Structure, diffusion, and permeability of protein-stabilized monodispersed oil in water emulsions and their gels: a self-diffusion NMR study

Romoscanu, Alexandre I.; Fenollosa, Annia; Acquistapace, Simone; Gunes, Deniz; Martins-Deuchande, Teresa; Clausen, Pascal; Mezzenga, Raffaele; Nydén, Magnus; Zick, Klaus; Hughes, Eric

doi:10.1021/la100774q

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Structure, diffusion, and permeability of protein-stabilized monodispersed oil in water emulsions and their gels: a self-diffusion NMR study

Romoscanu, Alexandre I. Nestlé Research Centre, Lausanne, Switzerland
Fenollosa, Annia Nestlé Research Centre, Lausanne, Switzerland
Acquistapace, Simone Nestlé Research Centre, Lausanne, Switzerland
Gunes, Deniz Nestlé Research Centre, Lausanne, Switzerland
Martins-Deuchande, Teresa Nestlé Research Centre, Lausanne, Switzerland
Clausen, Pascal Nestlé Research Centre, Lausanne, Switzerland
Mezzenga, Raffaele Department of Physics and Fribourg Center for Nanomaterials, University of Fribourg, Switzerland
Nydén, Magnus Department of Chemical and Biological Engineering, Chalmers University of Technology, Gothenbourg, Sweden
Zick, Klaus Bruker BioSpin GmbH, Silberstreifen, Rheinstetten, Germany
Hughes, Eric Nestlé Research Centre, Lausanne, Switzerland

06.04.2010

Published in:

Langmuir. - 2010, vol. 26, no. 9, p. 6184–6192

English Self-diffusion NMR is used to investigate monodispersed oil in water emulsions and the subsequent gel formed by removing the water through evaporation. The radius of the oil droplets in the emulsions is measured using a number of diffusion methods based on the measurement of the mean squared displacement of the oil, water, and tracer molecules. The results are consistent with the known size of the emulsions. Bragg-like reflections due to the restricted diffusion of the water around the oil droplets are observed due to the low polydispersity of the emulsions and the dense packing. The resulting data are fitted to a pore glass model to give the diameter of both the pools of interstitial water and the oil droplets. In the gel, information on the residual three-dimensional structure is obtained using the short time behavior of the effective diffusion coefficient to give the surface to volume ratio of the residual protein network structure. The values for the surface to volume ratio are found to be consistent with the expected increase of the surface area of monodisperse droplets forming a gel network. At long diffusion observation times, the permeability of the network structure is investigated by diffusion NMR to give a complete picture of the colloidal system considered.

Faculty

Faculté des sciences et de médecine

Department

Département de Physique

Language

English

Classification

Physics

License

License undefined

Identifiers

RERO DOC 20626
DOI 10.1021/la100774q

Persistent URL

https://folia.unifr.ch/unifr/documents/301643

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