Gaëlle Roudaut scite author profile

Most low water content or frozen food products are partly or fully amorphous. This review will discuss the extent to which it is possible to understand and predict their behavior during processing and storage, on the basis of glass transition temperature values (Tg) and phenomena related to glass transition. Two main conclusions are provisionally proposed. Firstly, glass transition cannot be considered as an absolute threshold for molecular mobility. Transport of water and other small molecules takes place even in the glassy state at a significant rate, resulting in effective exchange of water in multi-domains foods or sensitivity to oxidation of encapsulated materials. Texture properties (crispness) also appear to be greatly affected by sub-Tg relaxations and aging below Tg. Secondly, glass transition is only one among the various factors controlling the kinetics of evolution of products during storage and processing. For processes such as collapse, caking, crystallization, and operations like drying, extrusion, flaking, Tg data and WLF kinetics have good predictive value as regards the effects of temperature and water content. On the contrary, chemical/biochemical reactions are frequently observed at temperature below Tg, albeit at a reduced rate, and WLF kinetics may be obscured by other factors.

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Crispness: a critical review on sensory and material science approaches

Roudaut

Dacremont

Pamies

et al. 2002

Trends in Food Science & Technology

206

149

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Molecular mobility around the glass transition temperature: a mini review

Roudaut¹,

Simatos²,

Champion³

et al. 2004

Innovative Food Science & Emerging Technologies

173

112

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Influence of Water on the Crispness of Cereal‐based Foods: Acoustic, Mechanical, and Sensory Studies

Roudaut¹,

Dacremont²,

Meste³

1998

Journal of Texture Studies

140

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The texture properties of crispy breads were studied as a function of water content using compression tests, acoustic measurements and sensory analysis. The addition of water slowly lowers the characteristics associated with crispness up to 9%, after which they steeply decrease. Dynamic Mechanical Thermal Analysis (DMTA) measurements were carried out, at room temperature and at 5 Hz, on the same bread samples. The evolution of the textural properties of crispy bread are accompanied by an increase of the loss factor prior to the one associated to the glass transition. It was therefore proposed that the effect of water on the brittle character, on crispness and on the intensity of the sound emitted at fracture were due to the onset of molecular motions preceding or accompanying the glass transition.

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Gaëlle Roudaut

Applications of spray-drying in microencapsulation of food ingredients: An overview

Glass Transition and Food Technology: A Critical Appraisal

Crispness: a critical review on sensory and material science approaches

Molecular mobility around the glass transition temperature: a mini review

Influence of Water on the Crispness of Cereal‐based Foods: Acoustic, Mechanical, and Sensory Studies

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