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Article

Impact of Natural Juice Consumption on Plasma Antioxidant Status: A Systematic Review and Meta-Analysis

by
Fernanda S. Tonin
1,
Laiza M. Steimbach
1,
Astrid Wiens
1,
Cássio M. Perlin
2 and
Roberto Pontarolo
1,*
1
Department of Pharmacy, Pharmaceutical Sciences Postgraduate Program, Universidade Federal do Paraná, Av. Prof. Lothario Meissner 632, 80210-170 Curitiba, Brazil
2
Department of Pharmacy, Postgraduate Program in Pharmaceutical Care, Universidade Federal do Rio Grande do Sul, Av. Paulo Gama 110, 90040-060 Porto Alegre, Brazil
*
Author to whom correspondence should be addressed.
Molecules 2015, 20(12), 22146-22156; https://doi.org/10.3390/molecules201219834
Submission received: 27 October 2015 / Revised: 13 November 2015 / Accepted: 17 November 2015 / Published: 10 December 2015
(This article belongs to the Special Issue Antioxidants—A Risk-Benefit Analysis for Health)
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Abstract

:
Background: Oxidative stress may lead to overproduction of reactive species and a decrease in antioxidant defenses, resulting in chronic diseases such as diabetes and cancer. The consumption of natural compounds with an antioxidant profile may be a preventive alternative. Therefore, we aimed to obtain evidence regarding the potential antioxidant activity of juices in human plasma. Methods: A systematic review and meta-analysis was performed, which included randomized controlled trials that compared the use of fruit or vegetable juices vs. placebo or other beverages. An electronic search was conducted in PubMed, Scopus, International Pharmaceutical Abstracts, and SciELO. The outcome measures extracted were related to antioxidant status, e.g., vitamin C, superoxide dismutase (SOD), and catalase (CAT) levels and reduction in malondialdehyde (MDA) and antioxidant capacity measured as TEAC. Results: Twenty-eight trials were identified (n = 1089), of which 16 were used for meta-analysis. No significant differences were observed between juices and placebo with regard to TEAC, SOD, and CAT. However, juices were superior to control in enhancing vitamin C and reducing MDA. Conclusions: Natural juices are possible candidates for the management of oxidative stress. The effects of juices should be further investigated by conducting larger and well-defined trials of longer duration.

1. Introduction

Oxidative stress is characterized by an imbalance between the production of reactive species and antioxidant defense activity, and enhancement of oxidative stress has been associated with many conditions and chronic diseases such as cancer, diabetes, pulmonary disorders, neurodegenerative (e.g., Alzheimer’s disease) and cardiovascular diseases, and aging [1,2].
Antioxidant agents prevent oxidative stress and its consequences in cells and tissues (e.g., lipid peroxidation) that culminate in diseases. An antioxidant is a molecule that is sufficiently stable to donate an electron to a rampaging free radical and neutralize it. The antioxidants delay or inhibit cellular damage mainly through their free radical scavenging property and can safely interact with free radicals and terminate the chain reaction before vital molecules are damaged. Some such antioxidants, including glutathione, ubiquinol, and uric acid, are produced during normal metabolism. Other antioxidants are obtained from the diet [1,3].
Many research groups have analyzed the antioxidant properties of natural products. These properties have been investigated through chemical or biological methods, or both. It has been suggested that the consumption of food rich in antioxidants can retard or avoid the occurrence of many diseases [2,4].
In this context, there has been growing appreciation and understanding of the link between fruit and vegetable consumption and improved health. Biologically active components in plant-based foods, such as redox-active antioxidants (polyphenols, carotenoids, tocopherols, vitamins C and E, glutathione) and enzymes (superoxide dismutase (SOD) and catalase (CAT)) with antioxidant activity have high potential for modulating many processes during the development of diseases [5,6].
Guidelines for health promotion and disease prevention in the United States and around the world include recommendations to consume a variety of fruits and vegetables each day, since they provide significant quantities of nutrients, especially vitamins, sugars, minerals, and fiber [6,7,8].
An alternative way to consume proper amounts of fruits and vegetables is to choose beverages such as juices. During the last few years, the demand for these beverages has been increasing in several countries [4]. This may be attributed to change in dietary habits, taste preferences, and the way of life of present-day consumers [9].
Although it is universally accepted that fruit and vegetable intake can provide protective antioxidant status, there is no clear consensus about the effects of juice consumption on oxidative stress in humans. Many epidemiological studies have supported their beneficial effects, but large-scale double-blind, randomized, controlled clinical intervention studies and meta-analyses have not yet confirmed this premise [10].
Therefore, we conducted a systematic review and meta-analysis of all published randomized controlled trials (RCTs) to obtain evidence and provide a more precise estimate of the effect of fruit and vegetable juices on antioxidant status in human plasma, which could support their beneficial effects.

2. Results and Discussion

Through electronic searches, 1117 studies were retrieved after exclusion of duplicates. During the screening process (reviewing of titles and abstracts), 1038 records were excluded. After full-text analysis, 51 articles were excluded (Table S1, Appendix 1, see in Supplementary Materials); thus, 28 studies that were suitable for performing qualitative and quantitative analyses were obtained (Figure 1).
Molecules 20 19834 g001 550
Figure 1. Flowchart of included Randomized Controlled Trials.
Figure 1. Flowchart of included Randomized Controlled Trials.
Molecules 20 19834 g001
The 28 studies (n = 1089) included evaluated the effects of consumption of fruit or vegetable juices on healthy people or patients who had chronic diseases or a debilitating condition (e.g., diabetes, cancer, hemodialysis) [11,12,13,14,15,16,17,18,19,20,21,22,23,24,25,26,27,28,29,30,31,32,33,34,35,36,37,38]. Most studies (75%) utilized a parallel design and 17 of them used a placebo juice (mainly composed by flavored water and sucralose) for comparison. Another three studies used water as placebo and in eight studies an active control—another juice—was employed. The mean age of the subjects was 44.07 years (standard deviation 4.70) with a range between 20–70 years. The mean treatment duration was 3.6 weeks and intervention juices dosage ranged from 100 mL to 1000 mL daily. Juices compositions also varied among studies (e.g., derived from fruit and vegetables such as carrot, tomato, orange, different types of berries, grapes) (Table 1).
The quality assessment showed overall poor quality, resulting in a mean Jadad score [39] of 2.25 (range 1–4) (Table S2). All the studies scored, at least, on randomization and some trials were double-blinded. However, few studies described those methods properly and accounted for patient’s withdrawals or dropouts. Moreover, considering the risk of bias instrument, studies often failed to provide details about randomization procedures, allocation concealment, or blinding of participants and outcome assessments. More than 70% of studies (n = 20) were funded by industries or organization or presented conflicts of interest (Figures S2 and S3).
From the 28 eligible studies, 16 could be included in one or more meta-analysis of intervention vs. placebo, since they reported properly data for the outcomes measures related to antioxidant plasma activity or oxidative stress. The measures included weight gain during study (mean difference, MD from baseline); levels of the antioxidants vitamin C, SOD, and CAT; analysis of the biomarker malondialdehyde (MDA) related to lipid peroxidation and TEAC (Trolox-equivalent antioxidant capacity).
The study by Khan (2014) [26] was divided in two parts (a, b) for analysis since it reports two concentrations of intervention juices (low blackcurrant and high blackcurrant juices, respectively) against placebo. For the trials that reported data on mean change from baseline for TEAC, SOD, or CAT (Figure 2A–C), no significant differences were found in the subjects who received juice supplements, as compared to control subjects, with standardized mean differences (SMD) effects (95% confidence interval (CI)), 0.17 (−0.26, 0.59), −1.49 (−25.69; 22.71), and 0.71 (−0.26; 1.67), respectively).
In addition, the mean weight change was reported in eight trials and was not significantly different between intervention and placebo (0.08 [−0.11, 0.26]). The effects of juice consumption on increasing levels of vitamin C and reduction of MDA were significantly different compared to those of placebo and in favor to intervention; the values of SMD (95% CI) were 1.46 (0.53, 2.39) and −1.48 (−2.39, −0.58), respectively (Figure 2D–F). These positive results came mostly from studies where the interventions were fruits juices (pomegranate [35,36], grapes [32], cranberries [12], and blackcurrants [26]). One study report data on tomato juice [21].
Some of the meta-analyses (increased vitamin C, MDA reduction, and CAT) presented I2 values higher than 50%, which represents a high heterogeneity between studies. The sensitivity analysis showed that more than one study was responsible for the increase in I2. This heterogeneity is acceptable and could be explained by the intrinsic characteristics of the included studies, conduction and design of trials, and type of intervention and outcomes analyzed.
Overall, our systematic review and meta-analysis showed that juices can have health benefits since their consumption significantly affected the plasma concentration of an antioxidant agent (vitamin C) and reduced MDA levels. Fruits, especially berries and pomegranate, showed greater association with these benefits.
Molecules 20 19834 g002a 550Molecules 20 19834 g002b 550
Figure 2. Forest plot for the outcome measures related to antioxidant status in the human plasma. Mean change from baseline for (A): Trolox equivalent antioxidant capacity (TEAC); (B) superoxide dismutase enzyme (SOD); (C): catalase enzyme (CAT). Statistical method: Mean difference (MD) and standard mean difference (SMD) (IV, Random, 95% confidence interval (CI)). Test for overall effect was performed using Review Manager Software; (D): vitamin C increase; (E) MDA; (F) weight. Statistical method: SMD (IV, Random, 95% CI). Test for overall effect was performed using Review Manager Software.
Figure 2. Forest plot for the outcome measures related to antioxidant status in the human plasma. Mean change from baseline for (A): Trolox equivalent antioxidant capacity (TEAC); (B) superoxide dismutase enzyme (SOD); (C): catalase enzyme (CAT). Statistical method: Mean difference (MD) and standard mean difference (SMD) (IV, Random, 95% confidence interval (CI)). Test for overall effect was performed using Review Manager Software; (D): vitamin C increase; (E) MDA; (F) weight. Statistical method: SMD (IV, Random, 95% CI). Test for overall effect was performed using Review Manager Software.
Molecules 20 19834 g002aMolecules 20 19834 g002b
Table
Table 1. Characteristics of included studies.
Table 1. Characteristics of included studies.
Study (Ref.)No. of SubjectsCountryStudy DesignPopulationInterventionControlDurationGender (M/F)Age (Years) ± SD
Amagase [11]50ChinaParallelHealthy individualsGoji berry juice 60 mL twice dailyPlacebo juice1 month25 M: 25 F58.1 ± 4.8
Basu [12]36USAParallelHealthy women with metabolic syndromeCranberry juice 240 mL twice dailyPlacebo juice8 weeks36 F52.0 ± 8.0
Brivida [13]22GermanyCrossoverHealthy individualsTomato juice 330 mL dailyCarrot juice 330 mL/day2 weeks22 M-
Bub [14]27GermanyCrossoverHealthy individualsJuice A (mix of apple, mango, orange and blueberries)Juice B (mix of apple, mango orange, lime and apricot)2 weeks27 M35.0 ± 4.0
Butalla [15]68USAParallelOverweight breast cancer survivorsOrange carrot juicePurple carrot juice3 weeks68 F56.5 ± 8.0
Castilla [17]38SpainParallelHemodialysis patientsRed grape juice 50 mL twice dailyPlacebo juice2 weeks19 M: 19 F60.6 ± 3.6
Castilla [16]16SpainParallelHemodialysis patientsRed grape juice 50 mL twice dailyPlacebo juice2 weeks8 M: 8 F33–79
Duthie [18]20UKParallelHealthy individualsCranberry juice 250 mL three time dailyPlacebo juice2 weeks20 F27.8 ± 7.0
Ellinger [19]12GermanyCrossoverHealthy individualsJuice blend (acai, camu-camu, blackberry) 400 mL dailyPlacebo juice1 day6 M: 6 F33.0 ± 7.0
García-Alonso [20]18SpainParallelHealthy individualsTomato juice 300 mL dailyN-3 PUFA-enriched tomato juice 300 mL daily2 weeks18 F35–55
Ghavipour [21]64IranParallelHealthy overweight or obese womenTomato juice 330 mL dailyPlacebo (water)20 days64 F25.3 ± 0.7
Guo [22]26ChinaParallelHealthy elderly individualsPomegranate juice 250 mL dailyApple juice 250 mL daily4 weeks20 M: 6 F63.4 ± 4.5
Guo [23]44ChinaCrossoverPatients with fatty liver diseaseBayberry juice 250 mL twice dailyPlacebo juice2 weeks12 M: 32 F21.2 ± 1.2
Jacob [24]24GermanyParallelHealthy individualsTomato juice lycopene enriched 250 mL twice dailyTomato juice vitamin C enriched 250 mL twice daily2 weeks4 M: 20 F19–23
Karlsen [25]63NorwayParallelHealthy individuals with cardiovascular disease riskBilberry juice 330 mL dailyPlacebo (water)4 weeks46 M: 17 F50–70
Khan [26]64UKParallelHealthy individualsBlackcurrant juice (low and high concentration) 250 mL four times per dayPlacebo juice6 weeks43M: 21 F52.3 ± 9.7
Kuntz [27]30GermanyCrossoverHealthy individualsJuice (red grapes and bilberries) 330 mL dailyPlacebo juice2 weeks30 F24.0 ± 1.2
Lee [28]32KoreaParallelSmokersCarrot juice 300 mL dailyPlacebo juice8 weeks-35.6 ± 2.2
Lynn [29]51UKParallelHealthy individualsPomegranate juice 330 mL dailyPlacebo juice4 weeks16 M: 35 F37.5 ± 1.1
Mathison [30]12USACrossoverHealthy individualsCranberry juicePlacebo juice1 day6M: 6F27.5 ± 1.3
Parashar [31]26IndiaParallelHealthy elderly individualsPomegranate juice 250 mL dailyOrange juice 250 mL daily4 weeks20M: 6 F63.5 ± 4.5
Park [32]40KoreaParallelHealthy individuals with borderline hypertensionGrape juice 400 mL dailyPlacebo juice8 weeks40 M44.5 ± 2.0
Pourhamdi [33]80AzerbaijanParallelHealthy overweight or obese womenTomato juice 330 mL dailyPlacebo (water)20 days80 F20–30
Sabitha [34]33IndiaParallelDiabetic mellitus type 2 patientsNoni juice 30 mL dailyPlacebo juice21 days17 M: 16 F-
Shema-Didi [35]101IsraelParallelHemodialysis patientsPomegranate juice 100 mL dailyPlacebo juice12 months55 M: 46 F66.7 ± 12.1
Sohrab [36]44IranParallelDiabetic mellitus type 2 patientsPomegranate juice 250 mL dailyPlacebo juice12 weeks23 M: 21 F56.0 ± 6.8
Soriano [37]20SpainCrossoverHealthy individualsApple juice, vitamin C enriched 250 mL twice dailyApple juice polyphenol enriched 250 mL twice daily2 weeks8 M: 12 F23.5 ± 2.1
Uprichard [38]28New ZealandParallelDiabetic mellitus type 2 patientsTomato juice 250 mL twice dailyPlacebo juice4 weeks20 M: 8 F61.5 ± 7.0
Although there are many studies in the literature on the preventive role of pomegranate in metabolic syndrome, obesity, hypertension, and cardiovascular disease, and other diseases, a cause and effect relationship between the consumption of fruit juice and the claimed health effects has not been established yet. It may be related to some antioxidant compounds, such as vitamin C [40,41,42,43,44]. In addition, grape and berry juices are rich sources of the antioxidant flavonoids catechin, epicatechin, quercetin, and anthocyanins. Some human studies showed promising antioxidant activity results with these fruits. However, limitations included the sample size, short duration of supplementation, and the fact that only few indexes of antioxidant status were measured in clinical trials [8,45].
In our meta-analysis, other antioxidant agents (SOD, CAT) and the TEAC levels were not influenced by beverage intake. A possibility is that fruit juice intervention might modestly increase the subject’s antioxidant capacity, which can also be influenced by diet, daily dosage of juice (which may or may not reflect phytochemical bioavailability), the participant’s baseline characteristics, and health conditions. The RCTs included in the analysis presented significant differences in sample size and population particularities (e.g., age, sex, and clinical conditions). Most studies had limited sample sizes of varied gender and ethnicity, in addition to short treatment periods and a focus on early biomarkers rather than functional endpoints. Moreover, the effects of the intervention on cellular and tissue levels may not appear immediately. Antioxidant effects in vivo are dependent on the bioavailability of antioxidants, as determined by uptake, distribution, metabolism, and excretion [10,45]. Therefore, the effects of juices in this study might be mildly underestimated.
Furthermore, our assessment of the effects of juices on other outcome measures related to oxidative stress and antioxidant capacity (e.g., FRAP (ferric reducing ability of plasma) assay, ORAC (oxygen radical absorbance capacity) assay, and LDL oxidation) was limited by the small number of studies currently available on this topic. Because of the difficulty in measuring each antioxidant component separately and interactions among antioxidants, these assays have been developed to measure the total antioxidant capacity of serum or plasma. Although some included studies reported data on these assays, there is a lack of standardization in proper reporting of data (e.g., measurement units) in the case of these methods in clinical trials and this can be a barrier to gathering evidence [8,40,46].
Concerning other effects of juices, it is known that drinks contribute approximately 25%–50% of water intake; thus, they are important for meeting daily water needs and achieving hydration [47]. However, it has been argued that drinks contribute significantly to the increasing obesity rates worldwide, mainly because of their energy content and additionally supplemented sugars [47]. Weight gain and obesity are conditions related to oxidative stress. Concerning the meta-analysis of weight change, no differences were observed between interventions and placebo for any included study. Therefore, the daily consumption of juices, while avoiding excess consumption, is recommended.
The accumulating evidence for the involvement of oxidative stress in the pathogenesis of various diseases is an expanding field for scientists and health professionals. The studies examining the effect of juice consumption are varied in design and methodology. Natural antioxidants from fruits and vegetables present beneficial effects supported mostly by epidemiological studies [10,44]. Hence, they should be investigated further by well-designed, large-scale double-blind, randomized, controlled clinical trials and in other meta-analyses. In addition, extension studies should be performed in order to demonstrate the effects of interventional juices over time and in safety parameters (such as related to adverse events, allergies or problems of juice consumption) for participants.

3. Experimental Section

To conduct the systematic review, searches were performed in PubMed, Scopus, International Pharmaceutical Abstracts and SciELO, along with manual searching, in July 2015 with no time limits. The following search terms were used: clinical, trial, random*, antioxidant*, juice, beverage in combination with the Boolean operators AND and OR. We included RCTs conducted in human subjects, comparing the consumption of any fruit or vegetable juice with placebo, water or other controlled drink. Articles published in non-Roman characters were excluded. Following PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) recommendations, [48] titles and abstracts of records retrieved were initially screened and the full text of those considered relevant were then analyzed. The literature selection process was conducted by two independent reviewers, with a third reviewer in case of discrepancies.

3.1. Data Extraction and Quality Assessment

Data on the mean change of levels of SOD and CAT enzymes, as well as vitamin C, were collected as the outcome measures. These substances are antioxidant agents that protect cells and tissues from free radical damage. Another outcome measure extracted from the articles was the results on MDA changes. This substance is an oxidant marker of lipid peroxidation and its reduction in plasma is beneficial. Data from the TEAC, as a method to assess the global antioxidant plasma capacity, were also extracted [44,46].
Mean change from baseline in the weight of subjects was another main outcome since overweight and obesity can be related to chronic diseases and oxidative stress [10,43]. Two researchers performed data extraction independently, with a third reviewer resolving any discrepancies. The quality of the included studies was evaluated using two different tools: The Jadad Scale [39] and the Cochrane Collaboration’s tool for assessing the risk of bias [49]. The results of the quality assessment were used to derive conclusions accordingly, but no studies were excluded.

3.2. Data Analysis

When possible, pairwise meta-analysis of the included RCTs using a placebo as comparator were performed for the main outcome measures. For each meta-analysis, the primary effect size was the MD or SMD and its 95% CI. Pool effect size was calculated using the inverse variance method (fixed or random effects model) and p < 0.05 (two-tailed) was considered statistically significant. Between-trial heterogeneity was estimated using the I2 measure (I2 > 50%, significant heterogeneity) [50]. To evaluate the impact of any study on data heterogeneity, sensitivity analyses consisting of the hypothetical sequential removal of one study at a time were done. Statistical analysis was performed using Review Manager version 5.1 (The Nordic Cochrane Centre, The Cochrane Collaboration, Copenhagen, Denmark).

4. Conclusions

Collectively, the data presented in this systematic review and meta-analysis suggest that some potential health-related and disease prevention markers associated with consumption of juices should be further investigated.
Some types of fruit and vegetable juices could increase the antioxidant capacity in the plasma of healthy individuals and patients with chronic conditions, as evidenced by the increase of vitamin C levels and decrease in MDA. These data showed a potential function of juices as antioxidant beverages. Further studies are still needed to clarify the molecular processes and signaling pathways involved in the antioxidant capacity of fruit and vegetables juices in the human body.
Despite this potential, there are many unanswered questions related to fruit and vegetables juices and health in humans. There is a clear need for larger, well-controlled studies of longer duration with well-defined outcomes. Furthermore, it is important to determine an appropriate dose of juices that reflects bioavailability of phytochemicals and antioxidant agents in human plasma. The implications of the baseline health status should also be considered, since healthy individuals and patients with chronic conditions may not have the same antioxidant status.

Supplementary Materials

Supplementary materials can be accessed at: https://www.mdpi.com/1420-3049/20/12/19834/s1.

Acknowledgments

This project was supported by the Federal University of Paraná Postgraduate Research Programme. This funding source provided funds for a research assistant only.

Author Contributions

Author F.S.T. and R.P. designed the study and wrote the protocol; literature searches and analyses were completed by F.S.T. and L.M.S. and supervised by A.W.; and F.S.T., L.M.S. and A.W. undertook the statistical analysis, and C.M.P. confirmed all analysis; and F.S.T. and R.P. wrote the first draft of the manuscript. All authors edited and contributed to drafts of the manuscript. All authors approved the final draft of the manuscript.

Conflicts of Interest

The authors declare no conflict of interest.

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MDPI and ACS Style

Tonin, F.S.; Steimbach, L.M.; Wiens, A.; Perlin, C.M.; Pontarolo, R. Impact of Natural Juice Consumption on Plasma Antioxidant Status: A Systematic Review and Meta-Analysis. Molecules 2015, 20, 22146-22156. https://doi.org/10.3390/molecules201219834

AMA Style

Tonin FS, Steimbach LM, Wiens A, Perlin CM, Pontarolo R. Impact of Natural Juice Consumption on Plasma Antioxidant Status: A Systematic Review and Meta-Analysis. Molecules. 2015; 20(12):22146-22156. https://doi.org/10.3390/molecules201219834

Chicago/Turabian Style

Tonin, Fernanda S., Laiza M. Steimbach, Astrid Wiens, Cássio M. Perlin, and Roberto Pontarolo. 2015. "Impact of Natural Juice Consumption on Plasma Antioxidant Status: A Systematic Review and Meta-Analysis" Molecules 20, no. 12: 22146-22156. https://doi.org/10.3390/molecules201219834

APA Style

Tonin, F. S., Steimbach, L. M., Wiens, A., Perlin, C. M., & Pontarolo, R. (2015). Impact of Natural Juice Consumption on Plasma Antioxidant Status: A Systematic Review and Meta-Analysis. Molecules, 20(12), 22146-22156. https://doi.org/10.3390/molecules201219834

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