Effects of Selected Polysorbate and Sucrose Ester Emulsifiers on the Physicochemical Properties of Astaxanthin Nanodispersions

Anarjan, Navideh; Tan, Chin Ping

doi:10.3390/molecules18010768

Cited by 59 publications

(45 citation statements)

References 21 publications

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“…This finding might be explained by the increasing interference caused by the growing number of polysorbate molecules, which prevented the efficient diffusion of the organic phase into the aqueous phase. To the best of our knowledge, there are three other studies by Anarjan and Tan (2013), Cheong, Mirhosseini, and Tan (2010) and Saberi et al (2013), which were similar to our study in the sense that all three studies involved the fabrication of different nanoemulsions/nanodispersions by using Tween 20, 40, 60 and 80 (in the case of Cheong et al (2010), they used only Tween 20, 60 and 80). In their respective studies, Anarjan and Tan (2013) and Cheong et al (2010) found that, among all the Tween emulsifiers used, Tween 20…”

Section: Effects Of Different Polysorbate (Tween) Emulsifierssupporting

confidence: 80%

“…By contrast, Saberi et al (2013) noted that among these four types of Tween emulsifiers, Tween 80 produced nanoemulsions with the smallest particle sizes, whereas the largest particle size was obtained when Tween 60 was used, although both Tween 60 and Tween 80 have similar HLB values (the HLB for Tween 60 is 14.9 and the HLB for Tween 80 is 15.0). In comparing our findings with all three studies, we found that our observations were similar to those of Saberi et al (2013), but they were the exact opposite of the observations noted by Anarjan and Tan (2013) and Cheong et al (2010). In our case, Tween 80 produced smaller particle sizes when compared with Tween 20.…”

Section: Effects Of Different Polysorbate (Tween) Emulsifierscontrasting

confidence: 69%

“…It is interesting to note that our technique (solvent displacement) of producing the nanodispersion is similar to the technique (spontaneous emulsification) used by Saberi et al (2013); both techniques are categorized as low-energy methods. Conversely, Anarjan and Tan (2013) and Cheong et al (2010) employed the high-energy emulsification-evaporation technique. Saberi et al (2013) stated that, besides the HLB value, other factors, such as the molecular geometry of the emulsifier, should also be taken into consideration when trying to explain the effect of Tween emulsifiers on the particle size.…”

Section: Effects Of Different Polysorbate (Tween) Emulsifiersmentioning

confidence: 99%

“…Polysorbates are non-ionic, biodegradable and non-toxic emulsifiers that are commonly used in food products (Anarjan & Tan, 2013). In this experiment, we prepared a series of lutein nanodispersions by using various types and concentrations of Tween emulsifiers, namely Tween 20, 40, 60 and 80.…”

Section: Effects Of Different Polysorbate (Tween) Emulsifiersmentioning

confidence: 99%

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Forming a lutein nanodispersion via solvent displacement method: The effects of processing parameters and emulsifiers with different stabilizing mechanisms

et al. 2016

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A solvent displacement method was used to prepare lutein nanodispersions. The effects of processing parameters (addition method, addition rate, stirring time and stirring speed) and emulsifiers with different stabilizing mechanisms (steric, electrostatic, electrosteric and combined electrostatic-steric) on the particle size and particle size distribution (PSD) of the nanodispersions were investigated. Among the processing parameters, only the addition method and stirring time had significant effects (p<0.05) on the particle size and PSD. For steric emulsifiers, Tween 20, 40, 60 and 80 were used to produce nanodispersions successfully with particle sizes below 100nm. Tween 80 (steric) was then chosen for further comparison against sodium dodecyl sulfate (SDS) (electrostatic), sodium caseinate (electrosteric) and SDS-Tween 80 (combined electrostatic-steric) emulsifiers. At the lowest emulsifier concentration of 0.1%, all the emulsifiers invariably produced stable nanodispersions with small particle sizes (72.88-142.85nm) and narrow PSDs (polydispersity index<0.40).

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Section: Effects Of Different Polysorbate (Tween) Emulsifierssupporting

confidence: 80%

Section: Effects Of Different Polysorbate (Tween) Emulsifierscontrasting

confidence: 69%

Section: Effects Of Different Polysorbate (Tween) Emulsifiersmentioning

confidence: 99%

Section: Effects Of Different Polysorbate (Tween) Emulsifiersmentioning

confidence: 99%

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Forming a lutein nanodispersion via solvent displacement method: The effects of processing parameters and emulsifiers with different stabilizing mechanisms

et al. 2016

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“…Due to the long conjugated unsaturated double bond in the molecular structure of astaxanthin its properties are extremely unstable. Oxygen, light, heat and metal ions can cause damage to astaxanthin, causing it to oxidize or degrade . Astaxanthin possesses two identical asymmetric carbon atoms at C‐3 and C‐3 making three possible isomers with all‐transconfiguration of the chain: 1.)…”

Section: Marine Plant Sourcesmentioning

confidence: 99%

A Review of Pigments Derived from Marine Natural Products

Fan

Keen

et al. 2018

Israel Journal of Chemistry

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Since the early 20th century, a number of active natural pigments have been identified from marine sources, especially algae and marine microorganisms. This review presents 81 marine pigments, covering over 90 % known natural marine pigments. The objective of this article is to provide an overview on the types of pigments, their structural characterization, origins and biological functions that make them unique. We divide the major categories of pigments by chemical structure, either as carotenoids, indole derivatives (quinones and violacein), alkaloids (prodiginines and tambjamines), polyenes, macrolides, peptides, or terpenoids. Many of these pigments have a variety of biological activities, including antitumor, antibacterial, antioxidant and anti‐inflammatory. In addition, we discuss the development of biotechnology, and the contribution and utilization of marine natural pigments and the potential applications in the field of pharmaceutical research.

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Preparation of Highly Stable Z‐Isomer‐Rich Lycopene Nanodispersions via a Continuous‐Flow System with Selected Emulsifiers

Murakami

Kageyama

Hibino

et al. 2022

Euro J Lipid Sci & Tech

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As a potent antioxidant with numerous health benefits, lycopene finds multiple applications. Among the geometric isomers of lycopene, the Z-isomers have greater bioavailability than the all-E-isomer but are less stable and hence, less suitable for practical applications. Herein, highly stable Z-isomer-rich lycopene nanodispersions are produced through the thermal isomerization of (all-E)-lycopene in a flow reactor followed by continuous dispersion in an aqueous emulsifier (Tween 20, sucrose fatty acid ester, or polyglycerol fatty acid ester [PFAE]) solution upon agitation with an in-line swirl mixer. The effects of emulsifier type and other processing conditions (flow rate, pressure, temperature, lycopene Z-isomer ratio) on dispersion efficiency and properties are examined in detail, and finally, Z-isomer-rich lycopene nanodispersions (>60% of total Z-isomer ratio and <10 nm of mean particle size) are successfully obtained. Moreover, it is found that lycopene Z-isomers have greater encapsulation efficiency for dispersions with emulsifiers than that of the all-E-isomer. The storage test of the resulting dispersions clearly shows that the highest storage stability is achieved in the case of using PFAE, which effectively inhibits lycopene degradation and reverse (Z-to all-E) isomerization. Practical applications: To practical use of lycopene Z-isomers, it is essential to improve their storage stability as well as usability (i.e., dispersibility in water). The present study reveals that when producing the lycopene dispersions, the use of PFAE as an emulsifier allows to improve the stability of lycopene isomers and inhibit the Zto all-E-isomerization during storage. Given the high demand for stable Z-isomer-rich lycopene formulations, the obtained results promote the practical use of lycopene Z-isomers in diverse (e.g., food and cosmetic) industries.

show abstract

Effects of Selected Polysorbate and Sucrose Ester Emulsifiers on the Physicochemical Properties of Astaxanthin Nanodispersions

Cited by 59 publications

References 21 publications

Forming a lutein nanodispersion via solvent displacement method: The effects of processing parameters and emulsifiers with different stabilizing mechanisms

Forming a lutein nanodispersion via solvent displacement method: The effects of processing parameters and emulsifiers with different stabilizing mechanisms

A Review of Pigments Derived from Marine Natural Products

Preparation of Highly Stable Z‐Isomer‐Rich Lycopene Nanodispersions via a Continuous‐Flow System with Selected Emulsifiers

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