Recovering proteins from potato juice by complexation with natural polyelectrolytes

Kong, Xiangzhen; Kong, Lingzhi; Ying, Yusang; Hua, Yufei; Wang, Li

doi:10.1111/ijfs.12851

Cited by 8 publications

(4 citation statements)

References 30 publications

(47 reference statements)

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“…The addition of polysaccharide‐carboxymethyl cellulose (CMC), a precipitating agent, allows potato proteins to coagulate at pH 2.5 from PFJ by electrostatic interactions between protein and polysaccharide (Vikelouda & Kiosseoglou, ; Kong et al ., ). CMC treatment can result in a high recovery rate of patatin, however, owing to pH adjustment (2.5) required for complexation, it may impair the functionality of potato proteins (Vikelouda & Kiosseoglou, ).…”

Section: Separation and Purification Of Patatinmentioning

confidence: 97%

Towards potato protein utilisation: insights into separation, functionality and bioactivity of patatin

Liu

Soladoye

2019

Int J of Food Sci Tech

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Potato fruit juice (PFJ) is a dilute industrial by-product of potato starch industry containing potato protein that is abundant in patatin, a major storage protein. From an economic standpoint, conversion of potato protein into a high value-added food ingredient has received considerable attention. In this review, the structural and physicochemical characteristics of patatin are introduced. The separation and purification methods of patatin are compared and summarised. The functional properties of patatin as food ingredients are comprehensively reviewed. The beneficial effects of patatin on health and food application are emphatically presented. In addition, the current challenges for development of patatin as a functional food ingredient are also discussed. This review offers a theoretical basis for further application of patain in the food industry. Functionality and bioactivity of patatin Y. Fu et al. 2315 Functionality and bioactivity of patatin Y. Fu et al.

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Section: Separation and Purification Of Patatinmentioning

confidence: 97%

Towards potato protein utilisation: insights into separation, functionality and bioactivity of patatin

Liu

Soladoye

2019

Int J of Food Sci Tech

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“…Protein and polysaccharide are 2 key food ingredients, and their electrostatic complexation has been widely used in the design and control of food texture (Krzeminski et al, 2014;Wu et al, 2014), the microencapsulation of active ingredients (Jain et al, 2015;Zhao et al, 2018), and the purification of protein or polysaccharide (Kong et al, 2015;Ren et al, 2019). Because of their superior amphiphilicity, protein-polysaccharide complexes exhibit excellent interfacial activity and are expected to be effective emulsifiers or foaming agents (Schmitt and Turgeon, 2011).…”

Section: Introductionmentioning

confidence: 99%

Electrostatic complexation of β-lactoglobulin aggregates with κ-carrageenan and the resulting emulsifying and foaming properties

Zhao

Zhang

et al. 2020

Journal of Dairy Science

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The electrostatic complexation of protein and polysaccharide and the functional properties of the complexes are significantly affected by the structure of protein aggregates and are important in the development of new food ingredients. In this work, natural globular β-lactoglobulin (NGBLG), β-lactoglobulin nanoparticles (BLGNP), and β-lactoglobulin fibrils (BLGF) were prepared and complexed with κ-carrageenan (κ-car). Phase diagrams of the NGBLG-, BLGNP-, and BLGF-κ-car systems were established and divided into 4 regions: mixed soluble polymers (I), intramolecular soluble complex (II), intermolecular soluble complex (III), and intermolecular insoluble complex (IV). Aggregation shifted the boundaries of regions III and IV of BLGF-or BLGNP-κ-car to lower pH and higher protein aggregates/κ-car weight ratio (r), especially for BLGF-κ-car. The emulsifying and foaming properties of the 3 mixed systems were investigated in regions I and II. Complexes in region II had significantly better emulsifying properties than the corresponding mixtures in region I and the pure protein aggregates. Interestingly, phase separation resulted in different effects on the foaming properties of the 3 BLG-κ-car complexes, in which BLGF-κ-car complexation in region II decreased the foaming properties in region I but the complexation of NGBLG-κ-car and BLGNP-κ-car in region II increased the foaming properties. The BLGF-κ-car complex in regions I and II provided the best emulsifying and foaming properties. Interfacial data both on oil-water and air-water interfaces overall explained the emulsifying and foaming properties of the complexes.

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“…Therefore, potato proteins, like Solanic, are also used in food applications (Alting et al 2011;Boland et al 2013). In addition to the present food application and feed supplements, potato proteins are of great potential in specific biotechnological and pharmaceutical applications (Kong et al 2015;Zhang et al 2017). Protein quality is therefore becoming increasingly important in the industrial production of potato proteins (Grommers and van der Krogt 2009).…”

Section: Introductionmentioning

confidence: 99%

Modelling Potato Protein Content for Large-Scale Bulk Storage Facilities

Grubben¹,

Heeringen

Keesman

2019

Potato Res.

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The potato (Solanum tuberosum) is one of the main sources of natural starch. In recent decades, the valorisation of potato protein that results as a by-product in the starch industry has been gaining interest as well. As potato supply is seasonal and the protein content of potatoes during long-term storage is temperature-dependent, optimal storage of potatoes is of great importance. This paper explores a model describing potato protein content during a full storage season for the Miss Malina and Agria cultivars. The model combines Michaelis-Menten protein kinetics with the Arrhenius equation. Laboratory analyses were performed to monitor the protein components in both potato cultivars and to use for estimation of the kinetic parameters. The results indicate that the two cultivars have different synthesis and degradation kinetics.

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Recovering proteins from potato juice by complexation with natural polyelectrolytes

Cited by 8 publications

References 30 publications

Towards potato protein utilisation: insights into separation, functionality and bioactivity of patatin

Towards potato protein utilisation: insights into separation, functionality and bioactivity of patatin

Electrostatic complexation of β-lactoglobulin aggregates with κ-carrageenan and the resulting emulsifying and foaming properties

Modelling Potato Protein Content for Large-Scale Bulk Storage Facilities

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