Assessment of changes in crystallization properties of pressurized milk fat

Staniewski, B.; Smoczyński, Michał; Staniewska, Katarzyna; Baranowska, Maria; Kiełczewska, Katarzyna; Żulewska, Justyna

doi:10.3168/jds.2014-8531

Cited by 9 publications

(2 citation statements)

References 22 publications

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“…The fractal dimension, determined from the dependency between the perimeter and surface area of a particle, indicates the extent of development of the surface of the analyzed particles and allows for precise and unbiased comparison of particle microstructures obtained at various drying temperatures. The fractal image analysis method has been used to analyze surfaces of particles or aggregates, but also to investigate crystallization properties of milk fat, yoghurt microstructure or properties of aggregates in wastewater (Staniewski et al 2015;Smoczyński and Baranowska 2014;Smoczyński et al 2016;Florio et al 2019). Results of image analysis are presented in Table 1, whereas an example of a logarithmic dependency between particle perimeter and surface area is shown in Fig.…”

Section: Resultsmentioning

confidence: 99%

Fractal analysis of the microstructure of milk powders produced at various temperatures

Smoczyński

2020

J Food Sci Technol

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The quality of milk powder is largely determined during it manufacture process by the morphological characteristics of powder particles. Considering that, the main research objective of this study was to determine whether parameters of the production process contribute to differences in the microstructure of the manufactured powders, and by this means affect their functional traits. To diversify the milk powder production process, various temperatures of the inlet air were used during drying, i.e. 140, 150 and 160°C. An image fractal analysis was employed and powder particle sizes were compared with respective results achieved in the instrumental analysis using the laser diffraction method. Values of fractal dimensions decreased slightly along with drying temperature increase, what demonstrates that the technological parameters are reflected in the microstructure of milk powders produced. Although particle sizes determined with both methods fitted within the same range of values, the contribution of particular fractions slightly differed and the choice of the appropriate approach may not always be unambiguous. Finally, the fractal dimension is a precise parameter which provides the accurate and explicit characteristics of milk powder microstructure and as such should be recommended for the characterization of irregular structures of different food products.

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Section: Resultsmentioning

confidence: 99%

Fractal analysis of the microstructure of milk powders produced at various temperatures

Smoczyński

2020

J Food Sci Technol

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“…The specimen was then cooled at 5 °C/min to −20 °C where this temperature was maintained for 2 min. Final heating at 5 °C/min followed this process until 60 °C was reached (Staniewski et al., ).…”

Section: Methodsmentioning

confidence: 99%

Effect of Fractionation and Chemical Characteristics on the Crystallization Behavior of Milk Fat

Wang

Yuan

et al. 2019

Journal of Food Science

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The experiments reported in this study provided a more comprehensive insight into the effect of chemical composition on the crystallization behavior of milk fat (MF). MF was fractionated between 20 and 40°C into nine fractions with different melting points and was first subjected to the heating step (L20, L30, L40, and S40) followed by the cooling phase (SS40, SL40, SS30, SL30, and LL40). Furthermore, the species of fatty acids (FAs) and triglycerides (TAGs) of the MF fractions were identified. The thermodynamics, crystallization behavior, and polymorphs were determined using differential scanning calorimetry, pulsed nuclear magnetic resonance, and X-ray diffraction, respectively. The results indicated that L40 yielded the highest percentage (ß35% of the total MF) of all the fractions. Enthalpies of the melting and crystallization processes of solid fat content in this study were related to the different FA and TAG compositions of MF and its fractions. High melting fractions (HMFs) were enriched with long-chain saturated fatty acids and tri-saturated (S3) TAGs, and low melting fractions (LMFs) were enriched with short-chain unsaturated FAs and tri-unsaturated (U3) TAGs. Moreover, the various nucleation mechanisms of MF fractions were identified according to the Avrami equation. The polymorphic transformation from a β' form of double chain length structures to a β form of triple chain length occurred in the native MF and HMFs, whereas the LMFs displayed almost no crystals.Practical Application: This study represented the first time that nine fractions were obtained using MF fractionation via a heating step, followed by a cooling phase. Furthermore, the chemical composition of MF fractions was investigated. The results obtained from this study might be of specific value in understanding the functional properties of fat-based dairy food in both storage conditions and real-time applications.

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Crystallization Behavior of Sunflower Oil–Based Fats for Edible Applications

Herrera¹,

Martini²

2018

Crystallization of Lipids

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Assessment of changes in crystallization properties of pressurized milk fat

Cited by 9 publications

References 22 publications

Fractal analysis of the microstructure of milk powders produced at various temperatures

Fractal analysis of the microstructure of milk powders produced at various temperatures

Effect of Fractionation and Chemical Characteristics on the Crystallization Behavior of Milk Fat

Crystallization Behavior of Sunflower Oil–Based Fats for Edible Applications

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