Naturally degradable capsule provides a platform for sustained fragrance release.However,practical challenges such as low encapsulation efficiency and difficulty in sustained release are still limited in using fragran...Naturally degradable capsule provides a platform for sustained fragrance release.However,practical challenges such as low encapsulation efficiency and difficulty in sustained release are still limited in using fragranceloaded capsules.In this work,the natural materials sodium alginate and gelatine are dissolved and act as the aqueous phase,lavender is dissolved in caprylic/capric triglyceride(GTCC)as the oil phase,and SiO_(2) nanoparticles with neutralwettability as a solid emulsifier to form O/W Pickering emulsions simultaneously.Finally,multi-core capsules are prepared using the drop injection method with emulsions as templates.The results show that the capsules have been successfully prepared with a spherical morphology and multi-core structure,and the encapsulation rate of multi-core capsules can reach up to 99.6%.In addition,the multi-core capsules possess desirable sustained release performance,the cumulative sustained release rate of fragrance at 25℃over 49 days is only 32.5%.It is attributed to the significant protection of multi-core structure,Pickering emulsion nanoparticle membranes,and hydrogel network shell for encapsulated fragrance.This study is designed to deliver a new strategy for using sustained-release technology with fragrance in food,cosmetics,textiles,and other fields.展开更多
Non-aqueous emulsions have a wide range of applications in cosmetics,drug-controlled release,and the preparation of functional nanoparticles.However,due to the weaker polarity of non-aqueous solvents,these emulsions o...Non-aqueous emulsions have a wide range of applications in cosmetics,drug-controlled release,and the preparation of functional nanoparticles.However,due to the weaker polarity of non-aqueous solvents,these emulsions often exhibit inferior stability compared to their aqueous counterparts.In this experiment,the properties of quaternary ammonium surfactants in glycerol were investigated through surface tension measurements,to further enhance the stability of n-decane/glycerol emulsions,hydrophilic nanoparticles SiO_(2) were modified in situ using double tailed quaternary ammonium surfactants Di-C_(12)DAB and Di-C_(16)DAB.Stable n-decane/glycerol Pickering emulsions were successfully prepared.These emulsions were stable at 45℃for over six months,and no significant changes in droplet size occurred.The minimum droplet size of the emulsion was only 2-3μm.Contact angle measurements showed that the wettability of the silica surface was tremendously affected by the concentration and the alkyl chain length of the double-tailed surfactants.In the presence of Di-C_(12)DAB,the contact angle of glycerol on the silica surface increased monotonically with the surfactant concentration.This explains the phenomenon that the Pickering emulsions containing Di-C_(12)DAB and silica particles were stable within the contact angle range of 80°-120°.Comparatively,the contact angle of the glycerol on the silica surface in the presence of Di-C_(16)DAB first increased with surfactant concentrations and then decreased,reaching a maximum at 0.6 mmol/L.It can be concluded that Di-C_(12)DAB formed monolayers at the surface of silica particles within all investigated concentrations.On the contrary,Di-C_(16)DAB formed monolayers at concentrations below 0.6 mmol/L and formed double layers at concentrations above 0.6 mmol/L,leading to a non-monotonic change in the contact angle with respect to concentration.Using these stable non-aqueous Pickering emulsions as templates,polymer microspheres with a particle size of 2-3μm were successfully prepared with high yield.This work is helpful to expand the potential applications of non-aqueous emulsions in the encapsulation of drug,controlled release,material preparation,and cosmetic formulations.展开更多
Poly(octamethylene citrate)(POC)is a promising bioelastomer material in the biomedical field.However,its thermosetting nature poses a significant challenge to processing and molding,especially manufacturing the POC-ba...Poly(octamethylene citrate)(POC)is a promising bioelastomer material in the biomedical field.However,its thermosetting nature poses a significant challenge to processing and molding,especially manufacturing the POC-based elastomer particles as potential,degradable and toughened fillers.Firstly,a Pickering emulsion with a pre-polymer(pre-POC)solution in dimethyl carbonate as a dispersed oil phase,a Pullulan(PUL)aqueous solution as a continuous water phase,and chitin nanocrystal(ChiNC)as a particle-type emulsifier was constructed.Secondly,the POC-based core/shell structured microspheres were prepared by spray-drying of the emulsions,and characterized by a scanning electron microscope and a transmission electron microscope.Finally,the POC-based core/shell structured microspheres were used as elastomer fillers to strengthen and toughen a chitosan film,resulting in 26%increase in the tensile strength and 45%increase in the strain at break;the POC-based core/shell structured microsphere as a double-layer drug release system was built in which the hydrophilic drug of tetracycline hydrochloride(TCH)was released from the outer layer and the hydrophobic drug of curcumin was released from the inner layer,roughly following the Ritger-Peppas model.展开更多
Flexible and conformable nanomaterial-based functional hydrogels find promising applications in various fields.However,the controllable manipulation of functional electron/mass transport networks in hydrogels remains ...Flexible and conformable nanomaterial-based functional hydrogels find promising applications in various fields.However,the controllable manipulation of functional electron/mass transport networks in hydrogels remains rather challenging to realize.We describe a general and versatile surfactant-free emulsion construction strategy to customize robust functional hydrogels with programmable hierarchical structures.Significantly,the amphipathy of silk fibroin(SF)and the reinforcement effect of MXene nanosheets produce sable Pickering emulsion without any surfactant.The followed microphase separation and self-cross-linking of the SF chains induced by the solvent exchange convert the composite emulsions into high-performance hydrogels with tunable microstructures and functionalities.As a proof-of-concept,the controllable regulation of the ordered conductive network and the water polarization effect confer the hydrogels with an intriguing electromagnetic interference shielding efficiency(~64 dB).Also,the microstructures of functional hydrogels are modulated to promote mass/heat transfer properties.The amino acids of SF and the surface terminations of MXene help reduce the enthalpy of water evaporation and the hierarchical structures of the hydrogels accelerate evaporation process,expecting far superior evaporation performance(~3.5 kg m^(-2)h^(-1))and salt tolerance capability compared to other hydrogel evaporators.Our findings open a wealth of opportunities for producing functional hydrogel devices with integrated structure-dependent properties.展开更多
This study prepared and characterized amphiphilic carboxymethyl cellulose stearate(CMCS)recycled from sugarcane bagasse agro-waste(SB).The Fourier-transform infrared(FTIR)analysis confirmed cellulose,carboxymethyl cel...This study prepared and characterized amphiphilic carboxymethyl cellulose stearate(CMCS)recycled from sugarcane bagasse agro-waste(SB).The Fourier-transform infrared(FTIR)analysis confirmed cellulose,carboxymethyl cellulose(CMC),and CMCS structures,with CMCS showing increased H-bonding.X-ray diffraction analysis(XRD)revealed reduced crystallinity in CMC and CMCS.CMCS exhibited a hydrophobic nature but dispersed in water,enabling nanoemulsion formation.Optimal nanoemulsion was achieved with CMCS1,showing a particle size of 99 nm.Transmission electron microscopy(TEM)images revealed CMC’s honeycomb structure,transforming into spherical particles in CMCS1.Antimicrobial tests demonstrated strong activity of CMCS formulations against Escherichia coli and Staphylococcus aureus,with CMCS3 exhibiting the highest efficacy.These findings highlight the potential of CMCS-based nanoemulsions for antimicrobial applications and nanoemulsification.展开更多
The stability of oil-dominated emulsions,including oil-based drilling fluids and crude oils,is crucial for mitigating gas hydrate risks in the petroleum and natural gas industries.Nanoparticles can stabilize oilwater ...The stability of oil-dominated emulsions,including oil-based drilling fluids and crude oils,is crucial for mitigating gas hydrate risks in the petroleum and natural gas industries.Nanoparticles can stabilize oilwater systems(Pickering emulsions)by residing at the oil-water interface.However,their effects on the kinetics of hydrate formation in these systems remain unclear.To address this,we experimentally investigated how hydrophilic and hydrophobic nano-CaCO_(3) influence CH4 hydrate formation within dynamic oil-water systems.A series of hydrate formation experiments were conducted with varying water cuts and different concentrations of nano-CaCO_(3) at a particle size of 20 nm,under 3℃ and 6 MPa.The induction time,hydrate formation volume,and hydrate growth rate were measured and calculated.The results indicate that hydrophilic nano-CaCO_(3) generally inhibits hydrate formation,particularly at high water cuts,while hydrophobic nano-CaCO_(3) can significantly inhibit or even prevent hydrate formation at low water cuts.Water cut strongly influences the kinetics of hydrate formation,and nanoparticle concentration also impacts the results,likely due to changes in oil-water interface stability caused by nanoparticle distribution.This study will offer valuable insights for designing deepwater oilbased drilling fluids using nanoparticles and ensuring safe multiphase flow in deepwater oil and gas operations.展开更多
Transcatheter arterial embolization(TAE)is the mainstay for treating advanced hepatocellular carcinoma(HCC),and the performance of the embolization material is crucial in TAE.With the development of medical imaging an...Transcatheter arterial embolization(TAE)is the mainstay for treating advanced hepatocellular carcinoma(HCC),and the performance of the embolization material is crucial in TAE.With the development of medical imaging and the birth of“X-ray-free”technologies,we designed a new dual-mode imaging material of dimethoxy tetraphenyl ethylene(DMTPE)via emulsification by mixing poly(N-isopropylacrylamide-co-acrylic acid)(PNA)with lipiodol and fluorocarbons,which was evaluated for temperature sensitivity,stability,and dual-mode visualization in vitro.Additionally,blood vessel casting embolization and renal artery imaging were assessed in healthy rabbits.In a rabbit model with a VX2 tumor,the effectiveness of TAE for treating HCC was examined,with an emphasis on evaluating long-term outcomes of embolization and its effects on tumor growth,necrosis,and proliferation through imaging techniques.In vitro experiments confirmed that the temperature-sensitive dual-oil-phase Pickering emulsion had good flow,stable contrast,and embolism when the oil-to-oil ratio and water-to-oil ratio were both 7:3(v/v)and stabilized with 8%PNA.Similarly,in vivo,arterial embolization confirmed the excellent properties of DMTPE prepared at the abovementioned ratios.It was observed that DMTPE not only has an antitumor effect but can also achieve dual imaging using X-rays and ultrasound,making it a promising excellent vascular embolization material for TAE in tumor treatment.展开更多
A Pickering emulsion based on sodium starch octenyl succinate(SSOS)was prepared and its effects on the physicochemical properties of hairtail myofibrillar protein gels(MPGs)subjected to multiple freeze-thaw(F-T)cycles...A Pickering emulsion based on sodium starch octenyl succinate(SSOS)was prepared and its effects on the physicochemical properties of hairtail myofibrillar protein gels(MPGs)subjected to multiple freeze-thaw(F-T)cycles were investigated.The whiteness,water-holding capacity,storage modulus(G')and texture properties of the MPGs were significantly improved by adding 1%-2%Pickering emulsion(P<0.05).Meanwhile,Raman spectral analysis demonstrated that Pickering emulsion promoted the transformation of secondary structure,enhanced hydrogen bonds and hydrophobic interactions,and promoted the transition of disulfide bond conformation from g-g-g to g-g-t and t-g-t.At an emulsion concentration of 2%,theα-helix content decreased by 10.37%,while theβ-sheet content increased by 7.94%,compared to the control.After F-T cycles,the structure of the MPGs was destroyed,with an increase in hardness and a decrease in whiteness and water-holding capacity,however,the quality degradation of MPGs was reduced with 1%-2%Pickering emulsion.These findings demonstrated that SSOS-Pickering emulsions,as potential fat substitutes,can enhance the gel properties and the F-T stability of MPGs.展开更多
Lymph node targeting is a commonly used strategy for particulate vaccines,particularly for Pickering emulsions.However,extensive research on the internal delivery mechanisms of these emulsions,especially the complex i...Lymph node targeting is a commonly used strategy for particulate vaccines,particularly for Pickering emulsions.However,extensive research on the internal delivery mechanisms of these emulsions,especially the complex intercellular interactions of deformable Pickering emulsions,has been surprisingly sparse.This gap in knowledge holds significant potential for enhancing vaccine efficacy.This study aims to address this by summarizing the process of lymph-node-targeting transport and introducing a dissipative particle dynamics simulation method to evaluate the dynamic processes within cell tissue.The transport of Pickering emulsions in skeletal muscle tissue is specifically investigated as a case study.Various factors impacting the transport process are explored,including local cellular tissue environmental factors and the properties of the Pickering emulsion itself.The simulation results primarily demonstrate that an increase in radial repulsive interaction between emulsion particles can decrease the transport efficiency.Additionally,larger intercellular gaps also diminish the transport efficiency of emulsion droplet particles due to the increased motion complexity within the intricate transport space compared to a single channel.This study sheds light on the nuanced interplay between engineered and biological systems influencing the transport dynamics of Pickering emulsions.Such insights hold valuable potential for optimizing transport processes in practical biomedical applications such as drug delivery.Importantly,the desired transport efficiency varies depending on the specific application.For instance,while a more rapid transport might be crucial for lymph-node-targeted drug delivery,certain applications requiring a slower release of active components could benefit from the reduced transport efficiency observed with increased particle repulsion or larger intercellular gaps.展开更多
In recent years,Pickering emulsions and their applications have attracted a great deal of attention due to their special features,which include easy preparation and enhanced stability.In contrast to classical emulsion...In recent years,Pickering emulsions and their applications have attracted a great deal of attention due to their special features,which include easy preparation and enhanced stability.In contrast to classical emulsions,in Pickering emulsions,solid microparticles or nanoparticles that localize at the interface between liquids are used as stabilizers,instead of surfactants,to enhance the droplet lifetime.Furthermore,Pickering emulsions show higher stability,lower toxicity,and stimuli-responsiveness,compared with emulsions that are stabilized by surfactants.Therefore,they can be considered attractive components for various uses,such as photocatalysis and the preparation of new materials.Moreover,the nanoparticle morphology strongly influences Pickering emulsion stability as well as the potential utilization of such emulsions.Here,we review recent findings concerning Pickering emulsions,with a particular focus on how the nanoparticles morphology(i.e.,cube,ellipsoid,nanosheet,sphere,cylinder,rod,peanut)influences the type and stability of such emulsions,and their current applications in different fields such as antibacterial activity,protein recognition,catalysis,photocatalysis,and water purification.展开更多
Developing methods for efficient product/catalyst separation and catalyst recycling is meaningful in multi-phase catalytic reactions. Here, we reported a p H-responsive emulsion system stabilized by interfacially acti...Developing methods for efficient product/catalyst separation and catalyst recycling is meaningful in multi-phase catalytic reactions. Here, we reported a p H-responsive emulsion system stabilized by interfacially active TiO2 nanoparticles for achieving in situ product/catalyst separation and catalyst recycling. In this system, emulsification and demulsification process could be easily engineered through tuning the p H values. The emulsion droplets were destroyed completely at a p H value of 3–4, and the solid catalyst distributed in the aqueous phase could be used to the next reaction cycle after removal of the organic product and adjusting the p H to 7–8. Such a p H triggered switchable Pickering emulsion catalytic system not only shows good recyclability of the solid catalyst but also high catalytic efficiency,and could be recycled more than 10 cycles.展开更多
Pickering emulsions stabilized by solid particles have gained much attention,which afford high stability,low toxicity,controllable rheological properties and stimuli-responsive behavior compared to the traditional emu...Pickering emulsions stabilized by solid particles have gained much attention,which afford high stability,low toxicity,controllable rheological properties and stimuli-responsive behavior compared to the traditional emulsions emulsified by surfactants.Those particles,as the core parts of the emulsion systems,play an important role in the fabrication and application of Pickering emulsion systems,making them attractive in petroleum fields.In this review,the influence of various particles on the stability and properties of Pickering emulsion systems as well as recent researches associated with the stimuliresponsibility of Pickering emulsion systems are introduced.Specifically,the design of functional particles and Pickering emulsion systems with super stabilities and controllable rheological properties are listed.Furthermore,some petroleum application of Pickering emulsion systems for enhanced oil recovery and spilled oil collection as well as the application as soft templates to fabricate oil-absorbing material and as three-phase microreactors that most likely for petroleum application are discussed,and the issues hindering the actual application of Pickering emulsion systems are also evaluated.This review charts a way for Pickering emulsion studies that could lead to a valid petroleum application through design of the particles served as the enhancers of Pickering emulsion stability for purpose of tailoring chemical flooding.展开更多
This article reports the development of a novel switchable Pickering emulsion with rapid CO_(2)/N_(2) respon-siveness,which is stabilized using alumina nanoparticles hydrophobized in situ with a trace amount of a swit...This article reports the development of a novel switchable Pickering emulsion with rapid CO_(2)/N_(2) respon-siveness,which is stabilized using alumina nanoparticles hydrophobized in situ with a trace amount of a switchable superamphiphile via electrostatic interactions.With the introduction of CO_(2) for 30 s,the Pickering emulsion can be spontaneously demulsified with complete phase separation;the emulsion can then be reconstructed in response to N_(2) purging for 10 min followed by homogenization.Moreover,the stable Pickering emulsion can be stored for more than 60 days at room temperature with-out any visible change.The CO_(2)/N_(2)-responsive behavior of the switchable Pickering emulsion is attribu-ted to the reversible desorption/adsorption of the switchable surfactants on the surfaces of the alumina nanoparticles upon the alternative bubbling of CO_(2)or N_(2).Thanks to the simple fabrication of the surfac-tant and the hydrophobization of the alumina nanoparticles,this research has developed an extremely facile and cost-efficient method for preparing a rapidly CO_(2)/N_(2)-responsive switchable Pickering emul-sion.The dosage of the switchable surfactants has been significantly reduced by nearly 1500 times(from 150 to 0.1 mmol·L^(-1))as compared with the dosage used in previous studies.Moreover,the as-prepared CO_(2)/N_(2)-responsive switchable Pickering emulsion is environmentally friendly,mild,and nontoxic;thus,it holds great potential for practical applications with considerable economic and environmental benefits,such as oil transport,fossil fuel production,environmental gases detection,and the encapsulation and release of active ingredients.展开更多
Curcumin is a bioactive molecule with limited industrial application because of its instability and poor solubility in water.Herein,curcumin-loaded Pickering emulsion was produced using purified bacterial cellulose fr...Curcumin is a bioactive molecule with limited industrial application because of its instability and poor solubility in water.Herein,curcumin-loaded Pickering emulsion was produced using purified bacterial cellulose from fermented kombucha(KBC).The morphology,particle size,stability,rheological properties,and antioxidant activities of the curcumin-loaded Pickering emulsion were investigated.The fluorescence microscope and scanning electron microscopy images showed that the curcumin-loaded Pickering emulsion formed circular droplets with good encapsulation.The curcumin-load Pickering emulsion exhibited better stability under a wide range of temperatures,low p H,sunlight,and UV-365 nm than the free curcumin,indicating that the KBC after high-pressure homogenization improved the stability of the CPE.The encapsulated curcumin retained its antioxidant capacity and exhibited higher functional potential than the free curcumin.The study demonstrated that the KBC could be an excellent material for preparing a Pickering emulsion to improve curcumin stability and antioxidant activity.展开更多
The structure and properties of functional nanoparticles are important for stabilizing Pickering emulsion polymerization.Recently,cellulose nanocrystals(CNCs)are increasingly favored as a bio-based stabilizer for Pick...The structure and properties of functional nanoparticles are important for stabilizing Pickering emulsion polymerization.Recently,cellulose nanocrystals(CNCs)are increasingly favored as a bio-based stabilizer for Pickering emulsions.In this study,we reported a novel functionalized polyphosphoester-grafted CNCs for the stabilization of oil-in-water Pickering emulsions and the emulsion polymerization of styrene.First,polyphosphoester containing an amino group at one end of the chain,abbreviated as PBYP-NH2,was prepared by ring-opening polymerization(ROP)and hydrolysis reaction,wherein PBYP represents poly[2-(but-3-yn-1-yloxy)-2-oxo-1,3,2-dioxaphospholane].Subsequently,CNC-COOH was obtained via 2,2,6,6-tetramethylpiperidine-1-oxyl(TEMPO)oxidation of CNCs.The functionalized nanocrystals CNC-PBYP-COOH with carboxyl groups and polyphosphoester on the surface were obtained by the amidation reaction of PBYP-NH2 with CNC-COOH.Finally,we used CNC-PBYP-COOH as sole particle emulsifiers to stabilize styrene-in-water Pickering emulsions and studied its effects on the emulsions in details by using dynamic light scattering(DLS).The results indicated that the properties of these emulsions depended on the concentration of hydrophobically modified CNCs,volume ratios of oil to water,and pH values.The modified CNCs had higher ability to stabilize the styrene-in-water emulsions relative to the unmodified CNCs,and a stable oil-in-water(o/w)Pickering emulsion with diameter of hundreds of nanometers could be obtained.The resulting emulsions could be polymerized to yield nanosized latexes.The polyphosphoester-modified CNCs as green particle emulsifiers can efficiently stabilize nanoemulsions and latexes,which would promote the development of novel environmentally friendly materials.展开更多
Effects of water-soluble co-solvents (WSCs)on the properties of water/oil Picketing emulsions were investigated. Picketing emulsions were prepared in the system of 1,2,4-trimethylbenzene (TMB)/hydrophobic sil- ica...Effects of water-soluble co-solvents (WSCs)on the properties of water/oil Picketing emulsions were investigated. Picketing emulsions were prepared in the system of 1,2,4-trimethylbenzene (TMB)/hydrophobic sil- ica/water with varied concentrations of WSCs (ethanol, acetic acid and glycerin). Mean droplet diameter distribu- tions of the obtained emulsions were studied to investigate the effects of WSCs types and concentrations. The results demonstrated that mean droplet diameter distributions decreased at first and then increased with the increase of WSC concentration. Moreover, the effect of WSC concentration on the phase inversion locus was further investi- gated. At the same time, infrared radiation (IR)spectrometer was used to investigate the mechanism. The results showed that the WSC attaching on hydrophobic silica changed the wettability of the particles, which facilitated the formation and phase inversion of the emulsion. The hydrogen bonds between the co-solvent groups attaching on the solid particles made a great effect on the droplet size of the emulsion and strengthened the interaction among emulsifiers. Overall, proper WSC was in favor of the stability of Picketing emulsion.展开更多
In recent years, natural biodegradable nanoparticles as stabilizers of Pickering emulsions have attracted extensive attention. In this work, a Pickering emulsion composed of chitosan/Arabic gum nanoparticles (CS/GA NP...In recent years, natural biodegradable nanoparticles as stabilizers of Pickering emulsions have attracted extensive attention. In this work, a Pickering emulsion composed of chitosan/Arabic gum nanoparticles (CS/GA NPs), tea tree oil and vitamin E was formulated. Then the antibacterial, anti-inflammatory and wound healing abilities of the emulsion were evaluated. Pickering emulsion encapsulated the tea tree oil strengthened antibacterial activity towards Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa and Candida albicans. Besides, this multi-phase system offered a platform to load with vitamin E, which provides anti-inflammatory effects while antibacterial. Meanwhile, Pickering emulsion avoided contact between bacteria and skin when used in wound treatment.展开更多
Compared with traditional surfactant-stabilised emulsions, Pickering emulsions, stabilised by clay nanoparticles, have the advantages of strong interface stability, strong versatility, and low toxicity. Moreover, they...Compared with traditional surfactant-stabilised emulsions, Pickering emulsions, stabilised by clay nanoparticles, have the advantages of strong interface stability, strong versatility, and low toxicity. Moreover, they have excellent application potential in the fields of food and medicine. In this study, a food-grade Pickering emulsion stabiliser was prepared by physically adsorbing the cationic surfactant ethyl lauroyl arginate (LAE) on the surface of nano-montmorillonite (NMMT). Different LAE/NMMT combinations were assessed for their capacity to stabilise an oil-in-water emulsion at a low solid concentration (0.5%, w/v). The controllability of the droplet diameter and stability of the Pickering emulsions can be realised by changing the content of LAE. Scanning electron microscopy (SEM), and laser confocal microscopy (CLSM) confirmed the successful preparation of sunflower oil Pickering emulsion droplets stabilised by LAE/NMMT (0.0075%/1%). Additionally, the LAE/NMMT studied in this work could be used as a highly effective antibacterial surfactant with inorganic nanoparticles to efficiently stabilise Pickering emulsions, thus expanding the potential of preparing edible Pickering emulsion formulae.展开更多
Bacterial biofilm infection is a complicated and important global problem.Non-toxic biomass-based Pickering emulsions as an essential oil delivery system are a potentially effective means in biofilm treatment.Herein,t...Bacterial biofilm infection is a complicated and important global problem.Non-toxic biomass-based Pickering emulsions as an essential oil delivery system are a potentially effective means in biofilm treatment.Herein,the chitosan/gelatin complex nanoparticles(CGNPs)stabilized Pickering(CGP)emulsion loaded with cinnamon essential oil(CEO)was developed to inhibit and remove bacterial biofilms.CGNPs were initially successfully prepared with a particle size of 253.7 nm.Subsequently,CGP emulsions were prepared using CGNPs as the emulsifier and CEO as the oil phase,with the aqueous phase pH value of 5.5 and ionic strength of 50 mM.Amino groups of CGNPs were crosslinked with the aldehyde group of CEO via Schiff base reaction at the oil-water interface to form a denser core-shell structure,thus improving the stability of Pickering emulsion.The CGP emulsions exhibit controlled and long-term sustained release properties in essential oil delivery,with 89.8%,81.0%,and 62.2%CEO release within 168 h for CGP-0.1,CGP-0.2,and CGP-0.3,respectively.Moreover,CGP emulsions have stronger antioxidant activities(nearly 100%),broad-spectrum antibacterial activities(>90%),enhanced penetration and removal capabilities against preformed biofilms than single CEO or CGNPs,as well as its better biocompatibility than conventional surfactant-stabilized emulsions.Hence,CEO-delivered CGP emulsion could serve as a potential strategy against biofilm infections and bacterial resistance.展开更多
Objectives:Walnut protein-galactooligosaccharide(WalPI-GOS)nanoparticles were used to prepare high internal phase Pickering emulsions(HIPPEs).Materials and Methods:The entrapment properties of HIPPEs for cinnamon oil ...Objectives:Walnut protein-galactooligosaccharide(WalPI-GOS)nanoparticles were used to prepare high internal phase Pickering emulsions(HIPPEs).Materials and Methods:The entrapment properties of HIPPEs for cinnamon oil were investigated by varying the volume ratios of camellia and cinnamon oils(cinnamon oil contents:0%,2.5%,5.0%,10%,15%,and 20%),and the droplet size,rheological properties,Raman spectroscopy results,microstructure,thermal stability,storage stability,and antioxidant activity of HIPPEs were determined.Results:The droplet size of HIPPEs increased with increasing cinnamon oil content.Among the samples,HIPPEs enriched with the cinnamon oil content of 10%had the highest storage modulus,loss modulus,and apparent viscosity(13.64 Pa·s).However,the thixotropic recovery ability of HIPPEs decreased with the increase in cinnamon oil content.Raman spectroscopy and microstructural analysis revealed that proteins covalently cross-linked with cinnamaldehyde to form a three-dimensional network structure,which showed the highest stability when the cinnamon oil content was 10%.HIPPEs exhibited high thermal stability without delamination after heating,as well as good storage stability without delamination or discoloration after 15 d of storage at 25℃ and 50℃.Among the samples,HIPPEs enriched with 10%cinnamon oil had the lowest peroxide and malondialdehyde values during storage.The addition of cinnamon oil significantly enhanced the antioxidant activity of HIPPEs.Conclusions:The best overall performance of HIPPEs was achieved at a cinnamon oil content of 10%.This result provides a theoretical foundation for the development of WalPI and the application of cinnamon oil in food,as well as a theoretical basis for the development of novel food delivery systems.展开更多
文摘Naturally degradable capsule provides a platform for sustained fragrance release.However,practical challenges such as low encapsulation efficiency and difficulty in sustained release are still limited in using fragranceloaded capsules.In this work,the natural materials sodium alginate and gelatine are dissolved and act as the aqueous phase,lavender is dissolved in caprylic/capric triglyceride(GTCC)as the oil phase,and SiO_(2) nanoparticles with neutralwettability as a solid emulsifier to form O/W Pickering emulsions simultaneously.Finally,multi-core capsules are prepared using the drop injection method with emulsions as templates.The results show that the capsules have been successfully prepared with a spherical morphology and multi-core structure,and the encapsulation rate of multi-core capsules can reach up to 99.6%.In addition,the multi-core capsules possess desirable sustained release performance,the cumulative sustained release rate of fragrance at 25℃over 49 days is only 32.5%.It is attributed to the significant protection of multi-core structure,Pickering emulsion nanoparticle membranes,and hydrogel network shell for encapsulated fragrance.This study is designed to deliver a new strategy for using sustained-release technology with fragrance in food,cosmetics,textiles,and other fields.
文摘Non-aqueous emulsions have a wide range of applications in cosmetics,drug-controlled release,and the preparation of functional nanoparticles.However,due to the weaker polarity of non-aqueous solvents,these emulsions often exhibit inferior stability compared to their aqueous counterparts.In this experiment,the properties of quaternary ammonium surfactants in glycerol were investigated through surface tension measurements,to further enhance the stability of n-decane/glycerol emulsions,hydrophilic nanoparticles SiO_(2) were modified in situ using double tailed quaternary ammonium surfactants Di-C_(12)DAB and Di-C_(16)DAB.Stable n-decane/glycerol Pickering emulsions were successfully prepared.These emulsions were stable at 45℃for over six months,and no significant changes in droplet size occurred.The minimum droplet size of the emulsion was only 2-3μm.Contact angle measurements showed that the wettability of the silica surface was tremendously affected by the concentration and the alkyl chain length of the double-tailed surfactants.In the presence of Di-C_(12)DAB,the contact angle of glycerol on the silica surface increased monotonically with the surfactant concentration.This explains the phenomenon that the Pickering emulsions containing Di-C_(12)DAB and silica particles were stable within the contact angle range of 80°-120°.Comparatively,the contact angle of the glycerol on the silica surface in the presence of Di-C_(16)DAB first increased with surfactant concentrations and then decreased,reaching a maximum at 0.6 mmol/L.It can be concluded that Di-C_(12)DAB formed monolayers at the surface of silica particles within all investigated concentrations.On the contrary,Di-C_(16)DAB formed monolayers at concentrations below 0.6 mmol/L and formed double layers at concentrations above 0.6 mmol/L,leading to a non-monotonic change in the contact angle with respect to concentration.Using these stable non-aqueous Pickering emulsions as templates,polymer microspheres with a particle size of 2-3μm were successfully prepared with high yield.This work is helpful to expand the potential applications of non-aqueous emulsions in the encapsulation of drug,controlled release,material preparation,and cosmetic formulations.
文摘Poly(octamethylene citrate)(POC)is a promising bioelastomer material in the biomedical field.However,its thermosetting nature poses a significant challenge to processing and molding,especially manufacturing the POC-based elastomer particles as potential,degradable and toughened fillers.Firstly,a Pickering emulsion with a pre-polymer(pre-POC)solution in dimethyl carbonate as a dispersed oil phase,a Pullulan(PUL)aqueous solution as a continuous water phase,and chitin nanocrystal(ChiNC)as a particle-type emulsifier was constructed.Secondly,the POC-based core/shell structured microspheres were prepared by spray-drying of the emulsions,and characterized by a scanning electron microscope and a transmission electron microscope.Finally,the POC-based core/shell structured microspheres were used as elastomer fillers to strengthen and toughen a chitosan film,resulting in 26%increase in the tensile strength and 45%increase in the strain at break;the POC-based core/shell structured microsphere as a double-layer drug release system was built in which the hydrophilic drug of tetracycline hydrochloride(TCH)was released from the outer layer and the hydrophobic drug of curcumin was released from the inner layer,roughly following the Ritger-Peppas model.
基金support from the National Natural Science Foundation of China(Nos.51922020,52273064 and 52221006)the Fundamental Research Funds for the Central Universities(BHYC1707B)is gratefully acknowledged.
文摘Flexible and conformable nanomaterial-based functional hydrogels find promising applications in various fields.However,the controllable manipulation of functional electron/mass transport networks in hydrogels remains rather challenging to realize.We describe a general and versatile surfactant-free emulsion construction strategy to customize robust functional hydrogels with programmable hierarchical structures.Significantly,the amphipathy of silk fibroin(SF)and the reinforcement effect of MXene nanosheets produce sable Pickering emulsion without any surfactant.The followed microphase separation and self-cross-linking of the SF chains induced by the solvent exchange convert the composite emulsions into high-performance hydrogels with tunable microstructures and functionalities.As a proof-of-concept,the controllable regulation of the ordered conductive network and the water polarization effect confer the hydrogels with an intriguing electromagnetic interference shielding efficiency(~64 dB).Also,the microstructures of functional hydrogels are modulated to promote mass/heat transfer properties.The amino acids of SF and the surface terminations of MXene help reduce the enthalpy of water evaporation and the hierarchical structures of the hydrogels accelerate evaporation process,expecting far superior evaporation performance(~3.5 kg m^(-2)h^(-1))and salt tolerance capability compared to other hydrogel evaporators.Our findings open a wealth of opportunities for producing functional hydrogel devices with integrated structure-dependent properties.
文摘This study prepared and characterized amphiphilic carboxymethyl cellulose stearate(CMCS)recycled from sugarcane bagasse agro-waste(SB).The Fourier-transform infrared(FTIR)analysis confirmed cellulose,carboxymethyl cellulose(CMC),and CMCS structures,with CMCS showing increased H-bonding.X-ray diffraction analysis(XRD)revealed reduced crystallinity in CMC and CMCS.CMCS exhibited a hydrophobic nature but dispersed in water,enabling nanoemulsion formation.Optimal nanoemulsion was achieved with CMCS1,showing a particle size of 99 nm.Transmission electron microscopy(TEM)images revealed CMC’s honeycomb structure,transforming into spherical particles in CMCS1.Antimicrobial tests demonstrated strong activity of CMCS formulations against Escherichia coli and Staphylococcus aureus,with CMCS3 exhibiting the highest efficacy.These findings highlight the potential of CMCS-based nanoemulsions for antimicrobial applications and nanoemulsification.
基金supported by the National Natural Science Foundation of China(No.42402319,51704266)the Anhui Provincial Natural Science Foundation(No.2308085QE151)+3 种基金the Natural Science Research Project of Anhui Educational Committee(No.2023AH051222)Young Talent Nurturing Program of Anhui Association For Science and Technology(No.RCTJ202403)the Open Foundation of the Innovation Base of Fine Mine Prospecting and Intelligent Monitoring Technology(No.2023-MPIM-01)partly supported by the Open Fund of Engineering Research Center of Rock-Soil Drilling&Excavation and Protection(No.202407).
文摘The stability of oil-dominated emulsions,including oil-based drilling fluids and crude oils,is crucial for mitigating gas hydrate risks in the petroleum and natural gas industries.Nanoparticles can stabilize oilwater systems(Pickering emulsions)by residing at the oil-water interface.However,their effects on the kinetics of hydrate formation in these systems remain unclear.To address this,we experimentally investigated how hydrophilic and hydrophobic nano-CaCO_(3) influence CH4 hydrate formation within dynamic oil-water systems.A series of hydrate formation experiments were conducted with varying water cuts and different concentrations of nano-CaCO_(3) at a particle size of 20 nm,under 3℃ and 6 MPa.The induction time,hydrate formation volume,and hydrate growth rate were measured and calculated.The results indicate that hydrophilic nano-CaCO_(3) generally inhibits hydrate formation,particularly at high water cuts,while hydrophobic nano-CaCO_(3) can significantly inhibit or even prevent hydrate formation at low water cuts.Water cut strongly influences the kinetics of hydrate formation,and nanoparticle concentration also impacts the results,likely due to changes in oil-water interface stability caused by nanoparticle distribution.This study will offer valuable insights for designing deepwater oilbased drilling fluids using nanoparticles and ensuring safe multiphase flow in deepwater oil and gas operations.
基金supported by the Hubei Province Nature Science Foundation of China(Grant No.:2023AFB1077)the National Natural Science Foundation of China(Grant No.:82003308)+2 种基金the Doctoral Start-up Fund Project of Hubei University of Science and Technology,China(Grant No.:BK202118)the Innovation team and Medical research program of Hubei University of Science and Technology,China(Grant Nos.:2023T10 and 2022YKY05)the Hubei Province Key R&D Plan Big Health Local Special Project,China(Grant No.:2022BCE042).
文摘Transcatheter arterial embolization(TAE)is the mainstay for treating advanced hepatocellular carcinoma(HCC),and the performance of the embolization material is crucial in TAE.With the development of medical imaging and the birth of“X-ray-free”technologies,we designed a new dual-mode imaging material of dimethoxy tetraphenyl ethylene(DMTPE)via emulsification by mixing poly(N-isopropylacrylamide-co-acrylic acid)(PNA)with lipiodol and fluorocarbons,which was evaluated for temperature sensitivity,stability,and dual-mode visualization in vitro.Additionally,blood vessel casting embolization and renal artery imaging were assessed in healthy rabbits.In a rabbit model with a VX2 tumor,the effectiveness of TAE for treating HCC was examined,with an emphasis on evaluating long-term outcomes of embolization and its effects on tumor growth,necrosis,and proliferation through imaging techniques.In vitro experiments confirmed that the temperature-sensitive dual-oil-phase Pickering emulsion had good flow,stable contrast,and embolism when the oil-to-oil ratio and water-to-oil ratio were both 7:3(v/v)and stabilized with 8%PNA.Similarly,in vivo,arterial embolization confirmed the excellent properties of DMTPE prepared at the abovementioned ratios.It was observed that DMTPE not only has an antitumor effect but can also achieve dual imaging using X-rays and ultrasound,making it a promising excellent vascular embolization material for TAE in tumor treatment.
基金supported by the National Natural Science Foundation of China(U20A2067,32272360)。
文摘A Pickering emulsion based on sodium starch octenyl succinate(SSOS)was prepared and its effects on the physicochemical properties of hairtail myofibrillar protein gels(MPGs)subjected to multiple freeze-thaw(F-T)cycles were investigated.The whiteness,water-holding capacity,storage modulus(G')and texture properties of the MPGs were significantly improved by adding 1%-2%Pickering emulsion(P<0.05).Meanwhile,Raman spectral analysis demonstrated that Pickering emulsion promoted the transformation of secondary structure,enhanced hydrogen bonds and hydrophobic interactions,and promoted the transition of disulfide bond conformation from g-g-g to g-g-t and t-g-t.At an emulsion concentration of 2%,theα-helix content decreased by 10.37%,while theβ-sheet content increased by 7.94%,compared to the control.After F-T cycles,the structure of the MPGs was destroyed,with an increase in hardness and a decrease in whiteness and water-holding capacity,however,the quality degradation of MPGs was reduced with 1%-2%Pickering emulsion.These findings demonstrated that SSOS-Pickering emulsions,as potential fat substitutes,can enhance the gel properties and the F-T stability of MPGs.
基金supported by the National Natural Science Foundation of China(22373104 and 22293024)the Science Fund for Creative Research Groups of the National Natural Science Foundation of China(21821005)+1 种基金supported by the National Key Research and Development Program of China(2021YFE020527)support by the Distinguished Young Scholars of the National Natural Science Foundation of China(T2222022).
文摘Lymph node targeting is a commonly used strategy for particulate vaccines,particularly for Pickering emulsions.However,extensive research on the internal delivery mechanisms of these emulsions,especially the complex intercellular interactions of deformable Pickering emulsions,has been surprisingly sparse.This gap in knowledge holds significant potential for enhancing vaccine efficacy.This study aims to address this by summarizing the process of lymph-node-targeting transport and introducing a dissipative particle dynamics simulation method to evaluate the dynamic processes within cell tissue.The transport of Pickering emulsions in skeletal muscle tissue is specifically investigated as a case study.Various factors impacting the transport process are explored,including local cellular tissue environmental factors and the properties of the Pickering emulsion itself.The simulation results primarily demonstrate that an increase in radial repulsive interaction between emulsion particles can decrease the transport efficiency.Additionally,larger intercellular gaps also diminish the transport efficiency of emulsion droplet particles due to the increased motion complexity within the intricate transport space compared to a single channel.This study sheds light on the nuanced interplay between engineered and biological systems influencing the transport dynamics of Pickering emulsions.Such insights hold valuable potential for optimizing transport processes in practical biomedical applications such as drug delivery.Importantly,the desired transport efficiency varies depending on the specific application.For instance,while a more rapid transport might be crucial for lymph-node-targeted drug delivery,certain applications requiring a slower release of active components could benefit from the reduced transport efficiency observed with increased particle repulsion or larger intercellular gaps.
文摘In recent years,Pickering emulsions and their applications have attracted a great deal of attention due to their special features,which include easy preparation and enhanced stability.In contrast to classical emulsions,in Pickering emulsions,solid microparticles or nanoparticles that localize at the interface between liquids are used as stabilizers,instead of surfactants,to enhance the droplet lifetime.Furthermore,Pickering emulsions show higher stability,lower toxicity,and stimuli-responsiveness,compared with emulsions that are stabilized by surfactants.Therefore,they can be considered attractive components for various uses,such as photocatalysis and the preparation of new materials.Moreover,the nanoparticle morphology strongly influences Pickering emulsion stability as well as the potential utilization of such emulsions.Here,we review recent findings concerning Pickering emulsions,with a particular focus on how the nanoparticles morphology(i.e.,cube,ellipsoid,nanosheet,sphere,cylinder,rod,peanut)influences the type and stability of such emulsions,and their current applications in different fields such as antibacterial activity,protein recognition,catalysis,photocatalysis,and water purification.
基金the Natural Science Foundation of China (Nos. 21733009, 21573136, and U1510105)the Key Scientist and Technology Program of Shanxi Province (No. 20150313003-1)Shanxi Scholarship Council of China (No. 2015-003)
文摘Developing methods for efficient product/catalyst separation and catalyst recycling is meaningful in multi-phase catalytic reactions. Here, we reported a p H-responsive emulsion system stabilized by interfacially active TiO2 nanoparticles for achieving in situ product/catalyst separation and catalyst recycling. In this system, emulsification and demulsification process could be easily engineered through tuning the p H values. The emulsion droplets were destroyed completely at a p H value of 3–4, and the solid catalyst distributed in the aqueous phase could be used to the next reaction cycle after removal of the organic product and adjusting the p H to 7–8. Such a p H triggered switchable Pickering emulsion catalytic system not only shows good recyclability of the solid catalyst but also high catalytic efficiency,and could be recycled more than 10 cycles.
基金financially supported by the National Natural Science Foundation of China(No.21822807,21706099,21576120 and U1607125)Natural Science Foundation of Jiangsu Province(No.BK20170323 and BK20170523)+1 种基金Key Research and Development Program of Changzhou City(CE20195014)Graduate Research Innovation Program of Jiangsu Province(No.SJKY19_2576)。
文摘Pickering emulsions stabilized by solid particles have gained much attention,which afford high stability,low toxicity,controllable rheological properties and stimuli-responsive behavior compared to the traditional emulsions emulsified by surfactants.Those particles,as the core parts of the emulsion systems,play an important role in the fabrication and application of Pickering emulsion systems,making them attractive in petroleum fields.In this review,the influence of various particles on the stability and properties of Pickering emulsion systems as well as recent researches associated with the stimuliresponsibility of Pickering emulsion systems are introduced.Specifically,the design of functional particles and Pickering emulsion systems with super stabilities and controllable rheological properties are listed.Furthermore,some petroleum application of Pickering emulsion systems for enhanced oil recovery and spilled oil collection as well as the application as soft templates to fabricate oil-absorbing material and as three-phase microreactors that most likely for petroleum application are discussed,and the issues hindering the actual application of Pickering emulsion systems are also evaluated.This review charts a way for Pickering emulsion studies that could lead to a valid petroleum application through design of the particles served as the enhancers of Pickering emulsion stability for purpose of tailoring chemical flooding.
基金supported by the Natural Sciences and Engineering Research Council of Canada (NSERC)the Canada Research Chairs Program (Hongbo Zeng)the China Scholarship Council (CSC) (An Chen)
文摘This article reports the development of a novel switchable Pickering emulsion with rapid CO_(2)/N_(2) respon-siveness,which is stabilized using alumina nanoparticles hydrophobized in situ with a trace amount of a switchable superamphiphile via electrostatic interactions.With the introduction of CO_(2) for 30 s,the Pickering emulsion can be spontaneously demulsified with complete phase separation;the emulsion can then be reconstructed in response to N_(2) purging for 10 min followed by homogenization.Moreover,the stable Pickering emulsion can be stored for more than 60 days at room temperature with-out any visible change.The CO_(2)/N_(2)-responsive behavior of the switchable Pickering emulsion is attribu-ted to the reversible desorption/adsorption of the switchable surfactants on the surfaces of the alumina nanoparticles upon the alternative bubbling of CO_(2)or N_(2).Thanks to the simple fabrication of the surfac-tant and the hydrophobization of the alumina nanoparticles,this research has developed an extremely facile and cost-efficient method for preparing a rapidly CO_(2)/N_(2)-responsive switchable Pickering emul-sion.The dosage of the switchable surfactants has been significantly reduced by nearly 1500 times(from 150 to 0.1 mmol·L^(-1))as compared with the dosage used in previous studies.Moreover,the as-prepared CO_(2)/N_(2)-responsive switchable Pickering emulsion is environmentally friendly,mild,and nontoxic;thus,it holds great potential for practical applications with considerable economic and environmental benefits,such as oil transport,fossil fuel production,environmental gases detection,and the encapsulation and release of active ingredients.
基金supported by the earmarked fund for the Priority Academic Program Development of Jiangsu Higher Education Institutions(080-820830)。
文摘Curcumin is a bioactive molecule with limited industrial application because of its instability and poor solubility in water.Herein,curcumin-loaded Pickering emulsion was produced using purified bacterial cellulose from fermented kombucha(KBC).The morphology,particle size,stability,rheological properties,and antioxidant activities of the curcumin-loaded Pickering emulsion were investigated.The fluorescence microscope and scanning electron microscopy images showed that the curcumin-loaded Pickering emulsion formed circular droplets with good encapsulation.The curcumin-load Pickering emulsion exhibited better stability under a wide range of temperatures,low p H,sunlight,and UV-365 nm than the free curcumin,indicating that the KBC after high-pressure homogenization improved the stability of the CPE.The encapsulated curcumin retained its antioxidant capacity and exhibited higher functional potential than the free curcumin.The study demonstrated that the KBC could be an excellent material for preparing a Pickering emulsion to improve curcumin stability and antioxidant activity.
基金the National Natural Science Foundation of China(Nos.21975169 and 21374066)the Major Program of the Natural Science Project of Jiangsu Higher Education Institutions(No.15KJA150007)+2 种基金the Natural Science Foundation of Jiangsu Province(No.BK20171212)a Project Funded by the Priority Academic Program Development(PAPD)of Jiangsu Higher Education InstitutionsSoochow-Waterloo University Joint Project for Nanotechnology from Suzhou Industrial Park.
文摘The structure and properties of functional nanoparticles are important for stabilizing Pickering emulsion polymerization.Recently,cellulose nanocrystals(CNCs)are increasingly favored as a bio-based stabilizer for Pickering emulsions.In this study,we reported a novel functionalized polyphosphoester-grafted CNCs for the stabilization of oil-in-water Pickering emulsions and the emulsion polymerization of styrene.First,polyphosphoester containing an amino group at one end of the chain,abbreviated as PBYP-NH2,was prepared by ring-opening polymerization(ROP)and hydrolysis reaction,wherein PBYP represents poly[2-(but-3-yn-1-yloxy)-2-oxo-1,3,2-dioxaphospholane].Subsequently,CNC-COOH was obtained via 2,2,6,6-tetramethylpiperidine-1-oxyl(TEMPO)oxidation of CNCs.The functionalized nanocrystals CNC-PBYP-COOH with carboxyl groups and polyphosphoester on the surface were obtained by the amidation reaction of PBYP-NH2 with CNC-COOH.Finally,we used CNC-PBYP-COOH as sole particle emulsifiers to stabilize styrene-in-water Pickering emulsions and studied its effects on the emulsions in details by using dynamic light scattering(DLS).The results indicated that the properties of these emulsions depended on the concentration of hydrophobically modified CNCs,volume ratios of oil to water,and pH values.The modified CNCs had higher ability to stabilize the styrene-in-water emulsions relative to the unmodified CNCs,and a stable oil-in-water(o/w)Pickering emulsion with diameter of hundreds of nanometers could be obtained.The resulting emulsions could be polymerized to yield nanosized latexes.The polyphosphoester-modified CNCs as green particle emulsifiers can efficiently stabilize nanoemulsions and latexes,which would promote the development of novel environmentally friendly materials.
基金Supported by the National Basic Research Program of China(“973”Program,No.2012CB720302)
文摘Effects of water-soluble co-solvents (WSCs)on the properties of water/oil Picketing emulsions were investigated. Picketing emulsions were prepared in the system of 1,2,4-trimethylbenzene (TMB)/hydrophobic sil- ica/water with varied concentrations of WSCs (ethanol, acetic acid and glycerin). Mean droplet diameter distribu- tions of the obtained emulsions were studied to investigate the effects of WSCs types and concentrations. The results demonstrated that mean droplet diameter distributions decreased at first and then increased with the increase of WSC concentration. Moreover, the effect of WSC concentration on the phase inversion locus was further investi- gated. At the same time, infrared radiation (IR)spectrometer was used to investigate the mechanism. The results showed that the WSC attaching on hydrophobic silica changed the wettability of the particles, which facilitated the formation and phase inversion of the emulsion. The hydrogen bonds between the co-solvent groups attaching on the solid particles made a great effect on the droplet size of the emulsion and strengthened the interaction among emulsifiers. Overall, proper WSC was in favor of the stability of Picketing emulsion.
文摘In recent years, natural biodegradable nanoparticles as stabilizers of Pickering emulsions have attracted extensive attention. In this work, a Pickering emulsion composed of chitosan/Arabic gum nanoparticles (CS/GA NPs), tea tree oil and vitamin E was formulated. Then the antibacterial, anti-inflammatory and wound healing abilities of the emulsion were evaluated. Pickering emulsion encapsulated the tea tree oil strengthened antibacterial activity towards Staphylococcus aureus, Escherichia coli, Pseudomonas aeruginosa and Candida albicans. Besides, this multi-phase system offered a platform to load with vitamin E, which provides anti-inflammatory effects while antibacterial. Meanwhile, Pickering emulsion avoided contact between bacteria and skin when used in wound treatment.
文摘Compared with traditional surfactant-stabilised emulsions, Pickering emulsions, stabilised by clay nanoparticles, have the advantages of strong interface stability, strong versatility, and low toxicity. Moreover, they have excellent application potential in the fields of food and medicine. In this study, a food-grade Pickering emulsion stabiliser was prepared by physically adsorbing the cationic surfactant ethyl lauroyl arginate (LAE) on the surface of nano-montmorillonite (NMMT). Different LAE/NMMT combinations were assessed for their capacity to stabilise an oil-in-water emulsion at a low solid concentration (0.5%, w/v). The controllability of the droplet diameter and stability of the Pickering emulsions can be realised by changing the content of LAE. Scanning electron microscopy (SEM), and laser confocal microscopy (CLSM) confirmed the successful preparation of sunflower oil Pickering emulsion droplets stabilised by LAE/NMMT (0.0075%/1%). Additionally, the LAE/NMMT studied in this work could be used as a highly effective antibacterial surfactant with inorganic nanoparticles to efficiently stabilise Pickering emulsions, thus expanding the potential of preparing edible Pickering emulsion formulae.
基金supported by the National Natural Science Foundation of China(22305164)Natural Science Foundation of Sichuan Province(2023NSFSC1096,2024NSFSC1095)the Fundamental Research Funds for the Central Universities(2023SCU12079).
文摘Bacterial biofilm infection is a complicated and important global problem.Non-toxic biomass-based Pickering emulsions as an essential oil delivery system are a potentially effective means in biofilm treatment.Herein,the chitosan/gelatin complex nanoparticles(CGNPs)stabilized Pickering(CGP)emulsion loaded with cinnamon essential oil(CEO)was developed to inhibit and remove bacterial biofilms.CGNPs were initially successfully prepared with a particle size of 253.7 nm.Subsequently,CGP emulsions were prepared using CGNPs as the emulsifier and CEO as the oil phase,with the aqueous phase pH value of 5.5 and ionic strength of 50 mM.Amino groups of CGNPs were crosslinked with the aldehyde group of CEO via Schiff base reaction at the oil-water interface to form a denser core-shell structure,thus improving the stability of Pickering emulsion.The CGP emulsions exhibit controlled and long-term sustained release properties in essential oil delivery,with 89.8%,81.0%,and 62.2%CEO release within 168 h for CGP-0.1,CGP-0.2,and CGP-0.3,respectively.Moreover,CGP emulsions have stronger antioxidant activities(nearly 100%),broad-spectrum antibacterial activities(>90%),enhanced penetration and removal capabilities against preformed biofilms than single CEO or CGNPs,as well as its better biocompatibility than conventional surfactant-stabilized emulsions.Hence,CEO-delivered CGP emulsion could serve as a potential strategy against biofilm infections and bacterial resistance.
基金supported by the Yunnan Fundamental Research Projects(No.202401AS070012)the Youth Project of‘Xingdian Talent Support Plan’in Yunnan Province(YNWR-QNBJ-2018-046).
文摘Objectives:Walnut protein-galactooligosaccharide(WalPI-GOS)nanoparticles were used to prepare high internal phase Pickering emulsions(HIPPEs).Materials and Methods:The entrapment properties of HIPPEs for cinnamon oil were investigated by varying the volume ratios of camellia and cinnamon oils(cinnamon oil contents:0%,2.5%,5.0%,10%,15%,and 20%),and the droplet size,rheological properties,Raman spectroscopy results,microstructure,thermal stability,storage stability,and antioxidant activity of HIPPEs were determined.Results:The droplet size of HIPPEs increased with increasing cinnamon oil content.Among the samples,HIPPEs enriched with the cinnamon oil content of 10%had the highest storage modulus,loss modulus,and apparent viscosity(13.64 Pa·s).However,the thixotropic recovery ability of HIPPEs decreased with the increase in cinnamon oil content.Raman spectroscopy and microstructural analysis revealed that proteins covalently cross-linked with cinnamaldehyde to form a three-dimensional network structure,which showed the highest stability when the cinnamon oil content was 10%.HIPPEs exhibited high thermal stability without delamination after heating,as well as good storage stability without delamination or discoloration after 15 d of storage at 25℃ and 50℃.Among the samples,HIPPEs enriched with 10%cinnamon oil had the lowest peroxide and malondialdehyde values during storage.The addition of cinnamon oil significantly enhanced the antioxidant activity of HIPPEs.Conclusions:The best overall performance of HIPPEs was achieved at a cinnamon oil content of 10%.This result provides a theoretical foundation for the development of WalPI and the application of cinnamon oil in food,as well as a theoretical basis for the development of novel food delivery systems.
