Effects of Nutrition Interventions on Athletic Performance in Soccer Players: A Systematic Review

The expected outcome of this study is to review and analyze the influence of nutrition interventions on the performance of professional soccer players. The primary outcome of this study is to review and analyze the effectiveness of various nutrition interventions in improving the performance of professional soccer players in areas such as endurance, speed, agility, strength, power, explosiveness, and anaerobic capacity. In this study, our primary focus centers on athletes’ performance during the crucial preseason and ongoing training periods. By ‘performance’, we refer to the comprehensive spectrum of physical and skill-related capacities exhibited during these specific times. The preseason period, a significant preparatory phase leading up to competitive seasons, is critical for athletes to condition their bodies, enhance their skills, and mentally prepare for upcoming competitions. Concurrently, the training sessions across the year represent an essential platform for athletes to continuously maintain and advance their skill levels, physical condition, and competitive readiness. The measures and outcomes of these specific periods provide a broad and insightful lens into an athlete’s readiness, development, and potential for in-competition success. The secondary outcome is to evaluate the effectiveness of these interventions in enhancing recovery during the post-match period.

We carried out this systematic review using the PRISMA recommendations and the guidelines of the Cochrane Handbook of Systematic Reviews [83,84]. The protocol for this systematic review can be accessed and provides detailed information on the methodology and search strategies employed [85].

A systematic search was conducted in PubMed, Scopus, and the Web of Science (WOS), covering all studies published before 25 February 2023.

We searched clinical trial registers, including ClinicalTrials.gov, the WHO International Clinical Trials Registry Platform, and the European Clinical Trials Database. We also searched the web for clinical trials to identify relevant publications. We initially created search queries (Figure 1) to link generic keywords associated with clinical trial interventions on nutrition or diet for professional or semiprofessional soccer players. We applied no filters based on the players’ gender or age. When available, we included the publication of a clinical trial’s results in the review.

We searched Google Scholar for published articles of registered clinical trials not yet indexed in the databases (PubMed, Scopus, and WOS).

The inclusion criteria of this study were formulated according to the PICOS principles as follows: (1) P: The subjects were professional or semiprofessional soccer players. (2) I: The experimental group needs to use a nutrition or diet intervention. C: The control group required a different intervention (e.g., another supplement). (4) O: The outcomes were improvements in the players’ performance (without specific outcome measures specified). (5) S: The study type was randomized clinical trials.

We clearly distinguished between professional and semi-professional soccer players in defining our inclusion and exclusion criteria. This differentiation is pivotal to our study as it acknowledges the variance in the levels of physical preparation, training intensity, and body composition characteristics between these two groups. Professional players earn their living by playing soccer, signing club contracts, and being paid a regular salary. They are typically registered with a professional league or federation, as outlined by the FIFA regulations on the status and transfer of players. Professional soccer players train multiple times daily and maintain a body fat percentage typically not exceeding 10–11%, irrespective of the method used to predict fat [86,87].

In contrast, semi-professional soccer players who often play in lower-tier leagues and divisions may exhibit a more wide-ranging body fat percentage. This variability can be attributed to several factors, including less rigorous training regimens, dietary habits, and genetic predispositions [88]. On the other hand, semi-professional players do not depend solely on soccer for their income. While they may receive some form of compensation for playing, they usually have other sources of income and train less frequently, approximately two times a week.

We applied the following exclusion criteria: (1) repeated publication; (2) inability to obtain the full text; (3) incomplete or unavailable data; and (4) studies not published in Spanish or English. We excluded clinical trials that recruited participants or had not published results in clinical trial registries or scientific publications. We selected the most up-to-date information from the clinical trials registry and scientific publications, if available.

We removed duplicate studies using EndNote (version 20; Clarivate Analytics, Philadelphia, PA, USA) [89]. The study selection process was counted with assistance from the Rayyan website and a mobile application [90]. Two reviewers (SGA and FGG) independently screened the titles, abstracts, and keywords. If a study was considered a candidate, the full text was independently assessed and evaluated based on inclusion and exclusion criteria. The third reviewer (LGA) resolved disagreements through consultation with the first two. The authors accessed the full text whenever a study met the inclusion criteria. After searching and evaluating complete articles, four authors (SGA, FGG, LGA, and IAO) independently reviewed the text of all selected studies to determine their inclusion. The authors resolved any differences in their selections through discussion. The writers consulted a fifth author (RAB) if they could not agree.

The information extracted from the articles contained: the author, year, country, participants, sample size in the experimental and control groups (E/C), intervention (E/C), length of intervention days, and outcomes.

We used the Risk of Bias 2 (RoB 2) tool, recommended by the Cochrane Systematic Review Manual (5.1.0) [84,91], to assess the risk of bias in the included literature. This tool was employed to strictly evaluate the quality of the literature. In crossover designs, we used the Risk of Bias tools—RoB 2 for crossover trials [92]. Two reviewers (IAO and LGA) conducted independent assessments of the risk of bias for each included article, categorizing them as “low risk,” “some concerns,” or “high risk.”. Another reviewer (RAB) reviewed the results and resolved any disagreements.

A database search identified 60 records, of which 14 articles met the eligibility criteria [93,94,95,96,97,98,99,100,101,102,103,104,105]. Web searching of clinical trials identified two additional articles [106,107]. Thus, 16 articles were included in this review [93,94,95,96,97,98,99,100,101,102,103,104,105,106,107]. The articles included in this study were published between 1992 and 2023. Figure 2 presents the study selection flow.

There were 11 parallel clinical trials [15,95,96,97,100,101,102,103,105,106,107] and 5 cross-over studies [93,94,98,99,104]. The included studies had publication dates ranging from 1992 to 2023, with a median publication year of 2017.5 and a quartile deviation (QD) of 7 years. Of the sixteen studies included, the participants were only female in one study [37], while the remaining fifteen were male players. There were studies on all the continents except Africa. In 68.8% of the studies, researchers conducted their investigations in Europe. The countries with more studies were the UK (3) and Brazil (2) (Figure 3).

Some studies used several groups, like sedentary people and soccer players. We only studied the soccer players group [103,107]. The total number of participants was 310. The studies were of reduced size, with a median of 18.5 participants (QD = 5). The participants in 3 studies were semiprofessional players, and in 12 studies, professional players.

The Risk of Bias was evaluated separately for Parallel Clinical Trials and Cross Over studies.

Our review includes a range of studies examining various nutritional interventions, such as carbohydrate ingestion, supplementation with creatine, betaine, yohimbine, and other compounds, and the implementation of specific diets, such as the ketogenic diet. Of all the interventions, the more frequent interventions, 11 were dietetics supplements, while only 5 were diet interventions. The intervention more frequent was carbohydrate ingestion in four studies, followed by creatinine supplementation in three papers and tart cherry supplementation in three studies. In Table 1, we present a detailed list of studies, including author, country, design, participants, sex, intervention, control, timing, and duration of the intervention. Three studies conducted interventions during recovery following a game or training session. The remaining 12 studies were in the period prior to the measurement. In the post-studies, the mean of the treatment was one day (SD = 0.99). In the prior intervention, the average time of treatment was 14.95 days (SD = 11.11)

The included studies encompassed various outcome measures, reflecting the diverse aspects of physical conditioning, muscular function, and post-exercise responses in soccer players. The authors categorized these measures into four main groups: physical conditioning tests, muscular strength, power assessments, biomarkers of exercise-induced responses, and subjective assessments. (Table 2) Researchers frequently utilized physical performance tests, including the Loughborough Intermittent Shuttle Test (LIST), countermovement jump (CMJ), sprint tests, agility runs, and Yo-Yo Intermittent Recovery tests, in their studies. These tests evaluate various aspects of soccer performance, including endurance, speed, and agility. Muscular strength and power assessments included maximal voluntary isometric contraction (MVIC) measurements, leg press, bench press, and vertical jump. These outcomes provide insights into the soccer players’ strength, power, and explosiveness.

Additionally, mean power output (MPO) and fatigue index (FI) were assessed in some studies, offering further information about the players’ anaerobic capacity and susceptibility to performance decrements, following the guidelines presented by Enoka and Duchateau [108] on the appropriate usage of fatigue terminology. Biomarkers of exercise-induced responses included oxidative stress markers, vertical ground reaction force (VGRF), electromyography (EMG) muscle activation, and energy expenditure. These markers help evaluate the soccer players’ physiological and neuromuscular responses to the interventions and their potential effects on physical conditioning and post-exercise adaptations.

Subjective assessments, such as perceived recovery and delayed-onset muscle soreness (DOMS), were also reported in the studies. These outcomes provide valuable insights into the soccer players’ subjective experiences of recovery and overall well-being. Players participated in two soccer matches in one crossover study, and the intervention group won both. This result highlights the potential impact of nutritional interventions on real-world competitive outcomes for soccer players.

Overall, the various outcome measures reported across the 16 studies emphasize the complexity of evaluating the effects of nutritional interventions on soccer performance and recovery. In Table 2, we present a detailed summary of the outcome measures employed in each study, offering an overview of the performance and recovery variables assessed.

In light of the distinct physiological demands and nutritional requirements between professional and semi-professional athletes, we have divided theinto two segments to meticulously examine and compare the impact of nutritional interventions on these divergent groups, thereby ensuring the validity and relevance of our findings to each athlete’s specific level of training intensity and body composition. Section 3

There were 12 studies performed with professional soccer players.

There were three studies with semiprofessional soccer players. A crossover study investigated the impact of ingesting a carbohydrate-electrolyte solution on semi-professional soccer players’ recovery and skill performance during a 90-min Loughborough Intermittent Shuttle Test (LIST) [95]. The study used both LIST [18] and the Loughborough Soccer Passing Test as outcome measures to reflect the influence of this intervention on recovery and subsequent skill performance. Despite these measures, the study did not find any improvement in soccer skill performance after the players drank the carbohydrate solution. These results are similar to another study by the same authors that did not find significant differences between the carbohydrate-electrolyte solution and the control group. [20] Tart cherry juice was used in a clinical trial [97] and showed significant differences in countermovement jump (CMJ), maximal voluntary isometric contraction (MVIC), and delayed onset muscle soreness (DOMS). A study comparing the ketogenic diet to the Mediterranean diet reported no difference in physical performance tests, such as the CMJ and the Yo-Yo Intermittent Recovery Test [104].

Despite the varied results from the studies analyzed in this review, it is essential to remember that many athletes, including soccer players, commonly use creatine supplementation due to its established benefits in high-intensity and intermittent exercise scenarios [,,]. Creatine has been shown to enhance muscle phosphocreatine stores, improving performance in activities that involve short, intense bursts of effort [,,]. Athletes in soccer and other sports have used creatine as a supplement to increase energy and reduce fatigue. The ability of creatine to enhance blood flow and oxygen delivery to muscles is a possible explanation for these effects. Recent evidence in the field of creatine supplementation has shifted the traditional approach to creatine dosing. Current research recommends lower daily dosages for effective outcomes instead of the previous high ‘loading’ doses, which often entailed 20–25 g/day for 5–7 days. The recommended dosages of 3–5 g/day or 0.1 g/kg of body mass/day are well-tolerated and effectively increase intramuscular creatine stores, muscle accretion, and muscle performance/recovery []. While the ‘loading’ strategy might be beneficial for athletes seeking to maximize the ergogenic potential of creatine in a short period of time, those planning to use creatine over an extended period or to avoid potential weight gain associated with creatine ‘loading’ might find the ‘maintenance’ strategy more suitable. This shift towards lower daily dosages underlines the increasing emphasis on individualized nutrition strategies in sports performance. ^{99 100 107 99 100 107 74}

Furthermore, while anecdotal reports have associated creatine supplementation with muscle cramping and dehydration, current scientific evidence does not support these claims []. For instance, researchers evaluated injury rates in collegiate football players using creatine and found significantly less cramping, heat illnesses, and dehydration among creatine users than among non-users []. Creatine supplementation may even enhance tolerance to exercise in the heat, potentially reducing the risk of heat-related illnesses. Creatine can improve specific performance markers like repeated sprints, agility runs, and power output in soccer players. While creatine is generally considered safe, athletes should consult a healthcare professional or sports dietitian before starting any new supplementation regimen. As with all supplements, creatine should complement, not replace, a balanced diet and a well-structured training program. ^{74 110}

It is necessary to design randomized double-blind clinical trials with significant sample sizes and factorial designs that study the combination of a high carbohydrate diet and bicarbonate drinks with supplements such as creatine, betaine, and tart cherry.