Effects of Nutritional Supplements on Explosive Lower Limb Performance in Volleyball Players: A Systematic Review and Network Meta-Analysis

This review was conducted and reported in accordance with PRISMA 2020 and the PRISMA extension for Network Meta-Analyses (PRISMA-NMA). The protocol was prospectively registered in PROSPERO (CRD420251084241).

A systematic search was conducted in PubMed, Web of Science Core Collection, the Cochrane Central Register of Controlled Trials (CENTRAL), and Embase from inception to 1 August 2025, with no language restrictions. The full search syntax for PubMed was as follows: (“volleyball”[MeSH Terms] OR “volleyball”[All Fields]) AND (“caffeine”[All Fields] OR “beta-alanine”[All Fields] OR “magnesium”[All Fields] OR “grape juice”[All Fields] OR “iron”[All Fields] OR “creatine”[All Fields] OR “nutritional supplementation”[All Fields]) AND (“performance”[All Fields] OR “jump”[All Fields] OR “power”[All Fields] OR “strength”[All Fields] OR “skill”[All Fields]) AND (“randomized controlled trial”[Publication Type] OR “Randomized Controlled Trial”[MeSH Terms] OR “randomized”[All Fields]). Complete search strategies for all databases are provided in. Two reviewers (H.D. and S.L.) independently executed the search and screened records; disagreements were resolved by a third reviewer (M.L.), with consultation of a senior author (C.L.) when necessary. The full electronic search strategies are provided in. Supplementary Material S1 Tables S1–S4 Supplementary Material S1

Inclusion criteria. We included peer-reviewed, full-text randomized controlled trials enrolling volleyball athletes aged ≥14 years; participants of both sexes were included. Eligible interventions were pre-specified, commonly used dietary supplements intended to enhance lower limb performance; a total of 13 supplements met the inclusion criteria through a comprehensive literature search: β-alanine, creatine, caffeine, branched-chain amino acids, β-hydroxy-β-methylbutyrate, magnesium, beetroot juice, protein, carbohydrate, energy drinks, probiotics, L-citrulline, and grape juice. Comparators were placebo or usual practice and, where applicable, active comparators (other eligible supplements). Primary outcomes were objective, volleyball-relevant performance measures assessed with validated tests—vertical jump, lower limb peak power, lower limb mean power—plus adverse events. For interpretability, units and effect directions were harmonized a priori.

Exclusion criteria. We excluded non-randomized designs; non-volleyball samples; trials involving prohibited substances per the contemporaneous WADA Prohibited List; studies reporting only biochemical or purely subjective outcomes without any objective performance endpoint; secondary research (systematic reviews, narrative reviews, and meta-analyses), conference abstracts without full data, and studies with insufficient quantitative information for synthesis. For cross-over RCT, an adequate washout was required; multi-arm trials were eligible if data permitted appropriate analysis.

Records retrieved from all databases were imported into EndNote 20 for automated and manual de-duplication. Screening proceeded in three stages: (1) Title or abstract screening was performed by two independent reviewers (H.D. and S.L.), with uncertain records deliberately retained to minimize erroneous exclusions, and (2) any disagreements between the two independent reviewers were resolved through discussion with a third reviewer (M.L.). We did not formally calculate inter-rater agreement (e.g., kappa), but consensus was reached on all included studies after discussion, and (3) the final inclusion was made according to the pre-specified criteria.

Two reviewers (H.D. and S.L.) independently extracted data using a pilot-tested electronic form; disagreements were resolved by a third reviewer (C.L.). Extracted domains included the following: (1) study characteristics (publication year, country/region, design, and study period, where applicable); (2) participant characteristics (sample size, age, sex, competitive level, height, and body mass); (3) intervention details (supplement identity, dose and timing, and duration); (4) performance outcomes (vertical jump, lower limb peak power, and lower limb mean power); and (5) adverse events. When data were available only in graphical form, values were digitized using WebPlotDigitizer v5.2. Prior to synthesis, units and effect directions were harmonized (e.g., vertical jump in cm, agility time in s).

The primary outcome was vertical jump (cm), chosen for its direct relevance to spiking or blocking performance [1] and its widespread use with good test–retest reliability; secondary outcomes included lower limb peak power and lower limb mean power. When multiple jump tests were reported, we prioritized the countermovement jump (CMJ) as the primary vertical jump measure due to its widespread use and excellent reliability in volleyball performance testing, followed by the squat jump (SJ) if CMJ was not reported, and other jump tests thereafter. Effect sizes used MD for the same units or SMD otherwise, with directions harmonized so that higher values indicate better performance.

Risk of bias for RCT was appraised using RoB 2.0, covering five domains: randomization process, deviations from intended interventions, missing outcome data, measurement of the outcome, and selection of the reported result. Two reviewers performed independent domain-level judgments, with overall risk generated via the RoB 2.0 algorithm; disagreements were adjudicated by a third reviewer. Publication bias was evaluated using funnel plots and Egger’s regression test for outcomes with ≥10 studies. Confidence of evidence for network estimates was evaluated using CINeMA, considering within-study bias, reporting bias, indirectness, imprecision, heterogeneity, and incoherence, with an overall certainty rating reported for each outcome. Transitivity was assessed by comparing the distribution of potential effect modifiers (e.g., age, competitive level, dosing regimens, and testing protocols) across studies contributing direct and indirect evidence.

We conducted a random-effects network meta-analysis (NMA) under a Bayesian framework, implemented in R (v3.6.1) using gemtc (v0.8-2), which interfaces with JAGS (v4.3.0) for Markov chain Monte Carlo (MCMC) estimation. A Bayesian approach enables flexible modeling, coherent borrowing of strength across the evidence network, and probabilistic interpretation of treatment effects and ranking, which can be more informative for clinicians and coaches than traditional p-values.

Continuous outcomes were analyzed as mean differences (MD) when scales were common; otherwise, standardized mean differences (SMD; Hedges’ g) were used. Units were harmonized a priori: vertical jump (cm), lower limb peak power, and lower limb mean power (W). Outcome directions were aligned so that higher values indicated improvement. When trials reported multiple post-intervention assessments, we used the protocol-defined primary time window (earliest post-intervention), and we examined later time points in sensitivity analyses. Where only p-values, t-statistics, or CI were reported, we reconstructed standard errors and 95% confidence intervals (CIs) using established transformations; network estimates from the Bayesian model are reported with 95% credible intervals (CrIs). We interpreted I² < 40% as low heterogeneity, 40–75% as moderate, and >75% as substantial heterogeneity, in line with Cochrane guidelines.

Crossover trials were included only if an adequate washout period was reported; data from the end of each intervention period (after washout) were treated as if from a parallel design. For multi-arm trials, we either merged equivalent intervention arms (using established formulas for means and SDs to avoid double-counting controls) or, if arms were distinct, we included them as separate nodes with the Bayesian model accounting for the shared control group correlation.

Model specification and selection. We fitted both fixed-effect and random-effects Bayesian NMA models. Model adequacy was compared using the deviance information criterion (DIC) together with summaries of residual deviance and leverage; a DIC difference <3–5 was considered negligible, otherwise the model with the lower DIC was preferred. Given between-study heterogeneity in populations, protocols, and dosing schedules, the random-effects model was retained for all primary analyses.

Priors and MCMC. Unless stated otherwise, treatment effects used weakly informative Normal (0, 10⁴) priors and the heterogeneity SD used a Uniform prior; sensitivity analyses with alternative heterogeneity priors (e.g., half-Normal) yielded similar inferences. We ran 4 parallel chains with 5000 adaptation/burn-in iterations followed by 25,000 sampling iterations per chain. Convergence was assessed by trace/density plots and Gelman–Rubin R-hat (all ≤1.05), and by ensuring Monte Carlo SE was small relative to the posterior SD (target MCSE < 10%). Effective sample sizes are reported in the Supplement. Sensitivity analyses using alternative priors for heterogeneity (e.g., half-Normal distributions) were conducted to assess robustness, and the results remained consistent across specifications.

Transitivity, consistency, and ranking. The transitivity assumption was evaluated through both qualitative and quantitative approaches. First, we systematically compared the distributions of potential effect modifiers (including age, sex, training status, and baseline performance) across treatment comparisons. Second, we employed statistical tests for inconsistency (design-by-treatment interaction and node-splitting analyses) as indirect assessments of transitivity. The absence of significant inconsistency (all p > 0.05) in these analyses supports the validity of the transitivity assumption in our network. Global inconsistency was assessed with the design-by-treatment interaction test, and local inconsistency was checked via node-splitting (with a threshold p-value for significance). Treatments were ranked using SUCRA (Surface Under the Cumulative Ranking) alongside mean ranks and a 95% CrI; SUCRA values range from 0% to 100%, where 100% indicates a treatment that is certain to be the top performer and 0% indicates it is certain to be the worst performance, and rankings were interpreted as probabilistic summaries, not as evidence of statistical significance per se.

Sensitivity analyses. We (i) excluded trials judged overall high risk of bias by RoB 2.0 (two independent reviewers; with any disagreements resolved by a third independent reviewer); and (ii) explored an expanded network that incorporated trials from sports with matched testing protocols and effort durations (primary: badminton, and secondary: basketball/soccer). For (ii), we required identical test definitions/units/directions and examined transitivity by comparing age, competitive level, test protocol, and dosing regimen across direct/indirect contrasts. We interpreted this expansion exploratorily, focusing on whether treatment rankings and posterior means were materially altered.

Subgroups. We compared elite vs. non-elite athletes (a priori definitions based on competition level) and ≤21 vs. >21 years (aligned with FIVB adult–youth categorization) [25]. We report, for each split, the number of trials/participants and caution that subgroup inferences are underpowered where counts are small.

Network meta-regression. We fitted a Bayesian NMA with treatment–covariate interactions to test for effect modification by age group and competitive level. Covariates were mean-centered. We modeled interactions as exchangeable across treatments and used weakly informative priors on the interaction terms. Correlations from multi-arm trials were retained in the model. Given the limited number of trials, we prioritized parsimonious models and assessed the sensitivity of our conclusions to the choice of prior distributions.

Patients or members of the public were not involved in the design, conduct, reporting, or dissemination of this research because it synthesizes previously published trials.

The database search yielded 584 records (Figure 1). After de-duplication and title or abstract screening, 186 full-text articles were assessed for eligibility (Figure S1). The 35 included RCTs enrolled a total of 838 volleyball athletes, with sample sizes ranging from 8 to 48 participants per study (approximately 65% male). The interventions spanned durations of 1 to 10 weeks, and 13 distinct supplements were evaluated. The most frequently investigated supplements were caffeine (12 trials; 3–6 mg/kg). A detailed breakdown of all supplement doses and regimens is provided in Table 1. Participants had a mean age of 20.6 years (SD = 2.09), a mean body mass of 75.4 kg (SD = 7.7), and a mean stature of 180.9 cm (SD = 7.9); approximately 65% were male, and the mean sport-specific training experience exceeded 3 years (Table 1).

Sixteen supplements were initially identified; coenzyme Q10, iron, and zinc were excluded owing to the absence of eligible performance outcomes or the lack of a placebo-controlled comparator [61,62,63], and the study by Kartashev et al. was also excluded because of the unsuitable outcomes provided [64]. The final evidence network encompassed 13 interventions: branched-chain amino acids, β-alanine, caffeine, carbohydrates, β-Hydroxy-β-Methylbutyrate, creatine, magnesium, L-citrulline, beetroot, protein, energy drinks, and the placebo.

Domain-level risk of bias (RoB 2.0) is summarized in Figure 2. The most frequent limitations were incomplete reporting of allocation concealment and blinding (participants, personnel, and outcome assessors), and, in some cases, insufficient description of random sequence generation. Of the 35 RCTs assessed, 26 (74.3%) were deemed low risk in the randomization process domain; 25 (71.4%) were deemed low risk for deviations from intended interventions; 34 (97.1%) had no missing outcome data; and 30 (82.9%) were judged low risk for measurement of outcomes. Selective reporting was suspected in 4 (11.4%) studies, and 3 (8.6%) were rated overall high risk of bias (Figure 2, Supplementary Material S2 Figure S2).

These analyses revealed no evident asymmetry in the funnel plots, and the Egger’s test results (p > 0.05 for both outcomes) indicated no significant publication bias. For lower limb mean power, the limited number of available studies (<10) precluded a meaningful Egger’s test, though the corresponding funnel plot also showed no obvious asymmetry. All funnel plots and detailed statistical results have been provided in Supplementary Material S13.

Using CINeMA, confidence of evidence for network estimates was predominantly moderate or low (), with most downgrades attributable to imprecision (limited sample sizes and wide credible intervals), and, in selected comparisons, within-study bias and incoherence. The transitivity assumption appeared reasonable: distributions of key effect modifiers (e.g., age, sex, and competitive level) were broadly comparable across treatment contrasts, supporting the validity of indirect estimates (). Supplementary Material S9 Supplementary Material S9 Tables S9.1–S9.3

All Bayesian models demonstrated good convergence (Gelman–Rubin R-hat ≤ 1.05, with adequate effective sample sizes). Convergence diagnostics such as trace plots and R-hat values for all parameters are provided in Supplementary Materials S3 and S4. Node-splitting analyses detected no statistically significant local inconsistency for vertical jump, lower limb peak power (p > 0.05; Supplementary Material S5 Figures S5.1 and S5.2). For lower limb mean power, formal inconsistency testing was not feasible because the corresponding subnetwork lacked closed loops; results for this outcome should therefore be interpreted with caution.

These subgroup analyses are considered exploratory and hypothesis-generating, given the limited number of trials in each subset.

In the sensitivity analysis excluding high-risk-of-bias trials, the effect estimate for β-alanine on vertical jump was slightly attenuated (mean difference 4.1 cm, 95% CrI 0.8–7.5) compared to the primary analysis (4.6 cm), while β-alanine remained the top-ranked supplement (SUCRA 0.90). Similarly, the expanded network incorporating comparable testing protocols (primary: badminton; secondary: basketball and football) studies yielded comparable results (β-alanine MD 4.4 cm), confirming the robustness of our primary findings. () Supplementary Material S10

Network meta-regression did not identify competitive level or age group as significant effect modifiers for the primary outcomes (), suggesting no systematic modification of supplement effects by these characteristics. Supplementary Material S11

Competitive level. Among elite athletes, creatine significantly improved vertical jump height (MD 3.7; 95% CrI 0.14–7.45) and β-alanine increased lower limb peak power (SMD 1.33; 0.42–2.24). Among non-elite athletes, β-alanine significantly improved both vertical jump (MD 5.46; 0.75–10.02) and lower limb peak power (SMD 1.79; 0.56–3.01) (). Supplementary Material S12

Age. Using the FIVB age stratification, youth athletes exhibited a significant improvement in vertical jump with creatine (MD 3.53; 95% CrI 0.69 to 6.57); note that negative values denote improvement under the subgroup’s coding convention. Among adults, caffeine significantly increased vertical jump (MD 2.30; 0.27 to 4.32), and BCAA was associated with greater handgrip strength (MD 10.24; 7.22 to 13.28) (). Supplementary Material S13

Our study represents the first NMA specifically focused on volleyball athletes synthesizing the effects of 35 randomized controlled trials across different supplements for explosive lower limb performance and safety. Overall, β-alanine achieved the most favorable ranking and effect magnitude for vertical jump and lower limb peak power, followed by creatine and caffeine. On CINeMA, certainty ranged from low to moderate, with downgrades primarily for imprecision. While SUCRA values provide useful probabilistic rankings, it is crucial to emphasize that a higher rank does not necessarily indicate statistically significant or clinically meaningful differences between interventions.

From an applied standpoint, β-alanine and creatine could be utilized in training phases (e.g., 3.2–6.4 g/day for a 4–10 week loading protocol) to build explosive lower limb capacity, while caffeine (3–6 mg/kg) can be reserved for acute pre-match intake to yield immediate performance benefits.

Supplement efficacy appears to be moderated by training background, age, sport-specific demands, and nutritional baseline [96]. We explored whether supplement effects varied by competitive level and age. These analyses are exploratory and should be interpreted with caution, given limited study numbers and potential confounding with dosing, exposure duration, and test modality.

Competitive level. Signals suggested that creatine may yield larger gains in brief explosive tasks (e.g., vertical jump) among elite athletes—consistent with greater ATP-PCr turnover and the ability of well-trained competitors to translate small physiological advantages into performance-relevant outputs during short efforts [97]; operating closer to physiological ceilings, elite athletes can translate subtle physiological advantages into performance-relevant improvements during brief explosive efforts [98]. By contrast, the effects of β-alanine appeared more pronounced in non-elite athletes in our data, which is plausible if lower baseline carnosine allows a larger absolute increase with supplementation [16,99]. However, credible intervals were wide, and subgroup differences were not supported by robust interaction evidence; thus, these patterns are hypothesis-generating rather than confirmatory.

Age. Some evidence suggests that responsiveness to supplements may differ across youth vs. adult athletes [100]. In youth athletes, muscle creatine stores tend to be lower and neuromuscular plasticity higher; consequently, creatine may more readily augment muscle accretion, neural excitability, and vertical jump in adolescents [101]. By contrast, adults—having a higher baseline creatine—often exhibit smaller marginal returns to creatine, while demonstrating greater acute responsiveness to caffeine (potentially via more influential adenosine-receptor signaling) and thus relying more on immediate-effect agents for short-term gains [102].

Collectively, while mechanistic reasoning offers a coherent narrative (ATP-PCr for creatine in brief explosive tasks; H⁺ buffering for β-alanine with larger absolute changes when baseline carnosine is lower; central arousal for caffeine), our subgroup findings should be viewed as exploratory, because our analyses by age and competitive level included few trials per subgroup; thus, these findings should be viewed with caution. Larger, stratified trials are needed to confirm whether supplement effects truly differ by age or experience. Future studies should prespecify subgroup hypotheses, use interaction-focused models (e.g., Bayesian meta-regression), standardize test modality and dosing, and report posterior probabilities of interaction to distinguish true effect modification from confounding.

Based on our Bayesian synthesis, β-alanine shows the most credible improvement in vertical jump and lower limb peak power (overall low-to-moderate certainty), with creatine and caffeine as evidence-based alternatives.

Given the repeated, high-intensity, intermittent demands of volleyball [2], a 4–6-week β-alanine regimen improved vertical jump by ~4 cm on average in our analysis, which could meaningfully raise spike and block height and thus confer a competitive advantage. Caffeine may acutely increase vertical jump by ~2 cm; while the magnitude is modest, it can still be contextually valuable and is operationally flexible for pre-event use. These observations can inform cost–benefit decisions for practitioners: for example, periodizing 3.2–6.4 g/day β-alanine for 4–10 weeks or 5 g (or 0.33 g/kg)/day creatine for more than 1 week during training phases to maximize adaptations in lower limb peak power and vertical jump performance, as well as deploying caffeine from 3 to 6 mg/kg, taken pre-match to optimize competition day output and deploying the pre-match caffeine with tailored timing; however, using lower doses or different timing could yield smaller gains. It should be emphasized that statistical significance does not equate to practical significance; effect sizes must be interpreted against sport-specific thresholds and competitive context.

Safety and compliance. At recommended doses, most supplements are well tolerated. β-Alanine may provoke transient paresthesia [26], and caffeine warrants attention to individual susceptibility to neurostimulatory adverse effects (e.g., anxiety and tremors) [44,48,52]. A small rise in serum creatinine and hepatic enzymes (AST and ALT) was observed during creatine use [33]. Beetroot juice intake caused mild gastrointestinal discomfort [34]. Athletes should preferentially select third-party-certified products (contamination-free), follow evidence-based dosing, and consult sports-medicine professionals—particularly in anti-doping-tested environments [9].

This review is, to our knowledge, the first NMA of nutritional supplements with certainty appraised via CINeMA. Several limitations, however, warrant caution. First, the included trials differed substantially in competitive level, baseline fitness, dosage, and intervention duration, introducing clinical and methodological heterogeneity that may bias effect estimates. Observed heterogeneity may partly reflect differences in dose and supplementation duration. Incorporating age and competitive level in meta-regression reduced between-study heterogeneity (I²), suggesting partial explanatory power; however, because the number of trials was insufficient, our prespecified subgroup or meta-regression analyses on dose and duration could not be undertaken. Consequently, residual (unexplained) heterogeneity remains, and we interpreted the findings cautiously, downgrading certainty for inconsistency and imprecision in CINeMA. Although formal testing did not detect significant publication bias for the primary outcomes, the possibility of unpublished null results remains a concern that could potentially inflate the apparent efficacy of interventions. Additionally, incomplete outcome reporting in some included trials may have limited our ability to fully assess treatment effects across all relevant domains.

Second, the treatment network contained few direct head-to-head comparisons; consequently, many estimates relied on indirect evidence, which may reduce inferential stability and increase susceptibility to violation of transitivity assumptions [103]. Although some supplements (e.g., BCAA and HMB) showed favorable rankings, SUCRA reflects relative ordering rather than magnitude or certainty; the corresponding effects were small and/or imprecise, and certainty ranged from low to very low.

Third, most trials in our study lasted only a few weeks, so our findings primarily reflect short-term use; the long-term (multi-month) effects and safety of continuous supplementation in volleyball players remain unknown and warrant investigation.

Finally, our synthesis focused on single-agent effects and did not test potential complementarity among agents; for instance, creatine + β-alanine could theoretically couple phosphagen support with intracellular buffering [104]. We therefore recommend multi-arm or factorial RCT that directly compares combined versus single supplementation strategies, incorporate acute and where feasible, future research should consider pooling individual participant data (IPD) from trials to allow more nuanced subgroup and moderator analyses (age, sex, competitive level, habitual caffeine intake, baseline dietary creatine/β-alanine/nitrate/polyphenols), and incorporate mechanistic endpoints (e.g., ³¹P-MRS PCr recovery, muscle carnosine via HR-MRS together with ecologically valid volleyball outcomes (spike/block height, serve velocity, and match-play metrics) and systematic safety monitoring (including blinding integrity tests for caffeine)). Establishing standardized outcome reporting protocols and fostering international collaboration in volleyball supplement research would enhance comparability and impact. These steps will strengthen transitivity, reduce residual heterogeneity, and improve the external validity and interpretability of future evidence.

All aggregate data generated or analyzed during this study are included in this published article (and its). Data are available to qualified investigators on reasonable request. Supplementary Materials Information File