All rights reserved.”
“Background: Dairy foods are nutrient rich but also a source of saturated fat in the diets of children.
Objective: We assessed effects on learn more dietary intakes and health outcomes of changing dairy foods consumed by children from regular-to reduced-fat varieties.
Design: This study was a 24-wk cluster randomized controlled trial in 93 families with 4-13-y-olds who were randomly allocated to parental education regarding changing to reduced-fat dairy foods (n = 76 children) or reducing
screen time (n = 69 children). Study outcomes, which were measured at weeks 0, 12 (end of the intervention), and 24, included saturated fat, energy, and nutrient intakes; pentadecanoic acid and blood lipid concentrations; body mass index z this website score; and waist circumference. Multilevel analyses were used with adjustment for child-and family-level covariates.
Results: There were no group differences in overall dairy intakes (-45 g dairy; 95% CI: -141, 51 g dairy; P = 0.356). Saturated fat intakes were 3.3 percentage points lower (P < 0.0001) in
the intervention group at week 24 than in the comparison group. Pentadecanoic acid concentrations were lower at week 12 (0.03%; P = 0.012) but not at week 24. LDL-cholesterol concentrations were not different at week 12, but LDL-cholesterol concentration was 0.15 mmol/L lower in the intervention group at week 24 than in the comparison group (P = 0.037). There were no significant group differences in total energy or adiposity measures. Regular-fat
dairy foods decreased from 88% to 14% of dairy intake in the intervention group. Calcium, magnesium, and carbohydrate (percentage of energy) intakes were higher in the intervention group than in the comparison group; retinol intakes were lower in the intervention Bafilomycin A1 inhibitor group than in the comparison group; and overall vitamin A intakes were similar between groups.
Conclusion: Advice to parents to change to reduced-fat products was effective in reducing children’s saturated fat intakes but did not alter energy intakes or measures of adiposity. This trial was registered in the Australia New Zealand Clinical Trials Registry as ACTRN12609000453280. Am J Clin Nutr 2011;93:1117-27.”
“Artificial membranes are ideal supports for enzyme immobilization and biocatalysis. The binding of a commercial lipase, Lipolase T20 on to nitrocellulose (NC) membrane was achieved by physical adsorption followed by cross-linking with formalin (2%). The NC-immobilized lipase was characterized for its catalytic activity and operational stability, using p-nitrophenyl palmitate (p-NPP) hydrolysis as a model reaction system. Functionally membrane bound lipase was more stable than free lipase (55 degrees C) at higher temperature (65 and 75 degrees C) and at pH 9.0 to 9.5. The hydrolytic properties of NC-bound lipase were studied consecutively as a function of physicochemical parameters. The NC-bound lipase was highly hydrolytic toward relatively longer C-chain length esters.