National Safety Associates nutritional supplementation trial of fruit and vegetable extracts and vascular function (NNTV): study protocol for a randomised controlled trial

Increasingly, dietary intake and nutrition are recognised as playing a major role in the aetiology of CVD [1]. A number of epidemiologic and observational studies regularly report that consuming fruit and vegetables (F&Vs) can lower CVD risk. Among several studies that have looked into the beneficial effects of F&Vs in lowering CVD risk, Yusuf and colleagues [2] reported that the population attributable risk for acute myocardial infarction given irregular consumption of F&Vs was 12.9 %. Also, Crowe and colleagues [3] reported that participants consuming at least 80 g of F&Vs per day had a 22 % lower risk of fatal ischaemic heart disease. Berry fruits have also been shown a reduction in blood pressure as well as a reduction in the levels of pro-inflammatory markers and adhesion molecules, which are both markers of endothelial function [4].

Endothelial dysfunction is emerging as a potential set of early markers of cardiovascular disease risk. It is considered to play a principal role in the initiation and progression of atherosclerosis, and it is also present in later stages of vascular disease. Many studies have used a variety of tests in order to measure endothelial function as well as to assess the impact of potentially therapeutic interventions on the vasculature [5]. In a placebo-controlled crossover study, a short fruit extract intervention study led to improved endothelial vasodilation measured by flow mediated dilatation (FMD) in individuals at risk for CVD [6].

Evidence suggests that dietary flavonoids work in various ways and reduce oxidative stress, which is caused by factors such as smoking, obesity, hypertension and other pathological conditions [7]. Specifically, phytonutrients in F&Vs may have specific cardio-protective effects partially mediated through favourable effects on endothelial function, inhibition of angiogenesis and cell migration and proliferation in blood vessels [8]. Although recent health and public reports focus on the five portions of a range of F&V as being cardio-protective [9, 10], clear dose-response relations are poorly defined, which has resulted in major inconsistencies in F&Vs recommendations. Overall, the body of evidence is growing on the modulation of endothelial, as well as macro- and microvascular function (predictive of cardiovascular risk), due to interventions using different categories of F&Vs or chronic ingestion of selected phytonutrients. However, a paucity of studies have examined the vascular modulatory effects of chronic unselective exposure to a high dose of a very wide range of phytonutrients derived from F&Vs, and it is currently not known whether this can bring about similar magnitudes and patterns of vascular change as compared with exposure to selected F&Vs. We hypothesize that a high dose of unselective phytonutrients derived from F&Vs, when ingested chronically, will result in potentially beneficial changes (compared with placebo) to both macro- and microvascular measures, through modulation of endothelial and conduit function of arteries, thus mitigating cardiovascular risk.

The aim of this study is to evaluate the effects of supplementation with encapsulated fruit and vegetable powder compared with placebo on vascular and endothelial function before and after 12 weeks of intervention when they are both given with ‘5-A-Day’ dietary advice verbally and in writing.

Specifically, the primary objective of this trial is to assess whether there is a change in the carotid intima media thickness (cIMT) between the two groups.

The secondary objectives are to assess the following:

This study is a double-blind, randomised controlled trial for overweight and obese but otherwise healthy participants. It is being conducted at the Medical Research Council (MRC), Human Nutrition Research (HNR) unit in Cambridge, United Kingdom. The study had two stages of ethical approval; first, an internal research governance approval was granted by the Research Review Board (RRB) at MRC HNR, which comprises joint scientific and ethical peer review. Full independent research ethics approval was subsequently obtained from the NHS National Research Ethics Service (REC Reference: 13/EE/0095) and fully informed written consent is taken from all participants. Confirmation that this study does not fall under the legal definition of a Clinical Trial of an Investigational Medicinal Product (CTIMP) was sought from the Medicines and Healthcare Products Regulatory Agency (MHRA) Borderline Team.

The sample size calculation was performed according to cIMT changes over 12 weeks of supplementation. cIMT normal values in the general adult population (including overweight individuals) less than 65 years of age, range from 0.60 to 0.80 mm with a SD of 0.10 mm. [7]. Assuming a two-tailed t-test using a 5 % significance level (two-sided), a sample size of 37 in each group (74 participants in total) was determined to have 85 % power to detect a mean cIMT difference of 0.07 mm after 12 weeks of supplementation between the intervention and control groups, assuming a common SD of 0.10 mm. Allowing for a dropout rate of approximately 15 %, we aim to recruit 80 participants in total; n = 40 in the placebo and n = 40 in the intervention group.

When all inclusion criteria have been met and informed consent has been obtained, participants will be randomly allocated to one of the two groups. Randomisation is based on a blocked randomisation sequence generated by a research statistician independent to the study team and with the sequence unknown to both researchers and participants. Two independent code keepers at MRC HNR, who are not involved in the running of the study, are securely holding the randomisation code. To maintain scientific integrity, at no point will those either generating or holding the study codes, come into contact with participants or data analyses. The details of the allocation are concealed from the research team and the participants until all data collection and analysis are complete. Blinding of participants and research team to allocation status will be assured by identical capsule appearance and identical labelling between the placebo and the active supplementation. Blinding of the capsules, packaging and labelling have been undertaken by the funding company (National Safety Associates (NSA) LLC, USA).

All participants are provided with a booklet where they can record any potential side effects. In case they develop severe side effects, they are advised to stop the supplementation and will be excluded from the study. All serious and non-serious adverse events and/or reactions involving capsules supplementation are logged by a member of the study team in a password protected database. In addition, any abnormal results of clinical importance detected during the course of the study (screening, test visits 1 and 2) will be reported by the HNR clinical team to the participant’s general practitioner (GP).

A 15-ml blood sample will be collected from each participant at the screening visit and approximately 40 ml will be collected during test visits 1 and 2. Table 3 outlines the blood parameters that are analysed in each study visit.

Participants collect-24 hour urine samples, which will be used to investigate the bioavailability of key polyphenol compounds present in the capsules. In addition, hydration status is measured using urine osmolality and urine dip stick from both the urine collected over 24 hours and from the single urine sample collected during test visits 1 and 2.

A consort flowchart of enrolled participants will be provided, and the demographic characteristics recorded at the time of randomisation will also be described. Descriptive analysis will be conducted for all baseline variables to compare participants in both study groups. Results will be reported as means and standard deviations for continuous variables and frequencies with percentages for categorical variables. Two group comparisons for changes in primary and secondary outcome measures following 12 weeks of intervention will be made, assuming similar levels of variance between the two treatment groups and using two-tailed t-tests for normally distributed data. Paired t-tests will be used to assess within-group changes in study outcomes. Multiple linear regression models will be used to assess whether changes from baseline to 12 weeks were significant between the study groups. Regression analysis will be conducted, with adjustment for potential baseline confounding variables. Additionally, a sensitivity analysis will be performed, exploring variation in the standard deviation between the differences of the mean change in cIMT measurements. Exploratory within-group changes will also be assessed for each outcome measure.

This clinical trial was registered in February 2014. At the time of manuscript submission, the enrolment of volunteers was ongoing. The estimated study completion date is December 2015. Please refer to this study by its ISRCTN identifier: ISRCTN14315618.