Hydration of casein micelles and caseinates: Implications for casein micelle structure

Thom Huppertz; Inge Gazi; Hannemieke Luyten; Hans Nieuwenhuijse; Arno Alting; Erix Schokker

doi:10.1016/j.idairyj.2017.03.006

Hydration of casein micelles and caseinates: Implications for casein micelle structure

Thom Huppertz
, Inge Gazi
, Hannemieke Luyten
, Hans Nieuwenhuijse
, Arno Alting
, Erix Schokker

Research output: Contribution to journal › Article › peer-review

Abstract

By studying the hydration of casein micelles using a variety of techniques, a distinction could be made between water that appeared bound by the protein (∼0.5 g g⁻¹ protein), water associated with the κ-casein brush (∼1.0 g g⁻¹ protein) and water entrapped in the casein micelles (∼1.8 g g⁻¹ protein), yielding a total micellar hydration of ∼3.3 g g⁻¹ protein, in line with casein micelle voluminosity derived from intrinsic viscosity measurements. For caseinate particles, however, the main contributor to intrinsic viscosity was not protein hydration but the non-spherical particle shape. These non-spherical particles in caseinate are likely to be naturally present as primary casein particles (PCP) in casein micelles. PCP could be used to build casein micelles by controlled introduction of micellar salts. Based on the findings of this study, casein micelles could be described as a porous network of non-spherical PCP linked by calcium phosphate nanoclusters.

Original language	English
Pages (from-to)	1-11
Number of pages	11
Journal	International Dairy Journal
Volume	74
DOIs	https://doi.org/10.1016/j.idairyj.2017.03.006
Publication status	Published - Nov 2017
Externally published	Yes

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10.1016/j.idairyj.2017.03.006

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title = "Hydration of casein micelles and caseinates: Implications for casein micelle structure",

abstract = "By studying the hydration of casein micelles using a variety of techniques, a distinction could be made between water that appeared bound by the protein (∼0.5 g g−1 protein), water associated with the κ-casein brush (∼1.0 g g−1 protein) and water entrapped in the casein micelles (∼1.8 g g−1 protein), yielding a total micellar hydration of ∼3.3 g g−1 protein, in line with casein micelle voluminosity derived from intrinsic viscosity measurements. For caseinate particles, however, the main contributor to intrinsic viscosity was not protein hydration but the non-spherical particle shape. These non-spherical particles in caseinate are likely to be naturally present as primary casein particles (PCP) in casein micelles. PCP could be used to build casein micelles by controlled introduction of micellar salts. Based on the findings of this study, casein micelles could be described as a porous network of non-spherical PCP linked by calcium phosphate nanoclusters.",

author = "Thom Huppertz and Inge Gazi and Hannemieke Luyten and Hans Nieuwenhuijse and Arno Alting and Erix Schokker",

note = "Publisher Copyright: {\textcopyright} 2017 Elsevier Ltd",

year = "2017",

month = nov,

doi = "10.1016/j.idairyj.2017.03.006",

language = "English",

volume = "74",

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T1 - Hydration of casein micelles and caseinates

T2 - Implications for casein micelle structure

AU - Huppertz, Thom

AU - Gazi, Inge

AU - Luyten, Hannemieke

AU - Nieuwenhuijse, Hans

AU - Alting, Arno

AU - Schokker, Erix

PY - 2017/11

Y1 - 2017/11

N2 - By studying the hydration of casein micelles using a variety of techniques, a distinction could be made between water that appeared bound by the protein (∼0.5 g g−1 protein), water associated with the κ-casein brush (∼1.0 g g−1 protein) and water entrapped in the casein micelles (∼1.8 g g−1 protein), yielding a total micellar hydration of ∼3.3 g g−1 protein, in line with casein micelle voluminosity derived from intrinsic viscosity measurements. For caseinate particles, however, the main contributor to intrinsic viscosity was not protein hydration but the non-spherical particle shape. These non-spherical particles in caseinate are likely to be naturally present as primary casein particles (PCP) in casein micelles. PCP could be used to build casein micelles by controlled introduction of micellar salts. Based on the findings of this study, casein micelles could be described as a porous network of non-spherical PCP linked by calcium phosphate nanoclusters.

AB - By studying the hydration of casein micelles using a variety of techniques, a distinction could be made between water that appeared bound by the protein (∼0.5 g g−1 protein), water associated with the κ-casein brush (∼1.0 g g−1 protein) and water entrapped in the casein micelles (∼1.8 g g−1 protein), yielding a total micellar hydration of ∼3.3 g g−1 protein, in line with casein micelle voluminosity derived from intrinsic viscosity measurements. For caseinate particles, however, the main contributor to intrinsic viscosity was not protein hydration but the non-spherical particle shape. These non-spherical particles in caseinate are likely to be naturally present as primary casein particles (PCP) in casein micelles. PCP could be used to build casein micelles by controlled introduction of micellar salts. Based on the findings of this study, casein micelles could be described as a porous network of non-spherical PCP linked by calcium phosphate nanoclusters.

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VL - 74

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JO - International Dairy Journal

JF - International Dairy Journal

ER -

Hydration of casein micelles and caseinates: Implications for casein micelle structure

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