Meta-analyses of Fructose and Cardiometabolic Risk
מילות מפתח
תַקצִיר
תיאור
Background: Fructose has been implicated in chronic disease guidelines. The American Heart Association (AHA) and American (ADA), Canadian (CDA), and European (EASD) Diabetes Associations discourage dietary fructose at high intakes (>15-20% energy), citing its ability to aggravate blood lipids. The American Heart Association (AHA) and the World Health Organization (WHO) recommend reduced consumption (<5-7% and <10% energy, respectively) of added sugars, especially as high fructose corn syrup in sugar sweetened beverages, to decrease the risk of weight gain. These concerns, however, are based on inconsistent intervention data in humans. There is also paradoxical evidence that small, catalytic doses of fructose at a level obtainable from fruit (<10-g/meal) may improve glycemic control in humans.
Objective: To improve evidence-based guidance for fructose recommendations, the investigators propose conducting a series of 7 systematic reviews and meta-analyses of controlled feeding trials to assess the effect of oral fructose on cardiometabolic risk in humans. The first 6 systematic reviews and meta-analyses will each be conducted on a different area of cardiometabolic risk: (1) lipids, (2) glycemic control, (3) body weight, (4) uric acid, (5) blood pressure, and (6) non-alcoholic fatty liver (NAFL). The seventh meta-analysis will investigate the effect of small, "catalytic" doses of fructose at a level obtainable from fruit (<10-g/meal) on all areas of cardiometabolic risk.
Design: The planning and conduct of the proposed meta-analyses will follow the Cochrane handbook for systematic reviews of interventions. The reporting will follow the Preferred Reporting Items for Systematic reviews and Meta-Analyses (PRISMA) guidelines.
Data sources. MEDLINE, EMBASE, CINAHL and The Cochrane Central Register of Controlled Trials (Clinical Trials; CENTRAL) will be searched using appropriate search terms, supplemented by manual, hand searches of bibliographies.
Study selection: We will include controlled feeding trials investigating the effect of fructose in isocaloric exchange for other carbohydrate sources (isocaloric trials) or added to a control diet as a source of excess energy (hypercaloric trials) on cardiometabolic risk factors in humans. Studies that are <7-days diet duration, lack a control, or do not provide viable endpoint data will be excluded. To isolate the effects of fructose, we will also exclude trials in which fructose was administered exclusively as sucrose (bound fructose) or high-fructose corn syrup (42% to 55% of free fructose), except where these sweeteners were the comparator.
Data extraction. Two investigators will independently extract information about study design, sample size, subject characteristics, fructose form, dose, reference-carbohydrate, follow-up, and background diet profile. Mean±SEM values will be extracted for all outcomes. Standard computations and imputations will be used to derive missing variance data. Investigators will assess the quality/validity of each study using the Heyland Methodological Quality Score (MQS).
Outcomes: The first 6 of 7 proposed analyses will each assess a set of outcomes related to a different area of cardiometabolic risk: (1) lipids (fasting lipids [triglycerides, HDL-cholesterol [C], LDL-C, apo-B, total-C:HDL-C ratio, apo-B:apo-A1 ratio, non-HDL-C] and postprandial lipids(non-fasting peak, mean, and area under the curve [AUC] triglycerides), (2) glycemic control (fasting glucose and insulin, glycated blood proteins) and insulin sensitivity (Euglycemic-hyperinsulinemic clamp, frequent sampling intravenous glucose tolerance test [FSIGT], Homeostasis model assessment of insulin resistance [HOMA-IR], oral glucose tolerance test insulin sensitivity index [OGTT-ISI]), (3) body weight, (4) uric acid, (5) blood pressure (systolic BP, diastolic BP, mean arterial pressure), and (6) NAFL (imaging and spectroscopy endpoints of liver fat and biomarkers of hepatocellular injury [transaminases]). The last proposed analysis investigating the effect of small, "catalytic" doses of fructose will focus on all 6 outcomes.
Data synthesis. Meta-analyses will be conducted using the Generic Inverse Variance method applying random effects models expressed as standardized mean differences (SMDs) with 95% CIs. Paired analyses will be applied for crossover trials according to Elbourne et al. (Int J Epidemiol. 2002;31:140-149). Heterogeneity will be assessed by the Q statistic and quantified by I2. A priori subgroup analyses will be undertaken to explore sources of heterogeneity including the effect of underlying disease status, reference carbohydrate (comparator), fructose form, dose, follow-up, study design, baseline measurements, and study quality on the effect of fructose. Significant unexplained heterogeneity will be investigated by additional post hoc subgroup analyses (e.g. age, sex, level of feeding control, energy balance and composition of the background diet, etc.) and sensitivity analyses. Meta-regression analyses will assess the significance of subgroups analyses with piece-wise meta-regression techniques used to identify dose or follow-up thresholds. Publication bias will be investigated by inspection of funnel plots.
Knowledge translation plan: The results will be disseminated through interactive presentations at local, national, and international scientific meetings and publication in high impact factor journals. Target audiences will include the public health and scientific communities with interest in nutrition, diabetes, obesity, and cardiovascular disease. Feedback will be incorporated and used to improve the public health message and key areas for future research will be defined. Applicant/Co-applicant Decision Makers will network among opinion leaders to increase awareness and participate directly as committee members in the development of future guidelines.
Preliminary findings: A pilot project which explored the effect of fructose on lipids in diabetes identified 786 articles, of which 14 (16 trials)were included in a meta-analysis. Isocaloric exchange of fructose for carbohydrate had a triglyceride raising effect in type 2 diabetes only where the reference carbohydrate was starch, dose was >60-g/d, or follow-up was ≤4-weeks. These distinctions had not been appreciated previously (Sievenpiper et al. Diabetes Care 2009;32:1930-1937).
Significance: The proposed project will aid in knowledge translation related to the effects of dietary fructose on diabetes, and cardiovascular risk factors, strengthening the evidence-base for recommendations and improving health outcomes through informing consumers and guiding future research.
תאריכים
אומת לאחרונה: | 04/30/2015 |
הוגש לראשונה: | 05/24/2011 |
ההרשמה המשוערת הוגשה: | 05/31/2011 |
פורסם לראשונה: | 06/01/2011 |
העדכון האחרון הוגש: | 05/25/2015 |
עדכון אחרון פורסם: | 05/26/2015 |
תאריך תחילת לימוד בפועל: | 04/30/2009 |
תאריך סיום משוער משוער: | 02/28/2014 |
תאריך סיום משוער ללימודים: | 02/29/2016 |
מצב או מחלה
התערבות / טיפול
Other: Dietary fructose
שלב
קריטריונים לזכאות
מינים הזכאים ללימודים | All |
שיטת דגימה | Probability Sample |
מקבל מתנדבים בריאים | כן |
קריטריונים | Inclusion Criteria: - Trials in humans - Oral fructose intervention - Suitable control (i.e. another carbohydrate source in isocaloric exchange for fructose or a control diet which is compared with the same diet supplemented with excess energy from fructose) - >= 7-days diet duration - Viable endpoint data Exclusion Criteria: - Non-human studies - IV or parenteral fructose - High fructose corn syrup or sucrose intervention (except where these are the comparators) - Lack of a suitable control - < 7-days diet duration. - No viable endpoint data |
תוֹצָאָה
מדדי תוצאות ראשוניים
1. Lipid Analysis [June 2012]
2. Body Weight Analysis [November 2011]
3. Glycemic Control Analysis [June 2012]
4. Blood Pressure (BP) Analysis [January 2012]
5. Uric Acid Analysis [February 2012]
6. "Catalytic" Fructose Across Cardiometabolic Endpoints Analysis [January 2012]
7. Non-Alcoholic Fatty Liver (NAFL) Analysis [June 2012]