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Interventions and public health nutrition

Weight loss effects from vegetable intake: a 12-month randomised controlled trial

European Journal of Clinical Nutrition volume 68, pages 778785 (2014) | Download Citation



Direct evidence for the effects of vegetable intake on weight loss is qualified. The study aimed to assess the effect of higher vegetable consumption on weight loss.


A single blind parallel controlled trial was conducted with 120 overweight adults (mean body mass index=29.98 kg/m2) randomised to two energy deficit healthy diet advice groups differing only by doubling the serving (portion) sizes of vegetables in the comparator group. Data were analysed as intention-to-treat using a linear mixed model. Spearmans rho bivariate was used to explore relationships between percentage energy from vegetables and weight loss.


After 12 months, the study sample lost 6.5±5.2 kg (P<0.001 time) with no difference between groups (P>0.05 interaction). Both groups increased vegetable intake and lost weight in the first 3 months, and the change in weight was significantly correlated with higher proportions of energy consumed as vegetables (rho=–0.217, P=0.024). Fasting glucose, insulin and triglyceride levels decreased (P<0.001 time) and high-density lipoprotein cholesterol levels increased (P<0.001 time), with no difference between groups. Weight loss was sustained for 12 months by both groups, but the comparator group reported greater hunger satisfaction (P=0.005).


Advice to consume a healthy low-energy diet leads to sustained weight loss, with reductions in cardiovascular disease risk factors regardless of an emphasis on more vegetables. In the short term, consuming a higher proportion of the dietary energy as vegetables may support a greater weight loss and the dietary pattern appears sustainable.


Weight loss occurs when energy intake is less than energy expenditure,1 and achieving an energy deficit remains the main dietary target.2,3 The evidence for the specific impact of vegetables is qualified. The 2013 Australian Dietary Guidelines (ADG) review found suggestive evidence that vegetable consumption is associated with a reduced risk of weight gain4 and the 2010 Dietary Guidelines for Americans found the association was modest, but may be significant in the long term.5 These positions may reflect difficulties with food-based dietary trials.6,7 Randomised controlled trials provide the appropriate basis for nutrition recommendations,8 but for demonstrating long-term effects there are problematic issues. For example, dietary patterns may end up similar in control and intervention groups, or reduced energy intake may override effects from dietary patterns per se.

In a recent review, we found that randomised controlled trials demonstrated a greater weight loss from high vegetable intake when it occurred as part of a healthy background diet, the control diet constituted ‘usual intake’ and behavioural support was provided.9 In such circumstances, it is difficult to attribute the effects to vegetable consumption alone. Shorter feeding studies under highly controlled conditions can provide ‘proof of concept’,8 but in weight management long-term effects are more clinically relevant. This situation raises a number of questions for how to conduct the research itself.9 Some intervention studies have reported beneficial associations between actual vegetable consumption and weight loss for the whole study sample.10,11

The classification of vegetables (for example, potato chips vs other vegetables),12 gender and behavioural factors,13 and background cuisine14 also may be important considerations. Low-fat diets have appeared superior to high vegetable diets,15 but not always.16 Nevertheless, low energy density and increased satiety are plausible reasons for the reduced risk of weight gain with high vegetable intake,17 and emerging research suggests the phytochemical composition may be beneficial.18 Eating more vegetables may help shift cuisine patterns, proving efficacious in the long term. The aim of this study was to demonstrate the effects of a higher vegetable consumption on sustained weight loss in healthy overweight adults.

Materials and methods

Trial design

A single blind parallel randomised controlled trial was conducted between 2010 and 2012 in Wollongong, NSW, Australia. Participants were recruited by advertising in the local media. Inclusion criteria were healthy adults 18–65 years with a body mass index 25–35 kg/m2. Exclusion factors were major illnesses, diabetes mellitus, thyroid abnormalities, heavy alcohol consumption, recent acute or chronic disease, changing medications affect weight, weight loss >5 kg in last 3 months, fluctuating exercise patterns, strenuous exercise >1 h per day, pregnancy or lactation, dietary limitations, and dislike of vegetables. One hundred subjects were considered sufficient to detect a minimum between-group weight loss difference of 2.7 kg as significant with 80% power and a two-tailed α of 0.05.19 This assumes a 40% post-randomisation dropout rate (20 subjects per group) and a within-group weight loss s.d. of 3.5 kg (using available literature19). A researcher not associated with the clinical interface (MJB) conducted the randomisation using the RALLOC command in STATA V10.0 (College Station, TX, USA) with the randomisation performed in blocks of 2, 4 or 6 and block sizes randomised within four strata, used to divide the sample by sex and body mass index (25–30 kg/m2 and 30–35 kg/m2). The master list was provided by strata and reference to the block size and order was removed, and consecutive numbers for allocation provided.

Dietary intervention

An accredited practising dietitian provided participants with a personalised diet prescription based on core food groups from the Australian Guide to Healthy Eating,20 that is, vegetables, fruit, grain foods, meat/fish/eggs/cheese, milk/yoghurt and nuts/seeds/spreads/oils, providing ~80% energy requirements for age, weight and sex as per the Mifflin equation.21 The energy intake of the diets was managed by careful dietary modelling of all food groups including vegetables. All participants were requested to consume at least five servings of vegetables each day, but the servings were different between control vs comparator (0.5 vs 1.0 cup cooked; 1 vs 2.0 cups of raw, respectively). Doubling portion size has been shown to be effective in increasing vegetable consumption in a disguised way.22 Foods high in saturated fat and added sugars (cakes, biscuits and soft drinks) were discouraged, in keeping with the ADG including the 2013 update.17

Initial consultations lasted 1 h, with 30-min follow-up at months 1, 2, 3, 6, 9 and 12 by the same dietitian. E-mail messages were sent 2 weeks before clinic visits. Short message service was sent to participants’ mobile phones with reminders of appointments and encouragement to maintain study requirements. Booklets outlining the recommended number of servings of food groups per day and a 4-day estimated food record (including one weekend day) were provided. The high vegetable group were given extra support and materials on use of vegetables.

Outcome measures

The primary outcome of body weight (kg) was measured in an upright position in minimal clothing and without shoes using scales with a bio-electrical impedance component to also estimate body fat (%) (Tanita TBF-662, Wedderburn Pty Ltd, Ingleburn, NSW, Australia). Body weight was assessed at similar times of the day at 0-, 1-, 2-, 3-, 6-, 9- and 12-month time points.

Secondary clinical outcome measures were indicators of lifestyle disease risk: fasting insulin, glucose and blood lipids: total cholesterol, low-density lipoprotein cholesterol, high-density lipoprotein cholesterol and triglycerides (sampled at 0, 3, 6, 9 and 12 months). Fasting blood samples were sent to quality assured pathology laboratories (Southern Illawarra Medical Laboratory (a fully owned subsidiary of Sonic Health Care Limited, Wollongong, NSW, Australia) for lipids; and Cardinal Bio-Research Pty Ltd, Brisbane, QLD, Australia, for F2 isoprostanes).

Additional information was collected via questionnaire at the 0-, 3-, 6-, 9- and 12-month appointments. The following assessments were also made:

  1. Physical activity using the Baecke physical activity questionnaire.23

  2. Subjective ratings of food intake behaviour using visual analogue scales (found reliable for this purpose,24,25 scale completely coinciding with the 4th day of the 4-day food record kept between appointments).

  3. Digestive comfort (items relating to thirst, nausea, diarrhoea or constipation using a reference period of the 24 h before the appointment) using a scale (100 mm) within the range of 0–10 (0=not at all, 10=extreme).

  4. General diet acceptability score (referencing the period from the last clinical time, scored on a scale of 0–10 (0=extremely unacceptable, 10=extremely acceptable), and including items related to satisfaction with the diet).

  5. Perceptions of health, measured with questions from the Medical Outcomes Study 36-item Short Form Health Survey (SF-36): (‘In general, would you say your health is excellent/very good/good/fair/poor? Compared to one year ago, how would you rate your health in general? (better/somewhat better/about the same/somewhat worse/much worse). During the past 4 weeks, to what extent has your physical health or emotional problems interfered with your normal social activities with family, friends, neighbours or groups? (not at all/slightly/moderately/quite a bit/extremely)’).


Dietary intake was assessed by diet history interview conducted by an Accredited Practising Dietitian for each participant at 0, 3, 6, 9 and 12 months.26 Participants were asked to report their usual intakes of types and amounts of foods starting with the first meal of the day and indicating variations within a 2- to 4-week period. They were asked specific questions on vegetable intake, including identifying the individual vegetables in dishes. Plasma F2 isoprostanes (sampled at 0, 3 and 12 months, see section Outcome measures), were measured, given the potential for the phytochemicals in vegetables to act as anti-oxidants, and the previously observed negative associations with F2 isoprostanes and high vegetable diet patterns.27

Data analysis

Data were entered into OpenClinica version beta 3.1.2 clinical trial software (Isovera Inc, Boston, MA, USA) for clinical data management, using the double-entry method by at least two independent researchers for completeness. Dietary data were calculated and analysed using FoodWorks (Version 6; Xyris Pty Ltd, Kenmore Hills, QLD, Australia, 2009) nutrient analysis software using the AUSNUT 2007 food composition survey database.28 As weight loss is predicated on total energy intake, vegetable intake data were presented as a percentage of total energy intake.

To examine diet acceptability and monitor changes in appetite, scores were presented so that: for digestive discomfort, the lower the score the less thirst, nausea, diarrhoea or constipation; for satiety, the higher the score the less hungry, less satisfied, lesser sense of fullness, less desire to eat more, and seldom wanting salty, sweet, savoury or fatty foods, respectively; for general diet acceptability, the higher the score the more satisfied, greater ease with preparing food, the greater the effort to adhere to diet plan, more acceptance of core food items and greater ease with continuing on the diet.

Data were analysed using SPSS (version 19.0, SPSS Chicago, IL, USA, 2010) statistical analysis software. Primary and secondary analyses of all continuous variables were conducted using a linear mixed model, which uses all available data regardless of whether the subjects complete the study, the type III fixed effects were used to determine significance. Skewed variables were loge or square root transformed before analysis, and values before transformation were reported to assist with interpretations. The analysis was conducted on an intention-to-treat basis on trial completion. Owing to non-normal distributions, Spearman’s correlations were used to assess relationships between changes in vegetable intake and isoprostane levels and to assess correlations between change in weight and change in vegetable consumption (% energy). The study was approved by the University of Wollongong Human Research Ethics Committee and registered with Australia New Zealand Clinical Trials Register Network (ACTRN12610000784011).



Of the 383 adults who volunteered for the study, 207 completed screening. Of these 67 did not meet eligibility criteria and 20 did not enrol. Thus, n=120 adults were randomised to control and comparator groups and n=93 completed through to 12 months (77.5% completion; Figure 1). The mean age was 48.9±9.3 years. Seven participants withdrew before the start and a further n=18 participants later withdrew consent because of moving out of the area, family or personal health issues. Data from n=2 participants were not included in the final analysis because of extreme non-compliance and starting medications likely to affect weight (data removed after 3 months, Figure 1). There were no adverse effects from the trial.

Figure 1
Figure 1

Enrolment, randomisation and follow-up of study participants.

Between-group effects

After 12 months, both groups lost weight (P<0.001, time effect), with no difference between groups in weight loss (P=0.776, interaction effect; Table 1) or reported energy intake (P=0.701, interaction effect; Table 2). Reported physical activity was not different between groups and did not change throughout the trial (P=0.170, time; P=0.690, interaction; Baecke score). Compared with the controls, the comparator group reported consuming a significantly greater proportion of energy intake from vegetables (P=0.020, interaction; Figure 2).

Table 1: Anthropometric measures from baseline to 12 months (mean ±s.d.)
Table 2: Reported energy intake, physical activity score and reported vegetable intakes from baseline to 12 months (mean ±s.d.)
Figure 2
Figure 2

Vegetable intake expressed as a proportion of total energy intake from baseline to 12 months.

Intervention effects

The sample produced a mean weight loss of 6.5±5.2 kg (range –27.8 to +5 kg) and this was associated with reported change in energy intake (P=0.002, 3 months; P=0.009 12 months) estimated at about –2000 kJ/day (P<0.001, time effect; Table 2). Reported energy intake was significantly lower than baseline at all-time points (P<0.001). Vegetable consumption increased substantially in the first 3 months (Table 2) and the proportion of energy consumed as vegetables was significantly different from baseline at all-time points (P<0.001; Figure 2). Both groups reduced energy intake from high-energy-dense vegetables (time effect P=0.005) and increased energy intake from low-energy-dense vegetables (P<0.001; Table 2). Most of the weight loss occurred in the first 3 months and was maintained. By 12 months, there was a shift in reported consumption away from higher energy vegetables (P=0.005, time effect) to lower energy vegetables (P<0.001, time effect).

The change in weight was significantly correlated with the increase in proportion of energy consumed as vegetables at 3 months (rho=–0.217; P=0.024; n=108; Figure 3a). The association did not remain significant at 12 months (rho=–0.193; =0.06; n=92; Figure 3b). With increasing vegetable intake, there were reductions in isoprostane levels and this was significant for change in vegetable intake from baseline to 3 months represented as percentage of dietary energy (rho=–0.198; P=0.046) and from baseline to 12 months (rho=–0.231; P=0.030). There were significant changes in macronutrient intakes: a reduction in energy from total fat by about 5%, an increase in protein energy by about 3% and an increase in carbohydrate energy by about 2% (time effects all P<0.000; data not shown).

Figure 3
Figure 3

(a) Relationship between change in weight and change in vegetable intake as % of total energy intake at 3 months. (b) Relationship between change in weight and change in vegetable intake as % of total energy intake at 3 months.

Secondary effects

All biochemical parameters improved with the exception of the near normal total and low-density lipoprotein cholesterol levels. Total high-density lipoprotein increased, improving the total cholesterol: high-density lipoprotein ratio (Table 3). Diet acceptability was high throughout the trial (Table 4). All digestive discomfort scores remained relatively low. Ratings for constipation, diarrhoea and nausea were low (range 0.59±1.39–1.71±3.07, maximum 10) with the natural sensation of thirst slightly higher (range 3.32+2.51–4.44±2.86, maximum 10).

Table 3: Clinical variables from baseline to 12 months (mean ±s.d.)
Table 4: Digestive comfort, satiety and diet acceptability ratings from baseline to 12 months (mean ±s.d.)

The higher vegetable group reported a greater increase in hunger satisfaction (P=0.005 interaction) with a marginally significant decrease in score by the control group from 6 to 12 months (P=0.077). All trial participants reported being less hungry throughout the trial (P<0.001, time), they were less inclined to eat more food (P=0.002, time) and to desire sweet foods (P<0.001; 0.049, time, respectively). They reported less desire for fatty food (P=0.001, time).

All items on general diet acceptability were high (around 7–8 where 10=extremely acceptable), with no differences between groups (P>0.05, interaction), except ‘ease to continue’ item (P=0.050, interaction), which was lower score for the higher vegetable group at 6 months (P=0.012, time) only.

The study participants’ perceptions of personal health appeared to improve between baseline and 12 months (data not shown). The proportion reporting their health as ‘excellent’ increased fourfold and the proportion noting ‘very good’ doubled compared with the baseline. About half of the trial participants reported their health as being ‘better than a year ago’. The proportion indicating that physical or emotional problems interfered with normal activities decreased three- to fourfold.


Our finding that low-energy healthy dietary advice17 produced substantial and sustained weight loss regardless of differences in advice on vegetables (Table 1) is consistent with other studies of a similar nature.15,16,29 However, by examining the variation in actual vegetable intake across the study sample, we confirmed similar reported findings11 that vegetable intake correlated with weight loss (Figure 3). The shifts in macronutrient profile were consistent with an increase in the relative amount of vegetables in a dietary pattern comprising core staple foods, as was advised. The secondary analysis warrants further discussion because, despite the reported value of increasing vegetable portion size,22 this advice strategy did not prove sufficient to create a difference in energy intakes in our groups receiving healthy dietary advice based on 80% of energy requirements.

The primary analysis confirms that total dietary energy is the most important dietary variable for weight loss,2 but does little to clarify on best ways to get there and why. We know from studies using ad libitum dietary approaches that supporting an increased vegetable intake does not reduce energy intake,30 or compare favourably against a low-kilojoule diet,11 (and there are challenges in encouraging greater consumption of vegetables).31 Low-kilojoule/low-fat dietary advice appears to be more sustainable than diets focusing on vegetables intake,32 although providing vegetables in the short term may enable what is known as ‘proof of concept’ conditions.8 We need to look beyond the single outcome measure of weight loss. Although we did achieve significant differences between groups in energy consumed as vegetables, this was not enough to have an effect on weight loss (Figure 2) because they were both reducing energy intake. For the group, however, vegetable intake was correlated with weight loss, as has been found before.11 Indeed a greater number of participants or a longer period of follow-up may have proven more informative. Nevertheless, as energy balance is a total diet effect, any single food group can only make a contribution to weight loss. Weight maintenance is the key goal and this requires sustained dietary change. Our data suggest increasing the relative energy contribution of vegetables may provide a viable key strategy, and we explored this further from a broader perspective.

The comparator group reported greater hunger satisfaction (P=0.005), consistent with reports suggesting that vegetables act via controlling for hunger.16 Reviews suggest that encouraging and supporting healthy diets with significant amounts of vegetables are likely to be effective because, although there are limitations on other foods, the central message is positive.33 In terms of the vegetable content of both diets, the literature suggests that establishing long-term habituation through repeat presentation of vegetables at all meals34 and the encouragement of vegetable variety35,36 may help establish lasting change essential to prevent weight regain,37 and we appeared to be seeing that. It should also be noted that the dietary advice strategy focused on shifting from high- to low-energy-dense vegetables and this was reflected in the reported dietary change for the study sample (Table 2).

There were other health considerations. The biomarker (F2 isoprostane) results were consistent with observations that a high vegetable intake is associated with a lower level of the markers of oxidative damage.27 The pattern of reduction in F2 isoprostanes was consistent with the pattern of weight change and vegetable consumption. A recent review of vegetables containing phytochemicals with potential anti-obesity properties specifically identifies common vegetables as sources of known agents that may have contributed to these effects.18 Although this was not a particularly high-risk sample, the participants were tending to insulin resistance, yet they showed significant reductions in waist circumference (Table 2), fasting insulin and triglyceride levels and increases in high-density lipoprotein cholesterol (Table 3). These changes are indicative of a substantial risk reduction for developing type 2 diabetes.38 The effects may not be limited to weight loss alone and this area warrants further research.

There were necessary controls on energy intakes and the background diet in this study, which made it difficult to expose effects of a single food group, as acknowledged in the literature.7 Dietary change is not just about desirable foods going into the diet; it is also about taking others out. In a recent publication,39 we reported that participants with poor baseline dietary patterns lose substantially more weight than those starting with healthy dietary patterns. Future research might test whether shifting eating patterns from a low to a high vegetable intake may have an impact on achieving weight loss by replacing poor quality foods in the total diet.

In conclusion, a dietary energy deficit can be achieved in any number of ways.3 Advice to consume a healthy low-energy diet including five servings of vegetables per day can lead to sustained weight loss, with associated reductions in cardiovascular disease risk factors. In the short term, consuming a higher proportion of the dietary energy as vegetables may support a greater weight loss and the dietary pattern appears sustainable.


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This project has been funded by Horticulture Australia Limited using the vegetable levy and matched funding from the Australian Government. The study was approved by the University of Wollongong Human Research Ethics, Committee and registered with ANZCTR (www.anzctr.org.au) (ACTRN12610000784011).

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  1. School of Medicine, Smart Foods Centre, Illawarra Health and Medical Research Institute, University of Wollongong, Wollongong, New South Wales, Australia

    • L C Tapsell
    • , M J Batterham
    • , R L Thorne
    • , J E O'Shea
    • , S J Grafenauer
    •  & Y C Probst


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Correspondence to L C Tapsell.

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