Producing micron- and nano-size formulations for functional foods applications

Panagiotou, Thomai; Fisher, Robert J.

doi:10.31989/ffhd.v3i7.48

Cited by 14 publications

(4 citation statements)

References 39 publications

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“…In general, more energy is required in the top-down methods as compared to the bottom-up methods [16]. Milling and homogenization are two common top-down approaches in which coarse particles are broken down into small particles [17,18]. In contrast, the "bottom-up" approaches, such as antisolvent precipitation, supercritical fluid technology, and spray freezing into liquid, are seldom employed.…”

Section: Introductionmentioning

confidence: 99%

Synthesis of Cefixime and Azithromycin Nanoparticles: An Attempt to Enhance Their Antimicrobial Activity and Dissolution Rate

Khan

Zahoor

Islam

et al. 2016

Journal of Nanomaterials

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In this study cefixime and azithromycin nanoparticles were prepared by antisolvent precipitation with syringe pump (APSP) and evaporator precipitation nanosuspension (EPN) methods. The nanoparticles were characterized by XRD, FTIR, SEM, and TGA. X-ray diffraction pattern of cefixime samples showed the amorphous form, while azithromycin samples showed crystalline form. The FTIR spectra of parental drugs and synthesized nanoparticles have no major structural changes detected. The SEM images showed that nanoparticles of both drugs have submicron sized and nanosized particles. TGA analyses showed that above 30°C the decomposition of cefixime samples starts and their weight gradually decreases up to 600°C, while, in case of azithromycin, 30°C to 250°C, very small changes occur in weight; from above 250°C decomposition of the sample took place to a greater extent. The antibacterial activities of raw drugs and prepared samples of nanoparticles were determined againstStaphylococcus aureus,Shigella,E. coli, andSalmonella typhiby agar well diffusion method. Every time the nanoparticles samples showed better results than parental drugs. The dissolution rates of raw drugs and prepared nanoparticles were also determined. The results were always better for the synthesized nanoparticles than parental drug.

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Section: Introductionmentioning

confidence: 99%

Synthesis of Cefixime and Azithromycin Nanoparticles: An Attempt to Enhance Their Antimicrobial Activity and Dissolution Rate

Khan

Zahoor

Islam

et al. 2016

Journal of Nanomaterials

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“…It also minimizes the concentrations needed in the food product and sensory effects. Another advantage of particle size reduction is to enable the enrichment of clear beverages with water insoluble nutraceuticals and improvement of the stability of fortified suspensions with nanoparticles. Géze et al.…”

Section: Resultsmentioning

confidence: 99%

Formulation and Characterization of Taxifolin‐Loaded Lipid Nanovesicles (Liposomes, Niosomes, and Transfersomes) for Beverage Fortification

Hasibi

Nasirpour

Varshosaz

et al. 2019

Euro J Lipid Sci & Tech

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In this study, nanovesicles such as transfersomes, niosomes, and liposomes prepared by an ethanol injection method (EIM) (EIM) and formulated with soybean lecithin, Tween 80, Span 60, and cholesterol, are used to improve the bioavailability of taxifolin, a natural antioxidant with beneficial properties for health and food preservation. Morphology, stability, and the in-vitro release of the optimal formulations are fully examined. The obtained results indicate that taxifolin-loaded nanovesicles present sizes ranging between 98 and 215 nm along with a narrow size distribution (polydispersity index less than 0.250). The zeta potential of nanovesicles is negative and in the range of −20.40 to −32.20 mV. The optimal formulations with the maximum encapsulation efficiency (72-75%) are the transfersomes formulated with lecithin and Tween 80 in the presence and absence of cholesterol. Additionally, in vitro release behavior of nanovesicles shows low taxifolin released (3.68-10.13%) at intestinal conditions, whereas more than 90% of taxifolin is released in gastrointestinal conditions. The compatibility between taxifolin and nanovesicles components is confirmed by FTIR. Transmission electron microscopy demonstrates spherical shaped particles around 200 nm. Backscattering profiles variations show the potential application of taxifolin nanovesicles for producing fortified apple juice with excellent physical stability. Practical Applications: Taxifolin is a flavanonol, which fulfills a particular task in preserving stable functions of the circulatory system owing to its special antioxidant ability and biological activity. Nevertheless, its low bioavailability is a salient drawback for biomedical and food applications. Thus, the current study is conducted to encapsulate taxifolin in nanovesicles (such as liposome, niosome, transfersome) by EIM to improve its bioavailability. Nanocarriers with relatively decent physical stability and high encapsulation efficiency can be brought about through Tween 80, soybean lecithin, and in the presence and absence of cholesterol as stabilizer which ensures the successful delivery of taxifolin to food formats such as beverages.

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“…Nanoparticles formed by anti-solvent precipitation show low polydispersity and high encapsulation With respect to food industry, nanoprecipitates produced by solvent displacement mainly aim to incorporate active substances that degrade under common processing conditions (heat, pH, light and mechanical stress), enhancing bioactive payload compared to conventional encapsulation, and to achieve customized release under GI digestion conditions. Solvent displacement nanoprecipitation is regarded as a very efficient method to entrap and stabilize lipophilic substances including carotenoids or hydrophobic polyphenols (curcumin), in food matrices, as well as to improve bioavailability (Chu et al, 2007a;Faisal et al, 2013;Kakran et al, 2012;Lobato et al, 2013;Mitri et al, 2011;Panagiotou and Fisher, 2013;Patel et al, 2010;Ribeiro et al, 2008;Tachaprutinun et al, 2009;Yin et al, 2009). …”

Section: Solvent Displacementmentioning

confidence: 99%

A comprehensive overview on the micro- and nano-technological encapsulation advances for enhancing the chemical stability and bioavailability of carotenoids

Soukoulis

Bohn

2017

Critical Reviews in Food Science and Nutrition

198

135

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Carotenoids are lipophilic secondary plant compounds, and their consumption within fruits and vegetables has been positively correlated with a decreased risk of developing several chronic diseases. However, their bioavailability is often compromised due to incomplete release from the food matrix, poor solubility and potential degradation during digestion. In addition, carotenoids in food products are prone to oxidative degradation, not only lowering the nutritional value of the product but also triggering other quality deteriorative changes, such as formation of lipid pro-oxidants (free radicals), development of discolorations or off-flavor defects. Encapsulation refers to a physicochemical process, aiming to entrap an active substance in structurally engineered micro- or nano-systems, in order to develop an effective thermodynamical and physical barrier against deteriorative environmental conditions, such as water vapor, oxygen, light, enzymes or pH. In this context, encapsulation of carotenoids has shown to be a very effective strategy to improve their chemical stability under common processing conditions including storage. In addition, encapsulation may also enhance bioavailability (via influencing bioaccessibility and absorption) of lipophilic bioactives, via modulating their release kinetics from the carrier system, solubility and interfacial properties. In the present paper, it is aimed to present the state of the art of carotenoid microencapsulation in order to enhance storability and bioavailability alike.

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Producing micron- and nano-size formulations for functional foods applications

Cited by 14 publications

References 39 publications

Synthesis of Cefixime and Azithromycin Nanoparticles: An Attempt to Enhance Their Antimicrobial Activity and Dissolution Rate

Synthesis of Cefixime and Azithromycin Nanoparticles: An Attempt to Enhance Their Antimicrobial Activity and Dissolution Rate

Formulation and Characterization of Taxifolin‐Loaded Lipid Nanovesicles (Liposomes, Niosomes, and Transfersomes) for Beverage Fortification

A comprehensive overview on the micro- and nano-technological encapsulation advances for enhancing the chemical stability and bioavailability of carotenoids

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