Acoustic properties of crystallized fat: Relation between polymorphic form, microstructure, fracturing behavior, and sound intensity

Gregersen, Sandra Beyer; Povey, M. J. W.; Andersen, Morten Daugaard; Hammershøj, Marianne; Rappolt, Michael; Sadeghpour, Amin; Wiking, Lars

doi:10.1002/ejlt.201500435

Cited by 5 publications

(3 citation statements)

References 35 publications

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“…Note that palmitic acid is the most abundant FA in BMF. , Second, the chain tilt angle for the β phase was assumed to be 36°, as confirmed in the literature for SOS . Other SOS-rich samples display chain tilt angles of 33 and 36° for the β′-3L and β-3L polymorphs, respectively. Thus, we limited possible chain tilts in the β-3L polymorph in BMF to vary from 33 to 36° and consequently found d S to vary in the range of 39–41 Å, from which d U values from 12 to 14 Å follow.…”

Section: Resultsmentioning

confidence: 99%

The Unique Crystallization Behavior of Buffalo Milk Fat

Pratama

Simone

Rappolt

2021

Crystal Growth & Design

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A full comprehension of milk fat crystallization is important for the structural development of dairy products such as butter, ice cream, and cheese. The influence of triacylglycerol (TAG) composition on the dynamic of milk fat crystallization and the nanostructure of the formed crystals was investigated using two chemically different types of milk fat, namely buffalo and cow milk fats (BMF; CMF). The TAG composition was determined using liquid chromatography and mass spectrophotometry (LCMS), whereas differential scanning calorimetry (DSC), small- and wide-angle X-ray scattering (SAXS and WAXS), and polarized light microscopy (PLM) were used to characterize the crystallization behavior of the two milk fats. A total of 37 TAG species were identified in both BMF and CMF, but in different proportions. In particular, BMF was found to have a higher amount of low-molecular-weight TAGs in comparison to CMF. This difference in chemical composition explains the different kinetics of polymorphic transformation in the two samples. Specifically, it clarifies the delay in the nucleation of the β′-polymorph in BMF in comparison to CMF. BMF also showed a higher nucleation rate due to its higher proportion of saturated TAGs and higher melting range. Finally, this work presents a novel interpretation of the mechanism of formation of the β-polymorph (53 Å), which has recently become the subject of a vivid debate in milk fat crystallization studies.

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Section: Resultsmentioning

confidence: 99%

The Unique Crystallization Behavior of Buffalo Milk Fat

Pratama

Simone

Rappolt

2021

Crystal Growth & Design

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“…The physical behavior of fats and oils is largely dependent on the fatty acid distribution of their triglyceride structure . The presence of high amounts of saturated fatty acids (57.78%) in the ASO may account for the observed high melting temperature of a large portion of the fat.…”

Section: Resultsmentioning

confidence: 99%

“…The fatty acid composition of ASO and SNO were comparable to their iodine values of 36.86 (mg I 2 100 g À1 ) and 52.06 (mg I 2 100 g À1 ), respectively. [25][26][27][28] The presence of high amounts of saturated fatty acids (57.78%) in the ASO may account for the observed high melting temperature of a large portion of the fat. A high iodine value indicates a high degree of unsaturation in the fat.…”

Section: Microscopy Analysismentioning

confidence: 99%

Determination of Physical Properties and Crystallization Kinetics of Oil From Allanblackia Seeds and Shea Nuts Under Different Thermal Conditions

Badu

Awudza

Budd

et al. 2018

Euro J Lipid Sci & Tech

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In this study, the fatty acid content, melting and cooling profiles, crystallization properties at different cooling rates and kinetics of crystallization of Allanblackia seed oil (ASO) and shea nut oil (SNO) are investigated. The fatty acid content is determined using gas chromatography coupled with mass spectrometry (GC/MS). The melting and cooling profiles, crystallization, and crystallization kinetics are investigated using differential scanning calorimetry (DSC) and the fat morphology is investigated using polarized light microscopy. The GC/MS results showed that ASO contains a high amount of saturated fats as compared with SNO. The DSC analysis revealed that ASO has a high melting temperature of 35.3 ± 2.1 °C and crystallizes earlier (16.8 ± 0.3 °C) in the constant rate cooling experiments. The crystallization patterns of both oils are observed to be dependent on the cooling rate. Under isothermal conditions, it is observed that both ASO and SNO shows high and low melting peaks with the low melting peak disappearing as the crystallization progressed. The Avrami model is used to estimate the crystallization kinetics of the oils under the isothermal conditions and it is inferred that ASO has a faster nucleation and subsequent crystal growth as compared with SNO. At room temperature SNO formed overlapping fat crystal particles while ASO gave distinct crystallized fat fractions during the crystallization at room temperature, as shown by the polarized light microscopy. Practical Application: The high melting temperature, the rate and the nature of crystallization of Allanblackia seed oil gives it good material functionality and desired plasticity, properties associated with possible industrial application. Additionally, the presence of high stearic acid content makes the Allanblackia seed oil a healthy choice for food, hence, it can be used as a substitute for cocoa butter in the food industry. The appearance of fat crystals during the crystallization at isothermal conditions at 16 °C of the Allanblackia seed oil.

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Rheology and Mechanical Properties of Fats

González-Gutiérrez

Scanlon²

2018

Structure-Function Analysis of Edible Fats

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Acoustic properties of crystallized fat: Relation between polymorphic form, microstructure, fracturing behavior, and sound intensity

Cited by 5 publications

References 35 publications

The Unique Crystallization Behavior of Buffalo Milk Fat

The Unique Crystallization Behavior of Buffalo Milk Fat

Determination of Physical Properties and Crystallization Kinetics of Oil From Allanblackia Seeds and Shea Nuts Under Different Thermal Conditions

Rheology and Mechanical Properties of Fats

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