Use of Raw and Physically Modified Rice Starches as Fat Replacer in Whipping Cream

Effect of utilizing heart of date palm powder as a new source of dietary fibers, carbohydrates, and protein on the characterization and biological properties of low-fat bio-Labneh

The heart of date palm powder serves as a valuable source of various biological macromolecules, such as dietary fibers and proteins, which contribute to its benefits as a health-enhancing ingredient. The main component of the heart date palm is carbohydrates, which provide a rapid energy source and its fiber content aids digestion and promotes feelings of fullness, thereby enhancing any diet. This research studied the possibility of incorporating the heart of date palm powder at varying concentrations (0, 3 %, 6 %, 9 %, and 12 % w/v) into low-fat bio Labneh made from a mix of camel and corn milk (75 %: 25 %). Over a 21-day cold storage period, adding the heart of date palm powder improved the textural properties, sensory qualities, and bioactive compound content of low-fat bio Labneh. Furthermore, no mold, yeast, or coliform bacteria were present throughout the 21-day cold storage. The total cell count of Bifidobacterium animalis ssp. lactis BB12 steadily increased until the 14th day of the cold storage. According to the sensory evaluation results, up to 12 % heart of date palm powder can be added to produce low-fat bio Labneh. This study lays the groundwork for further research into the use of heart of date palm powder as an innovative functional ingredient in dairy products.

Plant-Based Emulsions as Dairy Cream Alternatives: Comparison of Viscoelastic Properties and Colloidal Stability of Various Model Products

In the context of growing interest in plant-based food products for their potential health benefits and sustainability, this study investigates the effect of mono- and diglycerides of fatty acids application on physico-chemical properties of various plant-based cream products, compared to lecithin application in rice cream. Rheological and textural parameters, colour profile, and colloidal stability were analysed. The application of mono- and diglycerides modified the creams' viscoelastic behaviour, showing a decrease in viscoelasticity across the samples; although in oat-coconut cream resulted in a higher viscoelasticity, indicating the formation of a gel-like structure. Rice cream with lecithin emulsifier showed lower viscoelastic properties characterised by higher phase angle (tan δ). All samples behaved as pseudoplastic materials (with a flow behaviour index n < 1). For coconut and almond creams, the consistency coefficient increased and flow behaviour index decreased after emulsifier application. Interestingly, the emulsifier addition did not significantly affect the cream's colour profile, characterised by yellow hue angle (h*) as a dominant spectral component. The colloidal stability, indicated by a stability index (SI), was determined as well.

The colloid and interface strategies to inhibit lipid digestion for designing low-calorie food

Although fat is one of the indispensable components of food flavor, excessive fat consumption could cause obesity, metabolism syndromes and an imbalance in the intestinal flora. In the pursuit of a healthy diet, designing fat reducing foods by inhibiting lipid digestion and calorie intake is a promising strategy. Altering the gastric emptying rates of lipids as well as acting on the lipase by suppressing the enzymatic activity or limiting lipase diffusion via interfacial modulation can effectively decrease lipolysis rates. In this review, we provide a comprehensive overview of colloid-based strategies that can be employed to retard lipid hydrolysis, including pancreatic lipase inhibitors, emulsion-based interfacial modulation and fat substitutes. Plants-/microorganisms-derived lipase inhibitors bind to catalytic active sites and change the enzymatic conformation to inhibit lipase activity. Introducing oil-in-water Pickering emulsions into the food can effectively delay lipolysis via steric hindrance of interfacial particulates. Regulating stability and physical states of emulsions can also affect the rate of hydrolysis by altering the active hydrolysis surface. 3D network structure assembled by fat substitutes with high viscosity can not only slow down the peristole and obstruct the diffusion of lipase to the oil droplets but also impede the transportation of lipolysis products to epithelial cells for adsorption. Their applications in low-calorie bakery, dairy and meat products were also discussed, emphasizing fat intake reduction, structure and flavor retention and potential health benefits. However, further application of these strategies in large-scale food production still requires more optimization on cost and lipid reducing effects. This review provides a comprehensive review on colloidal approaches, design, principles and applications of fat reducing strategies to meet the growing demand for healthier diet and offer practical insights for the low-calorie food industry.

Enhancing starch nanocrystal production and evaluating their efficacy as fat replacers in ice cream: Investigating the influence of high pressure and ultrasonication

A preparation method involving the combination of high-pressure homogenization and ultrasound (HPH-US) techniques was employed to produce starch nanocrystals (NCs) from three botanical starch sources: chestnut, corn starch, and potato starch. The optimal conditions, determined using response surface methodology, consisted of a homogenization pressure of 60 MPa and ultrasound at 280 W for 30 min. The utilization of dynamic light scattering (DLS) and transmission electron microscopy (TEM) unveiled that the resulting starch particles exhibited nanometric dimensions ranging from 135.36 to 203.47 nm. The mechanical forces generated by the HPH-US treatment significantly enhanced the physicochemical properties of the starch NCs, leading to a partial disruption of the crystalline structure. Moreover, the potential application of the synthesized starch NCs as fat replacers (FRs) was investigated. As the degree of substitution increased, notable improvements were observed in the hardness and viscosity of ice cream, accompanied by a reduction in the melting rate. The overall sensory evaluation indicated that corn starch NCs held substantial promise as a viable alternative FR for enhancing the quality of ice cream.

Physicochemical and Functional Properties of Modified KJ CMU-107 Rice Starches as Pharmaceutical Excipients

Starch extracted from KJ CMU-107 rice, with amylose content of 13.4%, was modified to yield pre-gelatinized starch (PGS), carboxymethyl starch (CMS), crosslinked carboxymethyl starch (CLCMS), crosslinked starch (CLS), and hydroxypropyl starch (HPS). Their physicochemical properties were assessed in comparison with the native starch (NS), and their functional properties were then evaluated for potential use as pharmaceutical excipients. Scanning electron microscopic (SEM) images and X-ray diffraction (XRD) patterns showed that granules of all but one of the modified starches retained the native character and crystalline arrangement. The exception, PGS, exhibited extensive granular rupture, which correlated with the loss of crystallinity suggested by the amorphous halo in XRD. Energy-dispersive X-ray (EDX) data confirmed the modification by the presence of related elements. Carboxymethylation increased solubility in unheated water, while crosslinking improved swelling. All modified starches displayed improved oil absorption capacity by 17–64%, while CMS and CLCMS also exhibited significant moisture sorption at above 75% RH PGS and HPS exhibited lower gelatinization temperature (Tg) and enthalpic change (ΔH), while CLS showed higher Tg and ΔH. CMS, CLCMS, and CLS showed adequate powder flow and compactibility, qualifying as potential tablet excipients. The 5% w/v solutions of CMS, CLMS, and HPS also formed intact films with suitable tensile strength. Overall, modified starches derived from KJ CMU-107 could potentially be developed into new pharmaceutical excipients.