Alginateand chitosan are the most u

Alginate
and chitosan are the most used polysaccharides for NP preparations.
These NPs are of particular interest due to the fact that
they can be obtained from biopolymers which are biodegradable and biocompatible. Moreover, their preparation methods involve
easily handling in aqueous medium, thereby avoiding the use
of environmentally impacting organic solvents. Chitosan (CH), a
d-glucosamine and N-acetyl-d-glucosamine linked by beta (1–4)
glycosidic bond polymer, is a deacetylated form of chitin, an abundant
polysaccharide present in crustacean shells (Berger et al.,
2004; Muzzarelli et al., 2012; Tan et al., 2005). Nanoparticles having
hydrodynamic diameters of 400 nm, made of chitosan and alginate
gels were used for encapsulating an anticancer agent, aiming
at colon targeting (Laroui et al., 2010). The nanogel was reported
to collapse on the colon area, releasing the active component and
hence resulting in the expected healing effect.
In another approach, NPs obtained by polyelectrolyte complex
formation of chitosan and poly-gama-glutamic acid were shown to
have average hydrodynamic diameters in the range from 150 nm
to 330 nm, which were dependent on concentration and polymers
ratio as well as on pH medium (Hajdu et al., 2008).
Cashew gum is an exudate from Anacardium occidentale tree
and has similar properties to those of Arabic gum, whereby their
structures have a main chain of galactose units, having branches
of arabinose, glucose and rhamnose. Uronic acid units were also
found to be present in side chains (de Paula, Heatley, & Budd,
1998). Cashew gum nanoparticles were obtained by free radical
polymerization of acrylic onto cashew gum backbone, resulting in
particle sizes in the range from 71 nm to 420 nm (da Silva, Feitosa,
Paula, & de Paula, 2009). On another approach, nanoparticles of chitosan
and cashew gum were produced in aqueous medium by ionic
complexation (Oliveira, Ciarlini, Feitosa, de Paula, & Paula, 2009).
Lippia sidoides is a plant native of Brazilian Northeast region and its
leaves contains an essential oil rich in thymol which has fungicide
and bactericide activities (Camurc¸ a-Vasconcelos et al., 2007). The
oil has been demonstrated to have also a larvicide effect against
larvae of Aedes aegypti (Carvalho et al., 2003), the dengue vector
which is responsible for many deceases and even deaths in tropical
countries such as Brazil. Arabic gum has been used as an essential
oil encapsulating agent (Fernandes et al., 2008), using high oil
and polymer contents. This oil has also been recently encapsulated
in chitosan/cashew gum based beads obtained by a coacervation
method (Paula, Sombra, Cavalcante, Abreu, & de Paula, 2011), with
low loadings, ranging from 2.4% to 4.4%. Aiming to improve essential
oil loading and release profiles, our research group decided to
fully investigate a new matrix composed of chitosan and cashew
gum as an encapsulating agent for L. sidoides. The development of
polymeric matrices for encapsulation of a natural essential oil with
larvicide activity, would favor efficacy, associated with safety, in
the handling to the environment. Hence, this work reports on the
preparation by spray drying of chitosan–gum nanoparticles loaded
with L. sidoides leaves oil, as well as on the investigation of the
effects of polymer concentration, chitosan–gum relative ratio on
the nanoparticles particle size and encapsulation efficiency. In vitro
release studies and in vivo experiments were also carried out.