molecules

Review

Food-Grade Nanoemulsions: Preparation, Stability
and Application in Encapsulation of
Bioactive Compounds

Qingqing Liu 1 , He Huang 1, Honghong Chen 1, Junfan Lin 1 and Qin Wang 1,2,*
1 Key Laboratory of Grain and Oil Processing and Food Safety of Sichuan Province, College of Food and

Bioengineering, Xihua University, Chengdu 610039, China; liuqing_861006@163.com (Q.L.);
m18382104652@163.com (H.H.); shunwenanan@126.com (H.C.); DavidBowielin@outlook.com (J.L.)

2 Department of Nutrition and Food Science, College of Agriculture and Natural Resources, University of
Maryland, College Park, MD 20740, USA

* Correspondence: wangqin@umd.edu; Tel.: +1-301-405-8421

Academic Editor: Yangchao Luo
Received: 28 September 2019; Accepted: 14 November 2019; Published: 21 November 2019

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Abstract: Nanoemulsions have attracted significant attention in food fields and can increase the
functionality of the bioactive compounds contained within them. In this paper, the preparation
methods, including low-energy and high-energy methods, were first reviewed. Second, the physical
and chemical destabilization mechanisms of nanoemulsions, such as gravitational separation
(creaming or sedimentation), flocculation, coalescence, Ostwald ripening, lipid oxidation and
so on, were reviewed. Then, the impact of different stabilizers, including emulsifiers, weighting
agents, texture modifiers (thickening agents and gelling agents), ripening inhibitors, antioxidants
and chelating agents, on the physicochemical stability of nanoemulsions were discussed. Finally,
the applications of nanoemulsions for the delivery of functional ingredients, including bioactive lipids,
essential oil, flavor compounds, vitamins, phenolic compounds and carotenoids, were summarized.
This review can provide some reference for the selection of preparation methods and stabilizers that
will improve performance in nanoemulsion-based products and expand their usage.

Keywords: nanoemulsions; preparation; stability; application; encapsulation

1. Introduction

Nanoemulsions, exhibiting droplet sizes of <200 nm, represent liquid-in-liquid dispersions that are
kinetically stable. Water and oil are the two incompatible liquids most extensively applied in commercial
environments. Because of their small size, characteristics such as visible transparency, high surface area
per unit volume, sound stability and tunable rheology are often observed. Additionally, large-scale
nanoemulsions’ preparation is easily achievable in industrial conditions. Therefore, nanoemulsions
are especially suitable for commercial applications [1–3].

Since the oil and water phases are distributed relatively spatially, simple nanoemulsions can be
divided into oil-in-water (O/W) nanoemulsions denoting the dispersion of small oil droplets in an
aqueous medium, and water-in-oil (W/O) nanoemulsions signifying small water droplets distributed in
an oil medium [3]. Additionally, utilizing a two-step procedure, it is also possible to produce two types
of multiple nanoemulsions, namely water-in-oil-in-water (W/O/W) or oil-in-water-in-oil (O/W/O) [4].
For instance, the preparation of W/O/W nanoemulsions is achieved by assimilating the oil phase
comprising lipophilic surfactant with the water phase to form the initial W1/O nanoemulsions, which
are then homogenized with an additional water phase (W2) comprising hydrophilic surfactant [5].

Molecules 2019, 24, 4242; doi:10.3390/molecules24234242 www.mdpi.com/journal/molecules

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Molecules 2019, 24, 4242 2 of 37

The methods used for nanoemulsions’ preparation can be divided into two principal groups
namely low-energy and high-energy techniques. When environmental factors (e.g., composition or
temperature) or nanoemulsions’ compositions are modified, small droplets are generated, providing
the basis necessary for the successful operation of the low-energy methods [3,6–8]. High-energy
methods usually consume significant energy (~108–1010 W/kg) to form small droplets. Furthermore,
in the utilization of high-energy methods, the oil and water phases are breached and blended using
the powerful cavitational, shear and turbulent flow profiles created by the specifically designed
devices [9,10].

Nanoemulsions are thermo-dynamically unstable since the free energy required to separate
the oil phases from the water phases is lower than what is necessary for emulsification. Therefore,
nanoemulsions typically break down during storage due to various mechanisms, such as gravitational
separation (creaming or sedimentation), flocculation, coalescence and Ostwald ripening [11]. Moreover,
various chemical and biochemical reactions such as flavor loss, biopolymer hydrolysis, color fading
and lipid oxidation can adversely affect nanoemulsions, causing them to degrade during storage or
lose their acceptable quality characteristics. Among the chemical deterioration phenomena mentioned
above, lipid oxidation occurs the most frequently in nanoemulsions [12].

For several commercial uses, it is crucial that nanoemulsions-based products remain
physiochemically stable when exposed to unfavorable environmental conditions (including
temperature, mechanical forces, and ionic strength) during their production, storage, transportation
and application [3,6]. The addition of suitable stabilizers, including emulsifiers, weighting agents,
texture modifiers and ripening inhibitors can improve the physical stability of nanoemulsions [6,13].
Given that, three methods are commonly used to improve the nanoemulsions’ chemical stability,
including the manipulation of interfacial characteristics (e.g., thickness, charge, and chemical reactivity),
the addition of chelating agents or antioxidants, as well as controlling environmental elements (e.g.,
temperature, light, pH, and oxygen levels) [3,6].

So far, a number of food ingredients and additives, including bioactive lipids, vitamins, flavorings,
acidulants, preservatives, colorings, antioxidants and so on, have been encapsulated by nanoemulsions
and some of them are already available in the market [1,3,14]. A larger droplet surface area, as well as
a decline in particle size of the nanoemulsions may lead to increased functionality of the bioactive
compounds contained within them. The majority of the bioactive compounds are characteristically
lipophilic. Thus, O/W nanoemulsions are commonly used to improve the solubility and dispersibility of
lipophilic substance in aqueous media, enhance stability, appearance, taste or texture, increase uptake
absorption and bioavailability, and reduce the off-flavor (such as bitterness or astringency) [14–16].

In this review article, we will focus on the simple nanoemulsions and discuss the most relevant
research from the literatures in the last five years on nanoemulsions’ fabrication, stabilization and
application. This review paper contains five sections. The first section is the introduction. The second
section summarizes the various methods to prepare nanoemulsions. In the third section, we discuss the
physically destabilization mechanisms of nanoemulsions such as gravitational separation (creaming or
sedimentation), flocculation, coalescence and Ostwald ripening. Moreover, the chemical stability of
nanoemulsions are also discussed in this section. The fourth section reviews the stabilizers used in the
nanoemulsions, such as emulsifiers, texture modifiers, weighting agents, ripening inhibitors and other
components. The fifth section discusses the application of nanoemulsions in encapsulation of bioactive
compounds in the last five years.

2. Preparation

As described in Section 1, a number of methods were developed to facilitate nanoemulsions, which
include high-energy as well as low-energy techniques [17]. Selecting an appropriate method for the
preparation of nanoemulsions rely on the characteristics of the compounds needing homogenization
(specifically the surfactant and oil phases), as well as the required physicochemical attributes and
operational qualities of the ultimate product (including rheological, optical, release, and stability



Molecules 2019, 24, 4242 3 of 37

properties) [6]. Understanding the various fabrication methods is crucial for relevant personnel to
choose the most suitable preparation technique and fabricate nanoemulsions for special application.

2.1. Low-Energy Methods

Low-energy methods are denoted by changes in environmental conditions, as well as the
composition of the mixture influencing the development of oil nanodroplets within the mixed systems
containing surfactants, oil, and water. The most frequently used low-energy techniques are spontaneous
emulsion (SE), emulsion phase inversion (EPI) (including phase inversion composition (PIC), and phase
inversion temperature (PIT)) [8,18]. The principles of the characteristic low-energy techniques used to
O/W nanoemulsions were shown in Figure 1.

Molecules 2019, 24, x FOR PEER REVIEW  3  of  37 

 

and stability properties) [6]. Understanding the various fabrication methods is crucial for relevant 

personnel to choose the most suitable preparation technique and fabricate nanoemulsions for special 

application.   

2.1. Low‐Energy Methods 

Low‐energy methods  are  denoted  by  changes  in  environmental  conditions,  as well  as  the 

composition  of  the mixture  influencing  the  development  of  oil  nanodroplets within  the mixed 

systems containing surfactants, oil, and water. The most frequently used low‐energy techniques are 

spontaneous emulsion (SE), emulsion phase inversion (EPI) (including phase inversion composition 

(PIC), and phase inversion temperature (PIT)) [8,18]. The principles of the characteristic low‐energy 

techniques used to O/W nanoemulsions were shown in Figure 1. 

 

Figure  1.  Schematic  depiction  of  the  characteristic  low‐energy  techniques  used  to  create  O/W 

nanoemulsions, including phase inversion temperature (PIT), phase inversion composition (PIC) and 

spontaneous emulsion (SE) [19]. 

In this section, the low‐energy methods for nanoemulsions’ preparation and their application in 

encapsulation of bioactive compounds are summarized in Table 1 and introduced as follows. 

Table 1. Examples of application of low‐energy methods for nanoemulsions’ preparation. 

Emulsification 

Method 
Optimal Processing Conditions 

Bioactive 

Compound 

Encapsulated 

Droplet 

Diameter 

(nm) 

Reference 

SE 

(1) titration of organic phase into 

aqueous phase, (2) constant 

stirring, 600 rpm, (3) room 

temperature 

Peppermint 

essential 

oil 

≈50  [20] 

(1) titration of organic phase into 

the aqueous phase, (2) constant 
Citrus oil  10–30  [21] 

Figure 1. Schematic depiction of the characteristic low-energy techniques used to create O/W
nanoemulsions, including phase inversion temperature (PIT), phase inversion composition (PIC)
and spontaneous emulsion (SE) [19].

In this section, the low-energy methods for nanoemulsions’ preparation and their application in
encapsulation of bioactive compounds are summarized in Table 1 and introduced as follows.



Molecules 2019, 24, 4242 4 of 37

Table 1. Examples of application of low-energy methods for nanoemulsions’ preparation.

Emulsification Method Optimal Processing Conditions Bioactive Compound Encapsulated Droplet Diameter (nm) Reference

SE

(1) titration of organic phase into aqueous phase, (2) constant stirring, 600 rpm, (3) room temperature
Peppermint

essential
oil

≈50 [20]

(1) titration of organic phase into the aqueous phase, (2) constant stirring, 1000 rpm/10 min, (3) room temperature Citrus oil 10–30 [21]
(1) titration of organic phase into aqueous phase, (2) constant stirring, 750 rpm, (3) room temperature Citrus oil ≈100 [22]

(1) titration of organic phase into aqueous phase, (2) constant stirring, 600 rpm/15 min, (3) room temperature Cinnamaldehyde <100 [23]
(1) stirred, 1000 rpm/1 h, (2) room temperature Capsaicin 13–14 [24]

(1) deprotonated eugenol in hot alkaline added to surfactant mixtures, (2) the mixtures were acidified to pH 7.0, stirred,
600 rpm Eugenol ≈ 109–139 [25]

PIC

(1) mixed oil and surfactant, (2) oil phase added to aqueous phase, (3) phase inversion occurred at a certain oil-to water ratio,
(4) stirred, 30 min

Docosahexaenoic acid
Eicosapentaenoic acid <200 [26]

(1) aqueous phase (water, glycerol) added to organic phase (sunflower oil, polysorbate 80, curcumin), (2) stirred,
300 rpm/30 min Curcumin ≈200 [27,28]

(1) mixed organic phase and aqueous phase, (2) continuing stirred, (3) ambient temperature
Essential

Oils
Blend*

29.55–37.12 [29]

PIT
(1) all components were stirred, 30 min, (2) heated to 15 ◦C above the PIT, (3) the temperature was reduced to the PIT Cinnamon oil 101 [30,31]

(1) coarse emulsions were heated, 21–98 ◦C /0–3 h, (2) immediately quenching in ice/water with hand shaking Lemon oil ≈100 [32]
(1) mixing all components, (2) 3 temperature cycles (90–60–90–60–90–75 ◦C) Curcuminoids 20–100 [33]

Note: essential oils blend* containing cape jasmine absolute, wan saw long oil, lemongrass oil and basil oil.



Molecules 2019, 24, 4242 5 of 37

2.1.1. Spontaneous Emulsion (SE)

SE, also named as emulsification by solvent diffusion (ESD), can take place through numerous
mechanisms [10] and provides the potential for an affordable approach. The spontaneous formation of
an O/W nanoemulsion facilitated by specific temperatures relies on the chemical compounds present
in both phases, as well as the utilized emulsifier [34]. Whether surfactants are present or not, the
utilization of solvents can facilitate this spontaneous process [35,36]. From the points of view of cost,
flavor, and safety, the use of solvents is usually problematic in the food industry. Therefore, the SE
process usually includes adding an organic phase consisting of a hydrophilic surfactant and oil into an
aqueous phase consisting of water and potentially a co-surfactant [37].

Kinetic barriers can cause SE to occur slowly, while the ouzo effect initiates this process
immediately [10]. The ouzo effect results from a significant supersaturation of the oil, facilitating the
nucleation of oil droplets when combined with water. Consequently, instantaneous diffusion of the oil
to the closest droplet occurs and decreases the supersaturation to avoid any further nucleation [36].

Barzegar et al. prepared nanoemulsions by SE and found that the best nanoemulsions with droplet
size of around 50 nm were formed [20]. Zhao et al. prepared three types of essential oil nanoemulsions
by SE. At the same surfactant level, the nanoemulsions containing different essential oil displayed
particle sizes of about 10–30 nm, 10–30 nm and 50–500 nm, respectively [21]. Yildirim et al. prepared
stable nanoemulsions by SE. The best nanoemulsions with particle size of ~100 nm exhibited high
physical stability and antimicrobial activity [22]. Tian et al. prepared nanoemulsions by SE. Stable
nanoemulsions were obtained [23]. Ghiasi et al. prepared nanoemulsions by SE. The average droplet
diameter in the most superior nanoemulsions were 13–14 nm, while its continued stability exceeded
a storage period of eight months in extreme temperatures such as 4 ◦C and 45 ◦C [24]. Using SE,
Wang et al. produced nanoemulsions displaying a clearly established diameter of approximately
109−139 nm, a negative surface zeta-potential ranging between −28.5 mV and −35.8 mV, as well as a
spherical structure [25].

2.1.2. Emulsion Phase Inversion (EPI)

EPI, also known as catastrophic phase inversion (CPI), usually refer to the creation of W/O
nanoemulsions using traditional high-speed mixers. Then, these W/O nanoemulsions are transformed
into O/W nanoemulsions by modifying the temperature or the composition, that is PTC and PIC
methods [10]. Specifically, the PIC and PIT approaches denote transitional inversion resulting from
changing factors (temperature or composition), which influence the hydrophilic lipophilic balance
(HLB) in the system [38].

Phase Inversion Composition (PIC)

PIC, also named emulsion inversion point (EIP) [39], involves procuring O/W nanoemulsions
from their W/O analogs via a shift in the natural emulsifier curvature by altering the volume fraction
of the water at a given temperature. The nano-emulsification process using PIC involves the gradual
addition of the water phase to the oil phase, resulting in the steady increase of the water volume
fraction. A phase inversion can take place at a specific level, leading to the emergence of a bicontinuous
phase, which can ultimately capture oil phases into water phase and form O/W nanoemulsions [40].

The PIC method has many advantages, including low cost and the need for simple apparatus.
However, the preparation time of this process was longer than that of SE technique due to the smaller
driving forces of PIC method.

Zhang et al. prepared stable nanoemulsions by using the EIP method. The particle sizes of the
prepared nanoemulsions were <200 nm [26]. Borrin et al. produced nanoemulsions by EIP method
and incorporated them in pineapple ice creams to replace artificial yellow dyes [27,28]. Nantarat et al.
prepared nanoemusions by PIC. The average droplet size of the nanoemulsions produced was between
29.55 to 37.12 nm [29].



Molecules 2019, 24, 4242 6 of 37

Phase Inversion Temperature (PIT)

Nano-emulsification by PIT is also premised on transitional inversion, which is prompted by
HLB variations in the system, resulting from fluctuations in temperature [2]. Temperature-sensitive
surfactants become water-soluble a low temperature, while a positive surfactant layer curvature is
evident at the droplet interface. By contrast, the surfactants become oil-soluble at a high temperature,
with a negative surfactant layer curvature apparent at the droplet interface [41]. An intermediate
temperature (PIT) causes the surfactants to exhibit a similar affinity to both the oil and water phases,
consequently, producing a zero value for the spontaneous surfactant layer curvature at the droplet
interface [42]. Therefore, the oil in a lamellar liquid crystalline phase or bicontinuous phase is
completely solubilized [43]. The advantages of the PIT method are that it is a low-energy approach
without requiring high shear forces [44].

Chuesiang et al. fabricated nanoemulsions using the PIT method, where a mixture of oil, water
and surfactant was heated above the PIT and then quench cooled by stirring. Nanoemulsions with
particle size of 101 nm were obtained [30,31]. Su et al. fabricated nanoemulsions by the PIT method.
The best nanoemulsions had a particle size of approximately 100 nm and retained stability after a 15-day
storage period [32]. Jintapatanakit et al. prepared nanoemulsions by the PIT method. The droplets
size of nanoemulsions were 20–100 nm and polydispersity index (PDI) was below 0.2 [33].

2.2. High-Energy Methods

High-energy methods, denote mechanical techniques, employing mechanical equipment to
separate the dispersed phase into droplets inside the continuous phase to generate forces that are highly
disruptive [10]. Since high-energy methods permit the utilization of non-toxic/natural emulsifiers at
lower concentration levels, they are more appropriate for food-related nanoemulsions preparation,
while they are also expedient for production at an industrial scale and the necessary equipment is
available commercially [14]. Usually, two steps are involved when producing O/W nanoemulsions using
high-energy methods. Firstly, the coarse O/W emulsions were formed by mixing of the components
using a high-speed mixer or stirrer. Later on, the coarse emulsions are exposed to disruptive forces
to facilitate a reduction in the droplet diameter to 200~500 nm [10]. Based on the devices used,
high-energy methods include rotor-stator emulsification (RSE), high-pressure homogenization (HPH),
high-pressure microfluidic homogenization (HPMH) and ultrasonic homogenization (USH) [9,45].
The principles of high-energy techniques used to create O/W nanoemulsions were shown in Figure 2.

Molecules 2019, 24, x FOR PEER REVIEW  6  of  37 

 

at the droplet interface [42]. Therefore, the oil in a lamellar liquid crystalline phase or bicontinuous 

phase is completely solubilized [43]. The advantages of the PIT method are that it is a low‐energy 

approach without requiring high shear forces [44].   

Chuesiang et al. fabricated nanoemulsions using the PIT method, where a mixture of oil, water 

and surfactant was heated above the PIT and then quench cooled by stirring. Nanoemulsions with 

particle size of 101 nm were obtained [30,31]. Su et al. fabricated nanoemulsions by the PIT method. 

The best nanoemulsions had a particle size of approximately 100 nm and retained stability after a 

15‐day storage period  [32].  Jintapatanakit et al. prepared nanoemulsions by  the PIT method. The 

droplets size of nanoemulsions were 20–100 nm and polydispersity index (PDI) was below 0.2 [33].   

2. High‐Energy Methods 

High‐energy methods,  denote mechanical  techniques,  employing mechanical  equipment  to 

separate the dispersed phase  into droplets  inside the continuous phase to generate forces that are 

highly  disruptive  [10].  Since  high‐energy  methods  permit  the  utilization  of  non‐toxic/natural 

emulsifiers at lower concentration levels, they are more appropriate for food‐related nanoemulsions 

preparation, while  they are also expedient  for production at an  industrial scale and  the necessary 

equipment  is available  commercially  [14]. Usually,  two  steps are  involved when producing O/W 

nanoemulsions  using  high‐energy methods.  Firstly,  the  coarse O/W  emulsions were  formed  by 

mixing of  the components using a high‐speed mixer or stirrer. Later on,  the coarse emulsions are 

exposed  to disruptive  forces  to  facilitate a  reduction  in  the droplet diameter  to 200~500 nm  [10]. 

Based  on  the  devices  used,  high‐energy  methods  include  rotor‐stator  emulsification  (RSE), 

high‐pressure  homogenization  (HPH),  high‐pressure microfluidic  homogenization  (HPMH)  and 

ultrasonic homogenization  (USH)  [9,45]. The principles of high‐energy  techniques used  to  create 

O/W nanoemulsions were shown in Figure 2. 

 

Figure  2.  Schematic  portrayal  of  high‐energy  techniques  utilized  for  the  preparation  of  O/W 

nanoemulsions.  (A)  traditional  high‐speed mixers  are  usually  employed  to  form  a  coarse  O/W 

emulsions  before  emulsification  by  (B)  high‐pressure  homogenization  (HPH),  (C)  ultrasonic 

homogenization (USH), (D) high‐pressure microfluidic homogenization (HPMH) [10]. 

In this section, the high‐energy methods for nanoemulsions’ preparation and their application 

in encapsulation of bioactive compounds are summarized in Table 2 and introduced as follows. 

Table 2. Examples of application of high‐energy methods for nanoemulsions’ preparation. 

Figure 2. Schematic portrayal of high-energy techniques utilized for the preparation of O/W
nanoemulsions. (A) traditional high-speed mixers are usually employed to form a coarse O/W emulsions
before emulsification by (B) high-pressure homogenization (HPH), (C) ultrasonic homogenization
(USH), (D) high-pressure microfluidic homogenization (HPMH) [10].



Molecules 2019, 24, 4242 7 of 37

In this section, the high-energy methods for nanoemulsions’ preparation and their application in
encapsulation of bioactive compounds are summarized in Table 2 and introduced as follows.

Table 2. Examples of application of high-energy methods for nanoemulsions’ preparation.

Emulsification Method Optimal Processing Conditions Bioactive Compound Encapsulated Droplet Diameter (nm) Reference

RSE 24000 rpm/25 min docosahexaenoic acid 87 [46]
HPH 800 bar/8 cycles docosahexaenoic acid 11.17 [46]

103 M Pa/10 cycles pepper extract 132 ± 2.0-145 ± 1.0 [47]
60 MPa/3 cycles curcumin 203.6-260.6 [48]
40 kpsi/10 cycles fish oil 89.7 ± 27.7 [49]

HPMH

137.9 MPa/10 cycles rosemary essential oil 2.88 [50]
1000 bar/5 cycles docosahexaenoic acid 148 [51]
350 bar/5 cycles curcumin 275.5 [52]
13 kpsi/1 cycle fish oil <160 [53]

USH 350 W/5 min Resveratrol 20.41 ± 3.41 [54]
resveratrol cyclodextrin inclusion

complex 24.48 ± 5.70

20.5 kHz/400 W for 15 min thymus daenensis oil 171.88 ± 1.57 [55]

Combined method HPH (24,000 rpm/15 min) + HSP (800
bar/8 cycles) docosahexaenoic acid 11.31 [46]

2.2.1. Rotor-Stator Emulsification (RSE)

RSE is also known as high-speed homogenization (HSH). Various industries including food,
cosmetics and pharmaceutical companies commonly use rotor-stator mixers to produce emulsions.
They are usually considered as a standard method for emulsion preparation regarding dispersed phase
volume fractions and intermediate-to-high viscosity [56,57].

The hydrodynamic intensity and the size of the subsequent emulsion droplets depend on the
speed of the rotor, which commonly ranges 10 m/s and 30 m/s in industrial applications. The decrease
in mean droplet size is fairly low after migrating through the rotor-stator region. Therefore, several
migrations were necessary to achieve a steady-state droplet size, particularly for the formation of the
small droplet sizes essential to nanoemulsions [9]. However, the exclusive use of RSE is difficult to
produce nanoemulsions.

Karthik et al. prepared nanoemulsions by three methods (HSH, HPH and HSH + HPH). Among
them, the particle size of nanoemulsion obtained by HSH was 87 nm [46].

2.2.2. High-Pressure Homogenization (HPH)

HPH is a commonly used method in industrial nanoemulsion preparation [58]. It is used to
decrease the droplet size of coarse pre-emulsions (often prepared with a rotor-stator mixer) into
nano-size with narrow distribution [9]. HPH devices function on the same principle as those employed
for the amalgamation of beverages. A piston pump is used to push the macroemulsions through a
narrow valve situated downstream. During this procedure, the extreme hydraulic shear and turbulence
breaks apart the macroscale droplets to form smaller ones, and is repeated several times until the
successful formation of nanoemulsions [10,59]. Three main variables can be a matter of optimization
for HPH: number of pass cycles, working pressure, and system temperature [60].

Galvão et al. prepared nanoemulsions by using HSH (Ultra-Turrax), followed by HPH. The
average droplet size of nanoemulsions was 132 ± 2.0-145 ± 1.0 nm, which depended on the number of
cycles and working pressure applied [47]. Ma et al. prepared nanoemulsions using the HPH method.
The particle size of nanoemulsions was 203.6–260.6 nm [48]. Dey et al. produced nanoemulsions
via the use of HPH. The particle size, PDI and zeta-potential of nanoemulsions obtained were 89.7 ±
27.7 nm, 0.226 ± 0.021 and −12.54 ± 1.67 mV, respectively [49].

2.2.3. High-Pressure Microfluidic Homogenization (HPMH)

Microfluidic devices were used successfully in the development of nanoemulsions [14]. Indeed,
using HPMH can facilitate the large-scale production of size-tailored nanoemulsions. It has been
stated that HPMH is more effective than HPH during the formation of nanoemulsions subjected
to a single pass at an equal working pressure [10,60]. The HPH method and HPMH method are



Molecules 2019, 24, 4242 8 of 37

inherently similar. Both employ a high-pressure positive displacement pump to create nanoemulsions,
generally at a setting between 30 MPa and 120 MPa, but the specific device design in each case differ
considerably [10].

Llinares et al. prepared nanoemulsions by microfluidization. The best nanoemulsions showed
the lowest mean particle size (2.88 nm) [50]. According to Karthik et al., O/W nanoemulsions were
prepared by microfluidization with different emulsifiers. The nanoemulsions showed the lowest mean
particle size of 148 nm [51]. Raviadaran et al. produced and optimized nanoemulsions via the use of a
microfluidizer. Stable nanoemulsions with particle size of 275.5 nm, PDI of 0.257, zeta-potential of
−36.2 mV, and viscosity of 446 cP were obtained [52]. As reported by Liu et al., nanoemulsions were
prepared using a dual-channel high-pressure microfluidizer. Stable nanoemulsions were obtained with
particle size of <160 nm [53].

2.2.4. Ultrasonic Homogenization (USH)

Nanoemulsions can be effectively formed using USH devices. Inserting a sonication probe into the
prepared coarse emulsion promotes the generation of mechanical ultrasound vibrations, which induces
the formation and collapse of microbubbles in close proximity of the sonication probe. Therefore,
hotspots, high shear forces, and turbulence are created, ultimately resulting in effective nanoemulsions’
droplet disruption toward the nanoscale [61]. The nanoemulsions’ morphology is affected by power,
frequency/amplitude of the ultrasound waves, and treatment time. Additionally, hydrostatic pressure,
dissolved gas concentration, apparatus configuration, and temperature are also important in the
nano-emulsification processes performed using USH devices [62].

Laboratory-scale ultrasonic homogenizer has many benefits, such as simple operation, excellent
energy efficiency, and affordability. Additionally, there are more potential advantages at optimized
conditions, such as low emulsifier content requirements, excellent dispersion stability, and a decreased
risk of microbial contaminants entering the processing stage [62]. However, fabricating ultrasonic
devices suitable for industrial application remains challenging. Furhtermore, additional defects exist
in using sonication to prepare nanoemulsions. These include the emergence of hotspots, as well as
deterioration processes prompted by cavitation that may prove damaging to mutable components [14].
Moreover, abrasion of the sonication probe induced by cavitation increases the risk or releasing metal
ions into the emulsion [63].

Kumar et al. prepared nanoemulsion by the USH method. The average sizes of two different
nanoemulsions were 24.48 ± 5.70 nm and 20.41 ± 3.41 nm, respectively [54]. Moghimi et al. prepared
nanoemulsion by the USH method. The most stable nanoemulsions were produced with the particle
size of 171.88 ± 1.57 nm [55].

2.2.5. Combined Methods

Recently, more and more nanoemulsions were prepared by combined methods in order to
overcome the drawbacks of a single method.

Karthik et al. prepared nanoemulsions by HSH, HPH and HSH + HPH. The results showed that
HPH involved emulsification process (HPH and HSH + HPH) produced nanoemulsions that display
stability regarding morphology, particle size, and other physical attributes [46].

3. Stability

3.1. Physical Stability

The undesirable molecular interactions at the oil-water interface as a result of the hydrophobic
effect induces thermodynamic instability in nanoemulsions [59]. Nanoemulsions will eventually
degrade as a result of several mechanisms such as flocculation, gravitational separation, coalescence,
phase separation, and Ostwald ripening, as shown in Figure 3 [3,6]. Understanding the essential



Molecules 2019, 24, 4242 9 of 37

mechanisms responsible for nanoemulsions’ instability is crucial in developing systems exhibiting
adequate stability qualities.

Molecules 2019, 24, x FOR PEER REVIEW  9  of  37 

 

The undesirable molecular interactions at the oil‐water interface as a result of the hydrophobic 

effect  induces  thermodynamic  instability  in  nanoemulsions  [59]. Nanoemulsions will  eventually 

degrade as a result of several mechanisms such as flocculation, gravitational separation, coalescence, 

phase  separation, and Ostwald  ripening, as  shown  in Figure 3  [3,6]. Understanding  the essential 

mechanisms responsible for nanoemulsions’ instability is crucial  in developing systems exhibiting 

adequate stability qualities. 

 

Figure  3.  Schematic  representation  of  the  mechanisms  responsible  for  nanoemulsion  physical 

instability  (phase  separation):  gravitational  separation,  flocculation,  coalescence  and  Ostwald 

ripening. 

3.1.1. Gravitational Separation 

The  process  in which  nanoemulsion  droplets move  downward  (sedimentation)  or  upward 

(creaming) due to their density exceeding or being lower than that of the liquid surrounding it, is 

known as gravitational separation. Water tends to move in a downward direction, while oil migrates 

upward since most liquid oils are less dense than water in a liquid state. Therefore, sedimentation is 

common  in W/O nanoemulsions, while O/W exhibit more cases of creaming  [3,6]. An  increase  in 

droplet size, density contrast in conjunction with a decline in the aqueous phase viscosity, influence 

the motion speed of the droplets induced by gravitational separation [6].   

According to Arancibia et al., the inferior stability of nanoemulsions containing 15% avocado oil 

and  8%  starch  could  be  ascribed  to  gravitational  separation  of  phases  caused  by  fat  droplet 

flocculation/coalescence and starch precipitation/aggregation [64]. According to Chen et al., due to 

gravitational  separation  (sedimentation),  pure  cinnamaldehyde  could  not  produce  stable 

nano‐emulsions. The oil droplets moved downwards in the pure cinnamaldehyde system due to the 

higher density of cinnamaldehyde (1050 kg m‐3) than that of room temperature water (997 kg m‐3) 

[65].   

3.1.2. Flocculation and Coalescence 

The colloidal  interaction between  the droplets determines  two  types of droplet accumulation 

namely coalescence and flocculation [6].   

The process by which  two or more droplets attract  each other  to  form  clusters  is known as 

flocculation [6]. As reported by Bai et al., utilizing amphiphilic polysaccharides above a certain level 

as emulsifiers could promote emulsion  instability, which was attributed  to exhausted flocculation 

mechanism, could diminish  the stability of some nanoemulsion products  in  the  long run  [66]. As 

reported  by Li  et  al., D‐limonene  nanoemulsions  became  unstable  and  tended  to  flocculate  and 

coalesce, which caused a variation in zeta‐potential at the storage temperatures [67]. As reported by 

Figure 3. Schematic representation of the mechanisms responsible for nanoemulsion physical instability
(phase separation): gravitational separation, flocculation, coalescence and Ostwald ripening.

3.1.1. Gravitational Separation

The process in which nanoemulsion droplets move downward (sedimentation) or upward
(creaming) due to their density exceeding or being lower than that of the liquid surrounding it, is
known as gravitational separation. Water tends to move in a downward direction, while oil migrates
upward since most liquid oils are less dense than water in a liquid state. Therefore, sedimentation
is common in W/O nanoemulsions, while O/W exhibit more cases of creaming [3,6]. An increase in
droplet size, density contrast in conjunction with a decline in the aqueous phase viscosity, influence
the motion speed of the droplets induced by gravitational separation [6].

According to Arancibia et al., the inferior stability of nanoemulsions containing 15% avocado
oil and 8% starch could be ascribed to gravitational separation of phases caused by fat droplet
flocculation/coalescence and starch precipitation/aggregation [64]. According to Chen et al.,
due to gravitational separation (sedimentation), pure cinnamaldehyde could not produce stable
nano-emulsions. The oil droplets moved downwards in the pure cinnamaldehyde system due to the
higher density of cinnamaldehyde (1050 kg m-3) than that of room temperature water (997 kg m-3) [65].

3.1.2. Flocculation and Coalescence

The colloidal interaction between the droplets determines two types of droplet accumulation
namely coalescence and flocculation [6].

The process by which two or more droplets attract each other to form clusters is known as
flocculation [6]. As reported by Bai et al., utilizing amphiphilic polysaccharides above a certain level as
emulsifiers could promote emulsion instability, which was attributed to exhausted flocculation
mechanism, could diminish the stability of some nanoemulsion products in the long run [66].
As reported by Li et al., D-limonene nanoemulsions became unstable and tended to flocculate
and coalesce, which caused a variation in zeta-potential at the storage temperatures [67]. As reported
by Bai et al., a cream layer was evident for saponin-coated droplets when salt concentrations exceeded
300 mM, suggesting that the accumulation of droplets primarily resulted from flocculation instead of
coalescence [68].

The process by which a larger droplet is formed when several droplets collide and amalgamate
is known as coalescence [6]. As reported by Bai et al., rhamnolipids were able to stabilize O/W



Molecules 2019, 24, 4242 10 of 37

nanoemulsions. The droplets coated with rhamnolipids displayed stability following thermal treatments
between 30 ◦C to 90 ◦C, with salt concentrations below 100 mM NaCl, pH levels between 5 and
9, as well as storage for at least two weeks at room temperature. However, nanoemulsions were
unstable when subjected to storage conditions that were extremely acidic (pH 2–4) or in the presence
of high ionic strength (200–500 mM NaCl). These results were ascribed to coalescence caused by a
decline in the electrostatic repulsion among the droplets in the range and magnitude at high salt
and low pH levels [68]. Wooster et al. prepared triglyceride nanoemulsions by the HPMH method,
using a combination of Span 80 and Tween 80 as emulsifiers and n-alcohol as a co-solvent. However,
addition of an excess of n-alcohol led to nanoemulsion destabilization, coalescence was found to
be the primary destabilization mechanism [69]. According to Shu et al., nanoemulsions containing
astaxanthin stabilized by saponins displayed an extremely high sensitivity and were predisposed to
droplet coalescence when high salt concentrations were present. These results could be ascribed to a
decline in the electrostatic repulsion among the negatively charged droplets facilitated by the presence
of Na+ cations, and inducing the coalescence and instability of the droplets [70].

3.1.3. Ostwald Ripening

Driven by the curvature differences of the particles, dispersed phase molecules diffuse through
the continuous phase causing the expansion of larger droplets and the shrinkage of smaller droplets
in a process known as Ostwald ripening, which is the primary instability mechanism for such
nanoemulsions. Ostwald ripening occurs when the dispersed phase solubility in large droplets (small
curvature) is lower than in small droplets (large curvature), which prompts droplet growth due to the
appearance of a concentration gradient [71].

According to Ryu et al., nanoemulsions containing essential oil are especially susceptible to
Ostwald ripening because of a significant oil phase solubility in the aqueous phase even though
its predominantly hydrophobic nature [72]. According to Walker et al., during or soon after
homogenization, nanoemulsions containing thyme oil experienced swift droplet growth when low
levels of fish oil (<75%) were present. The reason was that the relatively high water-solubility of thyme
oil induced expeditious droplet growth as a result of Ostwald ripening [73].

3.2. Chemical Stability

Various biochemical and chemical reactions such as flavor loss, lipid oxidation, biopolymer
hydrolysis and color fading occur in nanoemulsions leading them to lose their favorable characteristics.
Of these, lipid oxidation is considered as one of the most significant types of chemical degradation [12].
The interfacial areas of nanoemulsions are relatively large, leading to accelerated lipid oxidation due to
water-soluble pro-oxidants (e.g., transition metals) coming into contact with oil-soluble reactants (e.g.,
polyunsaturated lipids and hydroperoxides) [74]. Park et al. suggested that the long-term stability of
nanoemulsions might exhibit a more significant association with the chemical stability instead of the
physical stability in the case of O/W nanoemulsions with retinol [75].

3.3. Correlative Instability Mechanism

Each instability mechanism is always associated with others or they appear simultaneously [8].
Powell et al. prepared nanoemulsions using Pluronic F68 and various oils generally utilized for
pharmaceutical and cosmetic applications, and explored their stability mechanisms. The eventual
destabilization appeared due to the rising of large drops which formed through coalescence and
Ostwald ripening and coalescence were responsible for the formation of large drops, which rose to cause
the ultimate destabilization [76]. According to Chen et al., for pure cinnamaldehyde, a transparent
layer was evident at the top of the nanoemulsion samples, showing that storage prompted the oil
droplets to sink to the bottom of the test tube, and might be attributed to both the physical and chemical
effects, such as chemical interaction, coalescence, Ostwald ripening, and sedimentation. In detail,
cinnamaldehyde displays relatively high water-solubility, inducing droplet expansion via Ostwald



Molecules 2019, 24, 4242 11 of 37

ripening. Consequently, the mean particle size of the nanoemulsions expands, resulting in accelerated
droplet coalescence and sedimentation [65].

4. Nanoemulsion Stabilizer

In order to satisfy the specific requirements of commercial applications, nanoemulsions should
be designed to improve their kinetic stability, which is achieved through meticulous structure and
composition control. Particularly, it is critical to select adequate aqueous and oil phases, as well as the
most suitable additives, such as emulsifier, weighting agent, texture modifier, and ripening inhibitor [6].
The stabilization mechanism usually refers to the physicochemical properties of nanoemulsion such as
composition, interfacial composition, electric charge, droplet size, physical state, aggregation state,
rheology property and so on [3,6].

For instance, apart from decreasing the droplet size, gravitational separation can also be reduced
by adding thickeners to improve the viscosity of the aqueous phase, or adding weighting agents to
decrease the density contrast. Droplet aggregation due to flocculation and coalescence can be restricted
by making sure that the repellent interactions (e.g., steric and electrostatic) of droplets exceed their
attractive interactions (e.g., hydrophobic, van der Waals, and depletion). This is often accomplished
by changing the aqueous phase composition or the nature of the emulsifier used [6]. The addition
of ripening inhibitors or the utilization of an oil phase displaying low water-solubility, can restrict
Ostwald ripening [6,77].

4.1. Emulsifier

During homogenization, the emulsifiers denoting a group of surface-active amphiphilic molecules
adsorb onto the oil–water interface. Their primary function is to reduce the interfacial pressure to
disrupt the droplets and create a defensive interfacial layer to restrict droplet accumulation [78].
Various emulsifier types are used in different industries for the stabilization and formation of
nanoemulsions [79]. In the food industry, low-molecular-weight surfactant (LMWS, e.g., Tween
series, Span series, phospholipid, glycolipid and so on), high-molecular-weight emulsifier (HMWE,
e.g., protein and polysaccharide), and the mixture of them are commonly used [78]. The specific
emulsifier that is used primarily ascertains the interfacial properties of nanoemulsions obtained, such
as hydrophobicity, thickness, chemical reactivity, and electric charge. As a consequence, the choice of a
suitable emulsifier is extremely important to prepare nanoemulsions for special applications.

4.1.1. Low-Molecular-Weight Surfactant (LMWS)

LMWS usually consist of a defined hydrophilic head (which can be nonionic or charged) and
a hydrophobic tail that is generally constituted of one or more acyl chains, may be synthetic or
natural. The molecular weight of those LWMSs is between approximately 250 g/mol to approximately
1200 g/mol [78,79]. In this section, different kinds of LMWSs for nanoemulsions’ preparation are
summarized in Table 3 and introduced as follows.

Synthetic Low-Molecular-Weight Surfactant (LMWS)

Examples of synthetic food-grade LMWS include mono- and diglycerides, sucrose esters,
derivatives of monoglycerides, and polyoxyethylene derivatives, such as Tween series, Span series,
sucrose monopalmitate and so on.

Li et al., prepared nanoemulsions using various surfactants and co-surfactants. Five suitable
surfactant mixtures of surfactants were identified, including Cremophor EL/glycerol (1:1, m/m),
Cremophor EL/1,2-propanediol (1:1, m/m), Tween 80/polyethylene glycol-400 (3:2, m/m), Tween
80/ethanol (3:2, m/m), and Tween 80/1,2-propanediol (3:1, m/m). All five nanoemulsions were
exceedingly stable, exhibiting mean droplet sizes under 20 nm for a minimum of 28 days [80].
According to Rajitha et al., the preparation of nanoemulsions was achieved by using Tween 80 as
surfactants. The prepared nanoemulsions displayed a mean particle size of 34 nm, a negative surface



Molecules 2019, 24, 4242 12 of 37

charge and a pH level that was skin compatible. The nanoemulsions were stable during storage
in a refrigerator for the entire experimental period (3 months) [81]. According to Rebolleda et al.,
nanoemulsions containing particle sizes of 40 nm can be obtained by combining 1% oil with 7.3%
surfactant mixture (37.4% of Span 80 and 62.6% of Tween 80). Nanoemulsions exhibited good stability
when stored at 4 ◦C for 60 days and only a slight destabilization occurred in the last days of the storage
at 25 ◦C for 60 days [82]. According to Llinares et al., nanoemulsions formulated by microfluidization
with different HLB values (obtained by using different Tween 80 and Span 80 mixtures) and surfactant/
oil ratio. Stable nanoemulsions with lowest droplet size (2.88 nm) were obtained when HLB was 10.5
and surfactant/ oil ratio was 1 [50].

Table 3. Examples of low-molecular-weight surfactants (LMWS) for nanoemulsions’ preparation.

Types LMWS Reference

Synthetic LMWS

Mixture of Cremophor EL and
glycerol/1,2-propanediol,
Mixture of Tween 80 and

PEG-40/ethanol/1,2-propanediol

[80]

Tween 80 [81]
Mixture of Tween 80 and Span 80 [50,82]

Natural LMWS

Sunflower Phospholipids [83]
Lecithin [84]

Modified Sunflower Lecithins
(Deoiled, Hydrolysed, Fractionation

with absolute ethanol)
[85]

Lysophosphatidylcholine
(Enzymatically Modified) [86]

Rhamnolipids [68,87]
QS [88–90]

Tea Saponins [91]
GS [70]

Argan Saponins [92]

Saponin extracted from the pericarp of
Sapindus mukorossi [93]

Natural Low-Molecular-Weight Surfactant (LMWS)

Although synthetic LMWS are extensively employed in the food industry, there remains increasing
interest in natural, biobased alternatives because of their low cytotoxicity [78,94]. Phospholipids,
glycolipids and saponins are usually used as natural LWMSs to produce nanoemulsions.

Phospholipids. Phospholipids are amphiphilic molecules naturally found in the cell membranes
of animals, plants, and microorganisms, which are extensively used as emulsifiers in food products.
The most common phospholipids in food-grade lecithins include phosphotidyletanolamine (PE),
phosphatidylcholine (PC), phosphatidic acid (PA), and phosphatidylinositol (PI) [94].

According to Komaiko et al., nanoemulsions (d < 150 nm) can be formed from sunflower
phospholipids. They have a surfactant-to-oil ratio higher that 1:1, as well as high PC levels produced
the smallest droplets. Furthermore, electrostatic repulsion was primarily credited for the physical
stability of the nanoemulsions. Therefore, the droplet accumulation occurred at high ionic strengths
(electrostatic screening) and low pH levels (low charge magnitude) [83]. Artiga-Artigas et al. prepared
nanoemulsions by using different kinds of surfactants (Tween 20, sucrose monopalmitate (SMP),
or lecithin). Nanoemulsions with 2.0% w/w lecithin remained stable during a storage period of
almost 86 days, while those containing Tween 20 or sucrose monopalmitate at equal concentrations
demonstrated destabilization after 5 days and 24 h, respectively [84]. Furthermore, modified
phospholipids have also been used as emulsifiers, but nearly no improved stability of modified
phospholipids-stabilized nanoemulsions has been achieved so far. As reported by Cabezas et al.,



Molecules 2019, 24, 4242 13 of 37

the nanoemulsions were prepared by using three modified sunflower lecithins (deoiled, hydrolysed,
and fractionation with absolute ethanol) as emulsifiers. The fine O/W nanoemulsions stabilized
by 1% volume of hydrolyzed sunflower lecithin showed the similar physical stability with those
stabilized by the mixture of hydrolyzed sunflower lecithin and non-hydrolyzed lecithins (0.5/0.5
or 0.75/0.25, m/m) [85]. Furthermore, O/W nanoemulsions prepared with lysophosphatidylcholine
(enzymatically modified PC) were less stable than those prepared with nature PC, despite their higher
water affinity [86].

Glycolipids. Glycolipids are surface-active compounds generated by a variety of microorganisms
comprised of fatty acids connected to a carbohydrate moiety. Rhamnolipids, sophorolipid, trehalolipids,
cellobiose lipids and mannosylerythritol lipids denote the most prevalent glycolipids [95,96]. Among
them, rhamnolipids were most usually used to prepare nanoemulsions. According to Deepika et al.,
a rhamnolipid biosurfactant manufactured using the mangrove sediment bacterium, Pseudomonas
aeruginosa KVD-HR42, reduced the surface tension from 65.23 to 30.14mN/m at a critical micelle
concentration value of 100mg/L, and showed excellent emulsion-forming capabilities. Furthermore,
severe NaCl concentrations, temperature, and pH levels did not adversely affect the stability of
the biosurfactant [87]. According to Bai et al., rhamnolipids were also suitable for use during the
formation of nanoemulsions with small droplets (surface-weighted mean diameter (d32) < 150 nm).
Rhamnolipid-coated droplets remained stable and could accumulate at various pH levels (5–9),
temperatures (20–90 ◦C), and salt concentrations (<100 mM NaCl). However, droplet accumulation
was evident in conditions involving high ionic strengths (200–500 mM NaCl), as well as highly acidic
(pH 2–4) environments [68].

Saponins. Saponins can be derived from various natural sources and denote a substantial category
of surface-active molecules comprised of hydrophobic areas such as phenolic structures, as well as
hydrophilic areas, including sugar groups [94].

Quillaja saponins (QS) is commonly used to prepare nanoemulsions. Sedaghat et al., suggested that
as a natural surfactant, QS can produce smaller nanoemulsions compared to SMP and octyl modified
starch (O-MS). Additionally, Nanoemulsions stabilized by QS were more resistant to stress conditions
(e.g., acidic pH and salt) while the nanoemulsions prepared with SMP were highly unstable [88].
According to Zhang et al., QS was superior to modified starch (MS) during nanoemulsion preparation,
with the smallest mean particle size of 69 nm, while the turbidity was signified by 102 nephelometric
turbidity units at 0.05% of the dispersed phase [89]. The effectiveness of numerous natural emulsifiers
at preparing O/W nanoemulsions were compared. The results showed that QS and WPI required a
lower amount of emulsifier to more efficiently induce nanoemulsion formation exhibiting droplets that
were smaller and finer than other two emulsifiers [90].

Additionally, saponins from other sources can also be used as emulsifiers. According to Zhu et al.,
nanoemulsions with particle (d < 200 nm) were stabilized by tea saponins displaying fairly low
surfactant-to-oil ratios. The subsequent nanoemulsions remained stable in conditions marked by a
variety of salt concentrations (≤200 mM NaCl), temperatures (30–90 ◦C), and pH levels (pH 3–8).
Moreover, an excellent long-term stability was observed when storing the nanoemulsions at varying
temperatures (5 ◦C, 37 ◦C, and 55 ◦C) [91]. According to Shu et al., Ginseng Saponins (GS) were
capable of producing nanoemulsions (volume mean diameter (d4,3) ≈ 125 nm) by HPH method. The
obtained nanoemulsions were stable without droplet coalescence in the case of thermal treatment
(30–90 ◦C, 30 min), storage (15 days at 5, 25 and 40 ◦C) and a limited pH level range. However,
nanoemulsions fabricated from GS were unstable when salt was present (>25 mM NaCl) and when
exposed to acidic environments (pH 3–6). The chemical stability of nanoemulsions relied significantly
on the storage temperature [70]. According to Taarji et al. a natural extract from argan oil press-cake
containing saponins could be utilized for producing nanoemulsion with limited particle sizes and
excellent physical stability compared to those obtained with Tween 20. However, these nanoemulsions
obtained were highly sensitive to the addition of salt (≥25 mM) and extreme acidic pH levels (pH
< 3) [92], leading to instability. According to Gundewadi et al., nanoemulsions were obtained by



Molecules 2019, 24, 4242 14 of 37

USH method with particle size of 37.7–57.6 nm when saponin extracted from the pericarp of Sapindus
mukorossi (0.4%) was used as biosurfactant [93].

4.1.2. High-Molecular-Weight Emulsifier (HMWE)

HMWEs comprises of different types of water-soluble molecules, mainly proteins and
polysaccharides [97]. In this section, different kinds of HMWEs for nanoemulsions’ preparation
are introduced as follows and summarized in Table 4.

Table 4. Examples of high-molecular-weight emulsifier (HMWE) for nanoemulsions’ preparation.

Types HMWS Reference

Protein

WPC [98]
WPI [90,99]
SC [100,101]

β-Lactoglobulin [102]
SPI, 7S, 11S [103]
Pea Protein [104]

LPI [105,106]
LPI modified by HPH [107]
Mixture of SC and SPI [108]

Mixture of MC and Globular (SPI,
PPC, WPC) [109]

Mixture of Zein and SC [25]
Mixture of SC and PPI [110,111]

Polysaccharides

GA [99,112,113]
SBP [113]

UHMP [114]
Pereskia Aculeata Miller [115,116]

WSMM [117]
OSA-Starch [118–120]
OSA-β-CD [121]
OSA-KG [122]

Mxiture of Protein and Polysaccharide
Mixture of SC, GA and WPH [123]
Mixture of WPI and Chitosan [124]

Mixture of SC and Pectin [125]

Conjugate of Protein and Polysaccharide

Conjugate of WPI and Dextran [126]
Conjugate of WPI and GG [127]

Conjugate of WP and Maltodextrin [128]
Conjugate of Ovalbumin and

D-lactose [129]

Conjugate of WPC and Pectin [130]

Conjugate of Protein/peptide and
Polyphenol

Conjugate of Lactalbumin and
Catechin [131]

Conjugate of ZH and TA [132]
Conjugate of RPH and CA [133]

Protein

Many food proteins, derived from plants, animals, insects, and microorganisms, are amphiphilic
molecules able to adsorb to the surfaces of oil droplets and stabilizing them against agglomeration.
Additionally, proteins tend to adsorb at the interface of oil and water, creating a viscoelastic film that
protects emulsion droplets against physical destabilization, particularly coalescence [134,135].

Animal protein. Proteins from animal origin, particularly from milk (whey protein (WP), casein
and β-lactoglobulin), have been widely used as emulsifiers but with differences in their emulsification
properties. Hwang et al. prepared nanoemulsions stabilized by whey protein concentrate (WPC).
Nanoemulsions with spherical forms and particle sizes between 190 nm and 210 nm were obtained [98].
As mentioned above, Bai et al. found that nanoemulsions with fine droplets are formed more efficiently
in the presence of WPI and QS than those of the other two emulsifiers, and require considerably less
emulsifier, while smaller droplets are produced [90]. Ozturk et al. prepared nanoemulsions using
two kinds of natural biopolymers (WPI and GA). The results showed that WPI was superior to GA in
utilizing low emulsifier concentrations to produce small droplets [99]. According to Zhang et al., O/W
sodium caseinate (SC) stabilized nanoemulsions exhibited desirable physical stability when subjected



Molecules 2019, 24, 4242 15 of 37

to heat treatment (80 ◦C, 90 min) and ion strength (100–500 mmol/L). However, nanoemulsions were
prone to accumulation when the pH levels were in close proximity to the isoelectric point of the casein
(pH 4–5) [100]. According to Kumar et al., SC nanoemulsions remained stable in differing processing
conditions such as ionic strength (0.1–1.0 M), temperature (63–121 ◦C), and pH (3–7) [101]. According
to Ali et al., nanoemulsions containing 1 wt% of β-lactoglobulin and 5 wt% of Miglyol 812 (the oil
displaying the lowest viscosity level) exhibited an exceedingly small droplet size (about 200 nm),
as well as low PDI. Additionally, the nanoemulsions were the most stable over 30 days at least [102].

Plant protein. Plant proteins have gained increasing interest as sustainable alternatives for
their animal-based counterparts to produce nanoemulsions in recent years [136]. Xu et al. prepared
nanoemulsions by ultrahigh pressure homogenization using soy protein isolate (SPI), β-conglycinin
(7S) or glycinin (11S) (two major proteins of SPI) as emulsifier. All nanoemulsions exhibited desirable
stability when subjected to different ionic strengths (0–500 mM NaCl), pH levels (<4 or >7), temperatures
(30–60 ◦C) and storing periods (0–45 days) [103]. Schoener et al. fabricated nanoemulsions with pea
protein as the emulsifier and found that the characteristics denoting digestion and bioaccessibility in
the nanoemulsions relied on carrier oil types (corn, fish and flaxseed oil) [104]. Primozic et al. studied
the influence of the concentration of lentil protein isolate (LPI) on the rheological nature, formation,
and stability of O/W nanoemulsions. They found that the average particle size for all nanoemulsions
ranged from 161 to 357 nm, unchanged over 28 days [105]. According to Tabilo-Munizaga et al., stable
lentil protein-based nanoemulsions were obtained by the HPH method (above 200 MPa, 2 passes)
using 1:1 of emulsifier: oil ratio [106]. According to Primozic et al., LPI was physically modified by
HPH and used as an emulsifier. Comparing to the unmodified LPI-stabilized nanoemulsions, the
nanoemulsions stabilized by modified LPI demonstrated a decline in the particle size to below 200 nm,
increase in their storage stability, less protein aggregation and more digestible [107].

Mixed animal protein and plant protein. Due to the inferior emulsifying qualities of the plant
proteins, researchers have consistently attempted to develop emulsions by using a combination of
plant proteins and animal proteins, especially SC and micellar casein (MC) [110]. According to
Ji et al., achieving stability in O/W nanoemulsions with uniform droplets (~250 nm, PDI <0.2) required
combining SC, SPI and HPH for their formation [108]. Liang et al. studied the influence of the
concentration levels and types of globular proteins on the flow behavior and physical characteristics
of nanoemulsions stabilized by MC-globular protein mixtures. The results showed the formation of
nanoemulsions (<300 nm), while the globular protein sources and the mixed MC-globular protein
ratios exhibited no significant effect on the nanoemulsification. The heat stability of the mixed
protein-stabilized nanoemulsions can be ranked as MC-SPI > MC-pea protein concentrate (PPC) >

MC-WPC at equal globular protein ratios [109]. Wang et al. created nanoemulsions which were
stabilized with a mixture of zein and SC. The subsequent nanoemulsions exhibited a spherical
morphology with a negative surface zeta-potential (from −28.5 mV to −35.8 mV), and a clearly
defined diameter (approximately 109 nm−139 nm). Moreover, the entrapment efficiency reached
84.24% with 2% (m/v) SC/zein at a 1:1 mass ratio. This formulation further indicated the most limited
size distribution leading to exceptional stability during an ambient storage (22 ◦C) period of up
to 30 days, while retaining excellent redispersibility following freeze-drying or spray-drying [25].
Yerramilli et al. prepared mixed protein-stabilized O/W nanoemulsions with a mixture of SC and pea
protein isolate (PPI) (1:1) and then compared them with those prepared with SC or PPI alone. The mixed
protein-stabilized nanoemulsions remained stable displaying no changes in droplet size and creaming
over the 6-month storage period, while SC-stabilized nanoemulsions exhibited depletion-induced
destabilization and PPI-stabilized nanoemulsions displayed extensive aggregation and enhanced
viscosity [110]. Nanoemulsions prepared by the mixture of SC and PPI (1:1) were stable without
significant changes in the droplet size during the storage of eight weeks [111].



Molecules 2019, 24, 4242 16 of 37

Polysaccharides

Numerous natural or chemically altered polysaccharides were used to form and stabilize emulsions
because they contained polar as well as non-polar groups on one molecule, such as GA, pectin, modified
starch (MS) and so on [94].

GA. Gum Arabic (GA) is one of the natural polysaccharide emulsifiers most widely used in food
and beverage. GA consists of a hydrophobic polypeptide backbone covalently attached to numerous
hydrophilic anionic polysaccharide chains consisting of arabinose, galactose, rhamnose and glucuronic
acid [137]. Moradi et al. prepared GA-stabilized nanoemulsions. The prepared nanoemulsions with a
zeta-potential of −13.5 mV to −47.8 mV and particle sizes between 10.01 nm and 171.2 nm revealed
the dilatant rheological qualities, as well as adequate radical scavenging antioxidant activity [112].
Bai et al. compared the effect of three different polysaccharide emulsifiers (GA, Beet Pectin (BP), and
corn fiber gum) on the formation and stability of O/W emulsions. The results demonstrated that
GA and BP were more efficient than corn fiber gum, and required less emulsifier, while producing
smaller droplets [113]. As mentioned above, Ozturk et al. prepared nanoemulsions using two kinds of
natural biopolymers (WPI and GA) and found that WPI was superior to GA in utilizing low emulsifier
concentrations to produce small droplets. However, at elevated temperatures and high ionic strength,
the nanoemulsions stabilized by WPI displayed flocculation instability near the protein isoelectric
point, while the GA-stabilized nanoemulsions remained stable [99].

Pectin. Pectin, a complex polysaccharide, includes three domains, namely rhamnogalacturonan-I
homogalacturonans, and rhamnogalacturonan-II [138]. The degree of methoxylation (DM) of pectin
varied with the variety, botanical origin, extraction conditions, and plant maturity. High methoxylated
pectin (HMP) with a DM of 60–80% are generally representative of commercial pectin derived from
apple pomace or citrus peel [139]. Pectin has been used as an emulsifier alone, such as sugar beet
pectin (SBP) and ultra-high methoxylated pectin (UHMP), but is usually examined as pectin-protein
complexes due to a lack of sufficient lipophilic moieties to adsorb the oil phase [140,141].

SBP contain more acetyl groups at the O-2 and O-3 positions within the galacturonic backbone,
as well as more covalently bound proteins evident in the lateral chains, and higher phenolic ester
content. The presence of these protein and phenolic groups signal its adsorption to the oil-water
interfaces, while reducing the interfacial tension [142,143]. As reported by Bai et al., the smaller droplet
diameter (310 nm) was obtained at 1% SBP, rather than that of 3% GA (740 nm) and 5% corn fiber gum
(4800 nm) [113]. UHMP can be prepared by esterification of common HMP. According to Hua et al.,
UHMP (molecular weight (MW) of 15,000 g/mol and DM of 91.02%) nanoemulsions prepared by the
EPI method at 20%–50% of solid-to-oil ratios had a 400 nm approximate small mean particle size
with a 17–20% creaming index. Additionally, the UHMP nanoemulsions were stable during 56 days
of storage, as well as a 14-day storage period at pH levels of 2–8. Moreover, thermal treatment at
a temperature of 85 ◦C accelerated the flotation capacity of large droplets without fracturing them.
The good emulsion property of UHMP can be attributed to the fact that high DM caused by sufficient
hydrophobic groups (e.g., methyl) could improve the lipophilicity of UHMP to adsorb the oil phase,
and reduce charge repulsions, which enhanced the pliability and pH stability of the interfacial pectin.
Furthermore, the small MW of UHMP induced the disintegration and motion of UHMP in the aqueous
environment [114].

Plant mucilage. Plant mucilages are hydrocolloids of vegetable origin, usually extracted from the
seeds, exudates, fruits, leaves, and tubers of upper plants. According to Martin et al. and Lago et al.,
the mucilage derived from the leaves of pereskia aculeata miller (or Ora-Pro-Nobis (OPN) in Brazil)
is mainly a polysaccharide rich in arabinogalactan and consists of arabinose, galactose, galacturonic
acid, and rhamnose, and is related to proteins. When OPN mucilage was used as an emulsifier,
nanoemulsion (116 ≤ d32 ≤ 171 nm) with increased density, polydispersity, and zeta-potential were
formed when using higher OPN mucilage concentrations and lower soybean oil levels [115,116].
According to Wu et al., compared with two commercial emulsifiers-GA and citrus pectin, water-soluble
yellow mustard mucilage (WSMM) exhibited the better emulsion stability and the higher surface



Molecules 2019, 24, 4242 17 of 37

activity. Additionally, WSMM also showed the highest zeta-potential and the best storage stability,
thermostability and freeze-thaw stability among the three polysaccharides [117].

Octenyl succinic anhydride-modified polysaccharide. Octenyl succinic anhydride (OSA) is
usually used to modify polysaccharides, such as starch, β-cyclodextrin (β-CD), Konjac glucomannan
(KG), GA, dextrin and so on [144,145].

OSA-modified starch (OSA-MS) is an effective emulsifier used to form various O/W emulsions
due to the content of its additional dual-function (hydrophobic and hydrophilic) groups. Sharif et al.,
prepared nanoemulsions by using OSA modified waxy maize starch as an emulsifier. A monomodal
size distribution was evident in the nanoemulsions demonstrating a mean particle size under 200 nm
and a zeta-potential exceeding −30 mV, suggesting that the dispersed oil droplets experienced a
strong electrostatic repulsion. Furthermore, the nanoemulsions displayed stability and shear thinning
towards coalescence during storage (4 weeks at 25 ± 2 ◦C) and prolonged bactericidal activities [118].
Sharif et al., prepared nanoemulsions using two OSA-MS (Purity Gum Ultra and Purity Gum 2000)
as emulsifiers. The results showed that Purity Gum ultra-stabilized nanoemulsions was higher than
Purity Gum 2000-stabilized nanoemulsions after storage for four weeks at 40 ◦C [119]. According
to Li et al., lycopene nanoemulsions stabilized by OSA-MS were fabricated using HPH. Lycopene
molecules tended to reside in the hydrophobic core of the O/W nanoemulsion droplets in the presence
of low lycopene concentrations. However, with increased lycopene loading, the molecules extended
into the O/W interface, reinforcing the lateral OSA molecule packing on the interfacial membranes,
while reduced mean particle size enhanced nanoemulsion stability [120].

Recently, OSA-β-cyclodextrin (OSA-β-CD) and OSA-Konjac Glucomannan (OSA-KG) have also
been successfully used to stabilize nanoemulsions. According to Cheng et al., the nanoemulsions
prepared by OSA-β-CD with different degree of substitution (DS) had a smaller oil droplet size
and better storage stability compared with those of the nanoemulsions fabricated using β-CD [121].
Li et al. prepared nanoemulsions stabilized by OSA-KG. The maximum emulsification yield exceeded
95%. Additionally, the droplet size and PDI of the OSA-KG nanoemulsion were below 5 nm and 0.5,
respectively, after 30 d of storage [122].

Some natural emulsifiers are ineffective during the formation and stabilization of oil-in-water
emulsions when used separately but become effective when used in combination with others. Different
combinations can be adopted to improve emulsifier functionality [146].

Mixture of Protein and Polysaccharide

As reported by Li et al., when SC, GA and whey protein hydrolysate (WPH) were used together
as emulsifiers, they were spontaneously-ordered adsorbed on the droplet surfaces. The oil droplets
of nanoemulsions obtained were fine and stable. Additionally, the stability of nanoemulsions was
enhanced with an increase of the GA ratio, when the concentration of GA reached 2.0 wt%, the
nanoemulsion always maintained homogeneity after storage for 30 days [123]. Silva et al. prepared
nanoemulsions stabilized by WPI and WPI-chitosan mixture. The results indicated that a one-month
storage period, as well as pH levels equal to those found in the stomach, were conducive to the stability
of both nanoemulsions, while phase separation and creaming occurred at intestinal pH levels [124].
As reported by Sharma et al., nanoemulsions were fabricated using SC (5%) and pectin (0.1%) as
emulsifiers by the HSH method. Nanoemulsions remained stable in all common food-processing
conditions, except at pH 3.0–5.0. During storage at at 25 ◦C, the particle size of nanoemulsions increased
from 172.1 ± 4.39 nm (0 th day) to 415.3 ± 23.38 nm (20 th day). The stabilization mechanism can
be attributed to steric repulsion instead of electrostatic repulsion. In brief, the pectin adsorbed on
the surface of the SC particles, leading to the formation of a thick layer during nanoemulsification.
When density and thickness of the pectin layers could adequately maintain the casein particles at a
distance substantial enough to prevent agglomeration via van der Waals attraction, the stability of
nanoemulsions was attained [125].



Molecules 2019, 24, 4242 18 of 37

Conjugate of Protein and Polysaccharide

According to many reports, chemically modifying proteins via polysaccharide conjugation
can maintain their molecular integrity and improve their solubility and emulsifying characteristics,
particularly at low pH levels (e.g., isoelectric point) [147]. Therefore, significant possibilities exist for
using conjugate of protein-polysaccharides as an alternative to protein alone to prepare nanoemulsions.

So far, various protein–polysaccharide conjugates have been formed by Maillard reaction and
used to prepare nanoemulsions. Fan et al. prepared nanoemulsions, which were stabilized with WPI
and WPI-dextran (5 kDa, 20 kDa and 70 kDa) conjugates, with mean particle sizes of 156.8, 156.0 and
155.6 nm, respectively. These values were substantially lower than those stabilized with WPI (165.6 nm).
Furthermore, the pH stability of the nanoemulsions was exhibited a marked improvement following
glycosylation, particularly when the pH level approached the isoelectric point of 5.0. No significant
creaming or flocculation was evident in any of the nanoemulsions after a 30-day storage period at 25 ◦C
and 50 ◦C [126]. As reported by Farshi et al., nanoemulsions with particle size of 75 nm were prepared
using the USH method with WPI-Guar Gum (GG) as an emulsifier. The significantly improved
physical stability of the nanoemulsion was observed when WPI-GG (GG content of 0.1%–0.2% wt) was
used [127]. Sonu et al. prepared nanoemulsions with the USH technique employing WP–maltodextrin
(MD) conjugates with different ratios as emulsifiers. The mean zeta-potential, droplet size, and poly
dispersity index of nanoemulsions prepared with 5.0% oil and 9.0% WP–MD (1:2 w/w) conjugate
were -19.64 ± 0.23 mV, 116.60 ± 5.30 nm, and 0.205 ± 0.02, respectively. Additionally, nanoemulsions
were stable during different types of food processing procedures (e.g., heat treatments (63 ◦C/30 min
of pasteurization, 80 ◦C/10 min of fore warming, 100 ◦C/10 min of boiling, and 121 ◦C/15 min of
sterilization), pH levels (3.0–7.0), ionic strength (0.1–1.0 M)), and storage conditions (e.g., 15 days
at 25 ◦C) [128]. Liu et al., indicated that the emulsifying properties of the ovalbumin-D-lactose
conjugate were considerably higher than ovalbumin at pH 7.0. Additionally, the nanoemulsions
prepared by ovalbumin-D-lactose conjugate showed good pH, thermal, and storage stabilities [129].
Gharehbeglou et al. comparatively studied WP-pectin conjugate with small molecule surfactants for
preparing and stabilizing double nanoemulsions. The results indicated that the minimum particle size
of Tween 80-stabilized double nanoemulsions and WPC-pectin conjugate-stabilized ones were 98 and
100 nm, respectively. Additionally, the double nanoemulsions that were prepared using WPC-pectin
conjugate presented a zeta-potential below−30 mV; demonstrating enhanced stability during long-term
storage [130].

Conjugate of Protein/Peptide and Polyphenol

It has already been established that protein/peptide–polyphenol conjugates, especially the covalent
conjugates, improve the antioxidant activity of proteins. The oxidative stability of nanoemulsions
stabilized by protein/peptide–polyphenol conjugate is always higher than those stabilized by
protein/peptide alone [148].

As reported by Yi et al., lactalbumin–catechin conjugate was used as an emulsifier to produce
nanoemulsions. The nanoemulsions that were stabilized with lactalbumin and lactalbumin-catechin
conjugates exhibited average droplet diameters of 158.8 and 162.7 nm, respectively [131]. As reported
by Wang et al., Zein hydrolysate (ZH)–tannic acid (TA) complex was used as an emulsifier to produce
nanoemulsions with mean particle size of 120 nm. The nanoemulsions that were stabilized with a
ZH–TA complex presented significant encapsulation efficacy, as well as exceptional physical stability.
Furthermore, the nanoemulsions that were stabilized using a ZH–TA complex displayed higher
oxidative stability with lower levels of lipid hydroperoxides and volatile hexanal than when employing
ZH alone for stabilization [132]. According to Pan et al., the emulsifying capacity of the rice protein
hydrolysates (RPH) could be significantly enhanced following covalent interaction with chlorogenic
acid (CA) at 0.025%. The nanoemulsions stabilized by RPH-CA conjugate possessed a remarkable
physical stability, as evidenced by the lowest changes in size (80 nm) and zeta-potential (3.34 mV) of



Molecules 2019, 24, 4242 19 of 37

the nanoemulsions during storage. Moreover, oxidative stability of RPH-CA stabilized nanoemulsions
was high to successfully restrict lipid oxidative degradation during storage [133].

4.1.3. Mixture of High-Molecular-Weight Emulsifier (HMWE) and Low-Molecular-Weight Surfactant
(LMWS)

In this section, different kinds of mixture of HMWS and LMWE for nanoemulsions’ preparation
are summarized in Table 5 and introduced as follows.

Table 5. Examples of mixture of low-molecular-weight surfactant (LMWS) and high-molecular-weight
emulsifier (HMWE) for nanoemulsions’ preparation.

Types Mixture of LMWS and HMWE Reference

Mixture of protein and surfactant
Mixture of SSPI, Span 80 and Tween 20 [149]

Mixture of SPI and PC [150]
Mixture of WPI/PWP and Lecithin [151]

Mixture of polysaccharide and surfactant Mixture of OSA-Starch and PC [152]
Mixture of GA and Lecithin [153]

Mixture of protein, polysaccharide and surfactant Mixture of SC, β-CD and Tween 20 [154]

Mixture of Protein and Surfactant

Acccording to Dey et al., stable fish oil nanoemulsion stabilized with combination of
three emulsifiers (Sesame Seed Protein Isolate (SSPI), Span 80, and Tween 20) was fabricated.
The nanoemulsion prepared with a mixture of 0.5% (w/v) of SSPI, Span 80 and Tween 20 (1:1)
exhibited a reduced droplet size of 89.68 ± 2.375 nm, while the shelf-life stability improved during
storage for eight weeks [149]. Li et al. produced nanoemulsions by HPH mehod using the mixture
of SPI and PC as emulsifier. The best stability of nanoemulsions was observed when the content of
SPI and PC was 1.5% and 0.22%, respectively, the homogenization condition was 100 MPa/4 times.
Additionally, the average particle size, TSI and emulsification yield of the nanoemulsions obtained was
217 nm, 3.02 and 93.4%, respectively [150]. As reported by Shen et al., nanoemulsions were prepared
by six different emulsifiers, including WPI, Polymerized Whey Protein (PWP), WPI-lecithin mixture,
PWP–lecithin mixture, lecithin and Tween 20. All nanoemulsions obtained had the droplet size of the
194-287 nm, the entrapment efficiency of astaxanthin of 90% and showed good physical and chemical
stability during storage at 4 ◦C [151].

Mixture of Polysaccharide and Surfactant

According to Zhong et al., nanoemulsions stabilized with PC are inherently unstable and prone to
phase separation when exposed to particular environmental stresses, such as moderate ionic strength
and low pH levels. The preparation and stability of PC-stabilized nanoemulsions could be improved
when OSA-MS was combinedly used as emulsifiers [152]. Hu et al. developed nanoemulsions using
lecithin and GA as specific emulsifiers, and studied their antimicrobial capabilities. The results
indicated that the nanoemulsions presenting a particle size of 103.6 ± 7.5 nm were produced during
the homogenizing aqueous phase (0.5% of GA, 0.5% of lecithin, w/v), in the presence of the essential
oil mixture (1.25%, w/v) and ethanol (as a co-surfactant) [153].

Mixture of Protein, Polysaccharide and Surfactant

Cheong et al. fabricated nanoemulsions that were stabilized using SC, Tween 20 and β-CD
and employing the HPH method. The optimum emulsifier concentration and process parameters
were determined to be 10% (w/w) and 28,000 psi/4 cycles, respectively. The nanoemulsions were
obtained with particle size of 122.2 nm, PDI of 0.147, and zeta-potential of −46.6 mV. Additionally,
the nanoemulsions showed good stability during storage ==for up to 6 weeks at 25 ± 2 ◦C [154].



Molecules 2019, 24, 4242 20 of 37

4.2. Weighting Agent

The weighting agent are hydrophobic substances with higher density than water, which include
ester gum, brominated vegetable oil, sucrose acetate isobutyrate, rosin gum, and more [78]. Weighting
agents are commonly employed in the formation O/W nanoemulsions. Since water generally displays a
higher density than both triglyceride and flavor oils, adding a weighting agent at suitable proportions
can increase the density of these compounds until their levels match that of the aqueous phase,
therefore, reducing the tendency for gravitational separation and inhibiting creaming [6,78].

As reported by Llinares et al. adding rosin gum to the dispersed phase of nanoemulsions as
weighting agent led to smaller droplet size values (from 580 nm to 350 nm), while elevated span values
accelerated the emulsion creaming destabilization [155].

4.3. Texture Modifiers

Texture modifiers are substances that are generally included in the continuous phase of emulsions
to achieve modified rheological properties, including thickening agents and gelling agents. Thickening
agents typically comprise of soluble polymers displaying extended structures, and can achieve
higher solution viscosity since it can modify the fluid flow profile. Gelling agents are capable of
generating chemical or physical cross-linking with its neighbors and imparts solid-like properties
to a nanoemulsion solution. The improved stability of nanoemulsions by texture modifiers can
be attributed that the inhibition of droplet movement and thereby the retardation of gravitational
separation [6,78]. Water-soluble polysaccharides and proteins are frequently employed as texture
modifiers, i.g. thickening agents or gelling agents [6].

Many natural and semisynthetic polysaccharides, such as alginates, pectin, chitosan,
carboxymethyl cellulose and so on, are usually considered as ideal thickening agent and gelling agent.
The gelation of alginate needs addition of divalent cations or reduction in pH of solution. The gelation
of pectin occurs at acidic pH or in the presence of calcium or other reagents. The gelation of chitosan
can be obtained by the concentration of aqueous solutions. The gelation of carboxymethyl cellulose
occurs in the presence of polyvalent cation [156]. So far, these water-soluble polysaccharides have
been used as thickening agents or gelling agents in nanoemulsions. According to Artiga-Artigas et al.,
nanoemulsions were prepared by microfluidization with Tween 20 and sodium alginate as emulsifier
and thickening agent, respectively. The smallest particle size was evident in these nanoemulsions at
261 nm, while exhibiting monomodal distributions with a 0.25 polydispersity index. Additionally, the
viscosity, zeta-potential, and whiteness index of nanoemulsions were 22.7 mPa.s, –37 mV, and 57.28,
respectively [157]. However, Salvia-Trujillo et al. observed both positive and adverse effects on the
nanoemulsion stability when sodium alginate was added to nanoemulsions. The positive effect was that
the addition of sodium alginate to the nanoemulsions improved their stability against lipid oxidation.
The negative effect denoted that droplet flocculation remained when sodium alginate concentrations
were higher than 0.05% (w/w) due to the appreciably increased viscosity of the nanoemulsions [158].
Guerra-Rosas et al. prepared nanoemulsions using Tween 80 and HMP as emulsifier and thickening
agent, respectively. The smallest droplet size (11 ± 1 nm) was revealed in the HMP-thickened
nanoemulsion [159]. According to Bai et al., polysaccharides (SBP, corn fiber gum) were used as
thickening agents of Tween 80-stabilized nanoemulsions. The polysaccharide influence at an increasing
solution viscosity and reducing flocculation, declined in the following order: SBP > corn fiber gum [66].
As reported by Thomas et al., nanoemulsion gels were created by incorporating nanoemulsions into 2 %
chitosan. The permeation rate of the nanoemulsion gel (37 ± 0.5 ◦C) emerged at 68.88 µg/cm2/h, which
was significantly lower than the value exhibited by the nanoemulsion (76.05 µg/cm2/h), indicating that
the rat skin permeation in the nanoemulsion gel was restricted. However, the retention of curcumin
on rat skin by nanoemulsion gel (980.75 ± 88 µg) is significantly higher than nanoemulsion (771.25 ±
67 µg) [160]. Arancibia et al. examined two thickeners, namely carboxymethyl cellulose (CMC) and
starch, as well as the influence they had on the physical qualities and lipid bioavailability of based
nanoemulsions. The results showed that starch-thickened nanoemulsions showed a smaller particle



Molecules 2019, 24, 4242 21 of 37

size (75.86–78.81 nm) and zeta-potential values (−1.3 to −6.9 mV) rather than that of CMC-thickened
nanoemulsions (77.62–98.48 nm, −49.7 to −53.3 mV). Additionally, contrary to samples thickened with
starch, the nanoemulsions that were thickened with CMC displayed enhanced stability and a lower
release rate of free fatty acids following lipolysis [64].

Proteins are also used as thickening agent and gelling agent. Primozic et al. reported that the
particle size distribution of flowable nanoemulsions prepared using LPI at 1–2 wt%, approached
a larger peak following a storage period of 28 days. However, the size distribution in the gelled
nanoemulsions that were prepared using 5 wt% LPI exhibited no changes from the original state since
it remained a robust gel following a storage period of 28 days [105].

4.4. Ripening Inhibitor

The ripening inhibitors are substances that are added to the nanoemulsion dispersed phase to
inhibit droplet expansion resulting from Ostwald ripening, therefore, disrupting the mixing effect [78].
These highly hydrophobic molecules exhibit and exceedingly low level of water solubility and are
represented by long-chain triglycerides such as sunflower oil, grape seed oil, corn oil, palm oil and
more. Generally, ripening inhibitors are employed in the preparation of O/W nanoemulsions containing
highly water-soluble oil phases, including flavor and essential oils [6].

Ryu et al. studied the effect of ripening inhibitor types (corn oil, palm oil, coconut oil, and canola
oil) on thyme oil emulsion stability, formation, and antimicrobial activity. A sufficient concentration of
ripening inhibitor was determined to be around 40% of the oil phase, while continued antimicrobial
activity during storage was evident in stable nanoemulsions with small oil droplets (d < 70 nm).
The antimicrobial activity displayed by the nanoemulsions was determined by the specific characteristics
of the ripening inhibitors used and their capacity to redirect hydrophobic antimicrobial components to
the segregated hydrophobic domain, leading to a decrease in the following order: palm oil ≈ corn oil >

canola oil > coconut oil [72]. As reported by Chang et al., the nanoemulsions prepared by combining an
appropriate amount of ripening inhibitor (≥60 % corn oil or ≥50 % medium chain triglyceride (MCT))
with essential oil demonstrated physical stability [161]. As reported by Zhang et al., the addition of
ester gum (EG) into the oil phase not only altered the viscosity of the phase, but also impeded Ostwald
ripening. As a result, QS-stabilized nanoemulsions retained their stability during a storage period of
two weeks at 23 ◦C, while nanoemulsions that were stabilized using MS displayed significantly higher
turbidity and mean particle sizes [89].

The weighting agent, texture modifier and ripening inhibitor used for nanoemulsions’ preparation
are summarized in Table 6.

Table 6. Examples of weighting agent, texture modifier, ripening inhibitor for nanoemulsions’ preparation.

Types Stabilizers Reference

Weighting Agent Rosin Gum [155]

Texture Modifiers

SBP [66]
Corn Fiber Gum [66]

CMC, Starch [64]
Sodium Alginate [157,158]

HMP [159]
Chitosan [160]

LPI [105]

Ripening Inhibitor

Corn Oil, Palm Oil,
Coconut Oil, Canola Oil [72]

MCT [161]
Ester Gum [89]



Molecules 2019, 24, 4242 22 of 37

5. Applications in Encapsulation of Bioactive Compounds

The use of many bioactive compounds, such as bioactive lipids, essential oils, flavor compounds,
vitamins, polyphenols, carotenoids and so on in the food industry remain challenging due to their
inadequate solubility in water as well as their stability in food preparations [14,162]. Generally,
nanoemulsions are usually designed to retain bioactive compounds during storage within a food
product but control their release when they encounter specific environmental conditions, such as the
mouth for flavors or the gastrointestinal tract for pharmaceuticals or nutraceuticals [163]. Additionally,
the delivery and slow release of hydrophobic bioactive compounds in O/W conventional emulsions or
nanoemulsions are beneficial to enhance their bioaccessibility by improving their solubility and the
incorporation of them into mixed micelles of the simulated gastrointestinal tract (GIT) system [164,165].

5.1. Bioactive Lipids

Essential polyunsaturated fatty acids (PUFAs), especially omega-3 oils, e.g., eicosapentaenoic
acid (EPA), docosahexaenoic acid (DHA), α-linoleic acid and α-linolenic acid, are the main bioactive
lipids [166,167]. PUFAs reportedly have substantial health benefits, such as the neuroplasticity of
nerve membranes, nervous system activity, memory-related learning, cognitive development, synaptic
transmission, and synaptogenesis [168]. However, bioactive lipids are highly unstable against oxidation
and presented low odor thresholds. Therefore, exceedingly low concentrations affected the sensory
parameters. Encapsulation of bioactive lipids in nanoemulsions is beneficial in reducing autoxidation,
displaying compatibility with various food products, enhancing functional properties, solubilizing
flavor or volatile compounds in lipids, while masking bitter or astringent tastes [169].

According to Zhang et al., stable DHA and EPA nanoemulsions were prepared by EPI method.
Within 20 days, the best nanoemulsions have good physical stability under different storage conditions,
and the retention rate of DHA/EPA can be stabilized at >60% [26]. Dey et al., suggested that
nanoemulsions demonstrated a considerably higher uptake rate of PUFAs in three small intestinal
regions, compared to conventional emulsions. Meanwhile, nanoemulsions showed a stronger resistance
to lipopolysaccharide-induced nitric oxide production in the peripheral blood mononuclear cells of
rats [49]. As reported by Karthik et al., DHA O/W nanoemulsions were fabricated by microfluidization
using Tween 40, SC or SL as emulsifiers. Among them, Tween 40 stabilized nanoemulsions showed
improved stability and extent of lipid digestibility [51].

5.2. Essential Oils and Flavor Compounds

Essential oils, in the form of aromatic volatile liquids, as well as semi-liquids, are commonly
derived from the seeds, flowers, leaves, buds, fruits, bark, resins, and roots of plants. The antimicrobial
activity provided by essential oils is beneficial against several types of fungi, Gram-positive bacteria,
and Gram-negative bacteria [170]. The nature of essential oils, including hydrophobic, volatile and
reactive, limits the incorporation of them into food matrices directly [171]. The significant application
challenges regarding the incorporation of essential oils into food could be negated by their encapsulation
in nanoemulsions. Essential oils loaded within nanoemulsions can be formed by two methods.

One method is homogenizing essential oils in the aqueous solutions containing emlsifier. According
to Xue et al. and Ma et al., nanoemulsions containing essential oils (e.g., thyme oil, eugenol) were
fabricated by directly homogenizing the essential oils in the aqueous solutions containing CS and
lecithin, indicating that the antimicrobial characteristics were similar or exceeded those of the free
essential oils [172,173]. As reported by Wang et al., eugenol (2-methoxy-4-(2-propenyl)-phenol),
which forms a major part of clove essential oil, presents a wide range of antibacterial and antifungal
activity. Eugenol-loaded nanoemulsions stabilized by the mixture of zein and SC were prepared by SE
method. The results showed that the entrapment efficiency of eugenol was 84.24% when 1% (v/v) of
eugenol and 2% (m/v) of SC/zein (1:1 mass ratio) were used. The obtained nanoemulsions demonstrated
the most restricted size distribution, and retained remarkable stability throughout a storage period



Molecules 2019, 24, 4242 23 of 37

at ambient temperatures (22 ◦C, 30 days), while exhibiting exceptional redispersibility following
freeze-drying or spray-drying [25]. According to Sharma et al., a synergistic O/W nanoemulsion
containing clove and lemongrass oil was developed and its potential as antifungal agents was explored.
The antifungal activity of clove and lemongrass oil was enhanced by formulation in nanoemulsions [174].
According to Moghimi et al., stable nanoemulsion of Thymus daenensis oil was produced by utilizing
lecithin and Tween 80 as emulsifiers, with droplet size of 171.88 ± 1.57 nm. The nanoemulsions showed
stronger antibacterial activity than pure oil against Acinetobacter baumannii, which is notoriously
resistant to multiple drugs. This result is evidenced by the minimum inhibitory concentration of
nanoemulsion and pure oil being 30–45 µg/mL and 62.5–87.5 µg/mL, respectively. Additionally, after
incubation for 24 h, the nanoemulsions exhibited remarkable anti-biofilm activity at a sub-lethal dose
(56.43% inhibition in 1/2 minimum inhibitory concentration) [55].

Another method is to pre-dissolve essential oils in commonly used oils and then emulsified in
the aqueous phase. As reported by Yang et al., nanoemulsions containing the mixtures of citrus oils
(e.g., bergamot oil and sweet orange oil) and common triacylglycerol oils (e.g., corn oil and MCT
oil) with different mixing ratios were produced. The subsequent results suggested that the stability
of nanoemulsions that contain mixed oil significantly exceeded that of nanoemulsions containing
pure citrus oil [175]. As reported by Tian et al., it was difficult using pure cinnamaldehyde as the oil
phase to form stable nanoemulsions. Stable nanoemulsions containing cinnamaldehyde were obtained
with the addition of MCT. Additionally, nanoemulsions containing cinnamaldehyde and MCT could
provide an enhanced long-term inhibition on the bacterial growth of Escherichia coli compared with
pure cinnamaldehyde [23].

Recently, essential oil nanoemulsion-containing films have been produced and used for active
food packaging. However, this aspect has been extensively described elsewhere [10] and is not repeated
in the present review.

5.3. Vitamins

As essential micronutrients, vitamins form a crucial part of human health. There are two types of
vitamins: fat-soluble (lipophilic) and water-soluble (hydrophilic). Vitamins A, E, D, and K are grouped
as the lipophilic vitamins, while vitamins B and C are hydrophilic.

Lipophilic vitamins are biologically sensitive material, displaying marginal chemical stability
and water solubility [176]. For instance, Vitamins A, and Vitamins E are easily oxidized, particularly
when exposed to light, heat, light, and metal ions. Furthermore, visible and fluorescent light possessed
the ability to alter the vitamin K structure dramatically. Vitamin D is the only element that was not
significantly affected by the processing and storage environments [177]. Nanoemulsions are usually
fabricated to improve their chemical stability, solubility and oral bioavailability.

Park et al. examined the stability of O/W nanoemulsions containing retinol (vitamin A) when
exposed to ultraviolet (UV) light and subjected to a storage period at varying temperatures (4 ◦C, 25 ◦C,
and 40 ◦C). The results suggested that UV light reduced the residual retinol in the emulsion systems that
utilized low oil concentrations during preparation compared to bulk oil. However, oil concentrations
exceeding 10 wt% caused residual retinol levels to be higher than in the bulk oil due to elevated emulsion
turbidity [75]. According to Ji et al., the vitamin A palmitate retention ration in the nanoemulsion
exceeded 93% following a storage period of three months at room temperature [108]. As reported
by Kadappan et al., the nanoemulsions-based delivery system increased in vitro bioaccessibility of
vitamin D3 by 3.94 folds, as evidenced by the significantly higher concentration of vitamin D3 in
micelles. An animal study showed that the nanoemulsions significantly increased the serum 25(OH)D3

by 73% [178]. According to Schoener et al., the type of carrier oil (corn oil, fish oil and flaxseed
oil) significantly affected the preparation, simulated gastrointestinal performance and stability of
vitamins D3 nanoemulsions stabilized by pea protein. The results showed that the three lipids were all
digested in the small intestinal simulation model within the first few minutes. Additionally, for the
different carrier oils, both the digestion rate in simulated gastrointestinal and vitamin bioaccessibility



Molecules 2019, 24, 4242 24 of 37

declined in the following order: corn oil > fish oil ≈ flaxseed oil [104]. As reported by Lv et al.,
nanoemulsions containing vitamin E were fabricated by dual-channel microfluidizer, using corn oil as
a carrier oil and using QS as an emulsifier. The optimized nanoemulsions resulted in a relatively high
vitamin bioaccessibility (53.9%) [179]. According to Moradi et al., the cellular uptake of a-tocopherol in
nanoemulsions displayed a rise of up to 12 times higher than microsized a-tocopherol [112]. As reported
by Campani et al., nanoemulsions containing vitamin K1 have been prepared to overcome some
difficulties associated to the incorporation of semi-solid vitamin K1 into food formulations. The results
showed that nanoemulsions could offer an option for the commercial development of a liquid and
aqueous formulation to deliver vitamin K1 [180].

5.4. Phenolic Compounds

Phenolic compounds displaying significant antioxidant properties can be employed in biological
preparations and various food products such as anti-microbial, anti-atherogenic, anti-inflammatory,
anti-thrombotic, and anti-allergenic agents [181]. Phenolic compounds are classified into lipophilic
and hydrophilic compounds.

Lipophilic phenolic compounds were usually encapsulated by O/W nanoemulsions. O/W
nano-emulsification, can reportedly improve the bioavailability of lipophilic phenolic compounds
due to higher absorption, solubility, and permeation into the body, as well as the safeguarding of
the lipophilic phenolic compounds in nanoemulsions within food preparations [169]. According to
Kumar et al., curcumin nanoemulsions with sodium caseinate were prepared. The cellular uptake of
curcumin was improved by nanoemulsification because that the slow release of curcumin in the intestine
is beneficial to incorporate it into mixed micelles of the bile salts or phospholipids [101]. Zheng et al.
prepared curcumin nanoemulsions by three different methods (e.g., pH-driven, conventional, and
heat-driven) and compared them with three curcumin supplements that are currently widely available.
The results showed that the bioaccessibility of all curcumin obtained nanoemulsions compared well to
even the most superior commercial formulation. Additionally, the nanoemulsions produced using
the pH-driven technique denoted the highest concentrations of curcumin in the mixed micelles
phase following exposure to a simulation of a gastrointestinal tract [182]. Sugasini et al. prepared a
phospholipid-stabilized nanoemulsion containing curcumin and carrier oil (sunflower oil, coconut oil,
or linseed oil) and explored the possibility of nanoemulsions to enhancing the curcumin bioavailability
and DHA levels in rats. The results indicated the presence of high DHA levels in tissue and serum lipids,
as well as elevated curcumin levels in the serum, heart, liver, and brain of rats given feed nanoemulsions
containing linseed oil and curcumin [183]. According to Silva et al., compared with WPI-nanoemulsions,
nanoemulsions stabilized by WPI-chitosan mixture showed the improved apparent permeability
coefficient of curcumin via Caco-2 cells, as well as the improved bioaccessibility and antioxidant
ability [124]. According to Singh et al., the rate and extent of bioavailability of t-resveratrol was
significantly enhanced by loading in nanoemulsions rather than that of free t-resveratrol. Alongside this,
the results of an in situ single pass intestinal perfusion study showed a remarkable enhancement in the
absorptivity and permeability parameters of nanoemulsions [184]. Son et al. prepared quercetin-loaded
O/W nanoemulsions containing Tween 80, caprylic/capric triglyceride (Captex® 355), soy lecithin,
and sodium alginate using the SE method. The nanoemulsion polydispersity index and particle
size were <0.47 and 207–289 nm, respectively. The nanoemulsions were stable at pH levels ranging
from 6.5–9.0 during a storage period of three months at 21 ◦C and 37 ◦C. Additionally, in rats that
received a diet high in cholesterol, the nanoemulsion containing quercetin displayed a more substantial
efficacy in decreasing the level of serum and hepatic cholesterol, with higher release of bile acid
into feces, compared to free quercetin [185]. As reported by Carli et al., nanoemulsion-encapsulated
quercetin was created with the EIP method and using two separate surfactants, namely Brij 30, and
Tween 80. Nanoemulsions were obtained with mean particle size of 180–200 nm. The retention of
quercetin was around 70% in nanoemulsions that contained 0.30% quercetin (w/w) and were stored
for 90 d. Additio