Supplemental Tables 1-5 from Omega-3 and Omega-6 Fatty Acids in Blood and Breast Tissue of High-Risk Women and Association with Atypical Cytomorphology

Supplemental Tables 1-5. Supplemental Table 1: comparison of fatty acid composition by cytologic atypia or not. Supplemental Table 2: Comparison of fatty acid composition of plasma phospholipids (PLs) by evidence of cytology atypia. Supplemental Table 3: Comparison of fatty acid composition of plasma triacylglycerides (TAGs) by evidence of cytology atypia. Supplemental Table 4: Comparison of fatty acid composition of breast phospholipids (PLs) by evidence of cytology atypia. Supplemental Table 5: Comparison of fatty acid composition of breast triacylglycerides (TAGs) by evidence of cytology atypia.</p

Demographic characteristics of 12 individuals with ADPKD who completed interviews after following a dietary intervention trial.

<p>Demographic characteristics of 12 individuals with ADPKD who completed interviews after following a dietary intervention trial.</p

Supplemental Table 1 from Omega-3-Acid Ethyl Esters Block the Protumorigenic Effects of Obesity in Mouse Models of Postmenopausal Basal-like and Claudin-Low Breast Cancer

Supplemental Table 1. Pilot dosing study - 8 weeks ad libitum consumption. Individual values (n=2) are shown.</p

Supplementary Figure 1 Legend from Omega-3-Acid Ethyl Esters Block the Protumorigenic Effects of Obesity in Mouse Models of Postmenopausal Basal-like and Claudin-Low Breast Cancer

Supplemental Figure 1. EPA+DHA supplementation does not significantly alter serum levels of A.</p

Supplemental Figure 1 from Omega-3-Acid Ethyl Esters Block the Protumorigenic Effects of Obesity in Mouse Models of Postmenopausal Basal-like and Claudin-Low Breast Cancer

Supplemental Figure 1. EPA+DHA supplementation does not significantly alter serum levels of A. TNF-a; B. MCP-1; C. Insulin; D. IGF-1; or E. IGF-BP3 in control or DIO mice (n=10 per group). Data shown are means {plus minus} SEM, statistically significant (P<0.05) differences are indicated by different letters.</p

Supplementary Tables 1-7 from Change in Blood and Benign Breast Biomarkers in Women Undergoing a Weight-Loss Intervention Randomized to High-Dose ω-3 Fatty Acids versus Placebo

Supplemental Table 1: Specimen collection and assay methods details. Supplemental Table 2 Adverse Events Supplemental Table 3. Value and changes in ratio of (DHA+EPA)/AA in erythrocyte phospholipids. Supplemental Table 4. Median relative difference (percent) between baseline and 12 months for 19 serum biomarkers (of a total of 24 assessed) which exhibited a statistically significant change over time* either for the total cohort of 35 women completing the 12-month trial and/or for groups defined by randomization or by dichotomization at 10% weight loss achieved at 6 months. Supplemental Table 5: Biomarker change at 12 months by subgroups defined by randomization arm (placebo vs ω-3 FA) and dichotomization by weight loss (10%). Biomarkers are grouped into categories of adipokines, cytokines, hormones/growth factors, and insulin. A total of 24 biomarkers or ratios were assessed at 12 months. Supplemental Table 6: Levels and changes for adiponectin assessed in serum collected both fasting and non-fasting, and in benign breast tissue acquired non-fasting by RPFNA. Supplemental Table 7: Baseline, 6-month, and 12-month values and change over time for Ki-67, Masood cytomorphology score. -</p

Supplemental Files from Modulation of Breast Cancer Risk Biomarkers by High-Dose Omega-3 Fatty Acids: Phase II Pilot Study in Postmenopausal Women

Supplemental Figure 1: CONSORT diagram for flow of potential and actual subjects enrolled on study. Supplementary Table 1. Demographic and risk information at baseline. Supplementary Table 2. Change in anthropomorphic variables. Supplementary Table 3: Changes in levels of cytokines and adipokines in RPFNA specimens, by Luminex. Supplementary Table 4: Changes in levels of mRNA in RPFNA specimens, by RT-qPCR. Supplementary Table 5: Changes in levels of all peptides and specific phosphopeptides in RPFNA specimens, by Reverse Phase Protein Array.</p

Supplemental Files from Modulation of Breast Cancer Risk Biomarkers by High-Dose Omega-3 Fatty Acids: Phase II Pilot Study in Premenopausal Women

Supplemental Figure 1: CONSORT diagram for flow of potential and actual subjects enrolled on study. Supplementary Table 1. Demographic and risk information at baseline. Supplementary Table 2. Change in fatty acid content in all five compartments. Supplementary Table 3. Change in anthropomorphic variables. Supplementary Table 4: Changes in levels of cytokines and adipokines in RPFNA specimens, by Luminex. Supplementary Table 5: Changes in levels of mRNA in RPFNA specimens, by RT-qPCR. Supplementary Table 6: Changes in levels of all peptides and specific phosphopeptides in RPFNA specimens, by Reverse Phase Protein Array.</p