- 1China Institute of Sport and Health Science, Beijing Sport University, Beijing, China
- 2Research Department of Physical Education, Xinjiang Institute of Engineering, Urumqi, China
- 3School of Sport Medicine and Physical Therapy, Beijing Sport University, Beijing, China
Background: Adolescent tennis players encounter critical physical demands, but the lack of comprehensive analysis of training types hampers the selection of optimal training programs. This study aims to conduct a systematic literature review to analyze the effectiveness and limitations of various training types on the physical demands of adolescent tennis players, summarizing the optimal training methods to enhance these physical qualities.
Methods: From March 2024, a comprehensive search was conducted across four electronic databases: SCOPUS, PubMed, EBSCOhost (SPORTDiscus), and Web of Science. Additionally, Google Scholar and other sources of gray literature were referenced. Original research articles with an experimental design were included. The methodological quality of the included studies was evaluated using the Physiotherapy Evidence Database (PEDro) scale, and the overall scientific evidence was determined through the best evidence synthesis (BES).
Results: Eighteen articles on exercise training met all inclusion criteria and were included in this systematic review. These studies maintained a high standard of quality, making their findings relatively credible. Among them, five studies investigated plyometric training, five focused on neuromuscular training, three explored functional training, two examined traditional strength training, and three assessed High-Intensity Interval Training.
Conclusion: To enhance speed, strength, power, agility, and dynamic balance, it is recommended to prioritize plyometric training, neuromuscular training, and functional training over traditional tennis training. Functional training is particularly effective for improving flexibility and balance, while plyometric training is more suited for increasing power and speed. Neuromuscular training, when performed before routine workouts, is beneficial for enhancing speed, flexibility, and strength. Hard surface training is ideal for boosting power, whereas sand training excels in improving strength, speed, and balance. Combining HIIT with strength training is especially advantageous for enhancing short-distance sprinting, repeated sprint ability, and power. By appropriately combining and utilizing these training methods, the physical capabilities and sports performance of adolescent tennis players can be comprehensively optimized.
Systematic Review Registration: https://www.crd.york.ac.uk/prospero/, identifier CRD42024578147.
Introduction
Tennis, recognized as the second-most popular global sport after soccer (Pluim et al., 2023), is a high-intensity intermittent sport that demands high levels of technical, tactical, psychological, and physical demands. Over the past decades, the sport has seen increased professionalization and commercialization, attracting more participants to tennis training (Brouwers et al., 2015). The sport’s rigorous requirements for stroke performance make systematic training and development essential.
For adolescent tennis players, technical skills and physical demands are critical to securing victories. Post-age 12, as players experience increases in height and muscle mass, these physical demands become pivotal in match outcomes (Barbaros et al., 2023). Tennis necessitates exceptional speed, strength, power, agility, and dynamic balance, essential for proficient serving and hitting (Lambrich and Muehlbauer, 2022). Adolescent tennis players can reach a maximum sprint speed of 17.4 km/h during matches, requiring over 100 accelerations per match, with an average of only 4.9 rallies per match and a rally duration of 8.3 s (Pluim et al., 2023). Superior speed enables adolescent tennis players to quickly position themselves during fast-paced matches, while strength helps stabilize their bodies for precise and powerful returns. Formidable power enhances the penetrating force of serves and baseline shots, providing a significant competitive edge. Advanced agility enhances footwork control, allowing players to swiftly adjust their posture and maintain balance during volleys and direction changes. Dynamic balance helps players maintain body control, ensuring stability even under pressure (Pluim et al., 2023; Caballero et al., 2021; Turner et al., 2023). Adolescence is a sensitive phase for developing these physical demands, and strategically combined training during this period can optimize the cyclical advancement of athletic demands (Lloyd and Oliver, 2012).
Current training methods for adolescents in tennis include Plyometric, Neuromuscular, Functional, Traditional Strength, and High-Intensity Interval Training (HIIT). Research shows that plyometrics and combined training enhance neural and muscular functions, improving physical demands (Deng et al., 2024). Neuromuscular training, involving exercises with regular short rests, is effective for boosting athletic demands (Lin et al., 2022). Functional training enhances sport-specific strength, flexibility, balance, and coordination (Yildiz et al., 2019). Resistance training increases maximal strength and force demands (Guo et al., 2022). While HIIT improves overall physical demands and metabolism, its effects on the neuromuscular system are less pronounced (Stankovic et al., 2023). Despite these insights, there is a lack of comprehensive summary and evaluation of various training approaches, presenting a challenge for coaches and athletes in selecting optimal training programs.
Considering the current gap in comprehensive analyses of physical training methods for adolescent tennis players, this study proposes a systematic review to thoroughly examine the effects of various exercise regimes on their physical demands. Through a detailed analysis of current literature, we aim to clarify the efficacy and constraints of each training method. This comprehensive understanding will serve as a scientific guide for coaches and athletes, and set a baseline for future investigations in enhancing training strategies for young tennis players.
Materials and methods
Protocol
The protocol for this systematic review adhered to the guidelines set forth by the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) and was registered in PROSPERO with the registration number CRD42024578147.
Search strategy
A comprehensive literature search was conducted using SCOPUS, PubMed, EBSCOhost (SPORTDiscus), and Web of Science. The search was conducted for all articles related to the physical demands of adolescent tennis players up to 31 March 2024. A Boolean search syntax using the operators” AND” and “OR” was applied. The keywords “training*”, “exercise*”, “intervention*”, ”physical training*”, “exercise training*”, “resistance training*”, “strength training*”, “aerobic exercise*”, ”power training*”, “fitness training*”, “endurance training*”, “conditioning training*”, “physical therapy*”, “adolescent*”, ”teen*”, “youngsters*”, “junior*”, “teenager*”, ”boy*”, ”girl*”, ”tennis*” were utilized. An example of a PubMed search is as follows {[“training*” (Title/Abstract) OR “exercise*” (Title/Abstract) OR “intervention*” (Title/Abstract) OR ”physical training*” (Title/Abstract) OR “exercise training*” (Title/Abstract) OR “resistance training*” (Title/Abstract) OR “strength training*” (Title/Abstract) OR “aerobic exercise*” (Title/Abstract) OR ”power training*” (Title/Abstract) OR “fitness training*” (Title/Abstract) OR “endurance training*” (Title/Abstract) OR “conditioning training*” (Title/Abstract) OR “physical therapy*” (Title/Abstract)] AND [“adolescent*” (Title/Abstract) OR ”teen*” (Title/Abstract) OR “youngsters*” (Title/Abstract) OR “junior*” (Title/Abstract) OR “teenager*” (Title/Abstract) OR ”boy*” (Title/Abstract) OR ”girl*” (Title/Abstract)] }AND [”tennis*” (Title/Abstract)]. Additionally, a manual search was conducted on Google Scholar and through reference lists to ensure no pertinent articles were overlooked. The data-gathering process was supported by skilled librarians to ensure accuracy and completeness.
Eligibility criteria
Only scholarly literature published in English was included in this review, regardless of the year of publication. Studies had to meet the criteria outlined in the PLCOS framework to be considered for analysis. Table 1 presents the inclusion and exclusion criteria for the systematic review. Studies were included if they met the following criteria (Pluim et al., 2023): the study must be a peer-reviewed publication in English, discussing a randomized controlled trial (RCT) or a non-RCT assessing the effect of exercise training interventions on physical demands (Brouwers et al., 2015); participants must be young tennis players (both male and female) (Barbaros et al., 2023); the study must have assessed at least one component of physical performance, such as speed, strength, power, agility, or dynamic balance (Lambrich and Muehlbauer, 2022). The study must include an intervention group that utilized a combination of one or more training methods, such as Plyometric, Neuromuscular, Functional, Traditional Strength, or HIIT.
Table 1. Inclusion criteria based on PICOS (population, intervention, comparison, outcome and study design). RCT, randomized controlled trial.
Studies were excluded if they met any of the following criteria (Pluim et al., 2023): included young athletes from sports other than tennis (Brouwers et al., 2015); combined exercise training interventions with other non-exercise training methods or included unsupervised training sessions (Barbaros et al., 2023); were observational studies or interventions focused solely on providing counseling for exercise training implementation; and (Lambrich and Muehlbauer, 2022) were published in languages other than English, including conference abstracts, letters to the editor, case reports, and brief communications.
Study selection
After searching four international electronic databases, the information about the retrieved studies (i.e., title, author, and year) was uploaded into Zotero reference management software to eliminate duplicates. Initially, an experienced librarian assisted with the retrieval process. Subsequently, two independent reviewers screened the titles and abstracts for eligible full-text studies. They then examined the full texts according to the inclusion and exclusion criteria to determine their eligibility. Throughout this process, the two independent reviewers (YG and JX worked independently, and in cases of disagreement, a third reviewer (GD) was consulted until consensus was reached. The selection procedure details are illustrated in Figure 1.
Data extraction and quality assessment
After completing the research selection process, two independent reviewers (YG and JX) collected relevant data from each included study. This data included the study title, participant characteristics, study design, details of the exercise training program, and study outcomes.
The methodology of the included studies was independently evaluated by two reviewers using the Physiotherapy Evidence Database (PEDro) scale. This tool consists of 11 items (Table 2) assessing four methodological domains: randomization, blinding, group comparison, and data analysis. Each item is scored as Yes (1 point) or No (0 points), with the total score excluding qualifying criteria due to their relevance to external validity. The PEDro scale measures methodological quality on a scale from 0 to 10, with higher scores indicating higher quality: 8–10 denotes outstanding quality; 5-7 denotes good quality; 3-4 denotes medium quality; and below 3 denotes poor quality. Additionally, best evidence synthesis (BES) was used to assess the overall body of scientific data. BES classifies evidence into five categories based on methodological quality, the quantity of research, and the consistency of findings (Pluim et al., 2023): Strong evidence: more than two high-quality studies agree on the findings (Brouwers et al., 2015); Moderate evidence: one high-quality study and several low-quality studies agree on the findings (Barbaros et al., 2023); Limited evidence: based on a single study or inconsistent findings from multiple studies (Lambrich and Muehlbauer, 2022); Conflicting evidence: conflicting study findings, with at least 75% consistency among studies (Caballero et al., 2021); No evidence: the finding was not reported in any study.
Table 2. Results of the methodological quality evaluation of the scale Physiotherapy Evidence Database.
Results
Study selection
A total of 3,400 papers were identified through database searches, as illustrated in Figure 1. The papers were distributed across the following databases: Web of Science (1,292), SportDiscus (1,079), Scopus (803), and PubMed (226). An additional eight studies were identified through Google Scholar and reference lists. After manually removing duplicates, 1795 records remained. These records’ titles and abstracts were reviewed, resulting in 63 papers deemed eligible for full-text analysis. Based on the exclusion criteria, an additional 45 studies were removed. Consequently, 18 RCTs and non-RCTs were included in this review to assess the effect of exercise training on the physical demands of young tennis players.
Study quality assessment
The PEDro scores varied from 3 to 7 for the studies included in this review (Table 3). The intra-observer reliability was established at k = 0.81 to 0.83, indicating very high consistency within the same rater across different time points. Similarly, the inter-observer reliability was found to range from k = 0.64 to 0.65, reflecting good agreement between different raters at the same time points. Because of the specificity of tennis training, sixteen publications with a PEDro score of >5, and two with a PEDro score of 3, indicating that the included studies had a high degree of methodological quality and that the research findings were reasonably reliable. Additionally, apart from two studies with a PEDro score of 3, all other studies satisfied the criteria of randomization, baseline similarity of groups, between-group comparison procedures; all of these studies satisfied the point estimate and variability reported; seventeen studies met the criteria for intention to treat analysis; and only one study satisfied the blind assessor criterion, one study dissatisfied <15% dropouts. However, no study has been conducted to justify the use of concealed allocation concealment, blind participants, or blind therapists.
Population characteristics
The population characteristics of the eighteen studies included in this review were evaluated on the following aspects (Pluim et al., 2023): sample size: there were 490 participants in the eighteen studies, ranging from 9 to 16 (Brouwers et al., 2015). gender: all eighteen of these studies examined young tennis players. Thirteen research studies focused exclusively on men, two reported on men and women, whereas the remaining three studies did not specify gender (Barbaros et al., 2023); age: none were over the age of 18. The age varied from 9.6 ± 0.7 to 16.9 ± 0.5 (Lambrich and Muehlbauer, 2022). training background: fifteen studies reported the training background of the participants (Caballero et al., 2021); dominant hand: seven studies reported on the dominant hand of participants, while eleven articles did not report on the dominant hand of participants.
Interventions characteristics
A total of 11 intervention programs are employed in the included studies. These programs encompass neuromuscular training (Fernandez-Fernandez et al., 2024) (Barber-Westin et al., 2010) (Mainer-Pardos et al., 2024) (Fernandez-Fernandez et al., 2018), core training (Bashir et al., 2019), functional training (YILDIZ et al., 2019) (Xiao et al., 2023), strength training (Fernandez-Fernandez et al., 2013), HIIT training (Fernandez-Fernandez et al., 2017) (Kilit and Arslan, 2019), plyometric training (Sinkovic et al., 2023) (Novak et al., 2023) (Behringer et al., 2013) (Fernandez-Fernandez et al., 2016), sprint training (Moya-Ramon et al., 2020), a combination of power and repeated sprint training (Fernandez-Fernandez et al., 2015), neuromuscular warm-up training, dynamic warm-up (Fernandez-Fernandez et al., 2020), rope jumping training (Shi et al., 2023). The duration of the trials covered in the eighteen studies ranged from 6 to 12 weeks. Additionally, the majority of studies use one to three training sessions per week and varied the time of each session from 30 to 90 min.
Based on the titles and abstracts of 16 studies, we categorize the training into five types of interventions: plyometric training, neuromuscular training, functional training, traditional strength training, and HIIT training. Additionally, according to the training plans and rest intervals of two other studies, we include jump rope training under plyometric training and core training under traditional strength training.
Results by training type
In this systematic review, we assessed the impact of various training modalities on adolescent tennis players across 18 studies. Five studies investigated plyometric training: three enhanced speed, power, and agility; two studies improved strength and serve speed, albeit with varied effects on serve accuracy; and one study enhanced dynamic balance. Five studies utilizing neuromuscular training all reported significant enhancements in speed and agility; four studies examined power and strength, each showing significant improvements; one study reported improvements in dynamic balance. Three studies on functional training demonstrated significant improvements in speed, strength, power, agility, and dynamic balance compared to control groups. Two studies on traditional strength training significantly enhanced strength and power but did not improve speed, agility, or dynamic balance. Additionally, it significantly enhanced serve speed without affecting serve accuracy. Two studies used HIIT in combination with other training, and one study examining HIIT training alone and found significant improvements in speed, power, and agility, but agility is not as good as on court tennis training.
Functional training showed significant improvements in power, agility, and dynamic balance compared to traditional strength training; however, there was no significant difference in speed between the two. Plyometric training significantly improved power and physical demands in 5m and 10 m sprint compared to traditional strength training, but it showed no significant difference in agility, and 20 m speed physical demands was inferior to traditional strength training. Neuromuscular training conducted before conventional training significantly improved speed and power, whereas no improvements were noted when neuromuscular training was performed after conventional training, except for in the 10 m sprint. Training on different surfaces revealed distinct impacts: sand surface training was more effective for speed, dynamic balance and strength, while hard training was superior for power; agility and 10 m sprint showed no difference between the two surfaces. Adding resistance bands to plyometric training significantly improved the power of adolescent tennis players, with no enhancements in speed or agility noted. Incorporating HIIT into conventional tennis training did not yield improvements in speed, power and agility. Additionally, combining power training with repeated sprint training significantly enhanced speed and power compared to repeated sprint training alone. Similarly, resistance sprint training improved power and 5 m sprint physical demands over conventional sprint training, but showed no significant differences for 10m, 20m, repeated sprints, or agility.
Discussion
This review encompasses 18 studies focused on evaluating the effects of various sports training modalities on the physical demands of adolescent tennis players. The findings demonstrate that plyometric, neuromuscular, and functional training significantly enhance strength, speed, power, agility, and dynamic balance; HIIT significantly increased endurance but did not improve agility; traditional strength training increased power but did not contribute to speed, agility or balance. It is crucial for the training regimen of adolescent tennis players to consider not only the combination and sequence of different training types but also the integration of multiple methods, as these factors critically influence physical demands enhancements.
Compared to conventional tennis training, plyometric, neuromuscular, and functional training significantly enhanced speed, strength, power, agility, and dynamic balance in adolescents. A high level of technical skill is essential in tennis, yet without a robust physical demands base, consistent and sustainable peak physical demands is unattainable (Lambrich and Muehlbauer, 2022). Plyometric training leverages the stretch-shortening cycle to optimize neuromechanical responses, enabling maximal force generation in minimal time by the nervous and muscular systems. This type of training can bridge the gap between strength and speed, improving throwing, jumping and speed physical demands (Eraslan et al., 2020), athletic physical demands in racquet sports (Deng et al., 2023), and children’s physical demands (Marzouki et al., 2022). Neuromuscular training stimulates peripheral receptors to enhance muscle reaction integration and unconscious movement responses via optimized input signals and cortical integration. This training improves dynamic posture control (Concha-Cisternas et al., 2023) and boosts children’s physical demands, particularly in girls (Faigenbaum et al., 2014). Functional training targets specific segments and connections in the human movement chain to execute precise actions. It includes activities like accelerating, decelerating, and stabilizing multi-dimensional motions that align with targeted actions (Xiao et al., 2021). Functional training emphasizes overall human movement training and can adjust joint angles, improve muscle function, and enhance movement efficiency to improve athletic physical demands (Bashir et al., 2022), and has a positive impact on the physical demands of both untrained children and experienced athletes (Bashir et al., 2022) (Li et al., 2023). Compared to conventional tennis training, HIIT better improves endurance but has poorer agility (Kilit and Arslan, 2019), traditional strength training increased power but did not contribute to speed, agility or balance. HIIT enhances the cardiovascular and metabolic systems through short bursts of high-intensity exercise, improving cardiorespiratory function and both aerobic and anaerobic muscle metabolism (Foster et al., 2015). These physiological adaptations significantly boost endurance performance. However, agility training requires rapid neuromuscular responses and coordination (Chaouachi et al., 2012). Traditional strength training induces neuromuscular adaptations such as improved intra- and inter-muscular coordination, increased muscle-tendon stiffness, and enhanced motor unit recruitment and firing rates, along with morphological changes (Llanos-Lagos et al., 2024). It effectively enhances adolescent power and indirectly improves sprinting and jumping abilities, but does not improve speed, agility, or balance (Westblad et al., 2021). In conclusion, plyometric, neuromuscular, and functional training significantly enhance speed, strength, power, agility, and dynamic balance in adolescents more than traditional tennis training, HIIT is more effective in developing endurance compared to traditional tennis training, and strength training excels in enhancing power over conventional tennis drills.
In addition to the variance in the effects of different training types compared to traditional tennis training on adolescent physical demands, discrepancies also exist among the different training modalities themselves. Functional training, which emphasizes movement patterns, stability, and power rather than isolating specific muscle groups like traditional strength training, significantly enhances power, agility, and balance, but not speed (Yildiz et al., 2019). This findings diverge from previous research, where 8 weeks of functional training improved speed and power more markedly in dragon boat athletes compared to traditional strength training, although it did not significantly enhance strength or agility (Wu et al., 2023). Despite there are differences in sports events, this discrepancy underscores the need for more comprehensive evidence to ascertain the differential effects of functional and traditional strength training in adolescent tennis players. Plyometric training has proven more effective than traditional strength training in enhancing adolescent power and speed (Sinkovic et al., 2023). In boys aged 11–16, maximal speed is determined by the ability to generate high levels of force within a very short ground contact time (approximately 140 milliseconds), while resisting vertical displacement of the center of mass and propelling the body forward (Meyers et al., 2019). Plyometric training, known for influencing stretch-shortening cycle activities, provides optimal responses for rapid, explosive actions, significantly enhances power and speed in adolescents more effectively than traditional strength training (Posnakidis et al., 2022) (Behm et al., 2017). Therefore, improving agility and balance is more suited to the use of functional training and improving power and speed is more suited to the use of plyometric training than strength training.
Different training sequences and surfaces can significantly impact the development of physical demands in adolescent tennis players. The timing of neuromuscular training can greatly affect its efficacy. Conducting neuromuscular training before regular tennis practice, rather than after, more effectively enhances speed, agility, and power (Fernandez-Fernandez et al., 2018). This enhancement is likely due to optimal neural and muscular preparation provided by pre-training sessions, facilitating better muscle fiber activation and recruitment during subsequent exercises. In contrast, neuromuscular training performed after routine practices may induce fatigue, reducing potential benefits in speed, agility, and power (Hammami et al., 2018). The choice of training surface also significantly impacts an athlete’s physical demands. Training on hard surfaces is better suited for improving explosive power (Fernandez-Fernandez et al., 2024) as it provides stable support and minimizes energy loss (Peitz et al., 2018). Conversely, sand training, with its inherent instability, increases muscle loading (Impellizzeri et al., 2008), making it more effective for enhancing strength, speed, and balance demands (Fernandez-Fernandez et al., 2024). However, both surfaces are equally effective in improving agility with no significant differences observed. Optimally utilizing these training environments and methods can significantly enhance training outcomes. Therefore, for optimal enhancement of speed, flexibility, and strength, it is advisable to conduct neuromuscular training before routine sessions; choose hard surfaces for improving explosive power, and sand surfaces for better strength, speed, and balance.
The effectiveness of combining different training methods to enhance the physical demands of adolescent tennis players varies. Incorporating resistance bands in plyometric training significantly enhances power but has minimal impact on speed and agility (Novak et al., 2023). The additional resistance can increase power but may also prolong ground contact time during rapid stretch-shortening cycle movements, which can affect improvements in speed and flexibility (Duchateau and Amiridis, 2023). HIIT combined with power training significantly outperforms traditional HIIT in 10-m sprints and power, with no notable differences in 20-m and 30-m sprints (Fernandez-Fernandez et al., 2015). HIIT integrated with strength training improves speed in 5-m sprints and power over traditional HIIT, but it does not enhance 10-m and 20-m sprints speed, repeated sprints speed and agility (Moya-Ramon et al., 2020). The benefits of combining HIIT with power and strength training likely arise from enhanced muscular strength and neuromuscular adaptability, directly improving physical demands related to explosive power and strength (Chang et al., 2022). Traditional HIIT, focused primarily on aerobic endurance, tends to overshadow the benefits of strength training in tests where endurance is increasingly demanded. Compared to exclusive tennis-specific training, combining specialized tennis training with high-intensity interval running does not yield improvements in speed, power, or agility (Fernandez-Fernandez et al., 2017). The cardiorespiratory endurance benefits of high-intensity interval running may require endurance physical demands metrics for detection. Therefore, for specific training goals and athletic needs, particularly when aiming to enhance short-distance sprinting, repeated sprint ability, and power, integrating HIIT with power and strength training is the superior choice.
This study also has several limitations. First, it only integrates studies comparing functional and plyometric training with traditional strength training and does not comprehensively clarify the advantages and disadvantages between various training modalities. Due to a lack of sufficient research in this area and differences in study designs, it is not possible to conduct a network meta-analysis to obtain higher-level evidence for determining the optimal training approach. Second, due to the limited number of relevant studies, we have not discussed in detail the effects of different age groups, training years or training durations on training outcomes. It would be very valuable if future research could determine which training methods are most effective for specific age groups or levels of experience. Third, as a systematic review of existing studies, this research does not provide definitive conclusions on how to effectively integrate different types of training. Additionally, our review was limited to studies published in English. The exclusion of unpublished data, gray literature, and relevant research in other languages might have introduced bias, potentially leading to an incomplete or skewed representation of the true effects of the training methods evaluated. Lastly, while this review considers the differences between various training types and offers recommendations based on training objectives, it does not provide specific details or guidelines on the content of each training method. The differences that specific training details may produce also warrant further investigation.
Conclusion
In conclusion, the factors influencing the effectiveness of physical training for adolescent tennis players are multifaceted. When selecting training methods to enhance the physical demands of speed, strength, power, agility, and dynamic balance in adolescents, plyometric training, neuromuscular training and functional training should be prioritized over traditional tennis training, while HIIT is preferable for enhancing endurance. Functional training is particularly suitable for improving flexibility and balance, while plyometric training is more effective for enhancing power and speed. Neuromuscular training performed before routine workouts is the better choice for improving speed, flexibility, and strength. Hard surface training should be used to increase explosiveness, whereas sand training is more appropriate for enhancing strength, speed, and balance. Additionally, combining HIIT with strength training is particularly beneficial when there is a need to improve short-distance sprinting, repeated sprint ability, and power, according to specific training goals and athletic requirements. Appropriately combining and utilizing these training methods can comprehensively and optimally enhance the overall physical demands and sports performance of adolescent tennis players.
Data availability statement
The original contributions presented in the study are included in the article/supplementary material, further inquiries can be directed to the corresponding authors.
Author contributions
YG: Writing–original draft, Writing–review and editing. JX: Writing–original draft. GD: Writing–review and editing. DB: Writing–review and editing.
Funding
The author(s) declare that no financial support was received for the research, authorship, and/or publication of this article.
Conflict of interest
The authors declare that the research was conducted in the absence of any commercial or financial relationships that could be construed as a potential conflict of interest.
Publisher’s note
All claims expressed in this article are solely those of the authors and do not necessarily represent those of their affiliated organizations, or those of the publisher, the editors and the reviewers. Any product that may be evaluated in this article, or claim that may be made by its manufacturer, is not guaranteed or endorsed by the publisher.
References
Barbaros P., Dudašek B., Milanović D., Šanjug S., Galić M. (2023). Measuring and assessing motor skills of selected Croatian U12, U14 and U16 tennis players. Front. Physiol. 14, 1241847. doi:10.3389/fphys.2023.1241847
Barber-Westin S. D., Hermeto A. A., Noyes F. R. (2010). A six-week neuromuscular training program for competitive junior tennis players. J. Strength Cond. Res. 24 (9), 2372–2382. doi:10.1519/JSC.0b013e3181e8a47f
Bashir M., Soh K. G., Samsudin S., Akbar S., Luo S., Sunardi J. (2022). Effects of functional training on sprinting, jumping, and functional movement in athletes: a systematic review. Front. Physiol. 13, 1045870. doi:10.3389/fphys.2022.1045870
Bashir S. F., Nuhmani S., Dhall R., Muaidi Q. I. (2019). Effect of core training on dynamic balance and agility among Indian junior tennis players. J. Back Musculoskelet. Rehabil. 32 (2), 245–252. doi:10.3233/BMR-170853
Behm D. G., Young J. D., Whitten J. H. D., Reid J. C., Quigley P. J., Low J., et al. (2017). Effectiveness of traditional strength vs. Power training on muscle strength, power and speed with youth: a systematic review and meta-analysis. Front. Physiol. 8, 423. doi:10.3389/fphys.2017.00423
Behringer M., Neuerburg S., Matthews M., Mester J. (2013). Effects of two different resistance-training programs on mean tennis-serve velocity in adolescents. Pediatr. Exerc Sci. 25 (3), 370–384. doi:10.1123/pes.25.3.370
Brouwers J., Sotiriadou P., De Bosscher V. (2015). Sport-specific policies and factors that influence international success: the case of tennis. Sport Manag. Rev. 18 (3), 343–358. doi:10.1016/j.smr.2014.10.003
Buchheit M., Laursen P. B. (2013). High-intensity interval training, solutions to the programming puzzle. Part II: anaerobic energy, neuromuscular load and practical applications. Sports Med. 43 (10), 927–954. doi:10.1007/s40279-013-0066-5
Caballero C., Barbado D., Hernandez-Davo H., Hernandez-Davo J. L., Moreno F. J. (2021). Balance dynamics are related to age and levels of expertise. Application in young and adult tennis players. PLOS ONE 16 (4), e0249941. doi:10.1371/journal.pone.0249941
Chang Y. H., Chou Y. C., Chang Y. C., Tan K. H., Wu M. H. (2022). The effects of high-intensity power training versus traditional resistance training on exercise performance. Int. J. Environ. Res. Public Health 19 (15), 9400. doi:10.3390/ijerph19159400
Chaouachi A., Manzi V., Chaalali A., Wong D. P., Chamari K., Castagna C. (2012). Determinants analysis of change-of-direction ability in elite soccer players. J. Strength Cond. Res. 26 (10), 2667–2676. doi:10.1519/JSC.0b013e318242f97a
Concha-Cisternas Y., Castro-Piñero J., Leiva-Ordóñez A. M., Valdés-Badilla P., Celis-Morales C., Guzmán-Muñoz E. (2023). Effects of neuromuscular training on physical performance in older people: a systematic review. Life (Basel) 13 (4), 869. doi:10.3390/life13040869
Deng N., Soh K. G., Abdullah B., Huang D. (2023). Effects of plyometric training on measures of physical fitness in racket sport athletes: a systematic review and meta-analysis. PeerJ 11, e16638. doi:10.7717/peerj.16638
Deng N., Soh K. G., Abdullah B. B., Huang D., Xu F., Bashir M., et al. (2024). Effects of plyometric training on health-related physical fitness in untrained participants: a systematic review and meta-analysis. Sci. Rep. 14 (1), 11272. doi:10.1038/s41598-024-61905-7
Duchateau J., Amiridis I. G. (2023). Plyometric exercises: optimizing the transfer of training gains to sport performance. Exerc Sport Sci. Rev. 51 (4), 117–127. doi:10.1249/JES.0000000000000320
Eraslan L., Castelein B., Spanhove V., Orhan C., Duzgun I., Cools A. (2020). Effect of plyometric training on sport performance in adolescent overhead athletes: a systematic review. Sports Health 13 (1), 37–44. doi:10.1177/1941738120938007
Faigenbaum A. D., Myer G. D., Farrell A., Radler T., Fabiano M., Kang J., et al. (2014). Integrative neuromuscular training and sex-specific fitness performance in 7-year-old children: an exploratory investigation. J. Athl. Train. 49 (2), 145–153. doi:10.4085/1062-6050-49.1.08
Fernandez-Fernandez J., De Villarreal E. S., Sanz-Rivas D., Moya M. (2016). The effects of 8-week plyometric training on physical performance in young tennis players. Pediatr. Exerc. Sci. 28 (1), 77–86. doi:10.1123/pes.2015-0019
Fernandez-Fernandez J., Ellenbecker T., Sanz-Rivas D., Ulbricht A., Ferrautia A. (2013). Effects of a 6-week junior tennis conditioning program on service velocity. J. Sports Sci. Med. 12 (2), 232–239.
Fernandez-Fernandez J., García-Tormo V., Santos-Rosa F. J., Teixeira A. S., Nakamura F. Y., Granacher U., et al. (2020). The effect of a neuromuscular vs. Dynamic warm-up on physical performance in young tennis players. J. Strength Cond. Res. 34 (10), 2776–2784. doi:10.1519/JSC.0000000000003703
Fernandez-Fernandez J., Granacher U., Sanz-Rivas D., Sarabia Marín J. M., Hernandez-Davo J. L., Moya M. (2018). Sequencing effects of neuromuscular training on physical fitness in youth elite tennis players. J. Strength Cond. Res. 32 (3), 849–856. doi:10.1519/JSC.0000000000002319
Fernandez-Fernandez J., Nakamura F. Y., Boullosa D., Santos-Rosa F. J., Herrero-Molleda A., Granacher U., et al. (2024). The effects of neuromuscular training on sand versus hard surfaces on physical fitness in young male tennis players. Int. J. Sports Physiol. Perform. 19 (1), 71–79. doi:10.1123/ijspp.2023-0162
Fernandez-Fernandez J., Sanz D., Sarabia J. M., Moya M. (2017). The effects of sport-specific drills training or high-intensity interval training in young tennis players. Int. J. Sports Physiology Perform. 12 (1), 90–98. doi:10.1123/ijspp.2015-0684
Fernandez-Fernandez J., Sanz-Rivas D., Kovacs M. S., Moya M. (2015). In-season effect of a combined repeated sprint and explosive strength training program on elite junior tennis players. J. Strength Cond. Res. 29 (2), 351–357. doi:10.1519/JSC.0000000000000759
Foster C., Farland C. V., Guidotti F., Harbin M., Roberts B., Schuette J., et al. (2015). The effects of high intensity interval training vs steady state training on aerobic and anaerobic capacity. J. Sports Sci. Med. 14 (4), 747–755.
González-Badillo J. J., Sánchez-Medina L., Ribas-Serna J., Rodríguez-Rosell D. (2022). Toward a new paradigm in resistance training by means of velocity monitoring: a critical and challenging narrative. Sports Med. - Open 8 (1), 118. doi:10.1186/s40798-022-00513-z
Guo W., Soh K. G., Zakaria N. S., Hidayat Baharuldin M. T., Gao Y. (2022). Effect of resistance training methods and intensity on the adolescent swimmer’s performance: a systematic review. Front. Public Health 10, 840490. doi:10.3389/fpubh.2022.840490
Hammami A., Zois J., Slimani M., Russel M., Bouhlel E. (2018). The efficacy and characteristics of warm-up and re-warm-up practices in soccer players: a systematic review. J. Sports Med. Phys. Fit. 58 (1–2), 135–149. doi:10.23736/S0022-4707.16.06806-7
Impellizzeri F. M., Rampinini E., Castagna C., Martino F., Fiorini S., Wisloff U. (2008). Effect of plyometric training on sand versus grass on muscle soreness and jumping and sprinting ability in soccer players. Br. J. Sports Med. 42 (1), 42–46. doi:10.1136/bjsm.2007.038497
Kilit B., Arslan E. (2019). Effects of high-intensity interval training vs. On-court tennis training in young tennis players. J. Strength Cond. Res. 33 (1), 188–196. doi:10.1519/JSC.0000000000002766
Lambrich J., Muehlbauer T. (2022). Physical fitness and stroke performance in healthy tennis players with different competition levels: a systematic review and meta-analysis. PLoS One 17 (6), e0269516. doi:10.1371/journal.pone.0269516
Li H., Cheong J. P. G., Hussain B. (2023). The effect of a 12-week physical functional training-based physical education intervention on students’ physical fitness—a quasi-experimental study. Int. J. Environ. Res. Public Health 20 (5), 3926. doi:10.3390/ijerph20053926
Lin J., Zhang R., Shen J., Zhou A. (2022). Effects of school-based neuromuscular training on fundamental movement skills and physical fitness in children: a systematic review. PeerJ 10, e13726. doi:10.7717/peerj.13726
Llanos-Lagos C., Ramirez-Campillo R., Moran J., Sáez de Villarreal E. (2024). Effect of strength training programs in middle- and long-distance runners’ economy at different running speeds: a systematic review with meta-analysis. Sports Med. 54 (4), 895–932. doi:10.1007/s40279-023-01978-y
Lloyd R. S., Oliver J. L. (2012). The youth physical development model: a new approach to long-term athletic development. Strength and Cond. J. 34 (3), 61–72. doi:10.1519/ssc.0b013e31825760ea
Mainer-Pardos E., Villavicencio Álvarez V. E., Moreno-Apellaniz N., Gutiérrez-Logroño A., Calero-Morales S. (2024). Effects of a neuromuscular training program on the performance and inter-limb asymmetries in highly trained junior male tennis players. Heliyon 10 (5), e27081. doi:10.1016/j.heliyon.2024.e27081
Marzouki H., Dridi R., Ouergui I., Selmi O., Mbarki R., Klai R., et al. (2022). Effects of surface-type plyometric training on physical fitness in schoolchildren of both sexes: a randomized controlled intervention. Biol. (Basel). 11 (7), 1035. doi:10.3390/biology11071035
Meyers R. W., Moeskops S., Oliver J. L., Hughes M. G., Cronin J. B., Lloyd R. S. (2019). Lower-Limb stiffness and maximal sprint speed in 11-16-year-old boys. J. Strength Cond. Res. 33 (7), 1987–1995. doi:10.1519/JSC.0000000000002383
Moran J., Ramirez-Campillo R., Liew B., Chaabene H., Behm D. G., García-Hermoso A., et al. (2021). Effects of vertically and horizontally orientated plyometric training on physical performance: a meta-analytical comparison. Sports Med. 51 (1), 65–79. doi:10.1007/s40279-020-01340-6
Moya-Ramon M., Nakamura F. Y., Teixeira A. S., Granacher U., Santos-Rosa F. J., Sanz-Rivas D., et al. (2020). Effects of resisted vs. Conventional sprint training on physical fitness in young elite tennis players. J. Hum. Kinet. 73 (1), 181–192. doi:10.2478/hukin-2019-0142
Novak D., Loncar I., Sinkovic F., Barbaros P., Milanovic L. (2023). Effects of plyometric training with resistance bands on neuromuscular characteristics in junior tennis players. Int. J. Environ. Res. Public Health 20 (2), 1085. doi:10.3390/ijerph20021085
Peitz M., Behringer M., Granacher U. (2018). A systematic review on the effects of resistance and plyometric training on physical fitness in youth- what do comparative studies tell us? PLOS ONE 13 (10), e0205525. doi:10.1371/journal.pone.0205525
Pluim B. M., Jansen M. G. T., Williamson S., Berry C., Camporesi S., Fagher K., et al. (2023). Physical demands of tennis across the different court surfaces, performance levels and sexes: a systematic review with meta-analysis. Sports Med. 53 (4), 807–836. doi:10.1007/s40279-022-01807-8
Posnakidis G., Aphamis G., Giannaki C. D., Mougios V., Aristotelous P., Samoutis G., et al. (2022). High-intensity functional training improves cardiorespiratory fitness and neuromuscular performance without inflammation or muscle damage. J. Strength Cond. Res. 36 (3), 615–623. doi:10.1519/JSC.0000000000003516
Shi Z., Xuan S., Deng Y., Zhang X., Chen L., Xu B., et al. (2023). The effect of rope jumping training on the dynamic balance ability and hitting stability among adolescent tennis players. Sci. Rep. 13 (1), 4725. doi:10.1038/s41598-023-31817-z
Sinkovic F., Novak D., Foretic N., Kim J., Subramanian S. V. (2023). The plyometric treatment effects on change of direction speed and reactive agility in young tennis players: a randomized controlled trial. Front. PHYSIOLOGY 14, 14. doi:10.3389/fphys.2023.1226831
Stankovic M., Djordjevic D., Trajkovic N., Milanovic Z. (2023). Effects of high-intensity interval training (HIIT) on physical performance in female team sports: a systematic review. Sports Med. - Open 9, 78. doi:10.1186/s40798-023-00623-2
Turner M., Russell A., Turner K., Beranek P., Joyce C., McIntyre F., et al. (2023). The association between junior tennis players’ physical and cognitive attributes and groundstroke performance. Int. J. Sports Sci. Coach. 18 (4), 1256–1265. doi:10.1177/17479541221106824
Westblad N., Petré H., Kårström A., Psilander N., Björklund G. (2021). The effect of autoregulated flywheel and traditional strength training on training load progression and motor skill performance in youth athletes. Int. J. Environ. Res. Public Health 18 (7), 3479. doi:10.3390/ijerph18073479
Wu C., Cheong M., Wang Y., Wang X., Zhang Q., Li M., et al. (2023). Impact of functional training on functional movement and athletic performance in college dragon boat athletes. Int. J. Environ. Res. Public Health 20 (5), 3897. doi:10.3390/ijerph20053897
Xiao W., Bai X., Geok S. K., Yu D., Zhang Y. (2023). Effects of a 12-week functional training program on the strength and power of Chinese adolescent tennis players. Child. (Basel) 10 (4), 635. doi:10.3390/children10040635
Xiao W., Soh K. G., Wazir MRWN, Talib O., Bai X., Bu T., et al. (2021). Effect of functional training on physical fitness among athletes: a systematic review. Front. Physiol. 12, 738878. doi:10.3389/fphys.2021.738878
Keywords: physical demands, adolescent tennis, neuromuscular training, functional training, traditional strength training, high-intensity interval training, plyometric training
Citation: Guo Y, Xie J, Dong G and Bao D (2024) A comprehensive review of training methods for physical demands in adolescent tennis players: a systematic review. Front. Physiol. 15:1449149. doi: 10.3389/fphys.2024.1449149
Received: 26 June 2024; Accepted: 03 September 2024;
Published: 13 September 2024.
Edited by:
Giancarlo Condello, University of Parma, ItalyReviewed by:
José Eduardo Teixeira, Instituto Politécnico da Guarda, PortugalMonoem Haddad, Qatar University, Qatar
Copyright © 2024 Guo, Xie, Dong and Bao. This is an open-access article distributed under the terms of the Creative Commons Attribution License (CC BY). The use, distribution or reproduction in other forums is permitted, provided the original author(s) and the copyright owner(s) are credited and that the original publication in this journal is cited, in accordance with accepted academic practice. No use, distribution or reproduction is permitted which does not comply with these terms.
*Correspondence: Gengxin Dong, ZGRneDA0MTlAMTYzLmNvbQ==; Dapeng Bao, YmFvZHBAb3V0bG9vay5jb20=
†These authors have contributed equally to this work and share first authorship