The association of low-molecular-weight hydrophobic compounds with native casein micelles in bovine milk

Cheema, Manpreet Kaur; Mohan, Maneesha S.; Campagna, Shawn R.; Jurat-Fuentes, Juan Luís; Harte, Federico

doi:10.3168/jds.2015-9461

Cited by 26 publications

(16 citation statements)

References 22 publications

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“…The formation of the complex between casein micelles and curcumin was attributed to hydrophobic interactions. Mohan et al ( 2013 ) showed that natural casein micelles have the ability to associate with hydrophobic vitamin A. Cheema et al ( 2015 ) reported that native casein micelles isolated from raw milk exhibited a stronger binding affinity toward hydrophobic compounds, including sphingomyelins, phosphatidylcholines, and phosphatidylethanolamines. Clearly, a further understanding of the ability and the mechanism of the binding of hydrophobic molecules within casein micelles would allow us to create novel nanometer-scale structures that would be suitable for the delivery of bioactive compounds.…”

Section: Nature-assembled Structures In Milkmentioning

confidence: 99%

Nature-Assembled Structures for Delivery of Bioactive Compounds and Their Potential in Functional Foods

2020

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Consumers are demanding more natural, healthy, and high-quality products. The addition of health-promoting substances, such as bioactive compounds, to foods can boost their therapeutic effect. However, the incorporation of bioactive substances into food products involves several technological challenges. They may have low solubility in water or poor stability in the food environment and/or during digestion, resulting in a loss of their therapeutic properties. Over recent years, the encapsulation of bioactive compounds into laboratory-engineered colloidal structures has been successful in overcoming some of these hurdles. However, several nature-assembled colloidal structures could be employed for this purpose and may offer many advantages over laboratory-engineered colloidal structures. For example, the casein micelles and milk fat globules from milk and the oil bodies from seeds were designed by nature to deliver biological material or for storage purposes. These biological functional properties make them good candidates for the encapsulation of bioactive compounds to aid in their addition into foods. This review discusses the structure and biological function of different nature-assembled carriers, preparation/isolation methods, some of the advantages and challenges in their use as bioactive compound delivery systems, and their behavior during digestion.

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Section: Nature-assembled Structures In Milkmentioning

confidence: 99%

Nature-Assembled Structures for Delivery of Bioactive Compounds and Their Potential in Functional Foods

2020

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“…α-casein was hydrolyzed at more than 99% with 0.064 g•L −1 of trypsin. This can be justified by the fact that α-casein might has less chance to participate in enzymatic reaction because in the interior part of casein micelle, calcium phosphate clusters bind with the phosphoseryl residues of α s -casein and β-casein, whereas κ-casein was present in the periphery of casein micelle and received chance to participate in enzymatic reaction [111]. Due to partial hydrolysis of β-casein with 0.008 g•L −1 of trypsin, some peptone and γ-casein with molecular weight~22 kDa might produce and they were hydrolyzed when milk with concentrated proteins was treated with 0.032 g•L −1 of trypsin.…”

Section: Molecular Weight Of Different Proteins In Concentrated Milk mentioning

confidence: 99%

Production of Liquid Milk Protein Concentrate with Antioxidant Capacity, Angiotensin Converting Enzyme Inhibitory Activity, Antibacterial Activity, and Hypoallergenic Property by Membrane Filtration and Enzymatic Modification of Proteins

et al. 2020

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Liquid milk protein concentrate with different beneficial values was prepared by membrane filtration and enzymatic modification of proteins in a sequential way. In the first step, milk protein concentrate was produced from ultra-heat-treated skimmed milk by removing milk serum as permeate. A tubular ceramic-made membrane with filtration area 5 × 10−3 m2 and pore size 5 nm, placed in a cross-flow membrane house, was adopted. Superior operational strategy in filtration process was herein: trans-membrane pressure 3 bar, retention flow rate 100 L·h−1, and implementation of a static turbulence promoter within the tubular membrane. Milk with concentrated proteins from retentate side was treated with the different concentrations of trypsin, ranging from 0.008–0.064 g·L−1 in individual batch-mode operations at temperature 40 °C for 10 min. Subsequently, inactivation of trypsin in reaction was done at a temperature of 70 °C for 30 min of incubation. Antioxidant capacity in enzyme-treated liquid milk protein concentrate was measured with the Ferric reducing ability of plasma assay. The reduction of angiotensin converting enzyme activity by enzyme-treated liquid milk protein concentrate was measured with substrate (Abz-FRK(Dnp)-P) and recombinant angiotensin converting enzyme. The antibacterial activity of enzyme-treated liquid milk protein concentrate towards Bacillus cereus and Staphylococcus aureus was tested. Antioxidant capacity, anti-angiotensin converting enzyme activity, and antibacterial activity were increased with the increase of trypsin concentration in proteolytic reaction. Immune-reactive proteins in enzyme-treated liquid milk protein concentrate were identified with clinically proved milk positive pooled human serum and peroxidase-labelled anti-human Immunoglobulin E. The reduction of allergenicity in milk protein concentrate was enzyme dose-dependent.

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“…In addition, to maximize protein identifications and expand the analysis of the milk proteome, multiple analytical approaches including fractionation techniques have been adopted. For example, casein which makes up 80 % of overall milk protein content was extracted using hydrophobic and hydrophilic procedures followed by size exclusion fractionation to identify low molecular weight molecules [ 33 ]. Similarly, enhanced identification of whey proteins was reported after precipitation of casein [ 34 , 35 ].…”

Section: Alternate Diagnostic Body Fluidmentioning

confidence: 99%

Challenges and opportunities of bovine milk analysis by mass spectrometry

Verma

Ambatipudi

2016

Clin Proteom

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Bovine milk and its products (e.g. cheese, yoghurt) are an important part of human diet with beneficial effects for all ages. Although analyses of different milk components (e.g. proteins, lipids) pose huge challenges, the use of mass spectrometric (MS)-based techniques is steadily improving our understanding of the complexity of the biological traits that effect milk yield and its components to meet the global demand arising from population growth. In addition, different milk constituents have various applications in veterinary research and medicine, including early disease diagnosis. The aim of the review is to present an overview of the progress made in MS-based analysis of milk, and suggest a multi-pronged MS strategy to better explore different milk components for translational and clinical utilities.

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The association of low-molecular-weight hydrophobic compounds with native casein micelles in bovine milk

Cited by 26 publications

References 22 publications

Nature-Assembled Structures for Delivery of Bioactive Compounds and Their Potential in Functional Foods

Nature-Assembled Structures for Delivery of Bioactive Compounds and Their Potential in Functional Foods

Production of Liquid Milk Protein Concentrate with Antioxidant Capacity, Angiotensin Converting Enzyme Inhibitory Activity, Antibacterial Activity, and Hypoallergenic Property by Membrane Filtration and Enzymatic Modification of Proteins

Challenges and opportunities of bovine milk analysis by mass spectrometry

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