Rheological, pasting and microstructural studies of dairy protein–starch interactions and their application in extrusion‐based products: A review

Kumar, Lokesh; Brennan, Margaret A.; Mason, Susan L.; Zheng, Haotian; Brennan, Charles S.

doi:10.1002/star.201600273

Cited by 44 publications

(37 citation statements)

References 45 publications

(78 reference statements)

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“…This behavior provided evidence that in the obtained products, the proteins were texturized; therefore, as the SWP/CS content increased, the WAI decreased because the texturization reduced the water‐binding capacity of whey proteins at extrusion temperatures >60°C, allowing a better interaction with the starch (Onwulata et al, 2011), which indicates that the morphological changes of the proteins caused the loss of their innate capacity to absorb water (Onwulata et al, 2010). The degree of solubility of the textured whey proteins depends on the amount of protein present, and the SWP/CS increased because at high temperature, mechanical cutting, shearing, and moisture change the globular molecular structures to new conformational states, affecting their secondary and tertiary structures and non‐covalent interactions and thereby changing the solubility (Kumar, Brennan, Mason, Zheng, & Brennan, 2017).…”

Section: Resultsmentioning

confidence: 99%

Optimization of an extrusion process for the development of a fiber‐rich, ready‐to‐eat snack from pineapple by‐products and sweet whey protein based on corn starch

Rivera‐Mirón

Torruco‐Uco

Carmona‐García

et al. 2020

J Food Process Engineering

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The aim of the present study was optimized extrusion cooking process for the development of a fiber‐rich, ready‐to‐eat snack from pineapple by‐products and sweet whey protein based on corn starch. The variables studied were the extrusion temperature (ET = 120–180°C), feed moisture content (FMC = 18–25 g/100 g), proportion of sweet whey powder/corn starch (SWP/CS = 0–59.5 g/100 g), and proportion of pineapple by‐product powder (PBP = 0–30 g/100 g), (PBP + [SWP + CS] = 100 g). Analysis of the standardized effects revealed that the SWP/CS proportion had the most significant importance among all the variables, followed by the PBP content. The optimal extrusion conditions were ET = 160.00°C, FMC = 23.04 g/100 g, SWP/CS = 52.08 g/100 g, and PBP =22.50 g/100 g. These results represent an alternative to add value to these raw materials of low commercial value while also avoiding the generation of waste and environmental pollution. Practical applications These results represent an alternative to add value to these raw materials of low commercial value, as well as avoiding the generation of waste and environmental pollution.

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Section: Resultsmentioning

confidence: 99%

Optimization of an extrusion process for the development of a fiber‐rich, ready‐to‐eat snack from pineapple by‐products and sweet whey protein based on corn starch

Rivera‐Mirón

Torruco‐Uco

Carmona‐García

et al. 2020

J Food Process Engineering

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“…High temperature heating significantly inactivates deteriorative enzymes and stabilizes WBR grains during the storage, but also causes some negative effects such as degradation of bioactive components (e.g., GABA, free phenolics, flavonoids, vitamin) and browning (Chalermchaiwat et al, 2015;Mir et al, 2016;Zhang et al, 2018). For example, compared with cold extrusion, hot extrusion has wider applications in the food industry, but it is a thermomechanical process where food materials are subject to high temperature, shear forces and pressures for a short time, thus causing the loss of thermally sensitive bioactive components (Alam et al, 2016;Kumar et al, 2017). On the other hand, the impact of heating and drying techniques on WBR is based on their effects on definite commonly-used indices such as texture, lipid degradation, taste, cooking properties, and major functional components.…”

Section: Accepted Manuscriptmentioning

confidence: 99%

Innovative processing techniques for altering the physicochemical properties of wholegrain brown rice (Oryza sativa L.) – opportunities for enhancing food quality and health attributes

Xia

Green

Zhu

et al. 2018

Critical Reviews in Food Science and Nutrition

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Rice is a globally important staple consumed by billions of people, and recently there has been considerable interest in promoting the consumption of wholegrain brown rice (WBR) due to its obvious advantages over polished rice in metabolically protective activities. This work highlights the effects of innovative processing technologies on the quality and functional properties of WBR in comparison with traditional approaches; and it is aimed at establishing a quantitative and/or qualitative link between physicochemical changes and high-efficient processing methods. Compared with thermal treatments, applications of innovative nonthermal techniques, such as high hydrostatic pressure (HHP), pulsed electric fields (PEF), ultrasound and cold plasma, are not limited to modifying physicochemical properties of WBR grains, since improvements in nutritional and functional components as well as a reduction in anti-nutritional factors can also be achieved through inducing related biochemical transformation. Much information about processing methods and parameters which influence WBR quality changes has been obtained, but simultaneously achieving the product stabilization and functionality of processed WBR grains requires a comprehensive evaluation of all the quality changes induced by different processing procedures as well as quantitative insights into the relationship between the changes and processing variables.

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“…Some important rheological properties, namely, dynamic viscosity, yield stress, creep-recovery behaviors, and viscoelastic behaviors, are frequently used to characterize the physical properties of food materials. Dynamic viscosity is used to predict velocity, shear, and residence-time distribution during extrusion and mixing (Davarcı, Turan, Ozcelik, & Poncelet, 2017;Kristensen & Jensen, 2011;Kumar, Brennan, Mason, Zheng, & Brennan, 2017), as well as to JFDS-2019-1113Submitted 7/10/2019, Accepted 9/4/2019 predict the energy cost to transport liquid food materials through pipelines (Hasan, Ghannam, & Esmail, 2010). Viscosity has also been reported to significantly influence sensory attributes, such as creaminess (Kilcast & Clegg, 2002), coarseness (Bahramparvar, Razavi, & Khodaparast, 2010), and firmness (Harte, Clark, & Barbosa-Cánovas, 2007).…”

Section: Introductionmentioning

confidence: 99%

Interlaboratory Measurement of Rheological Properties of Tomato Salad Dressing

Tan

Martini

Wang

et al. 2019

Journal of Food Science

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Rheological properties of food materials are important as they influence food texture, processing properties, and stability. Rotational rheometry has been widely used for measuring rheological properties. However, the measurements obtained using different geometries and rheometers are generally not compared for precision and accuracy, so it is difficult to compare data across different studies. In this study, nine rheometers from seven laboratories were used to measure the viscosity and viscoelastic properties of a commercial salad dressing. The measurements were obtained at three temperatures (8, 25, and 60 °C) using different diameter parallel plates (20, 40, 50, and 60 mm). Generally, the viscosity measurements among rheometers differed significantly (P<0.05). For larger geometry diameter (40, 50, and 60 mm) and at lower temperatures (8 °C), viscosity measurements at lower shear rate (0.01, 0.1, and 1.0 s−1) were significantly different. Rheometer brand significantly affected storage modulus only at low (0.01%) and high levels (10% and 100%) of strain. Temperature was an influencing factor on viscoelastic behaviors only at high strain (>10%). Storage moduli values obtained by frequency sweeps were not affected by rheometer or plate diameter. Overall, rheometer, geometry, and temperature can influence rheological measurements and care should be taken when comparing data across laboratories or published works. Higher shear rates (≥10 s−1) and moderate strains (0.1% to 10%) generally provide more repeatable data among different laboratories. Practical Application This study provides information on what factors may potentially influence rheological measurements conducted across different laboratories. It is useful for rheometer users who want to compare their experimental data to published data or compare two sets of published data. It is better to compare data collected at shear rates 10 s−1 and strains between 0.1% and 1.0%.

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Rheological, pasting and microstructural studies of dairy protein–starch interactions and their application in extrusion‐based products: A review

Cited by 44 publications

References 45 publications

Optimization of an extrusion process for the development of a fiber‐rich, ready‐to‐eat snack from pineapple by‐products and sweet whey protein based on corn starch

Optimization of an extrusion process for the development of a fiber‐rich, ready‐to‐eat snack from pineapple by‐products and sweet whey protein based on corn starch

Innovative processing techniques for altering the physicochemical properties of wholegrain brown rice (Oryza sativa L.) – opportunities for enhancing food quality and health attributes

Interlaboratory Measurement of Rheological Properties of Tomato Salad Dressing

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