19.1
Introduction
Nanoemulsions are classified as nanoscale emulsions which are specifically regarded
as kinetically stable systems. The nanoemulsions are optically isotropic mixtures and
can be translucent or transparent. However, microemulsions are also nanoscale
emulsion but are both thermodynamically and kinetically stable as compared to
nanoemulsions with a droplet size of less than 100 nm. These emulsions are liquid-
liquid colloidal dispersion with amphiphilic surface-active agents (Barkat et al.
2020; McClements 2012). Due to its nano-size, these novel drug delivery systems
offer enhanced solubility and permeability of poorly aqueous soluble compounds
(Ghai and Sinha 2012), optical clarity (de Oca-Ávalos et al. 2017), better bioavail-
ability (Li et al. 2017), and increased shelf life (de Oca-Ávalos et al. 2017; Sharma
and Sinha 2018; Parveen et al. 2015). Nanoemulsion mainly comprises three
components, i.e., oleaginous phase, surface-active agents, and aqueous phase. The
oleaginous phase involves the lipophilic components such as free fatty acids, mono-,
di-, or triacylglycerols, essential oils, etc. The role of surface-active agents is to
stabilize the nanoemulsion by preventing Ostwald ripening, coalescence, and floc-
culation. These surface-active molecules also prevent collision of small droplets and
provide kinetic stability to nanoemulsions. Surface-active agents form a layer around
the dispersed phase or droplet which can be monolayer or multilayer and reduce the
interfacial tension between two immiscible liquids. Selection of surface-active
agents with an appropriate hydrophilic-lipophilic balance (HLB) value is necessary
as this is an important parameter which determines the type of emulsion (oil in water
or water in oil). Moreover, the surface-active agents are important components of
nanoemulsion which determine as well as maintain the droplet size throughout the
shelf life. These surface-active molecules may be used as stabilizers, emulsifiers,
wetting agents, and viscosifiers. Finally, the third component is aqueous phase
which influences polarity, ionic strength, and phase behavior of nanoemulsion.
Sometimes apart from the aforesaid components, cosolvents are also utilized in
nanoemulsion formulation so as to increase the emulsification attribute and provide
stability to the nanoemulsion. Short-chain alcohols, proteins, and carbohydrates are
some of the examples that are utilized as cosolvents in nanoemulsion (Saxena et al.
2017). Amid the advancement in novel drug delivery systems for herbal bioactives,
nanoemulsion technology is highly popular throughout the globe. Herbal-derived
molecules or extracts have several therapeutic benefits and are scientifically proven
also. But challenges like higher molecular size, low aqueous solubility, lipid perme-
ability, and elevated degradation profile in vitro and in vivo lead to ineffective
pharmacodynamic and pharmacokinetic profile. Nanoemulsion technology is the
nanocarrier system which has the ability to overcome all aforesaid challenges and
potentiate the biological efficacy of herbal bioactives. Also, scientific studies have
meticulously provided the evidences which demonstrate dose minimization (Kazemi
et al. 2020), facilitate targeting (Shobo et al. 2018; Ahmad et al. 2018), improving
bioavailability (Zhao et al. 2013), release behavior (Macedo et al. 2014), and
reducing side effects (Maghbool et al. 2020). In this chapter, we highlight the
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