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The effects of beetroot and nitrate supplementation on body composition: a GRADE-assessed systematic review and meta-analysis

Published online by Cambridge University Press:  27 February 2023

Reza Afrisham
Affiliation:
Department of Clinical Laboratory Sciences, Faculty of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Vida Farrokhi
Affiliation:
Department of Hematology, Faculty of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Matin Ghanavati
Affiliation:
National Nutrition and Food Technology Research Institute, (Faculty of Nutrition Sciences and Food Technology), Shahid Beheshti University of Medical Sciences, Teheran, Iran
Omid Asbaghi
Affiliation:
Cancer Research Center, Shahid Beheshti University of Medical Sciences, Tehran, Iran
Shooka Mohammadi
Affiliation:
Nutrition and Metabolic Diseases Research Center, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
Mehrnaz Mohammadian
Affiliation:
Department of Exercise Physiology, Islamic Azad University of Ahvaz, Ahvaz, Iran
Tahereh Taghvaei-Yazdeli
Affiliation:
Department of Hematology, Faculty of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Shayan Safaei-Kooyshahi
Affiliation:
Department of Clinical Laboratory Sciences, Faculty of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Yasaman Jadidi
Affiliation:
Department of Clinical Laboratory Sciences, Faculty of Allied Medicine, Tehran University of Medical Sciences, Tehran, Iran
Damoon Ashtary-Larky*
Affiliation:
Nutrition and Metabolic Diseases Research Center, Ahvaz Jundishapur University of Medical Sciences, Ahvaz, Iran
*
*Corresponding author: Damoon Ashtary-Larky, email [email protected]
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Abstract

This systematic review and meta-analysis aimed to investigate the effects of beetroot (BR) or nitrate supplements on body composition indices. A systematic search was conducted for randomised controlled trials (RCT) published up to August 2022 among online databases including Scopus, PubMed/Medline, Web of Science and Embase. Meta-analyses were carried out using a random-effects model. The I2 index was used to assess the heterogeneity of RCT. A total of twelve RCT met the inclusion criteria for this meta-analysis. The pooled effect size of included studies indicated that BR or nitrate supplementation did not change body weight (weighted mean differences (WMD): –0·14 kg, 95 % CI –1·22, 1·51; P = 0·836; I2 = 0 %), BMI (WMD: −0·07 kg/m2, 95 % CI −0·19,0·03; P = 0·174, I2 = 0 %), fat mass (WMD: –0·26 kg, 95 % CI –1·51, 0·98; P = 0·677, I2 = 0 %), waist circumference (WMD: –0·28 cm, 95 % CI –2·30, 1·74; P = 0·786, I2 = 0 %), body fat percentage (WMD: 0·18 %, 95 % CI –0·62, 0·99; P = 0·651, I2 = 0 %), fat-free mass (WMD: 0·31 kg, 95 % CI –0·31, 1·94; P = 0·703, I2 = 0 %) and waist-to-hip ratio (WMD: 0, 95 % CI –0·01, 0·02; P = 0·676, I2 = 0 %). Subgroup analyses based on trial duration, BR or nitrate dose, study design, baseline BMI and athletic status (athlete v. non-athlete) demonstrated similar results. Certainty of evidence across outcomes ranged from low to moderate. This meta-analysis study suggests that BR or nitrate supplements cannot efficiently ameliorate body composition indices regardless of supplement dosage, trial duration and athletic status.

Type
Systematic Review and Meta-Analysis
Copyright
© The Author(s), 2023. Published by Cambridge University Press on behalf of The Nutrition Society

Body composition is a determinant of general population health and athletic performance(Reference Campa, Toselli and Mazzilli1). Various methods are recommended to ameliorate body composition such as adherence to different dietary approaches, along with exercise; they have mostly focused on increasing lean body mass and reducing body fat and/or weight(Reference Ashtary-Larky, Bagheri and Bavi2,Reference Ashtary-Larky, Bagheri and Tinsley3) . In addition to dietary and exercise interventions, dietary supplements have received increasing attention for body composition improvement among the general population and athletes(Reference Hayes and Cribb4,Reference Ashtary-Larky, Bagheri and Ghanavati5) . One of these dietary supplements is beetroot juice (BRJ)(Reference El-Ghandour and Ragheb6).

Red beetroot (BR) is a source of nitrates (NO3), antioxidants, betanin, phenolic compounds, minerals (Na, K, Fe, Ca, Cu, P, Mg and Zn), dietary fibres and vitamins (B complex, ascorbic acid and retinol)(Reference dos S Baião, da Silva and Paschoalin7). BR has a variety of edible roots that are used as a source of nutrients. It also has anti-inflammatory, antioxidant, anti-diabetic, anti-carcinogenic, hepatoprotective, wound healing and hypotensive properties(Reference Mirmiran, Houshialsadat and Gaeini8). BRJ is a rich source of NO3, which is especially popular among athletes for improving athletic performance and endurance(Reference Fernández-Elías, Courel-Ibáñez and Pérez-López9). Therefore, BRJ is considered a useful ingredient in food supplements, especially for athletes(Reference Chhikara, Kushwaha and Sharma10,Reference Domínguez, Maté-Muñoz and Cuenca11) . On the other hand, dietary supplements containing NO3 lead to limiting proton leakage in the mitochondrial electron transport chain, which increases energy production per oxygen unit (O2) and improves mitochondrial respiration(Reference Alshafie, El-Helw and Fayoud12). Some studies have reported that during drinking BRJ, NO3 is converted into NO2 by oral anaerobic bacteria and xanthine oxidase, and after swallowing NO2, it is immediately converted into nitric oxide (NO) in the stomach(Reference Morou-Bermúdez, Torres-Colón and Bermúdez13). Hypothetically, NO is a vasodilator compound that leads to increased blood flow and oxygen supply to skeletal muscles and improved contraction force in type II muscle fibres that contribute to rapid body contraction(Reference Fernández-Elías, Courel-Ibáñez and Pérez-López9). Moreover, NO inhibits cytochrome oxidase activity and can increase oxidative phosphorylation(Reference Kozlowska, Mizera and Mroz14).

Based on the International Olympic Committee, Australian Institute of Sport and International Society of Sports Nutrition guidelines, BRJ and nitrate are classified as supplements that may improve athletic performance(Reference Maughan, Burke and Dvorak1517). According to the characteristics mentioned for BRJ as a performance-enhancing supplement, it can be effective in body composition improvement. However, evidence regarding body composition improvement following BRJ and/or nitrate is equivocal. Animal studies showed that BRJ significantly decreased the body weight and body weight gain(Reference El-Ghandour and Ragheb6). A mechanistic study revealed that BJ may activate brown adipose tissue through increased UCP1 gene expression(Reference Otieno18). Conversely, human studies failed to support the results of animal studies. However, the general impact of BR and nitrate supplements on body composition changes is unsettled; thus, it is required to conduct a comprehensive systematic review and meta-analysis of randomised controlled trials (RCTs) on this topic. Therefore, we aimed to conduct a systematic review and meta-analysis of the pooled data from RCT to compare the efficacy of BR or nitrate supplements on body composition variables, including body weight, BMI, waist circumference (WC), fat mass (FM), body fat percentage (BFP), fat-free mass (FFM) and waist-to-hip ratio (WHR).

Methods and materials

Search strategy

This study was performed in accordance with the Preferred Reporting Items for Systematic reviews and Meta-Analyses statement (PROSPERO registration number: CRD42022378139). We carried out a comprehensive search with no language and time restrictions among online databases including Scopus, PubMed/Medline, Web of Science and Embase for the period up to August 2022. We used the following MeSH and non-MeSH terms in our search strategy to identify potentially relevant studies: ‘Beetroot juice’ AND weight, ‘Beetroot juice’ AND (‘body mass index’ OR BMI), ‘Beetroot juice’ AND (‘waist circumference’ OR WC), ‘Beetroot juice’ AND (‘percentage of body fat’ OR ‘body fat percentage’), ‘Beetroot juice’ AND (‘fat free mass’ OR ‘lean body mass’ OR FFM OR LBM), ‘Beetroot juice’ AND (‘fat mass’ OR FM), ‘Beetroot juice’ AND (‘waist–hip ratio’ OR ‘waist-to-hip ratio’ OR WHR), Beetroot AND weight, Beetroot AND (‘body mass index’ OR BMI), Beetroot AND (‘waist circumference OR WC’), Beetroot AND (‘fat free mass’ OR ‘lean body mass’ OR FFM OR LBM), Beetroot AND (‘percentage of body fat’ OR ‘body fat percentage’), Beetroot AND (‘fat mass’ OR FM), Beetroot AND (‘waist–hip ratio’ OR ‘waist-to-hip ratio’ OR WHR), nitrate AND weight, nitrate AND (‘body mass index’ OR BMI), nitrate AND (‘waist circumference’ OR WC), nitrate AND (‘fat free mass’ OR ‘lean body mass’ OR FFM OR LBM), nitrate AND (‘percentage of body fat’ OR ‘body fat percentage’), nitrate AND (‘fat mass’ OR FM), nitrate AND (‘waist–hip ratio’ OR ‘waist-to-hip ratio’ OR WHR), ‘nitric oxide supplement’ AND weight, ‘nitric oxide supplement’ AND (‘body mass index’ OR BMI), ‘nitric oxide supplement’ AND (‘waist circumference’ OR WC), ‘nitric oxide supplement’ AND (‘fat free mass’ OR ‘lean body mass’ OR FFM OR LBM), ‘nitric oxide supplement’ AND (‘percentage of body fat’ OR ‘body fat percentage’), ‘nitric oxide supplement’ AND (‘fat mass’ OR FM), ‘nitric oxide supplement’ AND (‘waist–hip ratio’ OR ‘waist-to-hip ratio’ OR WHR). Furthermore, all references of the included searches and previous review articles were searched to avoid omitting any relevant trials.

Study selection and eligibility criteria

This meta-analysis included RCT with a parallel or cross-over design that investigated the effects of BR or nitrate supplements on body composition measures (e.g. body weight, BMI, FM, BFP, FFM and WHR); their findings were presented as standard deviation and mean in the control and intervention groups. Articles that did not meet the eligibility criteria were omitted by reviewing the title, abstract and full text. Exclusion criteria were (1) all studies that investigated another combination with BRJ or nitrate, (2) experimental, animal and review studies, (3) studies conducted on children and pregnant women and (4) studies without a control group.

Data extraction

Data were extracted from eligible studies by three investigators (VF, RA), and a head investigator (DA) performed the final evaluation. The obtained data are (1) surname of the first author, (2) place of study, (3) year of publication, (4) duration of the study, (5) type and dose of BR or nitrate supplements, (6) sex, (7) age, (8) BMI and (9) health status of the participants.

Quality assessment

The risk of bias was assessed in eligible and included studies by using the Cochrane scoring system. In each study, several specific items were evaluated: randomisation process, allocation concealment, participant and staff blindness, outcome assessor blindness, inadequate outcome data, selective reporting and other biases. Three groups were created as a result: high risk of bias (general risk of bias > 2 high risks), unclear risk of bias (general risk of bias = 2 high risks) and low risk of bias (general risk of bias < 2 high risks). Table 2 provides a summary of the analyses’ findings.

Statistical analysis

Risk of bias assessment in eligible and included studies was performed using the Cochrane scoring system. In each study, several specific items were evaluated: the mean and standard deviation of the outcome measures (body weight, BMI, FM, BFP, FFM and WHR) examined for the control and intervention groups were used to obtain general results. If the standard deviation of the mean difference was not reported in the studies, we calculated it using the following formula: sd change = square root ((sd baseline) 2 + (sd final) 2 – (2R × sd baseline × sd final)) (R = 0·8)(Reference Asbaghi, Ashtary-Larky and Bagheri19). The combined effect size was expressed as the weighted mean difference and 95 % CI. Heterogeneity between study estimates was investigated using the Q-test and the Cochrane 12 index. Sensitivity analysis was performed to determine the impact of each study on the overall effect size. Publication bias was evaluated using Egger’s test and funnel plot analysis. To examine sources of heterogeneity, we accomplished subgroup analyses based on trial duration, intervention dose, baseline BMI, study design and athletic status.

Assessment of certainty

The entire level of evidence certainty across the research was assessed and summarised using the Grading of Recommendations Assessment, Development and Evaluation (GRADE) system(Reference Guyatt, Oxman and Vist20).

Results

Study selection

The initial multi-database search identified 5211 publications. After removing duplicates, 3894 records were screened and 3686 reports were excluded. The eligibility of remaining 208 articles was assessed and twelve articles that met the inclusion criteria were selected for this meta-analysis. The selection and screening process of eligible studies is summarised in Fig. 1.

Fig. 1. Flow chart of study selection for inclusion trials in the systematic review.

Study characteristics

A total of twelve RCTs involving 500 participants (301 cases and 299 controls) were included in this meta-analysis(Reference Kozlowska, Mizera and Mroz14,Reference Capper, Houghton and Stewart21Reference Blekkenhorst, Lewis and Prince31) . Six of the studies had two trial arms(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25,Reference van der Avoort, Ten Haaf and Bongers26,Reference Córdova-Martínez, Caballero-García and Bello28,Reference Burgos, Viribay and Calleja-González29,Reference Blekkenhorst, Lewis and Prince31) . Table 1 provides the characteristics of the twelve included trials. The studies were published between 2016 and 2022. Three were cross-over trials(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25,Reference Blekkenhorst, Lewis and Prince31) and nine studies used a parallel design(Reference Capper, Houghton and Stewart21Reference Srivastava, Siddiqi and Singh24,Reference van der Avoort, Ten Haaf and Bongers26Reference Siervo, Shannon and Kandhari30) . The duration of interventions ranged from 4 to 12 weeks and sample sizes in the trials were between 10 and 80 participants. Their mean age and BMI varied between 22 to 70 years and 22·5 to 36 kg/m2, respectively. Study settings were Spain(Reference Córdova-Martínez, Caballero-García and Bello28,Reference Burgos, Viribay and Calleja-González29) , Poland(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25) , Australia(Reference Blekkenhorst, Lewis and Prince31), Egypt(Reference Matar, Farrag and Hafez22), Iran(Reference Karimzadeh, Behrouz and Sohrab23), the Netherlands(Reference van der Avoort, Ten Haaf and Bongers26), the UK(Reference Capper, Houghton and Stewart21), the USA(Reference Townsend, Hart and Haynes27), India(Reference Srivastava, Siddiqi and Singh24) and Tanzania(Reference Siervo, Shannon and Kandhari30). Eight arms were conducted among both sexes(Reference Capper, Houghton and Stewart21,Reference Karimzadeh, Behrouz and Sohrab23,Reference Srivastava, Siddiqi and Singh24,Reference van der Avoort, Ten Haaf and Bongers26,Reference Siervo, Shannon and Kandhari30,Reference Blekkenhorst, Lewis and Prince31) , while six and four arms included only men(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25,Reference Townsend, Hart and Haynes27Reference Burgos, Viribay and Calleja-González29) or women(Reference Kozlowska, Mizera and Mroz14,Reference Matar, Farrag and Hafez22,Reference Kozłowska, Mizera and Gromadzińska25,Reference Córdova-Martínez, Caballero-García and Bello28) , respectively. The trials were carried out among triathletes(Reference Burgos, Viribay and Calleja-González29), baseball players(Reference Townsend, Hart and Haynes27), elite fencers(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25) , older healthy participants(Reference Capper, Houghton and Stewart21), elderly men and women(Reference Córdova-Martínez, Caballero-García and Bello28). In addition, the studies enrolled patients with pre-hypertension(Reference van der Avoort, Ten Haaf and Bongers26,Reference Blekkenhorst, Lewis and Prince31) , hypertension(Reference Siervo, Shannon and Kandhari30), non-alcoholic fatty liver disease(Reference Srivastava, Siddiqi and Singh24), type 2 diabetes mellitus(Reference Karimzadeh, Behrouz and Sohrab23) and polycystic ovary syndrome(Reference Matar, Farrag and Hafez22). A daily dose of BR or nitrate supplements was between 2 and 200 g. Table 2 presents the risk of bias assessment in the twelve included studies.

Table 1. Characteristic of included studies in meta-analysis

(Mean values and standard deviations)

IG, intervention group; CG, control group; DB, double-blinded; SB, single-blinded; PC, placebo-controlled; CO, controlled; RA, randomised; NR, not reported; F, Female; M, Male; NR, not reported; NAFLD, non-alcoholic fatty liver disease; T2DM, type 2 diabetes mellitus; PCOS, polycystic ovary syndrome.

Table 2. Risk of bias assessment

General low risk < 2 high risk.

General unclear risk = 2 high risk.

General high risk > 2 high risk.

Effect of beetroot or nitrate supplementation on body weight

Ten RCTs(Reference Kozlowska, Mizera and Mroz14,Reference Capper, Houghton and Stewart21,Reference Karimzadeh, Behrouz and Sohrab23,Reference Kozłowska, Mizera and Gromadzińska25Reference Blekkenhorst, Lewis and Prince31) with 400 participants were included in a meta-analysis to investigate the effect of BR or nitrate supplementation on body weight. The pooled analysis of sixteen trial arms did not indicate any significant changes in the body weight of intervention group participants compared with those in untreated or placebo groups (weighted mean differences (WMD): –0·14 kg, 95 % CI –1·22, 1·51; P = 0·836; I2 = 0 %). The results of categorical subgroup analyses for the effect of BR or nitrate intake on body composition indices are summarised in Table 3. The sub-analyses suggested no significant differences in body weight between subgroups in terms of duration of intervention, the dose of BRJ or nitrate supplementation, study design, baseline BMI of participants and athletic status (athlete v. non-athlete).

Table 3. Subgroup analyses of beetroot (BR) juice on anthropometric indices in adults

(95 % confidence intervals)

WC, waist circumference; FM, fat mass; BFP, body fat percentage; FFM, fat-free mass; WHR, waist-to-hip ratio; WMD, weighted mean differences.

Effect of beetroot or nitrate supplementation on BMI

Six trials(Reference Capper, Houghton and Stewart21Reference Srivastava, Siddiqi and Singh24,Reference Burgos, Viribay and Calleja-González29,Reference Blekkenhorst, Lewis and Prince31) including eight arms (n 266) provided data to evaluate the effect of supplementation with BR or nitrate on BMI; the meta-analysis failed to show any significant differences in BMI between the intervention and control groups (WMD: −0·07 kg/m2, 95 % CI −0·19,0·03; P = 0·174, I2 = 0 %) (Fig. 2(b)); similar findings were observed in subgroup analyses (Table 3).

Fig. 2. Forest plot detailing weighted mean difference and 95 % CI for the effect of beetroot or nitrate intake on (a) body weight (kg); (b) BMI (kg/m2), (c) waist circumference (cm), (d) fat mass (kg), (e) body fat percentage (%), (f) fat-free mass (kg) and (g) waist-to-hip ratio.

Effect of beetroot or nitrate supplementation on waist circumference

Figure 2(c) shows a forest plot of three RCTs(Reference Karimzadeh, Behrouz and Sohrab23,Reference van der Avoort, Ten Haaf and Bongers26,Reference Blekkenhorst, Lewis and Prince31) that examined the effects of BR or nitrate supplementation on WC among individuals subjected to BRJ intervention compared with the placebo group; a pooled analysis of five trial arms with 201 participants (WMD: –0·28 cm, 95 % CI –2·30, 1·74; P = 0·786, I2 = 0 %) and subgroup analyses revealed no significant effects on WC (Table 3).

Effect of beetroot or nitrate supplementation on body fat mass

Three studies(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25,Reference Townsend, Hart and Haynes27) with five arms (n 84) reported the effect of BR or nitrate intake on FM of participants (BRJ or nitrate group v. controls) (Fig. 2(d)); the outcome analysis (WMD: –0·26 kg, 95 % CI –1·51, 0·98; P = 0·677, I2 = 0 %) and subgroup analyses found no significant change in FM (Table 3).

Effect of beetroot or nitrate supplementation on body fat percentage

Four trials(Reference Capper, Houghton and Stewart21,Reference Townsend, Hart and Haynes27Reference Burgos, Viribay and Calleja-González29) containing six arms (n 128) were included in the meta-analysis to determine the effect of BR or nitrate supplementation on BFP. The analysis did not show any significant differences in BFP between the two groups (intervention and control) (WMD: 0·18 %, 95 % CI –0·62, 0·99; P = 0·651, I2 = 0 %) (Fig. 2(e)); no significant differences were observed between subgroups (Table 3).

Effect of beetroot or nitrate supplementation on fat-free mass

Four studies(Reference Kozlowska, Mizera and Mroz14,Reference Kozłowska, Mizera and Gromadzińska25,Reference Townsend, Hart and Haynes27,Reference Córdova-Martínez, Caballero-García and Bello28) with seven effect sizes (n 100) were evaluated regarding the effect of BR or nitrate supplementation on FFM; the meta-analysis did not find significant differences in FFM between the intervened and placebo groups (WMD: 0·31 kg, 95 % CI –0·31, 1·94; P = 0·703, I2 = 0 %) (Fig. 2(f)); there was no significant difference between subgroups (Table 3).

Effect of beetroot or nitrate supplementation on the waist-to-hip ratio

Two RCTs(Reference Karimzadeh, Behrouz and Sohrab23,Reference Blekkenhorst, Lewis and Prince31) with three arms (n 98) reported the impact of BR or nitrate intake on the WHR of participants (intervened v. untreated group) (Fig. 2(g)). The pooled data analysis (WMD: 0, 95 % CI –0·01, 0·02; P = 0·676, I2 = 0 %) and subgroup analyses did not show any significant changes in WHR (Table 3).

Publication bias

Begg’s and Egger’s tests did not find publication bias for the majority of evaluated outcomes (BMI, WC, BFP, FFM and WHR). However, it was detected in studies related to the effects of BR or nitrate supplementation on body weight (Begg’s test, P = 0·031; Egger’s test, P = 0·028) and FM (Egger’s test, P = 0·003). Funnel plots showed some level of asymmetry for body weight and BMI outcomes, while they looked symmetrical for WC, FM, BFP, FFM and WHR (Fig. 3(a)–(g)).

Fig. 3. Funnel plots for the effect of beetroot or nitrate intake on (a) body weight (kg); (b) BMI (kg/m2), (c) waist circumference (cm), (d) fat mass (kg), (e) body fat percentage (%), (f) fat-free mass (kg) and (g) waist-to-hip ratio.

Sensitivity analysis

The sensitivity analysis indicated that each outcome in these meta-analyses did not change through the systematic removal of each study; none of the studies did substantially affect the overall effect size, the direction of the association and statistical significance.

Grading of Recommendations Assessment, Development and Evaluation assessment

The certainty of the evidence was assessed for all evaluated outcomes according to the GRADE framework (Table 5). The quality of evidence was graded as moderate for BMI, WC, BFP, FFM and WHR owing to a downgrade for serious imprecision. It was identified as low for body weight and FM outcomes due to the serious risk of imprecision and publication bias.

Table 4. Sensitivity analysis and publication bias

WC, waist circumference; FM, fat mass; BFP, body fat percentage; FFM, fat-free mass; WHR, waist-to-hip ratio.

Table 5. GRADE profile of beetroot (BR) intake for anthropometric indices

(95 % confidence intervals)

WMD, weighted mean differences; WC, waist circumference; FM, fat mass; BFP, body fat percentage; FFM, fat-free mass; WHR, waist-to-hip ratio.

1. There is significant publication bias for body weight (P = 0·028) and FM (P = 0·003).

2. There is significant effects of BR intake on body weight, BMI, WC, FM, BFP, FFM and WHR.

Discussion

This systematic review and meta-analysis intended to evaluate available evidence related to the effects of BR or nitrate supplementation on body composition measures. The present study failed to show any association between BR or nitrate supplementation and body composition indices (body weight, BMI, FM, WC, BFP, FFM and WHR). All included studies indicated that BR or nitrate supplementation did not significantly change the body composition indices of the intervened groups compared with controls. The subgroup analyses suggested no significant differences in body composition-related outcomes between subgroups in terms of duration of intervention, the dose of BR or nitrate supplement, study design, baseline BMI of participants and athletic status (athlete v. non-athlete). The findings indicated that BR or nitrate supplementation did not significantly change the body composition indices of the intervened groups compared with controls. However, the present study revealed that the majority of claims about the advantages of BR consumption on weight loss or body composition improvement found on the labels of several products are not supported by clear scientific data.

There is consensus that NO derived from BR can exert an effect on endothelial function by increasing cyclic guanosine monophosphate (cyclic GMP) in vascular smooth muscle, which can lead to increased blood flow, oxygen delivery and better resistance to fatigue during exercise efforts(Reference Aucouturier, Boissière and Pawlak-Chaouch32Reference Vanhatalo, Bailey and Blackwell34). Due to the role of NO in oxidative phosphorylation efficiency(Reference Clerc, Rigoulet and Leverve35), BR has been proposed to improve performance during intensive endurance efforts in which the main source of energy is oxidative phosphorylation(Reference Domínguez, Maté-Muñoz and Cuenca36). However, the results of a recent systematic review and meta-analysis showed no changes in peak and mean power output, two main measures of athletic performance, during high-intensity interval training and sprint interval training following chronic or acute supplementation of BRJ(Reference Wong, Sim and Burns37). Therefore, the evidence regarding the effective dose of BRJ supplementation, maximum useful dose and appropriate duration of BRJ supplementation to improve performance and endurance measures is equivocal(Reference Domínguez, Maté-Muñoz and Cuenca11). It can be the first reason why the recent studies failed to show any significant changes in body composition indices after BRJ supplementation.

In a well-designed study, the administration of 180 mg nitrate in the form of red spinach extract before each resistance training session could not improve adaptation to resistance training and performance among baseball players, and no changes were observed in their body composition(Reference Townsend, Hart and Haynes27). Meanwhile, the absolute dose of nitrate for increasing athletic performance without side effects has not yet been determined, although some studies showed an improvement in training performance following NO3 supplementation in dosages greater than or equal to 400 mg(Reference Williams, Martin and Mintz38,Reference Mosher, Sparks and Williams39) and the lower dose of NO3 could improve athletic performance measures(Reference Gonzalez, Accetta and Spitz40). Besides controversial evidence regarding effective nitrate dose, the elevation of plasma NO3 following inorganic nitrate or BR supplementation and its effects on exercise performance is under debate(Reference Jonvik, Nyakayiru and Van Dijk41Reference Tatlici and Cakmakci43). It has been hypothesised that nitrate-rich supplement products could improve exercise performance by increasing plasma NO3 levels, but the evidence is equivocal(Reference Capper, Houghton and Stewart21,Reference Stanaway, Rutherfurd-Markwick and Page44) . It should be stated that the post-intervention plasma levels of NO3 or intramuscular NO3 concentration contributed to the ergogenic effects of BR products, while its values were not measured in some of the included studies in the present meta-analysis(Reference Matar, Farrag and Hafez22Reference Kozłowska, Mizera and Gromadzińska25,Reference Townsend, Hart and Haynes27Reference Burgos, Viribay and Calleja-González29) . Therefore, the results of these studies should be interpreted with caution, in which plasma levels of NO3 following BR products and their subsequent effects on body composition were not assessed.

The majority of the included studies in the current meta-analysis were conducted to determine the effects of BRJ on inflammation, oxidative stress, lipid profile levels, blood pressure and liver enzymes in patients; thus, none of these studies was designed to assess the effect of partial substitution of carbohydrate intake with BR or nitrate on weight loss. In this regard, one of the included RCT was conducted to evaluate the effects of BRJ on oxidative stress and inflammatory markers in patients with type 2 diabetes mellitus who were asked to maintain their regular dietary habits during the study(Reference Karimzadeh, Behrouz and Sohrab23). In that study, supplementation with 24 ml BRJ for 12 weeks did not show any changes in body weight, BMI, WC and WHR compared with the control group; no changes in body composition indices may partially be explained by no differences in energy content intake between the two groups and in each group at the end of the study(Reference Karimzadeh, Behrouz and Sohrab23). In another included RCT among patients with non-alcoholic fatty liver disease, supplementation with 5 mg of BR powder daily for 3 months could reduce liver enzyme levels, lipid profiles and liver size compared with controls, but BMI remained unchanged(Reference Srivastava, Siddiqi and Singh24). The health benefits of BRJ have been ascribed to phytochemical components like polyphenols, carotenoids, betalains and anthocyanins, which manifested high stability and antioxidant capacity(Reference Clifford, Howatson and West45,Reference Kayın, Atalay and Türken Akçay46) .

The remaining included studies in this meta-analysis aimed to determine the effects of BRJ supplementation on athletic performance measures among trained individuals; the dietary recommendations and the training protocol of these studies were not designed to achieve weight loss or body composition changes. An RCT with cross-over design evaluated the impact of the combination of dietary recommendation and BRJ supplementation on muscle damage, oxidative stress and vo2 max in elite fencers for 4 weeks(Reference Matar, Farrag and Hafez22); it failed to show any differences in body composition measures compared with the group received dietary recommendations alone(Reference Kozłowska, Mizera and Gromadzińska25). The maximal plasma concentration of NO3 occurs within 2–3 h after BRJ consumption and the ergogenic effects of BRJ were observed at a supplementation dose of 6–8 mmol NO3(Reference Domínguez, Cuenca and Maté-Muñoz47); thus, it is important to design study protocols to consider the timing of BRJ supplementation, duration of training and dose of BRJ, as well as optimise the ergogenic potential of BRJ and its effects on body composition improvement in further studies.

It is worth mentioning that the advantages of BR consumption on body weight management may attribute to its green leaves and stems which are rich in fibres and low in energy content(Reference Ceclu and Nistor48). Previous studies have reported a positive association between increased consumption of low-energy foods like root vegetables and weight loss(Reference Rolls49). Therefore, future studies are deemed necessary to prove the weight-lowering effect of BR supplementation; trials should utilise whole BR in the context of a healthy dietary pattern instead of BR supplementation alone or substituting portion of energy-dense foods with BR.

This meta-analysis had some limitations; there was a lack of RCT that examined the concurrent effects of BR supplementation and exercise efforts or dietary plans on body composition indices. In addition, the majority of the included RCT did not measure baseline plasma concentrations of NO3, its changes during the study period and dietary intake of NO3 using a validated methodology. Furthermore, there was a lack of research that used body composition measures as their primary outcome and most included studies measured body composition variables as the secondary outcome. However, this study is the first one to review the effects of nitrate-rich products on body composition indices. The low heterogeneity among the included studies is one of the strengths of the current review and meta-analysis.

Conclusion

This meta-analysis declared that supplementation with BR or nitrate could not ameliorate body composition indices regardless of supplement dosage, trial duration and athletic status. So, this study backs some claims of BR product labels regarding the effectiveness of BR supplementation on body composition changes. Further longer-term trials with larger sample sizes are warranted.

Acknowledgements

This research received no specific grant from any funding agency, commercial or not-for-profit sectors.

R. A. and D. A. L. were the leader in the current study and revised the manuscript. V. F., T. T. V. and S. S. K. searched databases and O. A. analysed the data. M. G., S. M., Y. J. and M. M. contributed to the conception and writing of the manuscript. All authors have read and approved the final manuscript.

The authors declare that they have no competing interests.

References

Campa, F, Toselli, S, Mazzilli, M, et al. (2021) Assessment of body composition in athletes: a narrative review of available methods with special reference to quantitative and qualitative bioimpedance analysis. Nutrients 13, 1620.CrossRefGoogle ScholarPubMed
Ashtary-Larky, D, Bagheri, R, Bavi, H, et al. (2022) Ketogenic diets, physical activity and body composition: a review. Br J Nutr 127, 18981920.CrossRefGoogle ScholarPubMed
Ashtary-Larky, D, Bagheri, R, Tinsley, GM, et al. (2021) Effects of intermittent fasting combined with resistance training on body composition: a systematic review and meta-analysis. Physiol Behav 237, 113453.CrossRefGoogle ScholarPubMed
Hayes, A & Cribb, PJJ (2008) Effect of whey protein isolate on strength, body composition and muscle hypertrophy during resistance training. Curr Opin Clin Nutr Metab Care 11, 4044.CrossRefGoogle ScholarPubMed
Ashtary-Larky, D, Bagheri, R, Ghanavati, M, et al. (2022) Effects of beta-alanine supplementation on body composition: a GRADE-assessed systematic review and meta-analysis. J Int Soc Sport Nutr 19, 196218.CrossRefGoogle ScholarPubMed
El-Ghandour, HM & Ragheb, EM (2018) Effect of red beetroot juice on body weight status of obese anemic rats. Egyptian J Nutr 33, 136.Google Scholar
dos S Baião, D, da Silva, DV & Paschoalin, VM (2020) Beetroot, a remarkable vegetable: its nitrate and phytochemical contents can be adjusted in novel formulations to benefit health and support cardiovascular disease therapies. Antioxidants 9, 960.CrossRefGoogle Scholar
Mirmiran, P, Houshialsadat, Z, Gaeini, Z, et al. (2020) Functional properties of beetroot (beta vulgaris) in management of cardio-metabolic diseases. Nutr Metab 17, 115.CrossRefGoogle ScholarPubMed
Fernández-Elías, V, Courel-Ibáñez, J, Pérez-López, A, et al. (2022) Acute beetroot juice supplementation does not improve match-play activity in professional tennis players. J Am Nutr Assoc 41, 3037.Google Scholar
Chhikara, N, Kushwaha, K, Sharma, P, et al. (2019) Bioactive compounds of beetroot and utilization in food processing industry: a critical review. Food Chem 272, 192200.CrossRefGoogle ScholarPubMed
Domínguez, R, Maté-Muñoz, JL, Cuenca, E, et al. (2018) Effects of beetroot juice supplementation on intermittent high-intensity exercise efforts. J Int Soc Sports Nutr 15, 2.CrossRefGoogle ScholarPubMed
Alshafie, S, El-Helw, GO, Fayoud, AM, et al. (2021) Efficacy of dietary nitrate-rich beetroot juice supplementation in patients with chronic obstructive pulmonary disease (COPD): a systematic review and meta-analysis. Clin Nutr ESPEN 42, 3240.CrossRefGoogle ScholarPubMed
Morou-Bermúdez, E, Torres-Colón, J, Bermúdez, N, et al. (2022) Pathways linking oral bacteria, nitric oxide metabolism, and health. J Dental Res 101, 623631.CrossRefGoogle ScholarPubMed
Kozlowska, L, Mizera, O & Mroz, A (2020) An untargeted metabolomics approach to investigate the metabolic effect of beetroot juice supplementation in fencers—a preliminary study. Metabolites 10, 100.CrossRefGoogle ScholarPubMed
Maughan, RJ, Burke, LM, Dvorak, J, et al. (2018) IOC consensus statement: dietary supplements and the high-performance athlete. Int J Sport Nutr Exerc Metab 28, 104125.CrossRefGoogle ScholarPubMed
Kerksick, CM, Wilborn, CD, Roberts, MD, et al. (2018) ISSN exercise & sports nutrition review update: research & recommendations. J Int Soc Sports Nutr 15, 38.CrossRefGoogle ScholarPubMed
AIS (2023) Australian Institute of Sport Position Statement. Supplements and Sport Foods in High Performance Sport. https://www.ais.gov.au/__data/assets/pdf_file/0014/1000841/Position-Statement-Supplements-and-Sports-Foods.pdf (accessed on 13 March 2023).Google Scholar
Otieno, D (2016) Effects of Beetroot Extract in Brown Adipose Tissue from Diet-induced Obese Mice. Greensboro: North Carolina Agricultural and Technical State University.Google Scholar
Asbaghi, O, Ashtary-Larky, D, Bagheri, R, et al. (2021) Effects of folic acid supplementation on inflammatory markers: a grade-assessed systematic review and dose–response meta-analysis of randomized controlled trials. Nutrients 13, 2327.CrossRefGoogle ScholarPubMed
Guyatt, GH, Oxman, AD, Vist, GE, et al. (2008) GRADE: an emerging consensus on rating quality of evidence and strength of recommendations. BMJ 336, 924926.CrossRefGoogle ScholarPubMed
Capper, TE, Houghton, D, Stewart, CJ, et al. (2020) Whole beetroot consumption reduces systolic blood pressure and modulates diversity and composition of the gut microbiota in older participants. NFS J 21, 2837.CrossRefGoogle Scholar
Matar, SS, Farrag, AA, Hafez, SM, et al. (2021) The bioactive effect of red beetroot on women with the Polycystic Ovarian Syndrome (PCOS). Egyptian J Nutr 36, 2149.Google Scholar
Karimzadeh, L, Behrouz, V, Sohrab, G, et al. (2022) A randomized clinical trial of beetroot juice consumption on inflammatory markers and oxidative stress in patients with type 2 diabetes. J Food Sci 87, 54305441.CrossRefGoogle ScholarPubMed
Srivastava, S, Siddiqi, Z, Singh, T, et al. (2019) Beetroot supplementation on non-alcoholic fatty liver disease patients. Curr Res Nutr Food Sci J 7, 96101.CrossRefGoogle Scholar
Kozłowska, L, Mizera, O, Gromadzińska, J, et al. (2020) Changes in oxidative stress, inflammation, and muscle damage markers following diet and beetroot juice supplementation in elite fencers. Antioxidants 9, 571.CrossRefGoogle ScholarPubMed
van der Avoort, CM, Ten Haaf, DS, Bongers, CC, et al. (2021) Increasing nitrate-rich vegetable intake lowers ambulatory blood pressure in (pre) hypertensive middle-aged and older adults: a 12-week randomized controlled trial. J Nutr 151, 26672679.CrossRefGoogle Scholar
Townsend, JR, Hart, TL, Haynes, JT IV, et al. (2022) Influence of dietary nitrate supplementation on physical performance and body composition following offseason training in Division I athletes. J Dietary Supplements 19, 534549.CrossRefGoogle ScholarPubMed
Córdova-Martínez, A, Caballero-García, A, Bello, HJ, et al. (2022) L-Arginine and beetroot extract supplementation in the prevention of sarcopenia. Pharmaceuticals 15, 290.CrossRefGoogle ScholarPubMed
Burgos, J, Viribay, A, Calleja-González, J, et al. (2022) Long-term combined effects of citrulline and nitrate-rich beetroot extract supplementation on recovery status in trained male triathletes: a randomized, double-blind, placebo-controlled trial. Biology 11, 75.CrossRefGoogle ScholarPubMed
Siervo, M, Shannon, O, Kandhari, N, et al. (2020) Nitrate-rich beetroot juice reduces blood pressure in Tanzanian adults with elevated blood pressure: a double-blind randomized controlled feasibility trial. J Nutr 150, 24602468.CrossRefGoogle ScholarPubMed
Blekkenhorst, LC, Lewis, JR, Prince, RL, et al. (2018) Nitrate-rich vegetables do not lower blood pressure in individuals with mildly elevated blood pressure: a 4-week randomized controlled crossover trial. Am J Clin Nutr 107, 894908.CrossRefGoogle ScholarPubMed
Aucouturier, J, Boissière, J, Pawlak-Chaouch, M, et al. (2015) Effect of dietary nitrate supplementation on tolerance to supramaximal intensity intermittent exercise. Nitric Oxide 49, 1625.CrossRefGoogle ScholarPubMed
Arazi, H & Eghbali, E (2021) Possible effects of beetroot supplementation on physical performance through metabolic, neuroendocrine, and antioxidant mechanisms: a narrative review of the literature. Front Nutr 8, 660150.CrossRefGoogle ScholarPubMed
Vanhatalo, A, Bailey, SJ, Blackwell, JR, et al. (2010) Acute and chronic effects of dietary nitrate supplementation on blood pressure and the physiological responses to moderate-intensity and incremental exercise. Am J Physiol Regul Integr Comp Physiol 299, R1121R1131.CrossRefGoogle ScholarPubMed
Clerc, P, Rigoulet, M, Leverve, X, et al. (2007) Nitric oxide increases oxidative phosphorylation efficiency. J Bioenerg Biomembr 39, 158166.CrossRefGoogle ScholarPubMed
Domínguez, R, Maté-Muñoz, JL, Cuenca, E, et al. (2018) Effects of beetroot juice supplementation on intermittent high-intensity exercise efforts. J Int Soc Sports Nutr 15, 2.CrossRefGoogle ScholarPubMed
Wong, TH, Sim, A & Burns, SF (2021) The effect of beetroot ingestion on high-intensity interval training: a systematic review and meta-analysis. Nutrients 13, 3674.CrossRefGoogle ScholarPubMed
Williams, TD, Martin, MP, Mintz, JA, et al. (2020) Effect of acute beetroot juice supplementation on bench press power, velocity, and repetition volume. J Strength Cond Res 34, 924928.CrossRefGoogle ScholarPubMed
Mosher, SL, Sparks, SA, Williams, EL, et al. (2016) Ingestion of a nitric oxide enhancing supplement improves resistance exercise performance. J Strength Cond Res 30, 35203524.CrossRefGoogle ScholarPubMed
Gonzalez, AM, Accetta, MR, Spitz, RW, et al. (2021) Red spinach extract supplementation improves cycle time trial performance in recreationally active men and women. J Strength Cond Res 35, 25412545.CrossRefGoogle ScholarPubMed
Jonvik, KL, Nyakayiru, J, Van Dijk, JW, et al. (2018) Repeated-sprint performance and plasma responses following beetroot juice supplementation do not differ between recreational, competitive and elite sprint athletes. Eur J Sport Sci 18, 524533.CrossRefGoogle Scholar
Wylie, LJ, Kelly, J, Bailey, SJ, et al. (2013) Beetroot juice and exercise: pharmacodynamic and dose-response relationships. J Appl Physiol 115, 325336.CrossRefGoogle ScholarPubMed
Tatlici, A & Cakmakci, OJMDS (2019) The effects of acute dietary nitrate supplementation on anaerobic power of elite boxers. Med Dello Sport 72, 225233.Google Scholar
Stanaway, L, Rutherfurd-Markwick, K, Page, R, et al. (2019) Acute supplementation with nitrate-rich beetroot juice causes a greater increase in plasma nitrite and reduction in blood pressure of older compared to younger adults. Nutrients 11, 1683.CrossRefGoogle ScholarPubMed
Clifford, T, Howatson, G, West, DJ, et al. (2015) The potential benefits of red beetroot supplementation in health and disease. Nutrients 7, 28012822.CrossRefGoogle ScholarPubMed
Kayın, N, Atalay, D, Türken Akçay, T, et al. (2019) Color stability and change in bioactive compounds of red beet juice concentrate stored at different temperatures. J Food Sci Technol 56, 50975106.CrossRefGoogle ScholarPubMed
Domínguez, R, Cuenca, E, Maté-Muñoz, JL, et al. (2017) Effects of beetroot juice supplementation on cardiorespiratory endurance in athletes. A systematic review. Nutrients 9, 43.CrossRefGoogle ScholarPubMed
Ceclu, L & Nistor, O (2020) Red beetroot: composition and health effects—a review. J Nutr Med Diet Care 6, 19.Google Scholar
Rolls, BJ (2017) Dietary energy density: applying behavioural science to weight management. Nutr Bull 42, 246253.CrossRefGoogle ScholarPubMed
Figure 0

Fig. 1. Flow chart of study selection for inclusion trials in the systematic review.

Figure 1

Table 1. Characteristic of included studies in meta-analysis(Mean values and standard deviations)

Figure 2

Table 2. Risk of bias assessment

Figure 3

Table 3. Subgroup analyses of beetroot (BR) juice on anthropometric indices in adults(95 % confidence intervals)

Figure 4

Fig. 2. Forest plot detailing weighted mean difference and 95 % CI for the effect of beetroot or nitrate intake on (a) body weight (kg); (b) BMI (kg/m2), (c) waist circumference (cm), (d) fat mass (kg), (e) body fat percentage (%), (f) fat-free mass (kg) and (g) waist-to-hip ratio.

Figure 5

Fig. 3. Funnel plots for the effect of beetroot or nitrate intake on (a) body weight (kg); (b) BMI (kg/m2), (c) waist circumference (cm), (d) fat mass (kg), (e) body fat percentage (%), (f) fat-free mass (kg) and (g) waist-to-hip ratio.

Figure 6

Table 4. Sensitivity analysis and publication bias

Figure 7

Table 5. GRADE profile of beetroot (BR) intake for anthropometric indices(95 % confidence intervals)