Effects of Soy Proteins and Hydrolysates on Fat Globule Coalescence and Whipping Properties of Recombined Low-Fat Whipped Cream

The interaction and synergetic effect of soy protein isolate (SPI) and its hydrolysates with different concentrations of monoglycerides were explored at the air-water/oil interfaces in recombined low-fat whipped cream (20%). The creams were made with 20% palm oil, 18% carbohydrate, 0.22% stabilizers, and 0.25–1.00% monoglycerides. The proteins used were native soy protein isolate (NSPI), commercial soy protein isolate (CSPI), soy protein hydrolysates by pepsin (SPHPe), soy protein hydrolysates by papain (SPHPa), and SC (sodium caseinate). Overrun, stability, rheological behavior, and texture of recombined low-fat whipped cream were studied. Results indicated that increasing concentration of monoglycerides was effective in improving the textural, whipping properties, and stability of recombined low-fat whipped cream. Increasing concentration of monoglycerides in the mix prompted the displacement of adsorbed protein from fat globules, built up a firmer structure of fat aggregates, and stabilized the trapped air bubbles in the structure of recombined low-fat whipped cream. At the same level of monoglycerides, SPHPa whipped cream produced a similar overrun, stability, and texture as SC. Due to the high proportion of β-conglycinin in SPHPe, a low degree of fat globule partial coalescence occurred and led to low overrun and weakened structure in recombined low-fat whipped cream.

     

Formation,Stability and In Vitro Digestion of β-carotene in Oil-in-Water Milk Fat Globule Membrane Protein Emulsions

The formation, stability and in vitro digestion of milk fat globule membrane (MFGM) proteins stabilized emulsions with 0.2 wt% β-carotene were investigated. The average particle size of β-carotene emulsions stabilized with various MFGM proteins levels (1%, 2%, 3%, 4%, 5% wt%) decreased with the increase of MFGM proteins levels. When MFGM proteins concentration in emulsions is above 2%, the average particle size of β-carotene emulsions is below 1.0 μm. A quite stable emulsion was formed at pH 6.0 and 7.0, but particle size increased with decrease in acidity of the β-carotene emulsion. β-carotene emulsions stabilized with MFGM proteins were stable with a certain salt concentrations (0–500 mMNaCl). β-carotene emulsions were quite stable to aggregation of the particles at elevated temperature and time (85 °C for 90 min). At the same time, β-carotene emulsions were stable against degradation under heat treatment conditions. In vitro digestion of β-carotene emulsion showed the mean particle size of β-carotene emulsions stabilized with MFGM proteins in the simulated stomach conditions and intestinal conditions is larger than that of initial emulsions and simulated mouth conditions. Confocal laser scanning microscopy of β-carotene MFGM proteins emulsions also showed the corresponding results to different vitro digestion model. There was a rapid release of free fatty acid (FFA) during the first 10 min and after this period, an almost constant 70% digestion extent was reached. Approximately 80% of β-carotene was released within 2 h of incubation under the simulated intestinal fluid. These results showed that MFGM protein can be used as a good emulsifier in emulsion stabilization, β-carotene rapid release as well as lipophilic bioactive compounds delivery.     

Comparing Carboxymethyl Cellulose and Starch as Thickeners in Oil/Water Emulsions. Implications on Rheological and Structural Properties

The study reported here aims to obtain information on how thickener type and concentration, and oil content influence rheology, particle size, particle charge and microstructure in o/w model emulsions. Emulsions were prepared at two oil concentrations (5 and 30 % wt/wt), each with three CMC concentrations (0.2, 0.3, and 0.4 % wt/wt), or three starch concentrations (2, 3, and 4 % wt/wt). For each oil concentration, a sample without any added thickener was prepared as reference. Both CMC and swollen starch granules showed a dominating effect on emulsion flow behavior, although the presence and concentration of fat droplets also played an important role. Viscoelasticity of CMC-based emulsions mainly depended of oil concentration whilst in starch-based emulsions the most influential ingredient was starch. A similar situation was detected in terms of particle size distribution; CMC effect was dependent on oil content and starch effect was mainly related to the volume occupied by swollen granules. Differences in microstructure and particle size distribution between CMC and starch emulsions were related to their rheological behavior. Apart from enabling the acquisition of food emulsions with different composition but with similar rheological behavior by adding different hydrocolloids, here we consider thickener effect on other properties in order to obtain food emulsions with adequate characteristics.     

Legume Protein Isolates for Stable Acidic Emulsions Prepared by Premix Membrane Emulsification

Proteins originating from dry legumes are not that much used in food formulations, yet, they are interesting components from a sustainability point of view, and could have interesting functional properties, e.g. for emulsion preparation. Therefore, this work focuses on the potential of the water soluble part of pea, chickpea and lentil protein isolates under acidic emulsions (pH 3.0) using a novel mild technique: premix membrane emulsification. Pea proteins (PP) and chickpea proteins (CP) lower the interfacial tension in the same way as whey protein isolate (WPI), which suggests that they could facilitate emulsion droplet formation similarly as WPI, while lentil proteins (LP) are slightly less effective. It is possible to make oil-in-water (O/W) emulsions with an average droplet diameter (d _4,3 ) of ~5 μm after 5 cycles in the premix system. The droplet size distribution of the emulsions remained constant during one day of storage, indicating that legume proteins are able to form and kinetically stabilize O/W emulsions. CP and PP exhibited emulsifying properties comparable to those of WPI, whereas LP is slightly less efficient, therewith indicating the great potential and that pea and chickpea protein isolates hold as emulsifiers in acidic food formulations.     

Phase Transition Stability of Cocoa Butter Emulsions

The impact of tempering-crystallization on microstructure and stability of water-in-cocoa butter (w/o) emulsions was analyzed using differential scanning calorimetry (DSC). The type and volume fraction of the disperse phase, and cooling rate during DSC analysis were systematically varied. Freshly prepared emulsions were additionally characterized by microscopy and laser diffraction. Fresh cocoa butter emulsions were composed of small and well dispersed droplets of an average size of 2.24 μm and 1.96 μm for water and 50 % sucrose solution as disperse phase, respectively. The thermograms revealed that the dissolved sugar lowered freezing and melting temperature and, dependent on volume fraction, the dispersion in the oil phase led to a change in solidification behavior. The temperature at the solidification peaks gives qualitative information about droplet size whereas width and number of exothermic events are related to particle size distribution (mono/polydispersity and mono/multimodality) and microstructure. Emulsions with water as dispersed phase show a clear shift of the freezing peaks of the disperse phase which points on modified emulsion microstructure because of droplet coalescence, which is more pronounced at higher volume fraction and lower cooling rate. Emulsions with sucrose solution as dispersed phase showed the greatest stability, wherein the volume fraction and the cooling rate does not matter. The results allow conclusions about the mechanisms of crystallization processes in cocoa butter emulsions resulting as network crystallization.     

Physical properties of emulsion-based hydroxypropyl methylcellulose films: Effect of their microstructure

The initial characteristics of emulsions and the rearrangement of the oil droplets in the film matrix during film drying, which defines its microstructure, has an important role in the physical properties of the emulsion-based films. The objective of this work was to study the effect of the microstructure (two droplet size distributions) and stability (with or without surfactant) of HPMC oil-in-water emulsions over physical properties of HPMC emulsion-based edible films. HPMC was used to prepare sunflower oil-in-water emulsions containing 0.3 or 1.0% (w/w) of oil with or without SDS, as surfactant, using an ultrasonic homogenizer. Microstructure, rheological properties and stability of emulsions (creaming) were measured. In addition, microstructure, coalescence of oil droplets, surface free energy, optical and mechanical properties and water vapor transfer of HPMC films were evaluated. Image analysis did not show differences among droplet size distributions of emulsions prepared at different oil contents; however, by using SDS the droplet size distributions were shifted to lower values. Volume mean diameters were 3.79 and 3.77μm for emulsions containing 0.3 and 1.0% without surfactant, respectively, and 2.72 and 2.71μm for emulsions with SDS. Emulsions formulated with 1.0% of oil presented higher stability, with almost no change during 5 and 3 days of storage, for emulsions with and without SDS, respectively. Internal and surface microstructure of emulsion-based films was influenced by the degree of coalescence and creaming of the oil droplets. No effect of microstructure over the surface free energy of films was found. The incorporation of oil impaired the optical properties of films due to light scattering of light. Addition of oil and SDS decreased the stress at break of the emulsion-based films. The replace of HPMC by oil and SDS produce a lower "amount" of network structure in the films, leading to a weakening of their structure. The oil content and SDS addition had an effect over the microstructure and physical properties of HPMC-based emulsions which lead to different microstructures during film formation. The way that oil droplets were structured into the film had an enormous influence over the physical properties of HPMC films.     

Enhancement of Carotenoid Bioaccessibility from Tomatoes Using Excipient Emulsions: Influence of Particle Size

The effect of excipient emulsions with different lipid droplet sizes on carotenoid bioaccessibility from tomatoes was investigated using a simulated gastrointestinal tract (GIT). Excipient emulsions with different surface-weighted mean droplet diameters were fabricated: d ₃₂  = 0.15 μm (small), 0.40 μm (medium), and 22.3 μm (large). Changes in particle size, microstructure, ζ-potential, and carotenoid bioaccessibility were measured when tomato-emulsion mixtures that had received different thermal and mixing treatments were passed through the GIT model. Carotenoid bioaccessibility decreased with increasing initial droplet size (small ≥ medium > large), which was attributed to two effects. First, smaller droplets extracted carotenoids from tomato tissue more efficiently. Second, smaller droplets were digested faster leading to more rapid mixed micelle formation, thereby increasing carotenoid solubilization in intestinal fluids. Carotenoid bioaccessibility was higher from boiled than raw tomatoes because thermal disruption of the plant tissue facilitated carotenoid release. Carotenoid bioaccessibility was higher when tomatoes were boiled with emulsions than when they were boiled alone and then added to emulsions. In conclusion, excipient emulsions are highly effective at increasing carotenoid bioaccessibility from tomatoes, but lipid droplet size must be optimized to ensure high efficacy.

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Graphical Abstract ?

     

Influence of Nanoemulsion Addition on the Stability of Conventional Emulsions

Interest in using nanoemulsions as delivery systems for lipophilic food ingredients is growing due to their high optical clarity, good physical stability, and ability to increase bioavailability. Nanoemulsion-based delivery systems may need to be incorporated into food matrices that also contain conventional emulsions. The aim of this work was to evaluate the effect of adding nanoemulsions (d?<?200 nm) to conventional emulsions (d?>?200 nm) on the creaming stability and microstructure of the mixed systems. Droplet flocculation and rapid creaming was observed when the nanoemulsion concentration exceeded a particular level: the critical flocculation concentration (CFC) was 3.75 % and 0.25 % (v/v) for conventional emulsions with average droplet diameters of 350 and 250 nm, respectively. Confocal microscopy indicated that there was appreciable droplet flocculation, and the fraction of individual droplets with diameters?<?100 nm decreased after 14 days storage, which was probably due to Ostwald ripening and/or coalescence. The results of the present study might have important implications for the incorporation of nanoemulsion-based delivery systems into food products containing larger fat droplets, such as dressings, sauces, or beverages.     

In Situ Enzymatic Synthesis of Polar Lipid Emulsifiers in the Preparation and Stabilisation of Aerated Food Emulsions

We report on the direct incorporation of a lipase derived from Rhizomucor miehei, into aeratable food emulsion formulations, with the objective of enzymatically generating polar lipid fractions during processing, and which are able to demonstrate equivalent functionality to chemically synthesised monoglycerides. Findings showed that the lipolysis of palm oil-in-water emulsions produced a combination of predominantly oleic monoglyceride and palmitic fatty acid fractions. The extent of hydrolysis was able to be controlled through concentration of enzyme, reaction time, and reaction temperature. Hydrolysis was terminated via inactivation of the enzyme through high heat treatment of emulsions. Emulsion properties, notably stability under shear, were seen to be highly dependent on the extent of lipolysis. When applied to model whipping and ice cream formulations, lipolytic generation of polar lipids was shown to promote both partial coalescence and fat globule adsorption to bubble surfaces, generating structures equivalent to those produced by use of commercial emulsifiers. Product properties, such as physical stability and material properties showed variation according to the extent of lipolysis. Our results demonstrated that enzymatic lipolysis of emulsions under controlled conditions could be optimised to deliver requisite droplet functionality for the structuring and stabilisation of aerated food emulsions. Findings are of significance, not only when considering the potential for replacement of chemically derived emulsifiers in such formulations, but also from the perspective that this approach can readily be incorporated into existing manufacturing process operations.     

The Influence of Emulsion Droplet Interactions on the Structural,Material and Functional Properties of a Model Mozzarella Cheese

We present findings on the influence of interfacial layer composition on the colloidal interactions and associated structural and material properties of oil-in-protein gel emulsions, as applied to a model Mozzarella cheese analogue. Model cheese samples were produced through thermal mixing of pre-prepared oil-in-water emulsions with a renneted casein gel. Sodium caseinate and Tween 20 were used as the emulsifiers. Microstructural analysis showed sodium caseinate stabilised droplets to be homogeneously dispersed within the cheese structure, whilst droplets stabilised by Tween 20 were phase concentrated into localised fat domains within the continuous protein network. Particle size measurements determined that, on chilled storage, the droplets in these localised regions underwent extensive partial coalescence, whilst the homogenously distributed caseinate droplets showed little change in droplet size. Small deformation rheology (4 to 80 °C) determined the sodium caseinate emulsion as providing a reinforcing effect on the protein network across the entire temperature range, while the Tween 20 emulsion was observed to mechanically strengthen the cheese structure at only at temperatures for which the fat phase was solid whilst serving to weaken the structure on transitioning to a molten state. Differences in droplet structure and stability were determined as influencing cheese melt and flow characteristics. During melting, no oiling-off observed for cheese samples comprising sodium caseinate stabilised droplets, compared to Tween 20 stabilised emulsions where extensive oiling-off was observed. Findings corroborate the hypothesis that caseinate coated droplets behave as active fillers within the protein network, whilst the Tween 20 stabilised emulsion are non-interactive.     

Impact of Electrostatic Interactions on Lecithin-Stabilized Model O/W Emulsions

Natural emulsifiers, particularly those extracted from plants, are highly wanted by food industry to meet consumers demand for clean label food and beverage products. The potential utilization of soy lecithin as an emulsifier in model coffee creamer was investigated in this study. The model oil-in-water (O/W) emulsions consisted of 10 wt% medium chain triglyceride were stabilized using either 1% or 5% soy lecithin (pH 7.0). The O/W emulsions were of whitish milky color (L*?=?88–92) and were able to whiten black coffee solutions (L* from 5.5 for black coffee to 44–56 for white coffees). Model O/W emulsions with smaller mean droplet diameters (0.11 to 1.09 μm), higher surface potentials (ζ?=??62 to ?72 mV), and better stabilities in hot coffee were fabricated using higher lecithin levels because there was more emulsifier to coat the oil droplet surfaces. Alteration of the electrostatic interactions in the model O/W emulsions (5% lecithin) by pH adjustment or calcium addition led to droplet aggregation under certain conditions, which was attributed to charge reduction by protonation of lecithin head groups and electrostatic screening by counter-ion accumulation and ion-binding. In particular, phase separation of the model creamer occurred at pH value around 4.5 when the system was acidified at a slow rate. Overall, this study suggests that lecithin-stabilized O/W emulsions may become unstable in coffee solutions with high acidity or calcium levels. The information obtained from this study provides insights on the use of plant-based emulsifiers in commercial food and beverage systems.     

Stability of Emulsions Using a New Natural Emulsifier: Sugar Beet Extract <Emphasis Type="Italic">(Beta vulgaris L.)</Emphasis>

This study describes the influence of environmental stresses on the stability of emulsions prepared by a natural sugar beet extract (Beta vulgaris L.). The emulsion stabilizing performance was compared to that of Quillaja extract, which is widely used within the food and beverage industry as natural surfactant. We investigated the influence of pH, ionic strength, heating and freeze-thawing on the mean particle size, ζ-potential and microstructure of oil-in-water emulsions (10% w/w oil, 0.75% w/w emulsifier). The emulsions stabilized by the anionic sugar beet extract were stable at pH 5–8 and against thermal treatments up to 60 °C. However, the prepared emulsions were unstable at acidic (pH 2–4) and basic pH conditions (pH 9), at high temperature (>60 °C), and at salt additions (> 0.1 M NaCl / CaCl₂). Moreover, they also phase separated upon freeze-thawing. Our results show that sugar beet extract is capable of stabilizing emulsions and may therefore be suitable as natural emulsifier for selected applications in the food and beverage industry.     

Microorganism viability influences internal phase droplet size changes during storage in water-in-oil emulsions

Water-in-oil emulsions provide an alternative for long-term stabilization of microorganisms. Maintaining physical stability of the emulsion and cell viability is critical for large-scale application. Water-in-oil (W/O) emulsions were prepared with the biolarvacide Lagenidium giganteum and the green alga Chlorella vulgaris. Physical stability was measured via light scattering measurements of the internal phase droplets and cell viability was measured by plating and enumerating colony forming units. Emulsions were demonstrated to stabilize L. giganteum and C. vulgaris for more than 4 months without refrigeration. Introducing nutrients into the internal phase of W/O emulsions without cells had no significant effect on changes in aqueous phase droplet size dynamics. Internal phase droplet size changes that occurred over time were greater in the presence of cells. Increases in droplet size were correlated with cell death indicating measurement of internal phase droplet size changes may be an approach for monitoring declines in cell viability during storage.     

Stability of CoQ10-Loaded Oil-in-Water (O/W) Emulsion: Effect of Carrier Oil and Emulsifier Type

Co-enzyme Q10 (CoQ10), a lipophilic compound that widely used in the food and pharmaceutical products was formulated in a κ-carrageenan coated oil-in-water (O/W) emulsion. In this work, we examined the solubility of CoQ10 in different carrier oils and effects of emulsifier type on the formation and stability of CoQ10-loaded O/W emulsion. Nine vegetable oils and four types of emulsifiers were used. CoQ10 was found significantly (p?<?0.05) more soluble in medium chain oils (coconut oil and palm kernel oil) as compared to other vegetable oils. The O/W emulsions were then prepared with 10 % (w/w) coconut oil and palm kernel oil containing 200 g CoQ10/L oil stabilized by 1 % (w/v) emulsifiers (sucrose laurate (SEL), sodium stearoyl lactate (SSL), polyglycerol ester (PE), or Tween 80 (Tw 80)) in 1 % (w/v) κ-carrageenan aqueous solution. Particle size distribution and physical stability of the emulsions were monitored. The droplet sizes (surface weighted mean diameter, D[3,2]) of fresh O/W emulsion in the range of 2.79 to 5.83 μm were observed. Irrespective of the oil used, results indicated that complexes of SSL/κ-carrageenan provided the most stable CoQ10-loaded O/W emulsion with smaller and narrower particle size distribution. Both macroscopic and microscopic observations showed that O/W emulsion stabilized by SSL/κ-carrageenan is the only emulsion that exhibited no sign of coalescence, flocculation, and phase separation throughout the storage period observed.     

Factors Affecting Foamed Emulsions Prepared with an Extract from <Emphasis Type="Italic">Quillaja saponaria</Emphasis> Molina: Oil Droplet Size,pH and Presence of Beta-Lactoglobulin

Oil is well-known to act as antifoam and to destabilize foam lamellae by bridging between two adjacent foam bubbles. It was hypothesized that an optimal oil droplet size exists with respect to the stability of a foamed emulsions, where the oil droplets are sufficiently small to postpone bridging and the amount of free surfactant is sufficient to stabilize the oil/water-interface and the air/water-interface. Emulsions with 0.3% Quillaja saponin and a median oil drop-let size between 0.2 and 2.0 μm were prepared under varying homogenization conditions and characterized in a dynamic foam analyzer. Results confirmed the above mentioned hypothesis. Stability of the foamed emulsions considerably increased with increasing pH, which was attributed to electrostatic repulsion between oil droplets and the effect on the balance between disjoining pressure and capillary pressure. In a binary system containing proteins and saponins, stability of foamed emulsions can be further increased when emulsifiers are added sequentially. When the emulsion is stabilized by β-LG and QS is added after emulsification stability of the foamed emulsion is distinctly higher compared to systems, where QS and β-LG are added prior to emulsification. Future studies should deepen our understanding of these complex dispersed systems by investigating the molecular interactions including other proteins and additional food constituents.     

Formation and Stability of ω-3 Oil Emulsion-Based Delivery Systems Using Plant Proteins as Emulsifiers: Lentil,Pea, and Faba Bean Proteins

Many sectors of the food industry are interested in replacing synthetic or animal-based ingredients with plant-based alternatives to create products that are more natural, environmentally friendly, and sustainable. In this study, the ability of several plant protein concentrates to act as natural emulsifiers in oil-in-water emulsions fortified with omega-3 fatty acids was investigated. The impact of emulsifier type on the formation and stability of the emulsions was determined by measuring changes in droplet characteristics (size and charge) under different homogenization, pH, salt, and temperature conditions. Pea (Pisum sativum), lentil (Lens culinaris) and faba bean (Vicia faba) protein concentrates all proved to be effective emulsifiers for forming and stabilizing 10 wt% algae oil-in-water emulsions produced by high-pressure homogenization. The droplet size decreased with increasing emulsifier concentration, and relatively small oil droplets (d < 0.3 μm) could be formed at higher emulsifier levels (5% protein). Lentil protein-coated droplets were the most stable to environmental stresses such as pH, ionic strength and temperature changes. These results have important implications for the production of functional foods and beverages from natural plant-based ingredients.     

Influence of Lipid Phase Composition of Excipient Emulsions on Curcumin Solubility,Stability, and Bioaccessibility

The influence of oil type on the ability of excipient emulsions to improve the solubility, stability, and bioaccessibility of curcumin was examined. Oil-in-water emulsions were prepared using coconut, sunflower, corn, flaxseed, or fish oils. These excipient emulsions were then mixed with powdered curcumin and incubated at 30 or 100 °C. For all oils, more curcumin was transferred from powder to excipient emulsion at 100 °C (190–200 μg/mL) than at 30 °C (30–36 μg/mL), which was attributed to increased curcumin solubility with temperature. Oil type influenced the stability and bioaccessibility of curcumin when excipient emulsions were exposed to simulated gastrointestinal tract conditions, which was attributed to differences in the molecular composition and physicochemical properties of the oils. Overall, the use of fish oil led to the highest effective curcumin bioavailability (38 %). This study provides valuable information for optimizing excipient emulsions to increase curcumin bioavailability in food, supplement, or pharmaceutical applications.     

Effect of plant growth regulators and elicitors on rhinacanthin accumulation in hairy root cultures of Rhinacanthus nasutus (L.) Kurz

Several biologically active secondary metabolites like anthraquinones, sterols, triterpenes, flavonoids and naphthoquinones are present in Rhinacanthus nasutus. Naphthoquinones are important group of compounds generally known as rhinacanthin (RC) consists of 15 derivatives named RC A–D and G–Q of which RC-C, RC-D and RC-N have various medicinal properties. The individual role of two auxins i.e. indole-3-butyric acid (IBA) and α naphthalene acetic acid (NAA) and two elicitors i.e. methyl jasmonate (MJ) and salicylic acid (SA) in Murashige and Skoog medium on hairy root growth and RC (RC-C, RC-D and RC-N) accumulation was investigated in the present study. Time course study revealed that IBA and NAA at 2.5 μM showed maximum fresh weight (FW) and dry weight (DW) 4 weeks after culture. However, RC production was maximum after 6 weeks of culture on both media. A concentration-dependent response was observed when various concentrations of MJ (2.0, 5.0, 10 and 15 μM) and SA (10, 50, 100 and 150 μM) were supplemented in the medium. On MJ and SA media the FW and DW decreased as the concentration of elicitors increased. However, this decrease was more severe in MJ treated cultures. All the MJ and SA treated cultures showed significantly higher amount of RC-C, RC-D and RC-N in hairy roots harvested 7 days after elicitation as compared to control. Of the two elicitors, MJ was more efficient in inducing RC accumulation than SA. The highest RC content (6.3 mg/g DW RC-C; 1.1 mg/g DW RC-D and 0.61 mg/g DW RC-N) was observed after treatment with 10 μM MJ which was about 1.7-, 2.5- and 3.5-fold higher RC-C, RC-D and RC-N respectively than the control.     

Cuttlebone as a Marine-Derived Material for Preparing Bone Grafts

The use of synthetic materials for biomedical applications still presents issues owing to the potential for unfavourable safety characteristics. Currently, there is increasing interest in using natural, marine-derived raw materials for bone tissue engineering. In our study, the endoskeleton of the mollusc Sepia, i.e. cuttlebone (CB), was used with regenerated cellulose (RC) to prepare three-dimensional composite bone grafts. CB microparticles were mechanically immobilised within a cellulose gel, resulting in a macroporous structure upon lyophilisation. The interconnected porous structure of the regenerated cellulose/cuttlebone (RC/CB) composite was evaluated by micro-computed tomography. The porosity of the composite was 80%, and the pore size predominantly ranged from 200 to 500 μm. The addition of CB microparticles increased the specific scaffold surface by almost threefold and was found to be approximately 40 mm^?1. The modulus of elasticity and compressive strength of the RC/CB composite were 4.0?±?0.6 and 22.0?±?0.9 MPa, respectively. The biocompatibility of the prepared RC/CB composite with rat hepatocytes and extensor digitorum longus muscle tissue was evaluated. The obtained data demonstrated that both the composite and cellulose matrix samples were non-cytotoxic and had no damaging effects. These results indicate that this RC/CB composite is a novel material suitable for bone tissue-engineering applications.     

Rheological and Physicochemical Studies on Emulsions Formulated with Chitosan Previously Dispersed in Aqueous Solutions of Lactic Acid

Chitosan, a natural, cationic polysaccharide, may be a hydrocolloid strategic to formulate acidic food products, as it can act as both bio-functional and technofunctional constituent. Typically, acetic acid is used to disperse chitosan in aqueous media, but the use of this acid is limited in food formulations due to its flavor. In this study, chitosan was firstly dispersed (0.1% m/V) in lactic acid aqueous solutions (pH 3.0, 3.5 or 4.0), and then evaluated regarding its thickener and emulsion stabilizer properties. O/W emulsions were prepared and characterized in terms of rheological properties, droplets average diameters and droplets ζ-potential. Emulsions containing chitosan were 3 times more viscous than controls without chitosan, and presented storage modulus (G’) higher than loss modulus (G”). Furthermore, they displayed two different populations of droplets (average diameters of 44 and 365 nm) and positive ζ-potential values (+50 mV). Droplets average diameters and ζ-potential did not present significant changes (p > 0.05) after storage at 25 °C during 7 days. This study showed that i) food organic acids other than acetic acetic acid can be used to disperse chitosan for technological purposes, and ii) chitosan dispersed at very low concentrations (0.1 m/V %) had relevant effects on rheological and physicochemical aspects of food-grade emulsions.