Enhancing Performance in Young Athletes: A Systematic Review of Acute Supplementation Effects

Ergogenic aids are substances intended to enhance sports performance and provide additional benefits, such as supporting muscle recovery, preventing injuries by promoting joint and muscle health, and assisting in managing training loads to optimize physical adaptations [1,2]. These supplements might not only enhance performance during competition but may also play a crucial role in maintaining overall athlete health and longevity by potentially reducing the risk of injury and supporting recovery processes. Athletes consume these supplements to enhance training adaptations, immune functioning, recovery, cognition, and decrease perceptions of fatigue [3,4]. Although supplements such as carbohydrates, protein, creatine, caffeine, beta-alanine, sodium bicarbonate, tart cherry, and beetroot juice are commonly sought after by athletes for enhancing sports performance, not all of these supplements have benefits that are fully evidence-informed [3]. Therefore, it is important to investigate the acute effects of ergogenic supplementation before implementing them in practice [5,6]. Various factors should be considered before the prescription of supplements to improve performance, including reducing the risk of doping infringements and health damage due to ingesting contaminated ingredients [7].

Young athletes undergo various stages of growth and maturation [8,9]. Therefore, applying the same supplementation guidelines designed for adult athletes could potentially influence the progression of performance in young athletes by altering the natural developmental trajectory or introducing risks associated with inappropriate use [9,10,11]. These effects may arise due to differing nutritional requirements compared to adults, which can be either higher or lower, or from the potential for excessive consumption relative to their specific nutrient needs [12,13]. Especially since it is thought that young athletes mirror the attitudes of those more experienced and adopt similar supplementation protocols that are recommended for adults [9,14]. Young athletes who excel in their fields deserve special attention due to the strenuous energy expenditure from intense physical training and the energy demands for growth and development [10,15]. One of the main objectives of coaches and parents of young athletes is to understand whether the training demand and nutritional intake are optimal for physical development, performance, and recovery. However, it is crucial for athletes to meet the nutritional demands of their sport, and we cannot overlook the impact of supplementation on sports performance [16].

Given the challenges in providing appropriate supplementation for young athletes, there is limited scientific evidence to develop supplementation guidelines for this population [9,17]. To fulfill, in part, this significant gap, the aim of our systematic review is to identify the studies published on acute (on the same day and/or before/during exercise) supplementation impacts on physical and/or cognitive performance in young athletes. Through this review, we hope to propose effective acute supplementation strategies that support young athletes in enhancing performance.

This systematic review aimed to investigate the acute effects of supplementation on performance in young athletes. The studies included in the review included heterogeneous participants with varied maturational levels, sexes, sample sizes, sports, and methodological approaches. The review encompasses studies with diverse methodologies, including varying exercise intensities, testing environments, and supplementation protocols. While this diversity reflects real-world scenarios, it also complicates direct comparisons and synthesis. The studies included in the review used carbohydrates, beetroot juice, and sodium citrate.

Carbohydrate supplementation consistently improved endurance capacity and increased blood glucose, but mixed effects were found for anaerobic performance. Equivocal findings were reported for beetroot juice, with a single study finding that power production was increased. The initial physical condition may influence the effectiveness of beetroot juice on anaerobic performance, with experienced athletes showing a limited response and recreationally active adolescents demonstrating greater strength gains, possibly due to lower prior physical adaptation [22,27]. The study assessing sodium citrate supplementation found improvements in shooting consistency [32].

Although our review established an age criterion for young individuals, it is essential to consider the complexities associated with maturation and development within this age group. A significant gap in the literature was found during the current review, which precluded adequate filtering of samples by age. Factors such as physical development and maturation can vary in young people. These factors can also affect growth, metabolic, and physiological capacities, and consequently, can influence supplementation outcomes. Notably, the impact of acute supplementation in girls was analyzed in only two studies [13,21]. One of these studies compared girls and adolescent females, demonstrating that exogenous carbohydrates improve glycogen sparing and reduce post-exercise lactate, highlighting potential benefits for prolonged efforts across maturational stages and sexes [13].

In boys, Timmons et al. [31] investigated how chronological age and pubertal stage influence substrate utilization during exercise, emphasizing that pubertal maturation has a greater impact than age. Prepubertal and early pubertal boys demonstrated a higher reliance on exogenous carbohydrates and better glycogen conservation, whereas mid- to late-pubertal boys exhibited increased endogenous carbohydrate oxidation. Additionally, Guth et al. [26] observed that young boys responded differently from adults, with boys who received the carbohydrate drink showing increased glycemia at 24 and 36 min of exercise.

Building upon previous findings, the study by Phillips et al. [11] has notable limitations, including considerable variability in participant body weight (62.0 ± 6.3 kg) and a small sample size (n = 7). The weight discrepancy likely influenced the carbohydrate dose consumed, as the beverage, containing 6% carbohydrate, was administered based on body mass (mL/kg), potentially introducing variability in the outcomes. Additionally, the small sample size reduces statistical power, and these factors call into question the conclusion that the 6% carbohydrate drink is the most effective.

In this review article, considerable methodological differences were reported across the studies. For instance, a wide range of exercise intensities was used in two studies [21,26], while a fixed-duration Wingate protocol was used in three studies [27,28,29]. A range of performance outcomes were used, including, the countermovement jump [22], a T-test [22], a simulated soccer match (termed the LIST) [11,20,24], and sport-specific movements and motor skill assessments [22,25]. Stough et al. [19] evaluated a group of younger children and applied playful activities involving badminton, squash, football, and a “hopping relay” skill. Despite the larger sample size compared to other studies analyzed, the evaluation methodology of Stough et al. [19] was the most complete for incorporating playfulness, adapting movements to the age group, and analyzing impacts on cognitive capacity. These types of assessments enhance testing reliability since the athletes are familiarized with the movements. This methodological approach to acquainting participants with the testing procedures was not apparent and/or reported throughout the studies. As such, learning effects may have occurred during some of the protocols used.

Two double-blind studies involved the application of various micronutrients and examined the performance of both children and young people [11,24]. In the study by Phillips et al. [24], both groups received electrolytes, containing 250 mg sodium, 60 mg magnesium, 90 mg potassium, and 20 mg calcium. Although food and carbohydrate intake were not controlled the day before and the day of the tests, participants were advised to have the same meals with similar portions on both days. This tends to be a method of dietary standardization used across the studies included in this review, particularly in experimental trials involving crossover designs with a placebo and intervention group. It is crucial to ensure that there are no differences in carbohydrate and energy intake between the intervention and placebo groups in the 24-h period preceding both trials. Most studies lacked dietary control [11,19,20,21,24,25,26,27,29,32], which may confound the results, as the benefits of carbohydrate intake on performance are well-established [4,33,34].

Carbohydrate intake’s effect on intermittent endurance and sprint performance was assessed, with participants consuming either 0.818 g/kg BM of carbohydrate gel or a placebo [20]. While sprint times and heart rate showed no significant changes, carbohydrate intake notably improved intermittent endurance capacity, allowing participants to sustain performance for a longer duration during a simulated team game. Carbohydrate gels are better accepted among athletes due to their practicality and digestibility [35]. One of the possible benefits of carbohydrate gels is their ability to offer a large amount of carbohydrates in smaller volumes [1]. Even though the intervention carried out by Phillips et al. [20] did not influence average sprint time, more studies could utilize carbohydrate gels due to their ability to offer high concentrations of carbohydrates in smaller portions. This makes it easier to administer the carbohydrates during competition intervals.

Mettler et al. [36] and Desbrow et al. [17] recommend the requirements for a young athlete during a growth phase while engaging in strenuous physical exertion. These recommendations suggest that children and adolescents require high energy and micronutrient demands to provide energy during peak periods of growth and development [37]. When they are exposed to training with a high energy demand and experience stress associated with competitive environments, it is plausible to assume that carefully considered supplementation would appear warranted to provide additional benefits. When analyzing studies with questionnaires [38,39,40,41], the intake of supplements is part of the routine of many young athletes, especially those at a competitive level. For instance, a recent study conducted in Switzerland involving nearly 500 elite adolescent athletes indicated widespread and large-scale use of dietary supplements, with the most commonly used being vitamin supplements, carbohydrate and electrolyte drinks, creatine, protein bars, and energy drinks. The study also concluded that the population had a low level of knowledge about the effects and purposes of supplementation [36]. Evidence also suggests that the most influential factors of supplementation are purported to be parents and coaches [42], and a large proportion of this population is unaware of the adverse effects of supplementation and unsure of the appropriate amounts and supplements suitable for young athletes [43].

It is challenging to determine the impact that a single acute supplementation may have on young individuals’ health outcomes [44]. For instance, the caffeine content in energy drinks often exceeds the recommended quantities for children and adolescents, which can impair sleep latency and, consequently, muscle growth, mental rest, and hormone production essential for this stage of life. Although caffeine was not addressed in this review, single-use instances in younger individuals can be harmful due to their smaller body mass and sensitivity to dosage [45]. Understanding the short-term effects of these supplements, especially during competitions or intense training, is also important. Even small, acute improvements in performance may, over time, support meaningful adaptations and might enhance overall athletic development [46]. While there are a wealth of studies involving the use of supplements, the efficacy of these substances remains equivocal, as there is a lack of research in young athletes. If these supplements are natural and safe for consumption—such as beetroot juice and other whole foods—meaning they are composed of non-toxic ingredients, free from preservatives, added ingredients, artificial colorings, and sugars, and are formulated with appropriate dosages for young athletes, then more research should be undertaken on their use in this population [47].

Adolescents and children have distinct energy and supplementation needs compared to adults, due to their unique growth and maturation characteristics [48]. These physiological variations become even more evident when examining energy and macronutrient intake in young athletes, which must be adjusted to meet specific growth and developmental needs, taking into account both maturation stage and training volume [49,50,51].

The variability in performance progression among young athletes within the same chronological age category reflects significant differences in growth, maturation, and training response, and consequently in their responses to supplementation [31,52]. Relative age effects favor those born earlier, resulting in the selection of athletes with average or advanced biological maturity, who tend to exhibit greater muscular strength, motor performance, and VO2max compared to their later-maturing peers [49,53]. As individuals mature, physiological changes such as increased hormone production, muscle development, and improved metabolic efficiency directly influence how the body metabolizes nutrients and responds to supplementation [50,53].

These maturation differences not only affect supplementation responses but also how dosages adjusted by kg of body mass should be considered. Early-maturing boys tend to exhibit more pronounced responses to supplements like carbohydrates and proteins due to higher hormonal levels [48,51]. In the present systematic review, the samples included participants at different Tanner stages, with seven studies failing to report maturation status, highlighting important methodological limitations that hinder the interpretation of findings from supplementation studies involving young athletes [19,21,22,23,25,27,32].

Despite the challenges in this area of research, this review showed where focus could be directed in future studies. No prospective studies were eligible for inclusion in the current review (i.e., studies that follow a group of people over time). Nonetheless, these types of studies are crucial to determine the cause-and-effect relationships and to capture changes in behaviors over time and during specific periods of training like competition or post-competition.

This systematic review presents some limitations that affect the practical applicability of acute-use supplements and highlight the need for further research focused on young athletes. First, the included studies used a variety of performance metrics, such as endurance capacity, power, sport-specific skills, and cognitive performance. While this diversity captures the complexity of athletic performance, it also complicates direct comparisons, weakening conclusions about the efficacy of specific supplements.

Additionally, although we used a variety of alternative keywords, we acknowledge that some relevant terms may have been overlooked, potentially limiting the scope of our search and excluding potentially important studies. We suggest that future reviews consider a more comprehensive set of terms to ensure broader literature coverage.

Furthermore, although the aim of the review was to evaluate both physical and cognitive performance, only one study actually explored cognitive outcomes. Given the importance of cognitive development in young athletes, a more detailed analysis of how supplements may influence cognitive functions during athletic activities would provide a more comprehensive understanding of supplementation effects. Another significant challenge is the small sample sizes in many of the studies analyzed, which may contribute to the variability observed in the results. Small samples represent a particularly notable limitation when evaluating complex performance outcomes, as individual variability can hinder robust conclusions. Additionally, inconsistencies in timing and dosage protocols for supplementation across studies add another layer of complexity. While some studies assessed effects immediately after ingestion, others introduced supplementation during exercise, which can affect absorption rates and peak efficacy, making it challenging to establish ideal timing and dosing for young athletes.

Finally, the limited use of advanced physiological assessments and reliance on subjective measures, such as perceived exertion, further complicates the interpretation of results. Objective metrics, such as VO2max, inflammatory markers, blood glucose monitoring, and GPS tracking, could provide more precise insights into the physiological effects of supplements but were rarely included. The lack of dietary control in many studies also represents a significant limitation, introducing the potential for confounding factors that interfere with the observed effects of supplementation.

Although supplementation is often used to enhance performance, some studies included in this review reported side effects that should be considered when recommending such strategies for young athletes. For example, gastrointestinal discomfort was a commonly reported adverse effect, particularly with higher doses of sodium citrate [32]. Nausea and bloating were observed in a few participants consuming concentrated nitrate solutions, which may limit their practical application in competitive settings [22,27]. Additionally, transient increases in perceived exertion and heart rate were noted with carbohydrate supplementation during prolonged or intense activities, potentially indicating a mismatch between energy supply and utilization [23,26]. Manipulating the carbohydrate concentration of the ingested solution has been associated with an increased risk of gastrointestinal distress, as highlighted by Phillips et al. [11]. Although no severe adverse events were reported, these findings underscore the importance of individual tolerance and dose adjustments when using supplements to support the performance of young athletes.

Despite these considerations, carbohydrate supplementation is a well-established strategy to enhance endurance and maintain blood glucose levels during prolonged exercise, particularly in long-duration activities. Consuming 1 g/kg–1.5 g/kg of body mass (BM) approximately 30 min prior to exercise provides a reliable energy source and may contribute to improved performance, particularly in adolescents. However, it is crucial to use these strategies with caution, as individual responses can vary, and the absence of severe adverse effects in the studies reviewed does not guarantee safety across all contexts.

The ingestion of approximately 0.8 g/kg of carbohydrates immediately before exercise and in fractional amounts during exercise has been shown to be especially beneficial for young athletes. This approach supports sustained energy availability, preserves endogenous carbohydrate stores, and may optimize performance in extended physical activities, particularly for children in the early stages of maturation, but individual tolerance should guide its implementation.

For high-intensity activities and technical skill demands, sodium citrate may serve as a useful buffer against muscle acidosis in youth populations. A suggested dose of 0.3 to 0.5 g/kg, administered 60 to 90 min prior to exercise, supports sports requiring explosive power and precision, though individual tolerance should be monitored due to potential gastrointestinal discomfort.

Similarly, beetroot juice containing 5.4 mg/kg BM of nitrate demonstrated greater efficacy in recreationally active youth athletes. Consuming beetroot juice 2–3 h before exercise, or pairing it with other nutrients, may improve nitrate absorption and effectiveness, especially for activities demanding explosive strength. While its application appears promising, more research is needed to confirm its safety and efficacy in young athletes, and its use should be approached with caution.

This systematic review aimed to assess the acute effects of supplementation on performance in young athletes. The findings indicate that carbohydrate supplementation may enhance endurance performance in young athletes, likely by increasing glucose availability. Providing carbohydrate sources during exercise is particularly relevant for young athletes, as their energy reserves are smaller than those of adults due to their lower muscle volume. Additionally, these exogenous glucose sources may be essential for sparing muscle and liver glycogen, stabilizing blood glucose levels, and supplying energy to the brain, which also requires support during exertion. Sodium citrate supplementation improved technical performance. Beetroot juice demonstrated greater efficacy in recreationally active youth athletes. Variability in findings across studies may be attributed to methodological factors, such as dietary control and standardization, participant characteristics, protocols used, and measurement techniques. Young athletes, especially those in phases of growth and development, require tailored nutritional strategies that differ from adult guidelines due to distinct maturation stages and growth rates. These strategies should prioritize essential nutrients to support growth, development, and both physical and cognitive performance. This review seeks to clarify current knowledge on acute supplementation in young athletes, highlight existing evidence, identify research gaps, and inspire further studies to enhance youth sports performance.

FCT-CIDAF doi: 10.54499/UIDP/04213/2020.

BM: Body Mass; CHO: Carbohydrate; CHO-E: Carbohydrates with Electrolytes; CHO-endo: Endogenous Carbohydrate; CHO-exo: Exogenous Carbohydrate; HR: Heart Rate; PL: Placebo; PRISMA: Preferred Reporting Items for Systematic Reviews and Meta-Analyses; RPE: Rating of Perceived Exertion; RR: Respiratory Rate VE: Minute Ventilation; VIE: Variable Intensity Exercise; WAnT: Wingate Test.

The following supporting information can be downloaded at: https://www.mdpi.com/article/10.3390/nu16244304/s1↗, Table S1: Search Strategy and Filters.

N.G., A.M. and H.S. designed the research question and performed the literature search; N.G., H.S. and D.M. analyzed and interpreted the data; N.G., D.M, A.M., A.F. and H.S drafted the manuscript; H.S. approved the final version. All authors have read and agreed to the published version of the manuscript.

The data that support the findings of this study are available from the corresponding author, NG.

The authors declare no conflicts of interest.

This research received no external funding.