Electrosprayed whey protein-based nanocapsules for β-carotene encapsulation

Rodrigues, Rui M.; Ramos, Philippe E.; Cerqueira, M. F.; Teixeira, J. A.; Vicente, António A.; Pastrana, Lorenzo; Pereira, Ricardo N.; Cerqueira, Miguel A.

doi:10.1016/j.foodchem.2019.126157

Cited by 40 publications

(19 citation statements)

References 21 publications

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“…It can be explained with the prevention of coalescence and flocculation as a result of a strong electrostatic impulse (Jain & Anal, 2018). and 1,016.78 nm (Rodrigues et al, 2020). In another study, the mean droplet size of oil/water emulsions containing different surfactants was found to range between 137.9 and 188.8 nm (Zeeb et al, 2015).…”

Section: Droplet Size and Zeta Potential Measurementmentioning

confidence: 95%

Encapsulation of mono,‐diglycerides obtained from rendering waste oil: Powder, interfacial, rheological and emulsion properties

Saraç

Doğan

2021

J. Food Process. Preserv.

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In the present study, the mono,-diglycerides obtained from rendering waste oil were encapsulated with skim milk powder (MP) and whey protein (WP), and the properties of surfactants obtained were determined. The encapsulation procedure performed in order to achieve ease of use and to determine potential protein-surfactant synergetic effects was performed with dry matter rates of 10% and 20% and surfactant/ encapsulation material rates of 1:2 and 1:3 (four different rates for each encapsulation material). The encapsulation efficiency, physiochemical properties, emulsifier stabilities, SEM images, steady, dynamic, and interfacial properties of specimens were determined. WP-coated products yielded better results in effective encapsulation efficiency (between 50.38% and 68.44%) and emulsion stability tests (between 23.99% and 37.77% for emulsion stability index), whereas MP-coated mono,-diglycerides yielded better results in viscosity analysis (between 18.04 and 32.13 mPa/s for 25°C)and powder properties such as Carr index (between 50.68% and 55.55%). When using MP and WP in mono-diglyceride encapsulation, new surfactants having different properties were obtained.Novelty Impact Statement: The powder, emulsion, and rheology properties affected by the coating material and whey protein and skim milk powder are good coating material for mono-diglycerides. Whey protein-coated products have effective encapsulation efficiency and emulsion stability tests. Skim milk powder coated monodiglycerides yielded better results in viscosity and powder property analysis such as Carr index.

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Section: Droplet Size and Zeta Potential Measurementmentioning

confidence: 95%

Encapsulation of mono,‐diglycerides obtained from rendering waste oil: Powder, interfacial, rheological and emulsion properties

Saraç

Doğan

2021

J. Food Process. Preserv.

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“…This loading capacity entails that a consumption of 4 g of capsules is required to obtain the recommended intake. Previous studies, such as the work of Rodrigues et al, reported very little loading capacities, meaning that up to 100 g of capsules may be required to get the recommended daily intake [31]. In a previous study carried out in a lab by López-Rubio et al [30], a loading capacity of 79.3 × 10 −3 % was obtained via the encapsulation in WPC of a suspension of β-carotene particles in glycerol (results shown in Table 2).…”

Section: Loading Capacitymentioning

confidence: 99%

“…In addition, the use of the emulsion allows obtaining particles with narrow size distribution, core-shell structures, and high retention of the bioactive compound [28]. This approach has been employed so far for the encapsulation of a wide number of bioactive compounds within a wide variety of biopolymer matrices [29], including the encapsulation of carotenoids [30,31]. Up to our knowledge, DES have never been applied in the encapsulation of bioactive compounds by electrospraying.…”

Section: Introductionmentioning

confidence: 99%

Encapsulation of β-Carotene by Emulsion Electrospraying Using Deep Eutectic Solvents

et al. 2020

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The encapsulation β-carotene in whey protein concentrate (WPC) capsules through the emulsion electrospraying technique was studied, using deep eutectic solvents (DES) as solvents. These novel solvents are characterized by negligible volatility, a liquid state far below 0 °C, a broad range of polarity, high solubilization power strength for a wide range of compounds, especially poorly water-soluble compounds, high extraction ability, and high stabilization ability for some natural products. Four DES formulations were used, based on mixtures of choline chloride with water, propanediol, glucose, glycerol, or butanediol. β-Carotene was successfully encapsulated in a solubilized form within WPC capsules; as a DES formulation with choline chloride and butanediol, the formulation produced capsules with the highest carotenoid loading capacity. SEM micrographs demonstrated that round and smooth capsules with sizes around 2 µm were obtained. ATR-FTIR results showed the presence of DES in the WPC capsules, which indirectly anticipated the presence of β-carotene in the WPC capsules. Stability against photo-oxidation studies confirmed the expected presence of the bioactive and revealed that solubilized β-carotene loaded WPC capsules presented excellent photo-oxidation stability compared with free β-carotene. The capsules developed here clearly show the significant potential of the combination of DES and electrospraying for the encapsulation and stabilization of highly insoluble bioactive compounds.

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“…These industries have widely used the encapsulation of bioactive compounds or drugs through methodologies such as spray-drying, complex coacervation, emulsification and salting-out (Cerqueira et al, 2014;Karim et al, 2016;Katona, Sovilj, Petrović, & Milanović, 2010;Romita, Cheng, & Diosady, 2011;Silva et al, 2019). Currently used techniques have disadvantages such as making use of temperature, pressure, or leading to low encapsulation efficiencies, which can be a problem depending on the encapsulated compound and the field of application (Costa et al, 2019;García-Moreno, Mendes, Jacobsen, & Chronakis, 2018;Marques et al, 2019;Rodrigues et al, 2020). Electrohydrodynamic (EHD) processing arises as an up-and-coming encapsulation technology, presenting a high encapsulation efficiency, low cost, allowing room or ambient working conditions, as well as controllable temperature and humidity, if needed.…”

Section: Introductionmentioning

confidence: 99%

“…EHDs allows a versatile production of micro and nano structures with high surface-area-to-volume ratio, combined with a narrow size distribution, simply by fine tuning its processing parameters. These characteristics and properties are of extreme interest for the production of micro and nano structures for the food industry, as the recent increase in publications and applications in this area shows (Costa et al, 2019;Deng, Kang, Liu, Feng, & Zhang, 2018;García-Moreno et al, 2018;Liao, Loh, Tian, Wang, & Fane, 2018;Rodrigues et al, 2020;Senthil Muthu Kumar et al, 2019). Parameters that influence structure morphology include voltage, tip-to-collector distance, flow rate, the selected solvent and polymer, its concentration and the viscosity of the solution obtained with it (Costa et al, 2019;García-Moreno et al, 2018;Marques et al, 2019;Senthil Muthu Kumar et al, 2019;Wang, Jansen, & Yang, 2019).…”

Section: Introductionmentioning

confidence: 99%

Food-grade hydroxypropyl methylcellulose-based formulations for electrohydrodynamic processing: Part I – Role of solution parameters on fibre and particle production

Prieto¹,

Lagarón²,

Pastrana³

et al. 2021

Food Hydrocolloids

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Electrohydrodynamic (EHD) processing allows the production of micro and nano structures with high surfacearea-to-volume ratio from biopolymers and environmentally friendly solvents. Such structures hold a very significant potential for application in the food area. The aim of this work was to assess the role of solution parameters in the formation of hydroxypropyl methylcellulose (HPMC)-based micro and nanostructures through EHD processing, establishing a relationship between variables such as viscosity and concentration, and processing zones (i.e., combinations of processing conditions that move the system towards electrospinningfibres are formedor electrosprayingparticles are formed).Micro and nano structures were produced through electrospinning and electrospraying using HPMC with low (HPMC LMW) and high (HPMC HMW) molecular weight. Solutions were characterized regarding surface tension, conductivity, viscosity, zero-shear rate and specific viscosity. Plotting specific viscosity versus concentration allowed determining the electrospraying and electrospinning zones, which were confirmed through scanning electron microscopy analysis. HPMC LMW led to the formation of particles. For concentrations between 1 and 2% (w/v) rod like particles were formed, and round particles were obtained for concentrations ranging from 3 to 6% (w/v). The mean particle diameter varied between 833 and 1188 nm, while the aspect ratio ranged from 1.3 to 3.7. Nanofibres were generated using HPMC HMW, being beaded fibres produced at a concentration of 1% (w/v) and smooth fibres produced for concentrations between 1.5 and 2.25% (w/v). The developed nanofibres displayed a mean diameter ranging between 79 and 161 nm.Electrospraying and electrospinning zones were successfully determined for HPMC LMW and HMW. Nevertheless, near transition zones variability regarding the obtained morphology was observed once other processing parameters (e.g., flow rate) can influence the morphology of fibers and particles.

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Electrosprayed whey protein-based nanocapsules for β-carotene encapsulation

Cited by 40 publications

References 21 publications

Encapsulation of mono,‐diglycerides obtained from rendering waste oil: Powder, interfacial, rheological and emulsion properties

Encapsulation of mono,‐diglycerides obtained from rendering waste oil: Powder, interfacial, rheological and emulsion properties

Encapsulation of β-Carotene by Emulsion Electrospraying Using Deep Eutectic Solvents

Food-grade hydroxypropyl methylcellulose-based formulations for electrohydrodynamic processing: Part I – Role of solution parameters on fibre and particle production

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