High Internal Phase Oil-in-Water Pickering Emulsions Stabilized by Chitin Nanofibrils: 3D Structuring and Solid Foam

Zhu, Ya; Huan, Siqi; Bai, Long; Ketola, Annika; Shi, Xuetong; Zhang, Xiao; Ketoja, Jukka A.; Rojas, Orlando J.

doi:10.1021/acsami.9b23430

Cited by 128 publications

(94 citation statements)

References 66 publications

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“…Next, we used the complexes to stabilize the Pickering emulsion and further evaluated the relationship between the complexes and emulsion stability based on the particle size, zeta potential, microscopic state, flocculation, and physical and storage stability of the emulsions. The particle size of the ChN‐F‐stabilized emulsion, D 4,3 , was 1.5–8.8 μm, an order of magnitude lower than that of the emulsion stabilized by ChN alone 3, 13 . Under the same mass ratio, the D 4,3 of the emulsion stabilized by the complexes at pH levels of 3 and 4 exhibited larger particles (Fig.…”

Section: Resultsmentioning

confidence: 93%

“…Zhu et al . successfully employed chitin nanofibers to prepare a high‐internal‐phase Pickering emulsion 13 . However, the method used for obtaining nanocrystals was simpler and more controllable than that used for forming nanofibers; moreover, the nanocrystals displayed a length of less than 1 μm, whereas the nanofibers presented a length of over 1 μm 14 .…”

Section: Introductionmentioning

confidence: 99%

“…Tzoumaki et al . demonstrated that the droplet sizes of these emulsions prepared with ChN were as large as 10–100 μm, and the physical stability of these emulsions required further improvement 13, 15 . The presence of opposite charges in the self‐assembled system provided ideas for preparing new Pickering stabilizers.…”

Section: Introductionmentioning

confidence: 99%

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Oil‐in‐water Pickering emulsion stabilization with oppositely charged polysaccharide particles: chitin nanocrystals/fucoidan complexes

Liu

Zhang

et al. 2020

J Sci Food Agric

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BACKGROUND Chitin nanocrystals (ChN) are insoluble particles that can be used as stabilizers for Pickering emulsions. Their unique cationic properties and antibacterial activity have generated considerable interest among researchers. However, ChN have remained largely underexplored. Furthermore, the droplets of the emulsions stabilized by ChN are as large as 10–100 μm, and their physical stability requires further improvement. Some studies have shown that the spontaneous reaction of oppositely charged particles can effectively stabilize the emulsions. Positively charged ChN and negatively charged fucoidan (F) were therefore compounded to stabilize Pickering emulsions, and the stability of these emulsions was analyzed qualitatively. RESULTS The results showed that the composite particles comprising two polysaccharides in a mass ratio of 1:1 and at a pH of 2 (ChN1‐F1‐pH 2) possessed the lowest sulfate content (20.1%) and almost zero potential (−3 mV), indicating a high degree of neutralization of the positively charged amino group in ChN and the negatively charged sulfate group in F. Meanwhile, ChN1‐F1‐pH 2 displayed a dense network structure that improved the dispersibility and wettability (contact angle = 9.3°). Fourier transform infrared spectroscopy results confirmed that ChN and F were effectively combined through electrostatic interaction or neutralization to produce a polyelectrolyte complex. Furthermore, the particle size of the Pickering emulsion stabilized by ChN‐F was significantly reduced, and the maximum size did not exceed 10 μm; the physical and storage stability also improved. The ChN1‐F1‐pH 2 emulsion presented excellent storage stability; in particular, the emulsions stabilized by ChN1‐F1‐pH 5 and ChN1‐F1‐pH 6 exhibited excellent flocculation stabilities. CONCLUSION The size of the emulsion droplets stabilized by the oppositely charged polysaccharide particles (ChN‐F complexes) reduced significantly. Furthermore, by changing the mass ratio and pH, the microstructure and binding degree of the complexes can be adjusted, thereby promoting their adsorption on the oil–water interface and improving the stability of the Pickering emulsion. © 2020 Society of Chemical Industry

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Section: Resultsmentioning

confidence: 93%

Section: Introductionmentioning

confidence: 99%

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Oil‐in‐water Pickering emulsion stabilization with oppositely charged polysaccharide particles: chitin nanocrystals/fucoidan complexes

Liu

Zhang

et al. 2020

J Sci Food Agric

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“…In addition, HIPE is hypercritical to stabilizer surface properties, thus, limiting the broader use. Thus, intensive efforts to developing Pickering emulgel with wide-ranged tailorable composition and concurrently possessing viscoelastic and interfacial stability are required 31 .…”

Section: Introductionmentioning

confidence: 99%

Interfacial jamming reinforced Pickering emulgel for arbitrary architected nanocomposite with connected nanomaterial matrix

et al. 2021

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Three-dimensional (3D) nanocomposite (NC) printing has emerged as a major approach to translate nanomaterial physical properties to 3D geometries. However, 3D printing of conventional NCs with polymer matrix lacks control over nanomaterial connection that facilitates maximizing nanomaterial advantages. Thus, a printable NC that features nanomaterials matrix necessitates development, nevertheless, faces a challenge in preparation because of the trade-off between viscosity and interfacial stability. Here, we develop viscoelastic Pickering emulgels as NC inks through jamming nanomaterials on interfaces and in continuous phase. Emulgel composed of multiphases allow a vast range of composition options and superior printability. The excellent attributes initiate NC with spatial control over geometrics and functions through 3D printing of graphene oxide/phase-change materials emulgel, for instance. This versatile approach provides the means for architecting NCs with nanomaterial continuous phase whose performance does not constrain the vast array of available nanomaterials and allows for arbitrary hybridization and patterns.

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“…In one such strategy, emulsions can be further stabilized by addition of solid colloidal particles[50]. The system composed by the combination of solid beads with two immiscible phases is known as Pickering emulsion and its improved stability is explained by the irreversible adsorption of the particles at the oil/water interface, which provides enough mechanical hindrance to avoid coalescence and retain the original pore size[51,52]. A schematic representation of HIPE preparation is shown inFigure 2.…”

mentioning

confidence: 99%

Colloidal systems toward 3D cell culture scaffolds

Vila-Parrondo

García‐Astrain

Liz‐Marzán

2020

Advances in Colloid and Interface Science

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Three-dimensional porous scaffolds are essential for the development of tissue engineering and regeneration, as biomimetic supports to recreate the microenvironment present in natural tissues. To successfully achieve the growth and development of a specific kind of tissue, porous matrices should be able to influence cell behavior by promoting close cell-cell and cell-matrix interactions. To achieve this goal, the scaffold must fulfil a set of conditions, including ordered interconnected porosity to promote cell diffusion and vascularization, mechanical strength to support the tissue during continuous ingrowth, and biocompatibility to avoid toxicity. Among various building approaches to the construction of porous matrices, selected strategies afford hierarchical scaffolds with such defined properties. The control over porosity, microstructure or morphology, is crucial to the fabrication of high-end, reproducible scaffolds for the target application. In this review, we provide an insight into recent advances toward the colloidal fabrication of hierarchical scaffolds. After identifying the main requirements for scaffolds in biomedical applications, conceptual building processes are introduced. Examples of tissue regeneration applications are provided for different scaffold types, highlighting their versatility and biocompatibility. We finally provide a prospect about the current state of the art and limitations of porous scaffolds, along with challenges that are to be addressed, so these materials consolidate in the fields of tissue engineering and drug delivery.

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High Internal Phase Oil-in-Water Pickering Emulsions Stabilized by Chitin Nanofibrils: 3D Structuring and Solid Foam

Cited by 128 publications

References 66 publications

Oil‐in‐water Pickering emulsion stabilization with oppositely charged polysaccharide particles: chitin nanocrystals/fucoidan complexes

Oil‐in‐water Pickering emulsion stabilization with oppositely charged polysaccharide particles: chitin nanocrystals/fucoidan complexes

Interfacial jamming reinforced Pickering emulgel for arbitrary architected nanocomposite with connected nanomaterial matrix

Colloidal systems toward 3D cell culture scaffolds

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