What this is
- () supplementation enhances strength performance and recovery in resistance-trained males.
- The study involved 11 physically active males who underwent two supplementation protocols: and a nitrate-free placebo.
- Results indicated that significantly improved repetitions, peak velocity, and muscle oxygenation during resistance exercises.
Essence
- Short-term supplementation improves strength performance and accelerates recovery in physically active individuals. Participants showed better performance metrics and reduced muscle soreness after intake compared to a placebo.
Key takeaways
- increased repetitions completed at 80% during bench press and back squat exercises. This suggests enhanced muscular endurance and strength performance.
- Peak movement velocity improved across all intensities with , indicating better power output during resistance training. This effect may contribute to greater training adaptations.
- Post-exercise recovery metrics showed faster recovery in jump performance and reduced muscle soreness with compared to the placebo. This highlights 's potential to support recovery in athletes.
Caveats
- The study's small sample size (n = 11) limits generalizability. Future research should include a larger and more diverse population.
- The reliance on self-reported dietary compliance without biochemical verification may introduce variability in results.
- Potential long-term health risks associated with high-dose nitrate consumption were not fully addressed, warranting caution in chronic use.
Definitions
- Beetroot juice (BJ): A natural source of dietary nitrate, used to enhance exercise performance and recovery.
- One-repetition maximum (1RM): The maximum amount of weight that a person can lift for one repetition of a given exercise.
- Delayed-onset muscle soreness (DOMS): Muscle pain and stiffness that occurs after intense exercise, typically peaking 24-72 hours post-exercise.
AI simplified
1. Introduction
Beetroot juice (BJ), rich in dietary nitrate (NO3−), has garnered increasing interest for its ergogenic potential in both sports performance and general cardiovascular health [1]. In sports nutrition, BJ supplementation is primarily attributed to its high NO3− content, which, upon ingestion, follows a complex pathway. Upon ingestion, NO3− is reduced to nitrite (NO2−) by oral bacteria and further converted into nitric oxide (NO) under hypoxic conditions, such as those during intense exercise [2,3,4]. Under hypoxic conditions such as those encountered during high-intensity resistance exercise, NO2− is further reduced to nitric oxide (NO), a potent vasodilator that improves muscle blood flow, optimizes oxygen delivery, and enhances mitochondrial efficiency by reducing the oxygen cost of adenosine triphosphate (ATP) production [5,6].
Although BJ has been extensively studied in endurance sports (e.g., reductions in oxygen consumption), its application in resistance training (RT) remains less explored. Emerging evidence suggests that acute BJ supplementation (6.4–13 mmol NO3−) improves muscular endurance, power output, and repetition volume in exercises like the bench press and back squat, with pronounced effects in lower-body movements due to greater muscle mass engagement [6,7,8,9]. Multi-day supplementation (≥6 days) may amplify the benefits by elevating plasma NO2−, enhancing calcium sensitivity, and sustaining performance across sets [6,7]. These effects align with velocity-based training paradigms, where BJ’s ability to preserve movement velocity could optimize sport-specific adaptations [10].
Moreover, BJ has shown promising effects in modulating cardiovascular responses during exercise. Its vasodilatory properties not only facilitate increased blood flow and improved lactate clearance but may also contribute to blood pressure regulation and enhanced endothelial function [9,10]. BJ’s cardiovascular effects extend beyond performance, including enhanced lactate clearance, blood pressure regulation, and endothelial function [11,12]. Its vasodilatory properties also modulate heart rate variability (HRV), reflecting improved autonomic balance and recovery—key metrics for athlete monitoring [13,14].
Furthermore, BJ-derived NO is a key modulator of heart rate variability (HRV), an established marker of autonomic nervous system function and recovery [15]. HRV reflects the dynamic interplay between sympathetic and parasympathetic activity and serves as a valuable tool for monitoring internal load and recovery status in athletes [16]. Advanced HRV analysis—using methods such as the root mean square of successive differences (RMSSD)—has been validated in various sports settings, providing insights into parasympathetic activation and neuromuscular recovery post-exercise [17]. BJ has also been recognized for its broader health benefits, including cardiovascular diseases, through improvements in vascular endothelial function and blood pressure regulation [18]. In the context of RT, these cardiovascular adaptations may support enhanced lower-limb strength and reduced muscle soreness by optimizing muscle perfusion and accelerating recovery processes [19].
However, several gaps remain in the current literature. Most studies have either focused on the acute or prolonged effects of BJ supplementation, with limited research exploring the combined effects of acute ingestion followed by short-term use (e.g., 3 days). This supplementation approach may be particularly relevant for athletes who perform multiple high-intensity sessions per week and seek immediate performance and recovery benefits. The practical relevance is especially pronounced for strength athletes, who often prioritize rapid power output and neuromuscular recovery between sessions, compared to endurance athletes, who may benefit more from sustained aerobic efficiency. Furthermore, while the majority of BJ research has focused on endurance modalities, emerging evidence underscores its potential to enhance RT performance through improved muscular strength, power, and recovery. Nevertheless, while available strength-related studies emphasize performance outcomes, they often neglect underlying physiological responses like HRV and muscle oxygenation—critical for monitoring internal load and recovery. For strength athletes, understanding these mechanisms could optimize training periodization, whereas endurance athletes may prioritize BJ’s oxygen utilization benefits, underscoring the need for modality-specific research frameworks.
Thus, there is a need to clarify whether short-term BJ supplementation can provide both performance and recovery benefits while modulating cardiovascular and neuromuscular responses. Considering these observations, this study aimed to examine the effect of short-term BJ supplementation on strength performance, HRV responses, and muscle oxygenation, while exploring its recovery effects on lower-limb strength and muscle soreness. The hypotheses were as follows: (i) short-term BJ supplementation would enhance strength performance, (ii) short-term BJ supplementation would positively influence heart rate variability (HRV) responses, and (iii) short-term BJ supplementation would improve recovery by enhancing lower-limb strength, reducing muscle soreness, and improving muscle oxygenation.
2. Materials and Methods
2.1. Population
The minimum required sample size was calculated using the software G*power (version 3.1.9.6; Kiel University, Kiel, Germany) using the F test family (repeated measures, within factors). We set the values of α and power (1 − β) at 0.05 and 0.95, respectively. The effect size, based on Ranchal-Sanchez et al. [11] and discussed between authors was estimated to be 0.5 (medium effect). The minimum sample size required was nine participants for this study.
Eleven physically active males (age: 21.3 ± 1.9 years; BMI: 21.42 ± 2.36 kg/m2; 1RM BS: 97 ± 14.18 kg; 1RM BP: 36 ± 4.59 kg) were recruited. All had prior RT experience (≥3 sessions/week for ≥6 weeks) and were familiar with BP and BS exercises. Exclusion criteria included medication use affecting muscle biology, prior creatine supplementation, kidney or liver conditions, low blood pressure, or musculoskeletal injuries. Compliance with these criteria was confirmed via interviews. Participants had to follow dietary guidelines, avoid strenuous activity, and refrain from nonsteroidal anti-inflammatory drugs (NSAIDs). Informed consent was obtained, and ethical approval was granted by the local Research Ethics Committee of High Institute of Sport and Physical Education of El Kef, El Kef, Tunisia (ISSEPK-0033/2024). The study was registered at the Pan African Clinical Trials Registry database on 15 May 2025 (PACTR202505827886996).
2.2. Experimentation Protocol
The study followed a double-blind, randomized, crossover, within-subject controlled design. During the first visit, participants underwent body composition assessment via bioimpedance (Tanita MC-780MA, Tokyo, Japan) and completed a familiarization protocol to standardize lifting techniques for BS and BP. To determine their one-repetition maximum (1RM), participants followed a warm-up protocol based on prior research investigating BJ effects on strength [7,11,14], adhering to the American Society of Exercise Physiologists (ASEP) guidelines for muscular strength assessment [20]. Both exercises were tested on the same day using a structured protocol: five repetitions at a 50% estimated 1RM, three repetitions at 70%, and up to five incremental 1RM attempts, each separated by 3 min rest intervals. Movement velocity was monitored [21,22] to confirm that 1RM loads aligned with expected velocities for maximal effort. These values were used to calibrate intensities for subsequent testing. Following the first visit, which included familiarization and 1RM determination, the protocol involved four testing sessions conducted over a two-week period, with at least 72 h of rest between sessions to ensure adequate recovery [23]. Testing occurred in the afternoon [24,25] under controlled environmental conditions (24 °C ± 1 °C) at a consistent time (±0.5 h) to minimize circadian effects [26,27]. Participants completed two supplementation protocols (BJ and placebo (PLA)), each involving two laboratory visits: one to assess acute ergogenic effects and another to evaluate 72 h recovery (Figure 1). Performance metrics—including incremental strength test outcomes (repetitions at 60%, 70%, 80% 1RM), peak HR, and muscle oxygen saturation (SmO2)—were recorded during BP and BS exercises. HRV indices and blood lactate were measured before and after the 1st and 2nd testing sessions. Recovery was tracked via countermovement jump (CMJ), squat jump (SJ), and upper (elbow flexor) and lower-limb (knee extensor) delayed onset muscle soreness (DOMS) assessed before and after the 1st testing session, at 24 h, at 48 h, and before and after the 2nd testing session (Figure 1).
2.3. Supplementation Protocol
Participants consumed Bio beetroot powder (Beta vulgaris; GymBeam GmbH, Berlin, Germany) dissolved in a nitrate-free placebo juice that matched in color, texture, and nutritional content, except for the absence of nitrate. The beetroot powder’s nitrate content and purity (7.26 mmol or 450 mg NO3− per 15 g) were confirmed by independent lab testing at CBS, University of Sfax, Tunisia. Detailed nutritional facts of the used beetroot powder are provided in Table 1. The placebo (PLA) was nitrate-free but nutritionally matched to beetroot juice (identical calories, carbs, sugars; Table 1). Two individuals, who were not involved in other study procedures, were responsible for randomizing participants and preparing supplement kits. These kits contained the assigned supplement, detailed usage instructions, measuring spoons, and a water bottle. The specific order in which participants received either BJ or the PLA was only revealed to researchers after all data had been collected. On the first day, participants took the full 15 g dose (in 900 mL of placebo juice) two hours before testing. Over the next two days, they consumed three 5 g servings (each in 300 mL juice) spaced throughout the day, with the final dose taken two hours before the second testing session (72 h later). This protocol ensured a consistent nitrate intake (i.e., 450 mg NO3− per day) sufficient to produce ergogenic effects [2,28].
Participants were required to abstain from food or beverages (except for water, which was allowed as needed) for at least two hours before each test to ensure accurate assessments. To maintain dietary consistency, participants completed a 24 h dietary recall before each test session [14]. These recalls were verbally conducted and recorded by a trained researcher to identify any deviations from dietary instructions, with particular attention to nitrate intake and the consumption of substances that could interfere with oral nitrate reduction. Further guidelines for participants included the following: (i) avoiding nitrate-rich foods (e.g., beetroot, celery, spinach) for 48 h before each testing session to control background dietary nitrate; (ii) avoiding foods high in stimulants (e.g., caffeine), gum, sweets, and alcohol, which could influence the oral microbiota for three days before testing; (iii) refraining from brushing their teeth on the morning of the test and avoiding antiseptic mouth rinses for at least one week before and throughout the study, as these could inhibit the conversion of nitrate to nitrite [29]; (iv) ensuring proper hydration; (v) avoiding intense physical activity; and (vi) sleeping at least eight hours each night. Compliance with these guidelines was emphasized during the initial briefing sessions, and adherence was verbally confirmed before each testing session.
2.4. Strength Exercise Protocol
During each testing session, participants started with an 8 min standardized warm-up under supervision, which included light muscle activation on a treadmill. After warming up, they performed the BS first, followed by the BP, both executed using a Smith machine, with a 3 min rest between exercises. Before the incremental strength test, participants completed a structured warm-up for both exercises, consisting of 12 repetitions at 10% of their 1RM, followed by 6 repetitions at 30% of their 1RM, with a 1 min rest between sets [11]. Afterward, they rested for 2 min before the test began. The incremental strength test comprised three sets with progressively increasing loads at 60%, 70%, and 80% of their 1RM, with repetitions performed until muscle failure. A 3 min rest was provided between sets to allow sufficient recovery and maintain performance [30]. Both BS and BP were performed through a full range of motion [31]. Participants were instructed to execute the concentric phase of each repetition at maximum velocity to enhance muscle strength development [22]. The full testing session, including the warm-up, lasted about 35 min.
2.5. Measurements
2.5.1. Incremental Strength Test and Performance
Maximum repetitions completed at 60%, 70%, and 80% RM until failure were noted for both the BP and BS. The maximum velocity (MV) and maximum power (MP) per set were recorded using the validated accelerometer-based sensor “Vmax Pro” (Blaumann & Meyer, Sports Technology UG, Magdeburg, Germany), which demonstrated high agreement with Vicon (R2 = 0.935) and T-Force (R2 = 0.968) systems during squat movements [32]. Execution velocity and power output were continuously monitored by the researchers.
2.5.2. Heart Rate Variability (HRV) Analysis
HRV was assessed at 5 min pre-session and 5 min post-session. Data were collected via a Polar H10 heart rate monitor and analyzed using the Elite HRV app (version 5.5.8) [33]. Time-domain parameters included the mean RR interval (MeanRR), root mean square of successive differences (RMSSD), and standard deviation of RR intervals (SDNN). Frequency-domain analysis evaluated low-frequency (LF) and high-frequency (HF) components. Peak heart rate during exercise was also recorded.
2.5.3. Muscle Oxygenation
Muscle oxygenation was assessed using Near-Infrared Spectroscopy (NIRS), a non-invasive method to monitor oxygen delivery and consumption in muscle tissue. This technique provided semi-quantitative data on oxygen levels in hemoglobin/myoglobin (tissue O2 stores) and total hemoglobin (THb) concentration, reflecting blood volume changes [34]. Real-time SmO2 was measured using the validated Moxy 3-Sensor Bundle (Fortiori Design LLC, Spicer, MN, USA) [35]. Additionally, THb was monitored to evaluate blood volume and flow dynamics in the muscle.
2.5.4. Lower-Limb Strength Tests
CMJ and SJ performances were quantified via the My Jump 2 app [36]. For SJ, participants executed a maximal vertical jump from a 90° knee angle with hands on hips. For CMJ, jumps begin from a standing position without arm swing. Three attempts per test were allowed, with the highest-performing attempt retained for analysis.
2.5.5. Blood Lactate Measurement
Lactate levels were assessed using Lactate Pro 2 (AKRAY Europe B.V., Amstelveen, The Netherlands). Samples were obtained from the sterilized earlobe (70% ethanol) following standardized protocols [37,38].
2.5.6. Delayed-Onset Muscle Soreness (DOMS)
DOMS was evaluated using a visual analog scale (0–10) for knee extensors and elbow flexors. Scores were normalized to 100% of the maximum perceived soreness [25,39], where 0 indicated no soreness and 10 represented intolerable discomfort.
2.6. Statistical Analysis
All statistical procedures were performed using the R programming language (version 4.4.0) [40]. Descriptive statistics are presented as mean ± standard deviation (SD). The normality of the data was assessed and confirmed using the Shapiro–Wilk test. To examine the effects of supplementation condition, time, and intensity, a three-way repeated measures analysis of variance (ANOVA) with Greenhouse–Geisser correction was conducted. When significant main or interaction effects were detected, post hoc pairwise comparisons with Bonferroni adjustments were performed. Delta change (∆pre-post) was calculated as follows: ∆pre-post (%) = ((score at post-session − score at pre-session)/score at pre-session) × 100. To assess differences in HRV indices between supplementation conditions and time effects, a two-way ANOVA was conducted, followed by post hoc pairwise comparisons with Bonferroni adjustments. Moreover, to assess recovery effects in CMJ, SJ, and DOMS between supplementation conditions and time effects, a two-way ANOVA was conducted, followed by post hoc pairwise comparisons with Bonferroni adjustments. Effect sizes were calculated as partial eta-squared (η2p), with small (0.01), moderate (0.06), and large (0.14) thresholds [41]. Standardized effect size (Cohen’s d) was used to interpret the magnitude of mean differences and classified according to Hopkins [42]: trivial (d ≤ 0.20), small (0.20 < d ≤ 0.60), moderate (0.60 < d ≤ 1.20), large (1.20 < d ≤ 2.0), very large (2.0 < d ≤ 4.0), and extremely large (d > 4.0). A significant level of p < 0.05 was used for all analyses. Normality was assessed using the Shapiro–Wilk test with the “rstatix” package (version 0.7.2) [43], and ANOVA for normally distributed data was conducted with the “afex” package (version 1.3-1) [44]. Pairwise comparisons were performed using the “emmeans” package (version 1.10.2) [45], and visualizations were generated with the “ggplot2” package (version 3.5.2) [46].
3. Results
3.1. Dietary Intake
Dietary intake for both BJ and PLA conditions are presented in Table 2. No significant differences in energy or macronutrient intake were found between conditions (p > 0.05).
3.2. Strenght Performance and Physiological Parameters
All three-way ANOVA results for reached repetitions, peak velocity, peak power, peak HR, SmO2, and tHb are presented in Table S1.
3.2.1. Reached Repetitions
Regarding the reached repetitions during BP, there were significant main effects of condition and intensity (Table S1). In all conditions and sessions, the pairwise comparisons showed that performance values increased significantly from 60% to 70% RM, 60% to 80% RM, and 70% to 80% RM (p < 0.001, d = 1.63 to 3.97; Figure 2). The reached repetitions for 80% RM in BJ were significantly lower in the second than the first session (p = 0.046, d = 0.69; Figure 2). Moreover, BJ presented higher values than the PLA, with significant differences observed at 80% RM (p = 0.0344, d = 0.74) in the first session, as well as at 70% RM in second session (p = 0.0189, d = 0.84) (Figure 2). During the BS, there were significant main effects of condition, session, and intensity (Table S1). The reached repetitions in BS increased significantly from 60% to 70% RM, 60% to 80% RM, and 70% to 80% RM (p < 0.001, d = 0.98–2.55; Figure 2) under all conditions and in all sessions, except from 70% to 80% RM in the first session for BJ (p = 0.1489, d = 0.63). BJ repetitions in the second session were significantly lower compared to those in the first session (p = 0.0126, d = 0.91) for 80% RM (Figure 2). BJ was reported to have significant higher repetitions compared to the PLA at 60% and 80% RM in the first session (p = 0.0104 and 0.0069, d = 0.95 and 096, respectively) (Figure 2).
3.2.2. Peak Velocity
Concerning velocity during BP, significant main effects of condition, session, and intensity were observed (Table S1). In all conditions and all sessions, velocity decreased significantly from 60% to 70% RM (p < 0.05, d = 0.86–1.72), 60% to 80% RM (p < 0.002, d = 1.78–2.21), and 70% to 80% RM (p < 0.05, d = 1.06–1.57), except from 70% to 80% RM in the first session for BJ (p = 0.395, d = 0.48) (Figure 2). In those given BJ, velocity at 60% RM was significantly lower in the second than the first session (p = 0.0114, d = 0.93; Figure 2). BJ presented significantly greater velocities at all intensity levels and sessions (p < 0.011, d = 0.94–2.29; Figure 2). Regarding the velocity under BS supplementation, significant main effects of condition, session, and intensity were found (Table S1). The PLA’s velocity decreased significantly from 60% to 80% RM in both sessions (p = 0.0002 and 0.0003, and d = 2.03 and 1.88, respectively, for the first and second sessions), while velocity decreased only in the first session from 70% to 80% RM (p = 0.0040, d = 1.33) (Figure 2). Similarly, velocity in the BJ decreased significantly from 60% to 80% RM across the first (p = 0.0026, d = 1.41) and the second sessions (p = 0.0029, d = 1.39), while a significant decrease was found from 70% to 80% RM in the first session (p = 0.0001, d = 2.13) (Figure 2). Moreover, velocity was significantly lower in the first compared to the second session in 70% RM for both the PLA (p = 0.0062, d = 1.04) and BJ (p = 0.0211, d = 0.82) (Figure 2). Additionally, BJ supplementation resulted in significantly higher velocity than the PLA did across all intensity levels in both the first and the second sessions (p < 0.05, d = 0.69–1.3) (Figure 2).
3.2.3. Peak Power
Concerning the peak power during BP supplementation, a significant main effect of intensity was found (Table S1). In the PLA condition, the power significantly increased from 60% to 80% RM, and from 70% to 80% RM (p < 0.0001, d = 2.35–4.77) in both sessions, while it increased from 60% to 70% RM in the second session only (p = 0.0073, d = 1.21) (Figure 2). Similarly for BJ, there were significant increases in power from 60% to 80% RM and from 70% to 80% RM (p < 0.0001, d = 2.35–3.94) across both sessions (Figure 2). However, BJ showed a significant increase from 60% to 70% RM in the first session only (p = 0.0442, d = 0.89) (Figure 2). Regarding the peak power during BS, there was a significant main effect of intensity and a significant condition × session × intensity interaction (Table S1). In all conditions and all sessions, power increased significantly from 60% to 70% RM (p < 0.0005, d = 1.8–4.19), 60% to 80% RM (p < 0.0001, d = 4.24–6.03), and 70% to 80% RM (p < 0.0001, d = 2.25–3.94) (Figure 2). Additionally, peak power significantly increased from the first to second session for performance under BJ supplementation at 60% RM (p = 0.0083, d = 0.99) and for performance on the PLA at 70% RM (p = 0.0367, d = 0.73) (Figure 2).
3.2.4. Peak HR
Regarding the peak HR recorded during the BP, there were significant main effects of condition and intensity (Table S1). Additionally, a significant condition × intensity interaction was found (Table S1). In both conditions, HR increased with increasing intensity (p < 0.0001, d = 0.78–6.84), except from 60% to 70% RM for BJ (p = 0.1304, d = 0.78) during the second session (Figure 3). Additionally, the PLA produced higher HRs compared to BJ across all intensity levels in both sessions (p < 0.05, d = 1.18–2.08) (Figure 3).
During the BS, there were significant main effects of condition and intensity; also, a significant condition × session × intensity interaction was detected (Table S1). For the PLA, during the second session, HRs significantly increased from 60% to 70% RM (p = 0.0014, d = 1.99), 60% to 80% RM (p = 0.0003, d = 3.02), and 70% to 80% RM (p = 0.0370, d = 1.14) (Figure 3). Similarly, during the first session, BJ was reported to lead to significant increases from 60% to 70% RM (p = 0.0314, d = 1.09) and from 60% to 80% RM (p = 0.0066, d = 1.16) (Figure 3). In contrast, for BJ, during the 2nd session, HRs significantly increased from 60% to 80% RM (p = 0.0307, d = 0.99) and 70% to 80% RM (p = 0.0137, d = 1.13) (Figure 3).
3.2.5. SmO 2
During BPs, there were significant main effects of condition and session, as well as a significant condition × session interaction (Table S1). BJ supplementation during the second session showed a significant decrease in SmO2 from 70% to 80% RM (p = 0.478, d = 0.87) (Figure 3). Additionally, BJ’s SmO2 was significantly higher in the second session compared to the first session for 70% (p = 0.0001, d = 2.03) and 80% RM (p = 0.0187, d = 0.85) (Figure 3). BJ led to higher SmO2 compared to the PLA during the first and second sessions, at 60% (p = 0.0048 and 0.0001, d = 1.09 and 1.94, respectively), 70% (p = 0.0169 and 0.0003, d = 0.86 and 1.61, respectively), and 80% RM (p = 0.0004 and 0.0001, d = 1.55 and 1.8, respectively) (Figure 3).
The analysis for SmO2 during BSs revealed significant main effects of the condition and session, as well as a significant condition × session interaction (Table S1). SmO2 under BJ supplementation showed a significant increase from the first to the second session at 60% (p < 0.0001, d = 10.24), 70% (p = 0.0009, d = 4.68), and 80% RM (p = 0.0004, d = 5.28) (Figure 3). Additionally, SmO2 was significantly higher under BJ supplementation during the second session compared to the PLA at 60% (p < 0.0001, d = 11.27), 70% (p = 0.0001, d = 6.57), and 80% RM (p = 0.0001, d = 5.94) (Figure 3).
3.2.6. Total Hemoglobin
Regarding the tHb during BPs, a significant main effect of condition was observed (Table S1), where tHb was significantly lower for those taking BJ compared to those on the PLA during ST at 80% RM (p = 0.0232, d = 0.81). Concerning tHb during BSs, there was a significant session × intensity interaction (Table S1), where a significant increase in tHb at 80% RM from AC to ST was revealed (p = 0.0266, d = 0.78) (Figure 3).
3.3. ∆Pre-Post Change in HRV Indices and Lactate
The ∆Pre-Post change in HRV indices and the lactate and ANOVA results are presented in Table 3. For MeanRR, there was a significant main effect of session, where the PLA and BJ showed a significant decrease from AC to ST (p = 0.0113 and 0.0123, d = 0.93 and 0.92, respectively). Similarly, RMSSD showed a significant main effect of session, with the PLA and BJ showing a significant decrease from AC to ST (p = 0.0027 and 0.021, d = 1.2 and 0.832, respectively), with a greater ∆Pre-Post change for the PLA compared to that for BJ at AC (p = 0.044, d = 0.69). For SDNN, no significant effects were found. Additionally, LF and HF showed a significant main effect of session, with significant decreases in HF changes for the PLA and BJ from AC to ST (p = 0.0025 and 0.0045, d = 1.21 and 1.1, respectively). Lastly, for lactate, there were no significant effects.
3.4. Post-Session Recovery
CMJ, SJ, and upper- and lower-limb DOMS results are visualized in Figure 4.
3.4.1. CMJ
The analysis showed no significant effects of condition (F(1, 10) = 4.42, p = 0.062, η2p = 0.306). However, there was a significant main effect of time (F(3.13, 31.26) = 91.38, p < 0.001, η2p = 0.901) and a condition × time interaction (F(2.21, 22.06) = 17.61, p < 0.001, η2p = 0.638). In the PLA, CMJ performance significantly decreased from Pre1 to Post1, (p < 0.0001, d = 5.55), and CMJ performance at Pre1 was significantly higher compared to that at 24 h, 48 h, and Pre2 (p < 0.0008, d = 2.03–4.07). However, CMJ performance significantly increased from Post1 to Pre2 (p = 0.0006, d = 2.5) and from 24 h to 48 h (p = 0.0021, d = 1.79). Also, CMJ performance significantly decreased from Pre2 to Post2 (p = 0.0008, d = 2.03). With BJ supplementation, CMJ performance decreased significantly from Pre1 to Post1 (p = 0.0002, d = 2.45), 24 h (p = 0.0001, d = 2.47), and 48 h (p = 0.0220, d = 1.31). CMJ performance also increased significantly from Post1 to 48 h (p < 0.0001, d = 3.09) and Pre2 (p < 0.0001, d = 4.74), and from 48 h to Pre2 (p < 0.0001, d = 3.5). There was also a significant decrease for CMJ performance under BJ supplementation from Pre2 to Post2 (p < 0.0001, d = 2.99). Otherwise, BJ led to higher CMJ performance compared to the PLA at 24 h (p = 0.0123, d = 0.92), 48 h (p = 0.0364, d = 0.73), and Pre2 (p = 0.0442, d = 0.69).
3.4.2. SJ
There was no significant effect of condition (F(1, 10) = 3.28, p = 0.1, η2p = 0.247). However, there was a significant main effect of time (F(2.66, 26.61) = 42.39, p < 0.001, η2p = 0.809) and a condition × time interaction (F(2.64, 26.42) = 6.40, p = 0.003, η2p = 0.390). In the PLA condition, SJ performance significantly decreased from Pre1 to Post1 (p < 0.0001, d = 3.63), 24 h (p < 0.0001, d = 5.99), and 48 h (p = 0.0085, d = 1.5). Additionally, performance was significantly increased from Post1 to Pre2 (p = 0.0001, d = 2.7) and from 24 h to Pre2 (p < 0.0001, d = 3.06). SJ performance decreased significantly from Pre2 to Post2 (p = 0.0078, d = 1.15). In BJ conditions, SJ performance significantly decreased from Pre1 to Post1 (p < 0.0001, d = 4.51) and at 24 h (p = 0.0007, d = 2.06). Furthermore, performance was significantly lower at Post1 compared to 24 h (p = 0.0004, d = 2.18), 48 h (p < 0.0001, d = 4.59), and Pre2 (p < 0.0001, d = 4.72), at 24 h compared to that at 48 h and Pre2 (p < 0.0001, d = 2.96 and 3.23), as well as at 48 h compared to that at Pre2 (p = 0.0020, d = 1.81). Furthermore, SJ performance under BJ conditions significantly decreased from Pre2 to Post2 (p = 0.0349, d = 1.22). Moreover, BJ led to higher SJ performance compared to the PLA at 24 h (p = 0.0449, d = 0.69) and 48 h (p = 0.0105, d = 0.94).
3.4.3. Upper-Limb DOMS
There were significant main effects of condition (F(1, 10) = 34.53, p < 0.001, η2p = 0.775) and time (F(2.63, 26.28) = 139.78, p < 0.001, η2p = 0.933), as well as a significant condition × time interaction (F(1.74, 17.40) = 9.59, p = 0.002, η2p = 0.490). DOMS for the PLA significantly increased from Pre1 to Post1 (p < 0.0001, d = 5.73), 24 h (p < 0.0001, d = 6.33), 48 h (p = 0.0001, d = 2.57), and Pre2 (p = 0.0034, d = 1.69). Additionally, DOMS was significantly higher at Post1 compared to Pre2 (p < 0.0001, d = 4), at 24 h compared to Pre2 (p < 0.0001, d = 4.4), and at 48 h compared to Pre2 (p = 0.0007, d = 2.07). DOMS significantly increased from Pre2 compared to Post2 (p < 0.0001, d = 4.45). Concerning the BJ condition, DOMS significantly increased from Pre1 to Post1 (p < 0.0001, d = 4.03), and 24 h (p = 0.0013, d = 1.92). Furthermore, DOMS was significantly higher at Post1 compared to 24 h (p = 0.0254, d = 1.26), 48 h (p = 0.0001, d = 2.89), and Pre2 (p < 0.0001, d = 5.22). DOMS under BJ supplementation at 24 h was also significantly higher compared to that at 48 h (p < 0.0001, d = 2.98) and Pre2 (p = 0.0028, d = 1.73). Furthermore, DOMS increased significantly from Pre2 to Post2 (p < 0.0001). Additionally, BJ led to lower DOMS compared to the PLA at 24 h (p = 0.0013, d = 4.39) and 48 h (p = 0.0016, d = 4.3).
3.4.4. Lower-Limb DOMS
There was neither a significant main effect of condition (F(1, 10) = 1.10, p = 0.319, η2p = 0.099) nor a condition × time interaction (F(2.05, 20.55) = 2.53, p = 0.103, η2p = 0.202). However, there was a significant main effect of time (F(3.37, 33.71) = 153.04, p < 0.001, η2p = 0.939). In the PLA condition, DOMS significantly increased from Pre1 to Post1 (p < 0.0001, d = 5.68), 24 h (p < 0.0001, d = 6.94), 48 h (p < 0.0001, d = 3.44), and Pre2 (p = 0.0371, d = 1.21). However, DOMS significantly decreased from Post1 to 48 h (p = 0.0233, d = 1.29) and Pre2 (p < 0.0001, d = 3.39), and from 24 h to 48 h (p = 0.0035, d = 1.69) and Pre2 (p < 0.0001, d = 2.79). Additionally, DOMS increased from Pre2 to Post2 (p = 0.0001, d = 2.83). DOMS under BJ supplementation significantly increased from Pre1 to Post1 (p < 0.0001, d = 3.47), 24 h (p < 0.0001, d = 3.47), and 48 h (p = 0.0043, d = 1.64). Furthermore, DOMS decreased from 24 h to 48 h (p = 0.001, d = 1.96) and Pre2 (p < 0.0001, d = 4.41), and from 48 h to Pre2 (p = 0.0004, d = 2.22). Also, DOMS reported significant increases from Pre2 to Post2 (p < 0.0001, d = 6.96). Moreover, BJ led to lower DOMS compared to the PLA at Pre2 (p = 0.0036, d = 1.14).
4. Discussion
The primary aim of this study was to assess the impact of short-term BJ supplementation on strength performance, HRV responses, muscle oxygenation, and post-exercise recovery. Results demonstrated that BJ significantly enhanced strength performance, as indicated by higher repetitions and peak velocity at 80% 1RM during BPs and BSs, alongside attenuated cardiovascular strain, with lower peak HRs in the BJ condition compared to those for the PLA, and moderated autonomic stress with smaller reductions in HRV indices under BJ supplementation such as RMSSD and HF. Also, BJ led to a higher SmO2 after 3 days of ingestion compared to the PLA. While the BJ improved post-exercise recovery of lower-limb strength (CMJ and SJ) and reduced upper-limb DOMS, it did not mitigate lower-limb DOMS or lactate accumulation. These outcomes confirm the hypothesis that BJ enhances strength performance and partially supports its role in improving recovery and HRV regulation.
Reached repetitions during both exercises decreased at higher intensities following BJ supplementation, suggesting a potentially ergogenic effect likely driven by enhanced neuromuscular efficiency and delayed fatigue. This performance enhancement was especially evident during the second session, where BJ outperformed the PLA at higher loads—possibly due to improved phosphocreatine resynthesis and faster calcium kinetics in type II fibers, as supported by previous findings from trained female athletes and team-sport players [47,48]. Peak velocity also reduced with increasing intensity, with BJ consistently achieving greater velocities than the PLA. On the other hand, peak power increased with rising exercise intensity in both exercises, suggesting that the essential load–power relationship of the neuromuscular system may overshadow any small ergogenic contributions of nitrate supplementation [6,14]. Furthermore, BJ, rich in dietary nitrates, enhances muscle performance by increasing NO bioavailability, which improves vasodilation and muscle contraction kinetics, with its high nitrate content being converted into NO in the body, playing a crucial role in muscle function by increasing the maximal shortening velocity and peak power of muscle fibers [47,49,50]. This effect is thought to result from NO’s role in improving blood flow and reducing the oxygen cost of exercise, thereby enhancing exercise performance [51].
These improvements in strength performance coincided with cardiovascular adaptations; BJ significantly reduced peak HR compared to the PLA, indicating reduced cardiovascular strain. This HR response, particularly during BPs at 60–70% 1RM in the second session, may reflect an adaptive effect from repeated NO exposure, which enhances cardiovascular efficiency at submaximal loads [52]. For the BS, the attenuated HR increased with BJ supplementation—especially in the second session—suggesting that NO helped maintain muscle oxygenation under high mechanical stress, minimizing the need for cardiac compensation [48,53]. In contrast, the PLA showed a HR rise at higher intensities, emphasizing the cardiovascular system’s reliance on elevated cardiac output when peripheral perfusion is limited [54]. BJ appears to stabilize oxygen delivery, reducing acute HR-driven strain and potentially improving exercise tolerance [49,55]. Mechanistically, BJ’s ergogenic effects proceed from the NO3−–NO2−–NO pathway, where NO3− is converted by oral bacteria and under hypoxia into NO, a potent vasodilator that enhances skeletal and coronary muscle perfusion, reduces systemic vascular resistance, and improves stroke volume [56,57]. Through the Frank–Starling mechanism, greater venous return stretches the myocardium, optimizing contractility and reducing the HR needed to maintain cardiac output. Simultaneously, NO enhances mitochondrial efficiency by reducing the oxygen cost of ATP production, thereby decreasing the metabolic drive for HR elevation [4]. These dual effects—vascular and mitochondrial—may explain the lower peak HR and improved performance with BJ. Beyond NO, BJ’s antioxidant and anti-inflammatory compounds (e.g., betalains and polyphenols) may mitigate oxidative stress and muscle damage, contributing to more efficient recovery and performance sustainability [58].
Furthermore, SmO2 responses supported the cardiovascular and performance findings, offering additional evidence of BJ’s vasoactive effects. During BPs, BJ elevated SmO2 across all intensities compared to the PLA, suggesting improved microvascular perfusion [4]. During the BS, SmO2 increases in BJ were observed only during the second session (after 3 days of supplementation), indicating a potential cumulative effect of repeated nitrate intake. This aligns with the nitrate–nitrite–NO pathway, in which dietary nitrate is reduced to nitrite by oral bacteria and further converted into NO in the bloodstream, particularly under hypoxic conditions typical of RT [3,59]. Repeated BJ ingestion resulted in greater NO availability, which in turn would have promoted vasodilation, improved capillary blood flow, and enhanced oxygen delivery to working muscles [4]. These vascular effects manifest as elevated SmO2, reflecting both improved oxygen supply and potentially more efficient oxygen extraction [60]. This is consistent with findings from endurance studies in which NO has been shown to optimize mitochondrial function and lower the oxygen cost of ATP production [61].
Importantly, HRV results demonstrated that BJ consumption reduced RMSSD from pre- to post-sessions, reflecting increased sympathetic dominance and internal workload. This transient decrease in RMSSD aligns with previous findings that RT typically suppresses parasympathetic modulation during intense exercise [62]. The higher total repetitions and HRs in the BJ further validate the existence of a state of increased physiological demand. Conversely, post-exercise, RMSSD returned to the baseline in both conditions, but with a high recovery slope in BJ, suggesting that BJ may enhance autonomic recovery through NO-induced improvements in vagal modulation, as supported by studies reporting accelerated parasympathetic recovery following strength exercise with BJ intake [61]. However, the absence of blood pressure changes and the short HRV measurement duration impose limitations on interpreting these findings fully, while the exercise order (BS preceding BP) might have introduced cumulative neuromuscular fatigue that altered HRV responses.
BJ supplementation significantly enhanced neuromuscular recovery, as evidenced by improved CMJ and SJ performance at 24 h and 48 h after the first session compared to the PLA. Following initial performance declines immediately post-exercise, BJ participants exhibited a more rapid return to near-baseline values after 72 h, demonstrating accelerated recovery kinetics [59,63]. These findings align with those in the literature, in which more than 60% of nitrate supplementation studies report improved recovery metrics, particularly in attenuating DOMS and restoring muscle function [64]. For example, upper-limb DOMS was notably reduced with BJ at 24 h and 48 h, likely due to NO-mediated anti-inflammatory effects and enhanced tissue perfusion—mechanisms supported by previous investigations showing nitrate-induced improvements in vascular function and inflammation modulation [65]. In contrast, lower-limb DOMS responses were less pronounced, which may reflect regional variability in NO bioavailability or differences in the muscle damage profile between upper and lower-limb exercise [66]. Furthermore, NO3− from BJ may accelerate recovery by preserving muscle excitability, improving sarcoplasmic calcium release, and promoting mitochondrial biogenesis [67]; these pathways contribute to faster phosphocreatine resynthesis that is often not captured by traditional biomarkers such as creatine kinase [65]. Importantly, these effects seem to be dose-dependent, with optimal recovery benefits observed around moderate nitrate doses (approximately 8–12.9 mmol), while higher doses may yield diminishing returns [68]. Furthermore, the synergistic action of bioactive compounds such as betalains may confer additional antioxidant and anti-inflammatory support, thereby enhancing recovery outcomes compared to when nitrate is administered in the form isolated salts [66,69]. Recent studies have also noted that acute BJ ingestion does significantly reduce RPE, and it does lower markers associated with muscle damage, thereby enhancing neuromuscular efficiency during repeated high-intensity bouts [64]. These benefits, observed in conjunction with improvements in CMJ and SJ performance at 24 h and 48 h after the first session, suggest that BJ can facilitate more rapid autonomic and functional recovery likely mediated by enhanced NO-induced vasodilation and improved calcium handling [70]. However, biochemical and molecular biomarkers are warranted to fully elucidate the contribution of NO-mediated mechanisms versus the potential synergistic effects of other beetroot components [1,58,69]. Collectively, these acute outcomes complement prior evidence showing that chronic BJ supplementation (over 5–7 days) augments training adaptations by increasing resistance exercise repetitions and mitigating post-exercise muscle soreness, primarily through improved oxygen delivery and neuromuscular function [59].
While our findings support the ergogenic effects of short-term BJ supplementation (450 mg nitrate/day) on physical performance, physiological responses, and recovery, it is important to acknowledge emerging concerns regarding long-term or high-dose nitrate consumption. Elevated nitrate intake can increase the endogenous formation of N-nitroso compounds (NOCs), which are known to contribute to carcinogenic processes, particularly through DNA adduct formation such as O6-alkylguanine [71,72]. The nitrate dose used in our study was selected based on prior recommendations for optimizing ergogenic benefits in athletic populations [28], while still considering safety guidelines. Nitrates are widely considered an effective ergogenic aid when taken acutely or chronically in doses ranging from approximately 5 to 16.8 mmol (300–1041 mg), typically 2–3 h prior to exercise, and are recommended for athletes seeking to improve performance or endurance, particularly for exercise durations of around 10–17 min [73]. This range of nitrate intake aligns with current research and expert recommendations for both acute and chronic effects, demonstrating its safety and effectiveness [73]. However, it is noteworthy that for some participants, this dose exceeds the acceptable daily intake (ADI) of 3.7 mg/kg body weight set for the general (non-athletic) population [74]. Previous acute studies have reported increased urinary and fecal excretion of NOCs following similar high doses [75,76]. Additionally, unlike whole vegetables such as spinach or beetroot—which contain antioxidants like vitamin C that can inhibit NOC formation—commercial BJ supplements typically lack such protective compounds [72,77]. While our study focused on short-term outcomes, regular or chronic BJ supplementation, especially without concurrent antioxidant intake, may raise health concerns. Epidemiological data suggests a potential link between prolonged nitrate exposure and an increased risk of colorectal and gastric cancers [78,79].
Therefore, although BJ supplementation appears safe and beneficial in the context of short-term use among healthy, physically active individuals, its long-term safety should be evaluated carefully, particularly in non-athletic populations. Future research should consider population-specific factors such as health status, physical activity levels, dietary habits, and baseline antioxidant intake when determining optimal dosing strategies to maximize ergogenic effects while minimizing potential health risks.
Strengths and Limitations
This study presents several strengths worth highlighting. It employed a double-blind, randomized crossover design, which enhances internal validity and reduces inter-individual variability, allowing for robust within-subject comparisons. The use of multiple, performance-relevant endpoints—including movement velocity, peak power, HRV, and SmO—offers a comprehensive assessment of both the acute and short-term effects of BJ supplementation. Additionally, the inclusion of practical recovery metrics such as jump performance and DOMS provides ecologically valid outcomes that are directly applicable to real-world resistance training contexts. 2
Several limitations should also be acknowledged. The study’s small sample size (n = 11), which excluded females and non-physically active individuals, may limit statistical power and generalizability. Although our study exclusively included male participants, this decision was based on the goal of controlling for hormonal fluctuations that could potentially influence the outcomes, particularly in relation to nitrate metabolism and performance. Future research should aim to include both male and female participants to provide a more comprehensive understanding of the effects of BJ supplementation across genders. While efforts were made to ensure blinding, inherent sensory differences between BJ and the PLA might have compromised this process, introducing potential bias. Reliance on self-reported dietary and lifestyle compliance without biochemical verification (e.g., plasma nitrate/nitrite levels) further adds variability, without biochemical verification (e.g., plasma nitrate/nitrite levels or urinary NOCs), prevents confirmation of strict protocol adherence, and obscures individual variability in nitrate metabolism. Crucially, the absence of molecular biomarkers (e.g., oxidative stress markers like malondialdehyde, inflammatory cytokines, or DNA adducts such as O6-alkylguanine) limits mechanistic insights into BJ’s ergogenic effects and its potential to stimulate carcinogenic pathways. While studies demonstrated increased urinary NOC excretion following acute BJ intake [], our design did not assess these outcomes, precluding a direct evaluation of safety risks alongside performance benefits. 76
Methodologically, the use of a Smith machine for the BS and BP, though enhancing safety and consistency, reduces ecological validity compared to that when free-weight training in real-world athletic settings is used. Similarly, semi-quantitative near-infrared spectroscopy (NIRS) and smartphone-based jump assessments, while pragmatic, lack the precision of laboratory-grade equipment (e.g., force plates and gas analyzers) and may underestimate subtle physiological changes. Moreover, while a 7-day washout period was implemented in accordance with Zhang et al. [], residual beetroot effects cannot be entirely ruled out in the crossover design, and the focus on acute and 72 h recovery precludes insights into long-term supplementation benefits. 68
5. Conclusions
The current findings underscore BJ’s multifaceted ergogenic potential, across strength performance, cardiovascular regulation, autonomic function, and recovery. BJ intake appears to enhance both acute and short-term RT outcomes, particularly in high-intensity, phosphagen-dependent tasks. Its benefits likely stem from the nitrate-mediated pathways, promoting improved muscle perfusion, oxygen utilization, and neuromuscular efficiency. Notably, the observed reductions in cardiovascular strain and improvements in HRV suggest favorable autonomic adaptations that may support both exercise tolerance and recovery. Additionally, BJ supplementation appears to accelerate neuromuscular recovery and attenuate muscle soreness, possibly through nitric oxide (NO)-related anti-inflammatory, antioxidative, and mitochondrial-enhancing effects.
Collectively, these outcomes position BJ as a practical, time-sensitive nutritional strategy for athletes seeking to optimize training performance and recovery during periods of intense resistance exercise. For practitioners, we recommend (i) timing BJ intake 2–3 h pre-exercise to align with peak plasma nitrate availability, (ii) pairing acute BJ supplementation (e.g., 450 mg nitrate/day) with antioxidant-rich foods (e.g., citrus fruits) to mitigate potential NOC-related risks, and (iii) reserving chronic use for targeted training phases until long-term safety data are established.
Future studies incorporating direct assessments of plasma nitrate/nitrite concentrations and mechanistic biomarkers are warranted to validate these physiological effects and further refine BJ supplementation protocols for athletic populations. Critical research gaps remain, including investigations into BJ’s efficacy and safety in underrepresented cohorts (e.g., female athletes, older adults, and elite competitors), dose–response relationships across training modalities, and longitudinal monitoring of molecular biomarkers (e.g., oxidative stress, inflammatory cytokines, and DNA adducts) to evaluate carcinogenic risks. Additionally, comparative studies examining BJ’s effects in free-weight versus machine-based training environments could enhance ecological validity, while trials combining BJ with dietary nitrosation inhibitors (e.g., vitamin C, polyphenols) may optimize its risk–benefit profile.