Mixing is a critical stage in breadmaking since it controls gluten development and nucleation of gas bubbles in the dough. Bubbles affect the rheology of the dough and largely govern the quality of the final product. This study used ultrasound (at a frequency where it is sensitive to the presence of bubbles) to nondestructively examine dough properties as a function of mixing time in doughs prepared from strong red spring wheat flour with various amounts of shortening (0%, 2%, 4%, 8% flour weight basis). The doughs were mixed for various times at atmospheric pressure or under vacuum (to minimize bubble nucleation). Ultrasonic velocity and attenuation (nominally at 50 kHz) were measured in the dough, and dough density was measured independently from specific gravity determinations. Ultrasonic velocity decreased substantially as mixing time increased (and more bubbles were entrained) for all doughs mixed in air; for example, in doughs made without shortening, velocity decreased from 165 to 105 ms(-1), although superimposed on this overall decrease was a peak in velocity at optimum mixing time. Changes in attenuation coefficient due to the addition of shortening were evident in both air-mixed and vacuum-mixed doughs, suggesting that ultrasound was sensitive to changes in the properties of the dough matrix during dough development and to plasticization of the gluten polymers by the shortening. Due to its ability to probe the effect of mixing times and ingredients on dough properties, ultrasound has the potential to be deployed as an online quality control tool in the baking industry.
There is a real need in modern breadmaking processes for tools that can non-invasively monitor the effect of processing and ingredients on the rheological properties of dough systems in order to better predict the cellular structure of the resulting loaf of bread. In this talk, we show that low-intensity ultrasound is a powerful tool for meeting this need. Low-frequency ultrasound (50 kHz) was used to study mechanically-developed bread doughs made from red spring wheat flour. Doughs were mixed for a fixed time under different headspace pressures to entrain different concentrations of bubbles within the dough. At this frequency, ultrasonic attenuation increased substantially as headspace pressure was increased, while ultrasonic velocity (which is related to the longitudinal modulus of the dough) decreased dramatically. Doughs containing shortening (0, 2, 4, 8 % w/w) were also prepared, with doughs mixed for various times at atmospheric pressure or under vacuum (0.04 atm). As mixing time increased when mixing at atmospheric pressure, velocity and density decreased while attenuation increased due to air entrainment. Similar trends were observed for doughs prepared with shortening, but velocities and densities at a given mixing time were progressively lower as shortening levels increased. Little variation in velocity or density was observed with mixing time for vacuum-mixed doughs, but changes in attenuation coefficient suggested that ultrasound was sensitive to the changes in dough matrix properties during dough development. Using similar breadmaking doughs, but with either yeast or chemical leavening reagents added, ultrasonic velocity and attenuation were measured as the dough fermented, using a setup in which the dough was allowed to expand freely in a plane perpendicular to the ultrasonic propagation direction. Changes in density of the proving dough was measured using a dynamic dough density system based on digital photography. For vacuum mixed doughs, there was a rapid reduction in velocity in the early stages of fermentation, even though density changed little over the same time period, indicating that fermentation products produced by yeast had a large effect on the properties of the dough matrix. Different chemical leavening systems confirmed that ultrasound was sensitive to effects associated with the dough matrix as well as gas cells since velocities differed at identical void fractions. We conclude that ultrasonic techniques provide a useful tool for studying the effects of bubbles and gas cells in opaque food systems such as dough, and can provide unique insights into events taking place in food processing operations.
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