Proving of Bread Dough: Modelling the Growth of Individual Bubbles

Shah, Phalguni; Campbell, Grant M.; McKee, SL; Rielly, Chris D.

doi:10.1205/096030898531828

Cited by 56 publications

(54 citation statements)

References 9 publications

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“…Others authors tried to evaluate the expansion by measuring the air content of the dough and the bubble size distribution (Shimiya and Nakamura 1997;Whitworth and Alava 1999;Bonny et al 2004). Modeling of the growth of bubbles in dough has been presented by Shah et al (1998) or Chiotellis and Campbell (2003). But the different biological and physical phenomena occurring during proving are very complex and difficult to model.…”

Section: Introductionmentioning

confidence: 99%

Assessment of Bread Dough Expansion during Fermentation

Chevallier

Zuniga

Le‐Bail

2010

Food Bioprocess Technol

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The aim of this work was to investigate different methods of measuring the expansion of bread dough during fermentation and to develop a mathematical model to describe the variation of dough volume. Dough was prepared with wheat flour, salt, yeast, and selected amount of water (56%, 58%, and 60% w/w flour basis). Proving time was 1 h and proving temperature investigated were 25, 30, and 35°C. Dough volume was measured with three methods: (1) vertical expansion in a flask, (2) horizontal expansion between two plates, and (3) free expansion method. Volume was measured either using displacement transducer or from image analysis of pictures taken during expansion. All the methods allowed monitoring the increase in dough volume as a function of proving time. Small differences were observed between the three methods. Free expansion shows a faster start of expansion in comparison with the two other methods. Expansion curves have been fitted with a modified Gompertz model (Romano et al., J Food Eng 83:142-148, 2007). They exhibited three phases: a lag phase, followed by a linear phase (constant expansion rate), and finally a phase with a decreasing expansion rate. Statistical analysis of the set of data showed that the proving temperature had a significant effect on the different parameters calculated (volume expansion ratio, expansion rate), while the water content had no significant effect.

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Section: Introductionmentioning

confidence: 99%

Assessment of Bread Dough Expansion during Fermentation

Chevallier

Zuniga

Le‐Bail

2010

Food Bioprocess Technol

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“…Similarly, the growth of these bubbles depends on the mass transfer dynamics of CO 2 diffusion into the nitrogen nuclei initially created. This depends on the solubility and diffusivity of CO 2 in the liquid dough phase, as well as the initial bubble size distribution (Shah et al, 1998;Chiotellis and Campbell, 2003a,b). Bran in the formulation could conceivably affect these and thereby slow bubble growth during proving, such that more of the CO 2 produced by the yeast is lost from the dough surface, giving less expansion and smaller loaf volumes.…”

Section: Introductionmentioning

confidence: 99%

Bran in Bread: Effects of Particle Size and Level of Wheat and Oat Bran on Mixing, Proving and Baking

2008

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The effects of adding wheat and oat bran, at different levels and milled to varying particle size ranges, to dough formulations were investigated, with respect to aeration and dough development during mixing, expansion during proving and fi nal baked loaf characteristics. Addition of bran reduced the density of the dough at the end of mixing, largely because of the increased water absorption, with bran particle size having little effect on dough density. Wheat bran substituted for fl our at 7.5% increased the capacity of the doughs to expand during proving, but despite this the baked loaf volumes were lower, and even lower at 15%. Grinding the wheat bran had little effect on optimum work input, water absorption and expansion during proving, but gave slightly lower loaf volumes and a fi ner crumb texture. The low correlation between proving expansion and baked loaf volume suggested that the effects of the wheat bran in bread formulations occurred during baking. By contrast, adding oat bran reduced both the maximum expansion capacity of the dough during proving and the baked loaf volume, suggesting that the oat bran exerted its effects largely during proving. Grinding the oat bran gave lower optimum work inputs and higher water absorptions, and reduced both proving expansion and baked loaf volumes.

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“…The model involved growth of a single bubble but the initial bubble size was determined by averaging the experimentally obtained bubble size distribution in the dough. Similar bubble growth models have been developed by Shah et al (1998) and Fan et al (1999). Shah et al (1998) took into account the diffusion of only CO 2 and neglected dough rheology, because according to them, the surface tension effects predominate over rheological factors.…”

Section: Introductionmentioning

confidence: 99%

“…Similar bubble growth models have been developed by Shah et al (1998) and Fan et al (1999). Shah et al (1998) took into account the diffusion of only CO 2 and neglected dough rheology, because according to them, the surface tension effects predominate over rheological factors. On the other hand, Fan et al (1999) assumed a temperature dependent power law rheology, a linear variation in temperature with time and diffusion of both CO 2 and water vapor.…”

Section: Introductionmentioning

confidence: 99%

“…Though, Chiotellis and Campbell (2003) extended the work of Shah et al (1998) to model a bubble size distribution, they did not take into account the continuous nucleation of new bubbles. The objective of the present work is therefore to model the dynamic evolution of the bubble size distribution inside the dough using a general population balance approach which takes into account both nucleation and growth of bubbles.…”

Section: Introductionmentioning

confidence: 99%

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