Raman spectroscopy of the polymorphic forms and liquid state of cocoa butter

Bresson, Serge; Rousseau, Dérick; Ghosh, Supratim; Marssi, M. El; Faivre, Vincent

doi:10.1002/ejlt.201100088

Cited by 55 publications

(70 citation statements)

References 38 publications

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“…This suggests that conformational differences exist between the polymorphs of SHs and Si‐SHs around the carbonyl bond, which is resolvable in Raman spectra. Similar observations were reported in the case of cocoa butter TAGs , StOSt (by conventional IR) and tristearin . However, Sprunt et al reported two bands for the β form of StOSt TAG.…”

Section: Resultssupporting

confidence: 78%

Crystallization and polymorphic behavior of shea stearin and the effect of removal of polar components

Ray

Smith²,

Bhaggan³

et al. 2013

Euro J Lipid Sci & Tech

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The crystallization of shea stearin was investigated both before and after pre‐treatment with silica to remove a small amount (0.7 wt%) of diacylglycerols (DAGs) and oxidized material. NMR (for solid fat content), X‐ray diffraction (XRD), polarized light microscopy, confocal Raman microscopy, and non‐isothermal, isothermal and “stop‐and‐return” differential scanning calorimetry (DSC) techniques were used. Four major polymorphs previously found with 1,3‐distearoyl‐2‐oleoyl‐sn‐glycerol (StOSt) were detected: α, γ, β′, and β; whilst evidence for a further (δ) polymorph was found by DSC and possibly XRD but not Raman spectroscopy. Isothermal crystallization of shea stearins by DSC at 20°C produced α and δ forms within 5 min which then transformed to γ. Microscope images showed that after 1 day these had transformed into β′ with a few crystals of β, with further conversion to β after one week. Silica treated samples showed a faster initial crystallization, with faster transformation or direct crystallization into δ and then γ and β′ forms. Non‐isothermal DSC also showed a faster transformation into γ from α on the subsequent remelt. However, further transformation into β appeared to occur at reasonably similar rates for both types, suggesting that DAGs have less influence on this transformation and may be excluded from higher forms. Practical applications: This paper has two main practical applications: (i) Provides knowledge and understanding of the crystallization and polymorphic behavior of commercial shea stearin, which is a widely used fat in the confectionery, cosmetic, and pharmaceutical industries. (ii) The presence of small amounts of DAGs significantly delays the crystallization process of shea stearin, particularly of the lower polymorphs.

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Section: Resultssupporting

confidence: 78%

Crystallization and polymorphic behavior of shea stearin and the effect of removal of polar components

Ray

Smith²,

Bhaggan³

et al. 2013

Euro J Lipid Sci & Tech

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“…These results indicated that PHEMA brushes were successfully grafted onto the PVC membrane surface. For the PVC‐g‐PHEMA‐g‐PBVIm‐Br membrane (M2), an obvious absorption band appeared at around 1163 cm −1 , which was correlated with C─H stretching in the imidazole ring. Meanwhile, the adsorption peak at 1563 cm −1 was attributed to the stretching vibration adsorption peak of ─C═N in the imidazole ring.…”

Section: Resultsmentioning

confidence: 99%

Improving the hydrophilic and antifouling properties of poly(vinyl chloride) membranes by atom transfer radical polymerization grafting of poly(ionic liquid) brushes

Cheng

et al. 2017

Polymers for Advanced Techs

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In this study, poly(1-butyl-3-vinylimidazolium bromide) (PBVIm-Br) was grafted onto the poly(vinyl chloride) (PVC) membrane surface via a 2-step atom transfer radical polymerization (ATRP) reaction. Poly(2-hydroxyethylmethacrylate) (PHEMA) was grafted onto the membrane surface by aqueous ATRP reaction; then, BVIm-Br was introduced onto the surface of the PHEMA-modified PVC membrane through traditional ATRP reaction. The analysis of surface chemistry confirmed the successful grafting of PHEMA and PBVIm-Br on PVC membrane surface, and the grafting density (GD) of PBVIm-Br gradually increased as the grafting time was prolonged. The modified membrane exhibited a positive charge and significantly enhanced surface hydrophilicity. The static water contact angle of the membrane surface decreased from 92.3°to 51.6°as the GD of the PBVIm-Br brushes increased. Filtration experiments indicated that the water flux of the modified membrane increased with increasing GD, and their recovered fluxes were more than twice than the original. In addition, the total fouling ratio of the membranes decreased from 89% in M0 to 67% in M5, and most of the fouling was reversible as the GD of PBVIm-Br brushes increased.These results indicated that the positive charged poly(ionic liquid) brushes featuring hydrophilic properties would have potential applications in membrane separation. KEYWORDS | Preparation of PVC membranesPoly(vinyl chloride) membranes were prepared using classical immersion precipitation method. | ATRP grafting of poly(ionic liquid) brushes onto PVC membranesThe grafting process includes 2 steps, which are shown in Figure 1. | Membrane characterizationThe chemical compositions of the membranes were characterized by The morphologies of the membranes were observed via scanning electron microscopy (SEM; Phenom G2 pro, Holland). Samples were fractured in liquid nitrogen to obtain orderly cross sections and then sputter coated with gold before SEM observation.The zeta potentials of the membranes were measured through a streaming potential method using an electro kinetic analyzer (SurPASS Anton Paar, GmbH, Austria). The pH of the solution was adjusted by adding NaOH or HCl solution, and the measurement was performed at 25°C.The water CAs of the membranes were measured with a data physics instrument (OCA20, Dataphysics, Germany) under a sessile drop model at room temperature, and the instrument was equipped with a camera to capture images. | Grafting densityThe final grafted PVC membranes were thoroughly washed in DI water and then dried in a vacuum oven at 55°C to constant weight; the grafting density (GD) (μg/cm 2 ) of the grafted membrane was calculated as follows 28:where W is the weight of the PVC grafted membrane (g), W 0 is the weight of the previous membranes before grafting (g), and A is the area of the membrane (m 2 ). | Filtration propertiesThe filtration properties of the membranes were examined using a vacuum filter apparatus. A piece of each test membrane (separation area of 3.46 cm 2 ) was fixed between the top ...

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“…More recently, Raman spectroscopy was used to characterize the different polymorphs of CB. Unique signatures were detected for all CB polymorphs . With X‐ray diffraction and Raman Spectroscopy, it is thus possible to identify the β VI polymorph in CB, which is often linked with the presence of fat bloom.…”

Section: Relationships Between Chocolate Microstructure and Polymorphmentioning

confidence: 98%

Relationship between chocolate microstructure, oil migration, and fat bloom in filled chocolates

Delbaere

Walle

Depypere

et al. 2016

Euro J Lipid Sci & Tech

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Fat bloom is one of the main quality problems in the chocolate industry. A bloomed chocolate product is characterized by the loss of its initial gloss and the formation of a gray-whitish haze, which makes the product unappealing from a consumer point of view. In the industry, most of the fat bloom related problems arise in filled chocolate products, like pralines and chocolate-coated biscuits. In these products, oil migration is considered the main cause of fat bloom development. It leads to the dissolution of solid cocoa butter crystals in the chocolate shell which may recrystallize with the formation of undesired crystals. These give rise, upon growth, to visual fat bloom. When looking at the available literature, most of the studies elucidate the possible mechanisms of oil migration and the subsequent fat bloom formation using model systems. These model systems are sometimes too distant from the real industrial applications and the important role of the microstructure of the products are often neglected, although it plays a crucial role in migration-induced fat bloom development. The main objective of this review is to describe the relationships between chocolate microstructure, oil migration, and fat bloom. Practical applications: This review can be used as a base for the development of microstructural strategies to retard oil migration and fat bloom development in filled chocolates. An important strategy to retard oil migration and migration-induced fat bloom is the creation of more dense structures. By creating denser structures, the overall mobility is reduced leading to a decrease in the rate and extent of oil migration. Also, more dense structures hinder recrystallization and Ostwald ripening, thereby delaying the migration-induced fat bloom development. As fillings are less standardized and not bound by legislation, modification of the filling composition and microstructure offers more opportunities in delaying fat bloom. The main objective of the review is to describe the relationships between chocolate microstructure, oil migration, and fat bloom, as illustrated in this scheme. The numbers indicate the four parts that are discussed in this review

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Raman spectroscopy of the polymorphic forms and liquid state of cocoa butter

Cited by 55 publications

References 38 publications

Crystallization and polymorphic behavior of shea stearin and the effect of removal of polar components

Crystallization and polymorphic behavior of shea stearin and the effect of removal of polar components

Improving the hydrophilic and antifouling properties of poly(vinyl chloride) membranes by atom transfer radical polymerization grafting of poly(ionic liquid) brushes

Relationship between chocolate microstructure, oil migration, and fat bloom in filled chocolates

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