Your search keyword '"Fernández Fraguas, Cristina"' showing total 3 results

1. Manipulation of the dry bean (Phaseolus vulgaris L.) matrix by hydrothermal and high-pressure treatments: Impact on in vitro bile salt-binding ability.

Author

Lin T, O'Keefe S, Duncan S, and Fernández-Fraguas C

Subjects

Cell Wall chemistry, Cell Wall ultrastructure, Hydrostatic Pressure, Phaseolus metabolism, Plant Proteins, Dietary chemistry, Solubility, Starch chemistry, Viscosity, Bile Acids and Salts metabolism, Dietary Fiber analysis, Food Handling methods, Phaseolus chemistry, Phaseolus ultrastructure

Abstract

The capacity of high-fiber foods to sequester BS during digestion is considered a mechanism to lower serum-cholesterol. We investigated the effect of hydrothermal (HT) and high-hydrostatic-pressure (HHP) on the bile salt (BS)-binding ability of dry beans, and how this relates to changes in bean microstructure, fiber content (insoluble-IDF/soluble-SDF), and viscosity. HT and HHP-600 MPa led to significant IDF reduction, including resistant starch (RS), whereas 150-450 MPa significantly increased RS, without modifying IDF/SDF content. Microscopy analysis showed that heating disrupted the bean cell wall integrity, protein matrix and starch granules more severely than 600 MPa; however, tightly-packed complexes of globular starch granules-protein-cell wall fiber formed at HHP ≤ 450 MPa. While HT significantly reduced BS-binding efficiency despite no viscosity change, HHP-treatments maintained or enhanced BS-retention. 600 MPa-treatment induced the maximum BS-binding ability and viscosity. These results demonstrate that BS-binding by beans is not solely based on their fiber content or viscosity, but is influenced by additional microstructural factors., (Copyright © 2019 Elsevier Ltd. All rights reserved.)

Published

2020

2. Effect of substituent pattern and molecular weight of cellulose ethers on interactions with different bile salts.

Author

Torcello-Gómez A, Fernández Fraguas C, Ridout MJ, Woodward NC, Wilde PJ, and Foster TJ

Subjects

Adsorption, Bile Acids and Salts antagonists & inhibitors, Calorimetry, Differential Scanning, Carbohydrate Conformation, Cellulose chemistry, Chemical Phenomena, Elastic Modulus, Food Additives chemistry, Hydrophobic and Hydrophilic Interactions, Mechanical Phenomena, Molecular Weight, Rheology, Taurocholic Acid antagonists & inhibitors, Taurocholic Acid chemistry, Taurodeoxycholic Acid antagonists & inhibitors, Taurodeoxycholic Acid chemistry, Viscosity, Bile Acids and Salts chemistry, Cellulose analogs & derivatives, Dietary Fiber analysis, Dietary Supplements, Food, Fortified, Hypromellose Derivatives chemistry, Methylcellulose chemistry

Abstract

Some known mechanisms proposed for the reduction of blood cholesterol by dietary fibre are: binding with bile salts in the duodenum and prevention of lipid absorption, which can be partially related with the bile salt binding. In order to gain new insights into the mechanisms of the binding of dietary fibre to bile salts, the goal of this work is to study the main interactions between cellulose derivatives and two types of bile salts. Commercial cellulose ethers: methyl (MC), hydroxypropyl (HPC) and hydroxypropylmethyl cellulose (HPMC), have been chosen as dietary fibre due to their highly functional properties important in manufactured food products. Two types of bile salts: sodium taurocholate (NaTC) and sodium taurodeoxycholate (NaTDC), have been chosen to understand the effect of the bile salt type. Interactions in the bulk have been investigated by means of differential scanning calorimetry (DSC) and linear mechanical spectroscopy. Results show that both bile salts have inhibitory effects on the thermal structuring of cellulose ethers and this depends on the number and type of substitution in the derivatised celluloses, and is not dependent upon molecular weight. Concerning the bile salt type, the more hydrophobic bile salt (NaTDC) has greater effect on these interactions, suggesting more efficient adsorption onto cellulose ethers. These findings may have implications in the digestion of cellulose-stabilised food matrices, providing a springboard to develop new healthy cellulose-based food products with improved functional properties.

Published

2015

3. Dry beans (Phaseolus vulgaris L.) modulate the kinetics of lipid digestion in vitro: Impact of the bean matrix and processing.

Author

Lin, Tiantian, O'Keefe, Sean, Duncan, Susan, and Fernández-Fraguas, Cristina

Subjects

*COMMON bean, *BEANS, *FAVA bean, *FREE fatty acids, *DIGESTION, *CHOLESTEROL metabolism, *DIETARY fiber

Abstract

[Display omitted] • Dry beans were fractionated into fiber fractions or manipulated into flours of diverse structural integrity. • Bean flours were more effective than bean fibers at reducing digestion of extrinsic lipids. • Hydrothermal and severe mechanical treatment decreased beans' capacity to reduce lipolysis rate and extent. • The delayed lipolysis was related to an increased viscosity, bean matrix integrity and lipid flocculation. • A simplified GC–MS method to analyze released free fatty acids in in vitro digested samples was developed. The lipid-lowering effect of dry beans and their impact on lipid and cholesterol metabolism have been established. This study investigates the underlying mechanisms of this effect and explore how the structural integrity of processed beans influences their ability to modulate lipolysis using the INFOGEST static in vitro digestion model. Dietary fiber (DF) fractions were found to decrease lipolysis by increasing the digesta viscosity, leading to depletion-flocculation and/or coalescence of lipid droplets. Bean flours exhibited a more pronounced reduction in lipolysis compared to DF. Furthermore, different levels of bean structural integrity showed varying effects on modulating lipolysis, with medium-sized bean particles demonstrating a stronger reduction. Hydrothermal treatment compromised the ability of beans to modulate lipid digestion, while hydrostatic-pressure treatment (600 MPa/5min) enhanced the effect. These findings highlight that the lipid-lowering effect of beans is not solely attributed to DF but also to the overall bean matrix, which can be manipulated through processing techniques. [ABSTRACT FROM AUTHOR]

Published

2023