Large‐Scale Preparation of Polymer Nanocarriers by High‐Pressure Microfluidization

Alkanawati, Mohammad Shafee; Wurm, Frederik R.; Thérien-Aubin, Héloı̈se; Landfester, Katharina

doi:10.1002/mame.201700505

Cited by 21 publications

(17 citation statements)

References 34 publications

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“…Characterization of particle size distribution would also provide additional insights. The smallest values of average diameter reported in previous studies, which generally ranged from 200–550 nm for simple emulsions [ 20 , 21 , 38 , 40 , 41 ], are comparable to the values obtained in the present work with double emulsions.…”

Section: Resultssupporting

confidence: 88%

“…For simplification, the term coalescence is used to refer to two distinct processes (coalescence and Ostwald ripening) as they both lead to an increase in particle size but cannot be easily distinguished [ 39 ]. Overprocessing can be attributed to the limited ability of the emulsifier to rapidly adsorb onto the newly created surfaces and to the high Brownian motion, which increase the probability of collisions leading to droplet coalescence at high microfluidization pressure [ 40 ]. When the timescale of collisions is shorter than that of adsorption, the interfaces of the newly formed oil droplets cannot be fully covered by the emulsifier (WPI in our study), resulting in insufficient droplet stabilization and increased coalescence [ 21 , 40 ].…”

Section: Resultsmentioning

confidence: 99%

“…Overprocessing can be attributed to the limited ability of the emulsifier to rapidly adsorb onto the newly created surfaces and to the high Brownian motion, which increase the probability of collisions leading to droplet coalescence at high microfluidization pressure [ 40 ]. When the timescale of collisions is shorter than that of adsorption, the interfaces of the newly formed oil droplets cannot be fully covered by the emulsifier (WPI in our study), resulting in insufficient droplet stabilization and increased coalescence [ 21 , 40 ]. Denaturation of the whey proteins may be a contributing factor, further decreasing the ability of WPI to effectively stabilize the droplets at 200 MPa.…”

Section: Resultsmentioning

confidence: 99%

“…To date, overprocessing during high-pressure emulsification has been reported mostly in simple emulsions, mainly O/W [ 20 , 21 , 38 ] and more rarely W/O [ 40 ]. The pressure ranges at which particle size was found to increase in these studies vary from 63–84 MPa [ 21 ], 69–105 MPa [ 37 ], 70–105 MPa [ 20 ], 90–150 MPa [ 38 ] and 150–300 MPa [ 41 ].…”

Section: Resultsmentioning

confidence: 99%

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Coencapsulation of Polyphenols and Anthocyanins from Blueberry Pomace by Double Emulsion Stabilized by Whey Proteins: Effect of Homogenization Parameters

et al. 2018

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Blueberry pomace is a rich source of high-value bioactive polyphenols with presumed health benefits. Their incorporation into functional foods and health-related products benefits from coencapsulation and protection of polyphenol-rich extracts in suitable carriers. This study aimed to create a water-in-oil-in-water (W1/O/W2) double emulsion system suitable for the coencapsulation of total phenolics (TP) and anthocyanins (TA) from a polyphenol-rich extract of blueberry pomace (W1). The effect of critical physical parameters for preparing stable double emulsions, namely homogenization pressure, stirring speed and time, was investigated by measuring the hydrodynamic diameter, size dispersity and zeta potential of the oil droplets, and the encapsulation efficiency of TP and TA. The oil droplets were negatively charged (negative zeta potential values), which was related to the pH and composition of W2 (whey protein isolate solution) and suggests stabilization by the charged whey proteins. Increasing W1/O/W2 microfluidization pressure from 50 to 200 MPa or homogenization speed from 6000 to 12,000 rpm significantly increased droplet diameter and zeta potential and decreased TA and TP encapsulation efficiency. Increasing W1/O/W2 homogenization time from 15 to 20 min also increased droplet diameter and zeta potential and lowered TA encapsulation efficiency, while TP encapsulation did not vary significantly. In contrast, increasing W1/O homogenization time from 5 to 10 min at 10,000 rpm markedly increased TA encapsulation efficiency and reduced droplet diameter and zeta potential. High coencapsulation rates of blueberry polyphenols and anthocyanins around 80% or greater were achieved when the oil droplets were relatively small (mean diameter < 400 nm), with low dispersity (<0.25) and a high negative surface charge (−40 mV or less). These characteristics were obtained by homogenizing for 10 min at 10,000 rpm (W1/O), then 6000 rpm for 15 min, followed by microfluidization at 50 MPa.

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Section: Resultssupporting

confidence: 88%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

Section: Resultsmentioning

confidence: 99%

See 2 more Smart Citations

Coencapsulation of Polyphenols and Anthocyanins from Blueberry Pomace by Double Emulsion Stabilized by Whey Proteins: Effect of Homogenization Parameters

et al. 2018

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“…For example, the reaction between multifunctional alcohols, amines, or thiols and diisocyanate compounds has shown the efficient encapsulation of a variety of payloads in polyurea, polyurethane, or polythiourea nanocapsules. 15 , 16 However, such reactions involving nucleophiles like alcohols and amines that are also present in sensitive biomolecules used as payloads could lead to side reactions and cause a partial or total decrease in the efficacy of the payload.…”

Section: Introductionmentioning

confidence: 99%

Polysaccharide-Based pH-Responsive Nanocapsules Prepared with Bio-Orthogonal Chemistry and Their Use as Responsive Delivery Systems

et al. 2020

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Bio-orthogonal reactions have become an essential tool to prepare biomaterials; for example, in the synthesis of nanocarriers, bio-orthogonal chemistry allows circumventing common obstacles related to the encapsulation of delicate payloads or the occurrence of uncontrolled side reactions, which significantly limit the range of potential payloads to encapsulate. Here, we report a new approach to prepare pH-responsive nanocarriers using dynamic bio-orthogonal chemistry. The reaction between a poly(hydrazide) crosslinker and functionalized polysaccharides was used to form a pH-responsive hydrazone network. The network formation occurred at the interface of aqueous nanodroplets in miniemulsion and led to the production of nanocapsules that were able to encapsulate payloads of different molecular weights. The resulting nanocapsules displayed low cytotoxicity and were able to release the encapsulated payload, in a controlled manner, under mildly acidic conditions.

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Microfluidic‐assisted preparation of nano and microscale chitosan based 3D composite materials: Comparison with conventional methods

Kımna

Deger

Tamburacı

et al. 2022

J of Applied Polymer Sci

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Although nanofillers contribute to improved physical characteristics and biological functionalities of polymer-based biomaterials, their dispersion in polymer matrices is still a challenging issue in terms of obtaining consistency for the inherent properties. To tackle this problem, homogenization techniques are applied to disperse the nanofillers in such polymers, however, these methods can cause undesired changes especially in the rheological properties and the physical structure of the biopolymer matrices. Recently, as a novel homogenization technique, microfluidization has been used to homogenize polymer nanocomposites to minimize these limitations. In this study, two different nanocomposite structures as chitosan/montmorillonite (CS/MMT) and chitosan/polyhedral oligomeric silsesquioxane nanocages (CS/POSS) were homogenized with microfluidization and investigated in terms of physical alterations. Furthermore, the effect of microfluidizer technique on material characteristics was compared with conventional homogenization techniques, i.e., ultrasonic bath and sonication in terms of solution, nano -(e.g., hydrodynamic size, drug encapsulation) and macroscopic material characteristics (e.g., porosity, mechanical properties, swelling and thermal degradation). It was found that the microfluidizer homogenization improves the physical characteristics in both nano and macroscale materials: Nanospheres obtained from CS/MMT composites showed enhanced stability, uniform size distribution (<100 nm, PDI: <0.2), and good encapsulation efficiency (>50%) whereas 3D porous CS/POSS scaffolds showed improved structural uniformity (i.e., homogeneous and interconnected microstructure) and enhanced thermal and mechanical properties. The obtained results indicate that the microfluidizer homogenization ensures a successful nanofiller dispersion in polymer matrices, thereby improving the biomaterial characteristics impressively compared to the sonication methods. K E Y W O R D S biomaterials, mechanical properties, microscopy, polysaccharides, porous materials Ceren Kimna and Sedef Tamburaci have equal contribution in this study.

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Large‐Scale Preparation of Polymer Nanocarriers by High‐Pressure Microfluidization

Cited by 21 publications

References 34 publications

Coencapsulation of Polyphenols and Anthocyanins from Blueberry Pomace by Double Emulsion Stabilized by Whey Proteins: Effect of Homogenization Parameters

Coencapsulation of Polyphenols and Anthocyanins from Blueberry Pomace by Double Emulsion Stabilized by Whey Proteins: Effect of Homogenization Parameters

Polysaccharide-Based pH-Responsive Nanocapsules Prepared with Bio-Orthogonal Chemistry and Their Use as Responsive Delivery Systems

Microfluidic‐assisted preparation of nano and microscale chitosan based 3D composite materials: Comparison with conventional methods

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