Fish oil (FO) supplementation reduces the risk of CVD. However, it is not known if FO of different qualities have different effects on lipoprotein subclasses in humans. We aimed at investigating the e Show more
Fish oil (FO) supplementation reduces the risk of CVD. However, it is not known if FO of different qualities have different effects on lipoprotein subclasses in humans. We aimed at investigating the effects of oxidised FO and high-quality FO supplementation on lipoprotein subclasses and their lipid concentrations in healthy humans. In all, fifty-four subjects completed a double-blind randomised controlled intervention study. The subjects were randomly assigned to receive high-quality FO (n 17), oxidised FO (n 18) or high-oleic sunflower oil capsules (HOSO, n 19) for 7 weeks. The concentration of marine n-3 fatty acids was equal in high-quality FO and oxidised FO (1·6 g EPA+DHA/d). The peroxide value (PV) and anisidine value (AV) were 4 mEq/kg and 3 in high-quality FO and HOSO, whereas the PV and AV in the oxidised FO were 18 mEq/kg and 9. Blood samples were collected at baseline and end of study. NMR spectroscopy was applied for the analysis of lipoprotein subclasses and their lipid concentrations. High-quality FO reduced the concentration of intermediate-density lipoprotein (IDL) particles and large, medium and small LDL particles, as well as the concentrations of total lipids, phospholipids, total cholesterol, cholesteryl esters and free cholesterol in IDL and LDL subclasses compared with oxidised FO and HOSO. Hence, high-quality FO and oxidised FO differently affect lipid composition in lipoprotein subclasses, with a more favourable effect mediated by high-quality FO. In future trials, reporting the oxidation levels of FO would be useful. Show less
Aging is associated with increased levels of circulating inflammatory markers and reduced muscle mass and strength. We investigated whether intake of protein-enriched milk for 12 weeks would influence Show more
Aging is associated with increased levels of circulating inflammatory markers and reduced muscle mass and strength. We investigated whether intake of protein-enriched milk for 12 weeks would influence markers of inflammation among adults ≥70years of age with reduced physical strength. In a double-blind randomized controlled intervention study, subjects were randomly allocated into two groups, receiving a protein-enriched milk (2×20g protein/d, n=14, mean (±SD) age 76.9±4.9 yrs) or an isocaloric carbohydrate drink (n=17, age 77.7±4.8 yrs) for 12 weeks. We measured serum and mRNA expression levels of inflammatory markers in PBMCs. Significant differences in the mRNA expression of nuclear receptor subfamily, group H, member 3 (NR1H3, encoding the LXRα transcription factor) and interferon gamma (INFG) were observed between groups. The mRNA level of TNFRSF1A was significantly reduced, while the mRNA level of dipeptidyl-peptidase 4 (DPP4) was significantly increased, in the control group. The serum level of TNFα increased significantly in the control group, while sTNFRSF1A increased significantly in both groups, but with no significant differences between groups. Consumption of a low-fat, protein-enriched milk for 12 weeks had minor effects on inflammatory related markers in older adults compared to an isocaloric carbohydrate drink. Show less
Previous reports have suggested that heterozygotes for ataxia-telangiectasia (A-T) have an increased risk of cancer, in particular breast cancer. The ATM gene, responsible for A-T, was recently cloned Show more
Previous reports have suggested that heterozygotes for ataxia-telangiectasia (A-T) have an increased risk of cancer, in particular breast cancer. The ATM gene, responsible for A-T, was recently cloned. Loss of heterozygosity (LOH) in the chromosome band 11q23, where the ATM gene is located, has been reported in several types of tumours including breast carcinomas. Whether the ATM gene is the target, and the sole target, for the LOH seen in this region is not yet known. In this study, 169 primary breast carcinomas and 10 metastases were examined for allelic imbalance (AI) using 10 microsatellite markers mapping to 11q23.1. Nine of the markers reside within a 10 Mb region surrounding the ATM gene, whereas the tenth locus, APOC-3, is located more than 12 Mb telomeric from this region. The highest frequencies of alteration were found for APOC-3 (45%), and for two markers located approximately 200 and 900 kb telomeric from ATM, D11S1294 (44%) and D11S1818 (44%). The marker located within the ATM gene, D11S2179, was altered in 37% of the informative tumours. The present deletion map indicates that three distinct regions at 11q23.1 may be involved in breast cancer development; one between the markers D11S1294 and D11S1818, a second close to APOC-3, and a third that is possibly the ATM-gene itself. Show less