■Bio-mathematics, Statistics and Nano-Technologies: Mosquito Control Strategies
12.4
Antimicrobial activity and mosquito repellency of encapsulated essential oils
221
12.5
Conclusion ................................................................
223
—————————————————————–
12.1
INTRODUCTION
Essential oils (EOs) are very promising in the biomedical industry due to their anti-
septic, antibacterial, antifungal and antioxidant properties. Especially, natural plant-based
ingredients like EOs have grown in popularity as they represent an eco-friendly and
biodegradable alternative for use in antimicrobial textile finishing. However, EOs have
shown to be difficult to achieve their full potential because of the chemical volatility and
instability they possess. This makes EOs prone to deterioration and loss of compounds
when exposed to environmental factors such as oxygen, heat, light and moisture. To over-
come these challenges, microencapsulation has been used as a viable technique to preserve
the essential biological and functional characteristics of the oils. The microencapsulation
can prevent the loss of volatile oil compounds while also allow for the controlled and sus-
tained release of the essential oils, enhancing bioavailability and efficacy against pathogens
(Chouhan et al. 2017).
Biopolymers, specifically natural occurring polysaccharides like chitosan and algi-
nates, are becoming popular carriers in encapsulation processes or nanoparticle forming
processes. The deacetylated form of chitin, chitosan, has been used to protect compounds
like EOs using methods like ionic gelation (Xu and Du 2003) and spontaneous emulsifi-
cation (Wilson et al. 2010). Keawchaoon and Yoksan (2011) prepared Carvacrol-loaded
chitosan nanoparticles using a two-step method combining emulsification and ionic gela-
tion, and showed that the resulting particles effectively inhibited the growth of E. coli, S.
aureus and Bacillus cereus with an MIC of 0.257 mg/mL and MBC of 8.225, 4.113 and
2.056 mg/ml respectively. Chitosan has also been used to successfully encapsulate oregano
EO, showing a two-phase release profile of the initial burst release and followed by a slow
drug release (Hosseini et al. 2013). Sayed et al. (2017) applied a nanoemulsion encapsu-
lating neem EO on cotton fabric and reported 71.73% and 65.69% reduction of S. aureus
and E. coli after 4 washes. In addition to their antimicrobial activity, a number of EOs also
possess mosquito repellent properties. Azeem et al. (2019) reported greater than 50% re-
pellency of Aedes aegypti mosquitos by Conyza sumatrensis, Erigeron canadensis, Mentha
spicata, Parthenium hysterophorus and Tagetes minuta EOs. M. spicata EO demonstrated
complete (100%) repellency and was comparable in activity to the commercially available
mosquito repellent N,N-diethyl-3-methylbenzamide (DEET). Specos et al. (2010) reported
greater than 90% repellency for up to 21 days when cotton fabric was treated with microen-
capsulated citronella EO.
Alginates are natural polymers extracted from brown algae and have been widely used
in the form of sodium alginate to encapsulate pharmaceutical actives and EO’s such as