Addition of glyceryl monostearate affects the crystallization behavior and polymorphism of palm stearin

Redefining shortening: Systematically characterizing traditional and new enriched diacylglycerol shortening and exploring their impact on processing applications

Compared to lard-based shortenings, diacylglycerol (DAG)-based shortenings have demonstrated beneficial effects, such as lowering blood lipids, and reducing postprandial blood glucose levels. In this study, different chain-length DAG oils were blended with lower melting point peanut oil DAG oil (PO-DAG-oil). The blend ratios for the three types of DAG-based shortenings were determined based on the solid fat content (SFC) of lard. Subsequently, 1 % of various emulsifiers were added, and the crystallization properties, rheological and textural characteristics, polymorphism, microstructure, water-absorbing capacity, and plasticity of the four shortening systems were examined. The emulsifiers found to be suitable for lard shortening, long chain fatty acid DAG (LCD-shortening), medium chain fatty acid DAG (MCD-shortening), and medium and long chain fatty acid DAG (MLCD-shortening) were Span60, PGFE, PGFE, and MAG, respectively. Cakes baked using DAG-based shortenings exhibited superior textural properties compared to those made with lard-based shortenings, supporting the application of high-melting-point DAG oils in shortening formulations.

Internal Factors Affecting the Crystallization of the Lipid System: Triacylglycerol Structure, Composition, and Minor Components

The process of lipid crystallization influences the characteristics of lipid. By changing the chemical composition of the lipid system, the crystallization behavior could be controlled. This review elucidates the internal factors affecting lipid crystallization, including triacylglycerol (TAG) structure, TAG composition, and minor components. The influence of these factors on the TAG crystal polymorphic form, nanostructure, microstructure, and physical properties is discussed. The interplay of these factors collectively influences crystallization across various scales. Variations in fatty acid chain length, double bonds, and branching, along with their arrangement on the glycerol backbone, dictate molecular interactions within and between TAG molecules. High-melting-point TAG dominates crystallization, while liquid oil hinders the process but facilitates polymorphic transitions. Unique molecular interactions arise from specific TAG combinations, yielding molecular compounds with distinctive properties. Nanoscale crystallization is significantly impacted by liquid oil and minor components. The interaction between the TAG and minor components determines the influence of minor components on the crystallization process. In addition, future perspectives on better design and control of lipid crystallization are also presented.

Crystallization Behavior and Physical Properties of Monoglycerides-Based Oleogels as Function of Oleogelator Concentration

Oleogels have been shown as a promising replacer of hydrogenated vegetable oil. Fatty acid glycerides, including some typical mono- and di-glycerides, were used to form oleogels. The concentration effects of fatty acid glycerides on the crystallization behavior and physical properties of oleogels were investigated by using different analysis techniques. The results showed that all the oleogels formed by saturated fatty acid glycerides (glyceryl monostearate (GMS), glyceryl monolaurate (GML), glycerol monocaprylate (GMC)) exhibited a solid-like behavior and were thermally reversible systems, while a higher amount of unsaturated fatty acid glycerides (monoolein (GMO), diolein (GDO)) were needed to form oleogels. The onset gelation concentration of GMS and GMC was found to be 2 wt% (w/w), while that of GML was 4 wt% by the inverted tube method. The crystallization results illustrated that the GMS and GMC formed small needle-like crystals with the presence of β and β' crystals, while GML formed large flake-like crystals with α crystals in oleogels, and faster cooling rates caused smaller crystals. GMS- and GMC-based oleogels had higher crystallinity, resulting in higher thermal stability and better mechanical properties than GML-based ones at the same monoglyceride (MAG) level. With the increasing MAG content, the oleogels showed a more compact three-dimensional network leading to higher mechanical properties and better thermal stability and resistance to deformations. Hence, MAG-based oleogels, especially GMC ones with medium chain fatty acid, could be a promising replacer for hydrogenation vegetable oils.