nanoparticles bioconjugates also sh

nanoparticles bioconjugates also show highly potent
antibacterial activity towards both Gram-positive and Gramnegative
bacteria (Table 1) [25]. The same group reported
earlier that chitosan enhanced nanoparticle stability, binding to
AuNPs or AgNPs through the amino group [33].
The reaction temperature is also an important factor in
controlling the size, shape and crystalline structure of Auchitosan
nanocomposites [34]. These composites were
successfully employed as a substrate for trace analysis of
amino acids by surface-enhanced Raman scattering.
Interestingly, a dendritic Ag-chitosan film obtained by
mixing the chitosan solution with Ag salts was also used as a
surface-enhanced Raman spectroscopy substrate [35]. A
similar Ag-chitosan film synthesised by a reduction of silver
ions in an acidic solution of AgNO3 and chitosan exhibited
antibacterial activity against E. coli and Bacillus (Table 1).
This film might be useful as a scaffold for wound dressings
and for grafting onto various bio-implants [26]. Genipin, a
cross-linking agent, was used to improve the structural
reinforcement and antibacterial properties of Ag-chitosan
nanoparticle bioconjugates (Table 1). AgNPs were also
embedded to a genipin-crosslinked chitosan film for wounddressing
applications [27]. Another important nanomedicinal
application for chitosan funcionalised AuNPs was reported
by Bhumkar et al. [36]. Using chitosan as both a reducing
and stabilising agent, the resulting Au-chitosan nanoparticles
were demonstrated to improve the transport of insulin across
the intestinal track of diabetic rats.
2.4 Cellulose
Cellulose is a polysaccharide consisting of a linear chain of
b(1,4)-linked D-glucose (Fig. 1d) and is one of the most
abundant polysaccharides found on earth [8]. Cellulose is a
main component of plant cell walls and thus is the main
component of plant fibres. Carboxymethylcellulose is an
ester derivative of cellulose usually used in the food industry
as a thickener and stabiliser. Cai et al. reported the
preparation of transparent nanoporous cellulose gels
obtained from an aqueous alkali hydroxide-urea solution,
and these gels were immersed in precursor salt solutions
(AgNO3, HAuCl4.3H2O or PtCl4) to synthesise metal
nanoparticles [37]. These metal-carrying gels were dried by
supercritical CO2 providing high transmittance, porosity,
surface area, moderate thermal stability and good mechanical
strength. These nanomaterials have many potential
applications, including their use as catalytic surfaces, use in
electro-optical devices and as antibacterial surfaces.
2.5 Starch
Starch is synthesised in plants and is a mixture of a-amylose
and amylopectin (Fig. 1e) [8]. a-Amylose is a linear polymer
with a(1,4)-glycosidic linkages and amylopectin has a(1,6)-
branches at every 24–30 glucose residues of the a-amylose
chain [8]. Starch-stabilised and glucose-reduced AgNPs
were prepared via the incubation of Ag salt with starch and
glucose at 408C for 20 h producing a particle with a mean
size of 5.3 nm [6]. This AgNP solution was stable without
any noticeable aggregation even after 2 months of storage.
Another thermal method, an autoclaving method (15 psi,
1218C, 5 min), was introduced for the synthesis of stable
AgNPs in the size range of 10–34 nm using soluble starch
as both a reducing and stabilising agent [38]. These AgNPs
are entrapped inside the helical amylose structure (Fig. 3),
as confirmed by iodometric titration.