Your search keyword '"Macías, D."' showing total 6 results

1. Effects of supercritical fluid extraction pressure on chemical composition, microbial population, polar lipid profile, and microstructure of goat cheese.

Author

Sánchez-Macías D, Laubscher A, Castro N, Argüello A, and Jiménez-Flores R

Subjects

Animals, Bacterial Load, Cheese microbiology, Cheese standards, Chromatography, Supercritical Fluid methods, Food Quality, Food Technology methods, Goats, Pressure, Cheese analysis, Lipids analysis

Abstract

The consumer trend for healthier food choices and preferences for low-fat products has increased the interest in low-fat cheese and nutraceutical dairy products. However, consumer preference is still for delicious food. Low- and reduced-fat cheeses are not completely accepted because of their unappealing properties compared with full-fat cheeses. The method reported here provides another option to the conventional cheese-making process to obtain lower fat cheese. Using CO(2) as a supercritical fluid offers an alternative to reduce fat in cheese after ripening, while maintaining the initial characteristics and flavor. The aim of this experiment was to evaluate the effect of pressure (10, 20, 30, and 40 × 10(6) Pa) of supercritical CO(2) on the amount of fat extracted, microbial population, polar lipid profile, and microstructure of 2 varieties of goat cheese: Majorero, a protected denomination of origin cheese from Spain, and goat Gouda-type cheese. The amount of fat was reduced 50 to 57% and 48 to 55% for Majorero and goat Gouda-type cheeses, respectively. Higher contents (on a fat basis) of sphingomyelin and phosphatidylcholine were found in Majorero cheese compared with control and goat Gouda-type cheeses. The microbial population was reduced after supercritical fluid extraction in both cheeses, and the lethality was higher as pressure increased in Majorero cheese, most noticeably on lactococcus and lactobacillus bacteria. The Gouda-type cheese did not contain any lactobacilli. Micrographs obtained from confocal laser scanning microscopy showed a more open matrix and whey pockets in the Majorero control cheese. This could explain the ease of extracting fat and reducing the microbial counts in this cheese after treatment with supercritical CO(2). Supercritical fluid extraction with CO(2) has great potential in the dairy industry and in commercial applications. The Majorero cheese obtained after the supercritical fluid extraction treatment was an excellent candidate as a low-fat goat cheese, lower in triglycerides and cholesterol but still with all the health benefits inherent in goat milk., (Copyright © 2013 American Dairy Science Association. Published by Elsevier Inc. All rights reserved.)

Published

2013

2. Lipolysis and proteolysis profiles of fresh artisanal goat cheese made with raw milk with 3 different fat contents.

Author

Sánchez-Macías D, Morales-Delanuez A, Moreno-Indias I, Hernández-Castellano LE, Mendoza-Grimón V, Castro N, and Argüello A

Subjects

Animals, Cheese standards, Electrophoresis, Polyacrylamide Gel, Fats analysis, Fatty Acids, Nonesterified analysis, Food Technology methods, Goats, Hydrogen-Ion Concentration, Lipids analysis, Lipolysis, Milk chemistry, Milk Proteins analysis, Proteolysis, Cheese analysis

Abstract

The objective of this study was to describe the proteolysis and lipolysis profiles in goat cheese made in the Canary Islands (Spain) using raw milk with 3 different fat contents (0.5, 1.5, and 5%) and ripened for 1, 7, 14, and 28 d. β-Casein was the most abundant protein in all cheeses and at all ripening times. Quantitative analysis showed a general decrease in caseins as ripening progressed, and degradation rates were higher for α(S1)-casein than for β-casein and α(S2)-casein. Furthermore, the degradation rate during the experimental time decreased with lower fat contents. The α(S2)-casein and α(S1)-casein levels that remained in full-fat and reduced-fat cheeses were less than those in low-fat cheese. In contrast, β-casein also showed degradation along with ripening, but differences in degradation among the 3 cheese types were not significant at 28 d. The degradation products increased with the ripening time in all cheeses, but they were higher in full-fat cheese than in reduced-fat and low-fat cheeses. The free fatty acid concentration per 100g of cheese was higher in full-fat cheese than in reduced- and low-fat cheese; however, when the results were expressed as milligrams of free fatty acids per gram of fat in cheese, then lipolysis occurred more rapidly in low-fat cheese than in reduced- and full-fat cheeses. These results may explain the atypical texture and off-flavors found in low-fat goat cheeses, likely the main causes of non-acceptance., (Copyright © 2011 American Dairy Science Association. Published by Elsevier Inc. All rights reserved.)

Published

2011

3. Physicochemical analysis of full-fat, reduced-fat, and low-fat artisan-style goat cheese.

Author

Sánchez-Macías D, Fresno M, Moreno-Indias I, Castro N, Morales-delaNuez A, Alvarez S, and Argüello A

Subjects

Adhesiveness, Animals, Cheese standards, Color, Elasticity, Fats analysis, Fats metabolism, Food Technology, Goats, Hydrogen-Ion Concentration, Milk chemistry, Milk Proteins analysis, Whey Proteins, Cheese analysis

Abstract

The objective of this study was to examine the physicochemical properties of cheese elaborated via traditional artisan methods using goat milk containing 5, 1.5, or 0.4% fat and ripened for 1, 7, 14, or 28 d. Seventy-two cheeses were produced (2 batches x 3 fat levels x 4 ripening times x triplicate). Proximal composition, pH, texture analysis, and color were recorded in each cheese. Protein and moisture were increased in cheese, and fat and fat in DM were decreased with decreasing fat in milk. Internal and external pH was higher in low-fat and reduced-fat cheese, and pH values decreased during the first 2 wk of ripening but increased slightly on d 28. Cheese fracturability, cohesiveness, masticability, and hardness increased with decreasing fat, whereas elasticity and adhesiveness decreased. Cheese lightness and red and yellow indexes decreased with decreasing fat content; during ripening, lightness decreased further but yellow index increased., (Copyright (c) 2010 American Dairy Science Association. Published by Elsevier Inc. All rights reserved.)

Published

2010

4. Farm and factory production of goat cheese whey results in distinct chemical composition.

Author

Moreno-Indias I, Castro N, Morales-delaNuez A, Sánchez-Macías D, Assunção P, Capote J, and Argüello A

Subjects

Animals, Fats analysis, Fatty Acids analysis, Lactose analysis, Milk Proteins analysis, Serum Albumin analysis, Cheese analysis, Food Handling methods, Goats, Industrial Waste analysis, Milk chemistry

Abstract

To analyze differences in fat and protein content in cheese whey (CW) manufactured in cheese-making factories and farms, goat CW samples were obtained from 60 cheese-making farms and 20 cheese factories. Gross composition of samples was analyzed by using an MIRIS device (MIRIS Inc., Uppsala, Sweden), whey protein composition was subjected to electrophoretic analysis, and fatty acid composition was analyzed via gas chromatography. Goat CW from farms contained higher dry matter content (70.6 vs. 50.8 g/L, farms vs. cheese factories, respectively) and a higher fat percentage (10.5 vs. 1.2% over dry matter, farms vs. cheese factories, respectively) than CW from cheese factories. Analysis of individual proteins showed that CW from farms contained higher concentrations of lactoferrin (0.4 vs. 0.2 mg/mL of CW, farms vs. cheese factories, respectively) and caprine serum albumin (0.6 vs. 0.4 mg/mL of whey, farms vs. cheese factories, respectively) than CW from cheese factories. No differences were observed in the fatty acid profile. The main fatty acids present in goat CW were C16:0, C18:1, C14:0, and C18:0. Thus, the origin of CW affects gross composition and the protein profile, but not the fatty acid profile.

Published

2009

5. Effects of addition of somatic cells to caprine milk on cheese quality

Author

Sánchez-Macías, D., Morales-delaNuez, A., Torres, A., Hernández-Castellano, L.E., Jiménez-Flores, R., Castro, N., and Argüello, A.

Subjects

*SOMATIC cells, *GOAT milk, *CHEESE, *FOOD quality, *FATTY acids, *PROTEOLYSIS

Abstract

Abstract: Milk quality criteria and limits for somatic cell count (SCC) established in many countries make it difficult to maintain SCC of bulk tank goat milk below the threshold, due to non-infection factors linked to goat physiology. The aim of this study was to objectively verify the effects of SCC on fresh caprine milk cheese. Somatic cells were recovered from pooled healthy goat milk, and added to low SCC raw or pasteurised goat milk. Miniature cheeses were made and evaluated after 1 and 7 d. Somatic cells had a major effect on lipolysis, increasing free fatty acids regardless of whether milk was raw or pasteurised. The effect of somatic cells on proteolysis was specific for caseins and the effects were different if cheeses are made from raw or pasteurised milk. It is concluded that somatic cells themselves in caprine milk can directly affect some cheese parameters. [Copyright &y& Elsevier]

Published

2013

6. Somatic cells: A potential tool to accelerate low-fat goat cheese ripening.

Author

Sánchez-Macías, D., Hernández-Castellano, L.E., Morales-delaNuez, A., Herrera-Chávez, B., Argüello, A., and Castro, N.

Subjects

*SOMATIC cells, *GOAT cheese, *CHEESE ripening, *CHEESEMAKING, *RAW milk, *CHEESE, *LIPOLYSIS

Abstract

Demand for healthy products has increased interest in low-fat caprine cheeses. These are characterised by higher hardness, cohesiveness and masticability, and lower odour and flavour intensities, than full-fat cheeses, which has led to evaluation of alternative manufacturing methods to improve sensory characteristics. Addition of milk somatic cells was used as a potential tool to improve the quality of fresh low-fat caprine cheese made with either raw or pasteurised milk. Proteolysis of α S1 -CN, α S2 -CN, and para -κ-CN was increased in low-fat cheeses made with raw milk when somatic cells were added. In contrast, reduced proteolysis was observed in low-fat cheeses made from pasteurised milk, except for that of β-CN, which was increased. Moreover, the addition of somatic cells increased the rate of lipolysis in low-fat pasteurised cheese. These changes in the rates of proteolysis and lipolysis could improve softness and flavour of low-fat cheeses. [ABSTRACT FROM AUTHOR]

Published

2020