1 IntroductionThe application of me

1 Introduction
The application of metallic nanoparticles is promising in many
areas such as optics, biomedical sciences, drug delivery,
catalysis and electronics [1–4]. Historically, the most
common synthesis of metallic nanoparticles has utilised
chemical reducing agents such as hydrazine, sodium citrate
and sodium borohydride to reduce the corresponding
precursor salts to create uniform suspensions [5]. Currently,
the green synthesis of metallic nanoparticles is being
investigated to improve and/or protect the environment
by decreasing the use of toxic chemicals and eliminating
biological risks in pharmaceutical and biomedical
applications. For the development of green chemistry,
Raveendran et al. suggested that three main factors in
nanoparticle preparation should be considered: solvent choice,
the use of an environmentally benign reducing agent, and the
use of a non-toxic material for nanoparticle stabilisation [6].
In green nanoparticle synthesis water is commonly used as an
environmentally benign solvent, replacing toxic organic
solvents. Recently, biological entities have been reported as
serving as both reducing and stabilising agents for green
synthesis of metallic nanoparticles [7]. This review focuses on
the use of polysaccharides and phytochemicals as the reducing
and stabilising agents in the green synthesis of gold
nanoparticles (AuNPs) and silver nanoparticles (AgNPs).
On earth, plants synthesise 4 × 1011 tons of carbohydrates
each year, and most of these carbohydrates are polysaccharides
(Fig. 1) [8]. Polysaccharides have many functionalities
including hydroxyl groups and a hemiacetal reducing end that
are capable of reducing precursor salts. The oxidation of
polysaccharide hydroxyl groups to carbonyl groups plays an
important role in the reduction of gold salts [9]. The reducing
end of polysaccharides can also be used to introduce an amino
functionality capable of complexing to and stabilising metallic
nanoparticles [10]. Carbohydrates with such amino groups
bind tightly to the surface of the AuNPs and AgNPs giving
them a hydrophilic surface [11]. The use of reducing end
chemistry introduces one amino group per polysaccharide
chain, and provides an excellent way of measuring the
exact amount of polysaccharides loaded onto a nanoparticle.
This measurement can be confirmed by subjecting the
particles to a heparinase I digestion and subsequent carbazole
assay [11]. The application of mammalian glycosaminoglycan
polysaccharides, the polysaccharide loading of gold
nanoparticles prepared using reductively aminated heparin,
heparin or hyaluronic acid (HA), as well as plant
polysaccharides (starch, cellulose, dextran and alginic acid)