Influence of supramolecular forces on the linear viscoelasticity of gluten

Kontogiorgos, Vassilis; Shah, Paras; Bills, Paul J.

doi:10.1007/s00397-015-0901-8

Cited by 15 publications

(27 citation statements)

References 53 publications

(67 reference statements)

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“…Yet, the compliance curves did not show any significant deviations from Hibberd's principle over the entire course of the creep and recovery phases for both the strong Bilux doughánd the weak Bison dough. It is important to note, however, that even with creep tests, probing the longest time scales in dough is not straightforward, because of aging effects that will continuously change the physicochemical and viscoelastic properties of the material [53]. We already mentioned [43] that a creep time of 30 min is not sufficient to reach the steady-state flow regime.…”

Section: Creep-recovery Testsmentioning

confidence: 99%

The Impact of Water Content and Mixing Time on the Linear and Non-Linear Rheology of Wheat Flour Dough

et al. 2017

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The viscoelastic properties of wheat flour dough are known to be very sensitive to small changes in water content and mixing time. In this study the simple scaling law originally proposed by [Rheol. Acta 9, 497-500] to capture the water dependency of the dynamic moduli in small amplitude oscillatory shear, was also applied to creep-recovery shear tests and extensional tests. The scaling law turns out to be valid not only in the linear region, but to a certain extent also in the non-linear region. At sufficiently high water levels, a 'free' water phase exists in dough, which attenuates the starch-starch and gluten-starch interactions. Dough characterisation after different mixing times shows that overmixing may cause a disaggregation or even depolymerisation of the gluten network. The network breakdown, as well as the subsequent (partial) recovery, are clearly reflected in the value of the strain-hardening index, for which a maximum is reached at a mixing time close to the optimum as determined with the Mixograph. Finally, the gluten proteins turn out to be much less susceptible to overmixing in an oxygen-lean environment, which demonstrates the significant role of oxygen in the degradation process.

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Section: Creep-recovery Testsmentioning

confidence: 99%

The Impact of Water Content and Mixing Time on the Linear and Non-Linear Rheology of Wheat Flour Dough

et al. 2017

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“…This time dependency is believed to stem from several factors such as enzymatic reactions ongoing in the flour, a continuous evolution in flour component interactions and the relaxation of the stresses induced during mixing, shaping and loading in the rheometer (Létang et al 1999). To eliminate the contribution of the latter, dough should be allowed sufficient resting time before starting the rheological experiments (Kontogiorgos et al 2016). It is, however, difficult to determine what a sufficient resting time would be, as the other physico-chemical factors will still induce time dependency.…”

Section: Shear Measurementsmentioning

confidence: 99%

“…The ability of the gluten network to incorporate compounds that contained either free thiol groups (Villegas et al 1963) or disulfide bonds (Jones and Carnegie 1971) indicates that SH/SS interchange reactions do indeed occur in dough. On the contrary, the second school of thought suggests that the continuity of the gluten network also strongly depends on hydrogen bonds, hydrophobic interactions, and chain entanglements (Jekle and Becker 2015;Kontogiorgos et al 2016). The primary function of the SS cross-links would then be to hold the (unbranched) polypeptide chains together within each glutenin molecule (Bloksma 1990).…”

mentioning

confidence: 99%

The Interplay Between the Main Flour Constituents in the Rheological Behaviour of Wheat Flour Dough

Meerts

Cardinaels

Oosterlinck

et al. 2016

Food Bioprocess Technol

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There is still considerable debate in the literature about the respective roles of starch and gluten in both the linear and non-linear rheology of wheat flour dough. Hence, to elucidate the individual contributions of gluten and starch to the overall dough behaviour, the rheological properties of dough and mixtures of different gluten-starch ratios were studied systematically in shear and extension, by means of an adequate rheological toolbox consisting of linear small amplitude oscillatory shear tests and non-linear tests such as creep-recovery in shear and uniaxial extension.The starch component plays a pivotal role in linear dough rheology. With increasing starch content, the linearity limit observed in oscillatory shear tests decreases as a power-law function. Starch also clearly affects the extensional viscosity at small strains. Consequently, in the linear region differences between different gluten systems may become obscured by the presence of starch. As breadmaking qualities are known to be intrinsically linked to the gluten network, it is imperative to probe the non-linear behaviour of dough in order to expose differences in flour quality. The quality differences between a strong and a weak flour type were revealed most clearly compliance in non-linear creep-recovery tests.Notwithstanding its earlier successful application to pure gluten gels, the accuracy of the critical gel model in predicting the linear rheological properties of dough was found to be limited, due to dough having a small linearity limit and a finite longest relaxation time.

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“…Temperature-induced conformational changes further complicate the landscape with additional formation of intermolecular β-sheets by loss of α-helices or interchange of disulfide linkages on heating (Georget and Belton, 2006). The cooperation of supramolecular forces, temperature and time on gluten viscoelasticity have been recently put under rheological scrutiny revealing that the importance of hydrogen bonding precedes over disulfide cross links (Kontogiorgos et al, 2016). Additionally, in the mesoporous structure of gluten,…”

Section: Introductionmentioning

confidence: 99%

“…It is evident from the above discussion that water levels would play critical role in the viscoelasticity of gluten networks and other similar hydrated biopolymer systems due to chain conformational changes and water resettling within the pores of the structures. In our previous investigations, we have focused on the influence of protein composition (Kontogiorgos and Dahunsi, 2014) and supramolecular forces (Kontogiorgos et al, 2016) on the relaxation dynamics of model gluten networks focusing, however, at one hydration level. The aims of the present investigation are to build on our previous findings and by using gluten as model system to explore the influence of hydration and decouple the mechanisms that contribute to the relaxation dynamics in hydrated gluten.…”

Section: Introductionmentioning

confidence: 99%

Linear viscoelasticity of gluten: Decoupling of relaxation mechanisms

Kontogiorgos

2017

Journal of Cereal Science

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The influence of water content on the relaxation dynamics of mesoporous gluten networks has been explored in a wide range of temperatures. The systems were investigated in the linear viscoelastic region by means of stress relaxation, creep and numerical analysis of data. Time-temperature superposition principle and sticky reptation dynamics have been used to provide molecular interpretation of gluten relaxation. Overall, hydration influences relaxation behaviour of the system, which can be linked to changes in the secondary structure of gluten proteins with increase in water content. Relaxation spectra calculated with Tikhonov regularization revealed the remarkable influence of water on the long times relaxation processes of the material. Creep measurements and extraction of dynamic data with direct conversion of creep data via Laplace transform augmented the experimental timeframe of observations to low frequencies unattainable by standard frequency sweeps. The predominance of loss modulus at long times is attributed to migration of water within the nanopores of the structure. Samples also exhibit self-similar relaxation a characteristic of systems existing at a critical state. Two relaxation mechanisms can be distinguished: one arising from viscoelastic relaxation of protein chains and an additional stemming from poroelastic relaxation owing to migration of water in the system.

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Influence of supramolecular forces on the linear viscoelasticity of gluten

Cited by 15 publications

References 53 publications

The Impact of Water Content and Mixing Time on the Linear and Non-Linear Rheology of Wheat Flour Dough

The Impact of Water Content and Mixing Time on the Linear and Non-Linear Rheology of Wheat Flour Dough

The Interplay Between the Main Flour Constituents in the Rheological Behaviour of Wheat Flour Dough

Linear viscoelasticity of gluten: Decoupling of relaxation mechanisms

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