Polymer microcapsules with liquid cores for controlled release

Loxley, Andrew L.

January 1998

No description available.

541

Emulsion stability; Heterocoagulation

The behaviour of gelatin and gelatin surfactant complexes at the electrolyte/oil interface

Gardiner, Michael

January 1990

No description available.

541

Emulsion stability study

Optimizing emulsion stability of high-oil pourable dressings using different stabilizers

Grizio, Miranda

January 1900

Master of Science / Department of Food Science Institute / Fadi M. Aramouni / To find an optimal formulation of oil-in-water (O/W) emulsion pourable dressings containing 60% and 70% soybean oil, nine stabilizers common to the dressing industry were tested, each at three concentrations. The stabilizers tested were xanthan gum, propylene glycol alginate (PGA), a xanthan gum/guar gum/sodium alginate blend, a viscosifying modified corn starch, an emulsifying modified corn starch, microcrystalline cellulose (MCC), liquid salted egg yolks, liquid salted whole eggs, and dried egg whites (DEW). The emulsions were made with a laboratory high shear disperser and evaluated over 8 weeks by measurement of creaming in 100- mL graduated cylinders and by change in viscosity as measured by a Brookfield viscometer. The stabilizers and concentrations most effective at preventing separation and maintaining viscosity were MCC at 1%, 2%, and 3% in the 60% oil emulsion and 0.25% xanthan gum in the 70% oil emulsion. Average viscosities ranged from 3300 - 23,400 centipoise (cP). The emulsifying starch and dried egg whites were also effective at preventing creaming, but failed to maintain viscosity. The other ingredients showed some initial emulsion stability followed by either a gradual or sudden decrease in stabilization, as seen by decreasing viscosity and eventual separation.

Oil-in-water emulsion

Emulsion stability

Dressing

Food Science (0359)

Amphiphilic Phase-transforming Catalysts for Transesterification of Triglycerides

Nawaratna, Gayan I

03 October 2013

Heterogeneous catalytic reactions that involve immiscible liquid-phase reactants are challenging to conduct due to limitations associated with mass transport. Nevertheless, there are numerous reactions such as esterification, transesterification, etherification, and hydrolysis where two immiscible liquid reactants (such as polar and non-polar liquids) need to be brought into contact with a catalyst. With the intention of alleviating mass transport issues associated with such systems but affording the ability to separate the catalyst once the reaction is complete, the overall goal of this study is geared toward developing a catalyst that has emulsification properties as well as the ability to phase-transfer (from liquid-phase to solid-phase) while the reaction is ongoing and evaluating the effectiveness of such a catalytic process in a practical reaction. To elucidate this concept, the transesterification reaction was selected. Metal-alkoxides that possess acidic and basic properties (to catalyze the reaction), amphiphilic properties (to stabilize the alcohol/oil emulsion) and that can undergo condensation polymerization when heated (to separate as a solid subsequent to the completion of the reaction) were used to test the concept. Studies included elucidating the effect of metal sites and alkoxide sites and their concentration effects on transesterification reaction, effect of various metal alkoxide groups on the phase stability of the reactant system, and kinetic effects of the reaction system. The studies revealed that several transition-metal alkoxides, especially, titanium and yttrium based, responded positively to this reaction system. These alkoxides were able to be added to the reaction medium in liquid phase and were able to stabilize the alcohol/oil system. The alkoxides were selective to the transesterification reaction giving a range of ester yields (depending on the catalyst used). It was also observed that transition-metal alkoxides were able to be recovered in the form of their polymerized counterparts as a result of condensation polymerization subsequent to completion of the transesterification reaction.

Transesterification

Phase-transforming catalysts

Soybean oil

Metal alkoxides

Emulsion stability

Estabilidade de emulsões na presença da biomassa da microalga Arthrospira platensis e do polímero hidroxipropil metilcelulose / Stability of emulsions using the biomass of Arthrospira platensis <microalgae and hydroxypropyl methylcellulose polymer

Shimada, Robson Takeshi

02 June 2017

Arthrospira platensis ou Spirulina é uma microalga com alto valor nutricional. Foram preparados extratos de Spirulina, caracterizados e aplicados como estabilizadores de emulsão de óleo de girassol comercial em água (O/A) (10% v/v) na ausência e na presença de quatro tipos de hidroxipropil metilcelulose (HPMC). Os extratos brutos de Spirulina foram preparados em tampões a pH 6 (EB6) e pH 8 (EB8) por sonicação para promover a lise celular e a libertação de proteínas e fosfolípides; Parte dos extratos foi centrifugada (EC6 ou EC8). Independentemente das condições de extração, todos os extratos apresentados apresentaram valores de potencial-&#950 médio variando de - (16 ± 2) mV a - (20 ± 2) mV, tamanho médio variando de (108 ± 52) nm a (306 ± 68) nm e atividade interfacial. As emulsões O/A preparadas com extratos de Spirulina (10 g / L) exibiram partículas com potencial- médio variando de - (16 ± 2) mV a - (27 ± 4) mV, tamanho médio variando de ~ 70 nm (EB6 ou EB8) a ~ 700 nm (EC6 ou EC8). No entanto, o EB6 levou a emulsões ligeiramente mais estáveis do que as outras. A combinação de EB6 (10 g / L) e HPMC (1,0 % m/m) levou a um aumento substancial na estabilidade da emulsão, embora os valores de potencial- diminuíram uma ordem de grandeza. Em particular, a HPMC com a maior massa molar e o maior grau de substituição de grupos metila conduziu a i) camada interfacial mais robusta resultante da formação de complexos entre cadeias HPMC e proteínas EB6 e (ii) meio contínuo mais viscoso. / Arthrospira platensis or Spirulina is a microalga with a high nutritional value. Extracts of Spirulina were prepared, characterized and applied as oil in water (O/W) (10 % v/v) emulsion stabilizers in the absence and presence of four types of hydroxypropyl methylcellulose (HPMC). The emulsions were prepared with edible sunflower oil. Crude extracts of Spirulina were prepared in buffers at pH 6 (CE6-Crude extract pH6) and pH 8 (CE8-Crude extract pH8) by sonication to promote cell lysis and protein and phospholipids release; part of the extracts was centrifuged (CCE6 or CCE8). Regardless of the extraction conditions, all extracts presented mean -potential ranging from (16 ± 2) mV to (20 ± 2) mV, mean diameter ranging from (108 ± 52) nm to (306 ± 68) nm and interfacial activity. The emulsions prepared with Spirulina extracts (10 g/L) displayed particles with mean -potential ranging from (16 ± 2) mV to (27 ± 4) mV, mean diameter ranging from ~ 70 nm (CCE6 or CCE8) to ~ 700 nm (CE6 or CE8). However, CE6 led to emulsions slightly more stable than the others did. The combination of CE6 (10 g/L) HPMC (1.0 wt %) led to substantial increase in the emulsion stability, although the -potential values decreased one order of magnitude. Particularly, the HPMC with the highest molecular weight and highest methyl substitution degree led to the most (i) robust interfacial layer resulting from the complex formation between HPMC chains and CE6 proteins and (ii) viscous continuous medium.

Complexação

Complexation

Emulsion stability

Emulsionante natural

Estabilidade de emulsão

Hidroxipropil metilcelulose

Hydroxypropyl methylcellulose

Natural emulsifier

Spirulina

Spirulina

Estabilidade de emulsões na presença da biomassa da microalga Arthrospira platensis e do polímero hidroxipropil metilcelulose / Stability of emulsions using the biomass of Arthrospira platensis <microalgae and hydroxypropyl methylcellulose polymer

Robson Takeshi Shimada

02 June 2017

Arthrospira platensis ou Spirulina é uma microalga com alto valor nutricional. Foram preparados extratos de Spirulina, caracterizados e aplicados como estabilizadores de emulsão de óleo de girassol comercial em água (O/A) (10% v/v) na ausência e na presença de quatro tipos de hidroxipropil metilcelulose (HPMC). Os extratos brutos de Spirulina foram preparados em tampões a pH 6 (EB6) e pH 8 (EB8) por sonicação para promover a lise celular e a libertação de proteínas e fosfolípides; Parte dos extratos foi centrifugada (EC6 ou EC8). Independentemente das condições de extração, todos os extratos apresentados apresentaram valores de potencial-&#950 médio variando de - (16 ± 2) mV a - (20 ± 2) mV, tamanho médio variando de (108 ± 52) nm a (306 ± 68) nm e atividade interfacial. As emulsões O/A preparadas com extratos de Spirulina (10 g / L) exibiram partículas com potencial- médio variando de - (16 ± 2) mV a - (27 ± 4) mV, tamanho médio variando de ~ 70 nm (EB6 ou EB8) a ~ 700 nm (EC6 ou EC8). No entanto, o EB6 levou a emulsões ligeiramente mais estáveis do que as outras. A combinação de EB6 (10 g / L) e HPMC (1,0 % m/m) levou a um aumento substancial na estabilidade da emulsão, embora os valores de potencial- diminuíram uma ordem de grandeza. Em particular, a HPMC com a maior massa molar e o maior grau de substituição de grupos metila conduziu a i) camada interfacial mais robusta resultante da formação de complexos entre cadeias HPMC e proteínas EB6 e (ii) meio contínuo mais viscoso. / Arthrospira platensis or Spirulina is a microalga with a high nutritional value. Extracts of Spirulina were prepared, characterized and applied as oil in water (O/W) (10 % v/v) emulsion stabilizers in the absence and presence of four types of hydroxypropyl methylcellulose (HPMC). The emulsions were prepared with edible sunflower oil. Crude extracts of Spirulina were prepared in buffers at pH 6 (CE6-Crude extract pH6) and pH 8 (CE8-Crude extract pH8) by sonication to promote cell lysis and protein and phospholipids release; part of the extracts was centrifuged (CCE6 or CCE8). Regardless of the extraction conditions, all extracts presented mean -potential ranging from (16 ± 2) mV to (20 ± 2) mV, mean diameter ranging from (108 ± 52) nm to (306 ± 68) nm and interfacial activity. The emulsions prepared with Spirulina extracts (10 g/L) displayed particles with mean -potential ranging from (16 ± 2) mV to (27 ± 4) mV, mean diameter ranging from ~ 70 nm (CCE6 or CCE8) to ~ 700 nm (CE6 or CE8). However, CE6 led to emulsions slightly more stable than the others did. The combination of CE6 (10 g/L) HPMC (1.0 wt %) led to substantial increase in the emulsion stability, although the -potential values decreased one order of magnitude. Particularly, the HPMC with the highest molecular weight and highest methyl substitution degree led to the most (i) robust interfacial layer resulting from the complex formation between HPMC chains and CE6 proteins and (ii) viscous continuous medium.

Complexação

Emulsionante natural

Estabilidade de emulsão

Hidroxipropil metilcelulose

Spirulina

Complexation

Emulsion stability

Hydroxypropyl methylcellulose

Natural emulsifier

Spirulina

Poly(High Internal Phase Emulsion) Foams and Fibers: Structure-Property Relationships

Bezik, Cody

02 September 2015

No description available.

Chemical Engineering

Polymers

High internal phase emulsion

polymeric monoliths

emulsion stability

porous fibers

[en] INJECTIVITY AND STABILITY OF OIL-IN-WATER EMULSIONS WITH LIPOPHILIC NATURAL SURFACTANTS / [pt] INJETIVIDADE E ESTABILIDADE DE EMULSÕES ÓLEO EM ÁGUA COM SURFACTANTES NATURAIS OLEOSOS

ALANDMARA ROSA DIONIZIO LEONCIO

27 April 2020

[pt] Emulsões estáveis de óleo-em-água (O/A) e água-em-óleo (A/O) são criadas em diferentes processos de produção de óleo devido à presença de tensoativos naturais, tais como asfaltenos, resinas, ácidos orgânicos solúveis em óleo, sólidos e ceras. Um filme interfacial é formado causando interações químicas entre os surfactantes e outras espécies na fase aquosa. Este trabalho tem como objetivo estudar a formação e estabilidade de emulsões estabilizadas por um ácido graxo como um surfactante natural, sob condições ambientes e de alta pressão, bem como seu comportamento de fluxo através de testes de injetividade em arenitos. Para este fim, o estudo da estabilidade da emulsão e análise de reologia interfacial foram realizadas através da avaliação da distribuição do tamanho de gotas e do módulo viscoelástico da interface em função da concentração de surfactante, composição aquosa e condições de fluxo. Nos testes reológicos, os resultados mostraram que a presença do ácido graxo na fase oleosa promoveu redução na tensão interfacial óleo-água e módulo elástico maior que o módulo viscoso, evidenciando importante atividade superficial. Todas as emulsões formadas com uma solução alcalina sem sais foram estáveis sob condições ambientes. Durante a injeção de emulsão em fluxo monofásico, o controle da mobilidade da água foi observado através da redução da permeabilidade absoluta como uma função forte da distribuição do tamanho da gota da emulsão e do número de capilaridade. / [en] Stable oil-in-water (O/W) and water-in-oil (W/O) emulsions are created in different processes of oil production due to the presence of natural crude oil surfactants, such as asphaltenes, resins, oil-soluble organic acids, solids, and waxes. An interfacial film is formed causing chemical interactions between the surfactants and other species in the water phase. This work aims to study the formation and stability of emulsions stabilized by a fatty acid as natural surfactant, under ambient and high-pressure conditions, and their flow behavior through injectivity tests in sandstones. To this end, study of emulsion stability and interfacial rheology analysis were performed by evaluating the droplet size distribution and interfacial viscoelastic modulus as a function of the surfactant concentration, aqueous composition, and flow conditions. In the rheological tests, results showed that the presence of the fatty acid in the oil phase promoted a reduction in the oil-water interfacial tension and elastic modulus larger than the viscous modulus, evidencing important surface activity. All emulsions formed with an alkaline solution without salts were stable under ambient conditions. During emulsion injection in single-phase flow, water mobility control was observed through the reduction of the absolute permeability as a strong function of emulsion drop size distribution and capillary number.

[pt] EMULSOES

[pt] INJETIVIDADE

[pt] ESTABILIDADE DE EMULSOES

[pt] MEIOS POROSOS

[en] EMULSIONS

[en] INJECTIVITY

[en] EMULSION STABILITY

[en] POROUS MEDIA

Preparation and characterisation of pheroid vesicles / Charlene Ethel Uys

Uys, Charlene Ethel

January 2006

Thesis (M.Sc. (Pharmaceutics))--North-West University, Potchefstroom Campus, 2007.

Pheroid

Emulsion stability

Particle size and size distribution

Zeta potential

Turbidity

pH

Current

Accelerated stability testing

Effect Of High Hydrostatic Pressure (hhp) And High Dynamic Pressure (hdp) On Stability And Rheological Properties Of Model Oil-in-water Emulsions

Bigikocin, Erman

01 September 2010

High pressure applications are alternatives to conventional methods in food processing. They provide interesting modifications in food structures which leads to new product formulations. The aim of this study is to identify the effects of two different treatments, high hydrostatic pressure (HHP) and high dynamic pressure (HDP) on stability and rheological properties of model oil-in-water emulsions. Microfluidization was selected among the HDP homogenization techniques. The performance of each process was analyzed in terms of rheological modifications and emulsion stability improvements compared to the coarse emulsions which were prepared with colloid mill homogenization. Stability of emulsions was determined comparatively by using an analytical photo-centrifuge device employing a novel analysis technology. Whey protein isolate (WPI) was used as an emulsifier in combination with a food polysaccharide as a stabilizer. The polysaccharides used were xanthan gum, guar gum and locust bean gum which are widely used stabilizing ingredients in food industry. The effective disruption of oil droplets and the degradation of polysaccharides by the shear forces under high pressure in HDP microfluidization yielded finer emulsions with lower viscosities. The finer emulsions obtained with this homogenization technique led to distinctive improvements in emulsion stability. On the other hand, the improvements in stability by HHP treatment were due to the thickening of the emulsions mainly induced by protein unfolding. The corresponding increases in viscosity were intensified in emulsion formulations with higher oil content. Apart from these, HHP treatment was found to be relatively more contributing to the enhancements in viscoelastic properties.

Oil-in-water emulsions

High hydrostatic pressure

High dynamic pressure

Emulsion stability

Rheology