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3/2024
vol. 18
 
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PHYSICAL ACTIVITY OF SOCIAL AND PROFESSIONAL GROUPS
Review paper

EFFECTIVENESS OF AQUATIC THERAPY ON FOOTBALL PLAYERS’ PERFORMANCE: A SYSTEMATIC REVIEW

Arnaaz Rusi Doctor
1, 2
,
Priyanshu Rathod
3

  1. School of Physiotherapy, RK University, Rajkot, India
  2. Sunandan Divatia School of Science, NMIMS University, Mumbai, India
  3. Faculty of Medicine, RK University, Rajkot, India
Health Prob Civil. 2024; 18(3): 320-327.
Online publish date: 2024/02/02
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Introduction

Aquatic therapy is a type of exercise that takes place in water. People have been using water for healing purposes for centuries due to its therapeutic properties. However, in the 20th century, aquatic therapy became more popular, especially for movement rehabilitation. The American Physical Therapy Association (APTA) recognized aquatic therapy as a legitimate form of physical therapy and rehabilitation in 1992 [1].

The effectiveness of aquatic therapy can be attributed to several fundamental principles that govern the behavior of water, including buoyancy, thermodynamics, hydrostatic pressure, density, and viscosity. These principles make water a safer and more efficient medium for rehabilitation. Aquatic training significantly reduces the impact forces experienced by bodily tissues during exercise, enabling increased amounts of training before reaching the injury threshold.

Aquatic exercises can significantly reduce peak impact forces (33% to 54%), impulse (19% to 54%), and rate of force development (33% to 62%) compared to land-based exercises. Numerous studies have highlighted the benefits of aquatic therapy in enhancing strength and power following injuries, as well as in sports performance [2-11].

Football is a high-impact contact sport that demands rigorous training regimens involving exercises characterized by substantial intensity and impact forces. The nature of the sport itself, which often includes dynamic movements, sudden changes in direction, and collisions, places football players at an inevitably higher risk of injury during their training sessions.

The training module for football players is designed to enhance all aspects of their physical fitness, which includes strength, speed, agility, and endurance. These exercises often involve dynamic movements, such as sprinting, jumping, and tackling, which impose great stress on the musculoskeletal system. This combination of high-intensity training drills and the repetitive nature of movements can cause overuse injuries that affect joints, muscles, and ligaments.

Aim of the work

The nature of football training demands high-intensity exercises and physical contact that heightens the risk of injuries for players. Therefore, it is of utmost importance to acknowledge these risks, and the implementation of comprehensive injury prevention measures is an integral aspect of ensuring the health and well-being of football athletes throughout their training regimens. This systematic review aims to examine studies conducted within the last decade to assess the effects of aquatic therapy exercise programs on key components of football players’ fitness, including speed, agility, and lower limb power.

Methods

This review study is performed following the PRISMA (Preferred Reporting Items for Systematic Reviews and Meta-Analyses) guidelines [12].

To conduct this review, comprehensive searches were carried out across multiple databases, namely PubMed, Google Scholar, and PEDro. The chosen keywords encompassed terms such as “aquatic therapy”, “sports players”, “football players”, “speed”, “agility”, “power”, “core strength”, and “kick velocity”. Boolean operators “AND” and “OR” were strategically employed to refine search queries, and the search scope was confined to articles published in English within the timeframe of 2012 to 2022. The screening process involved a meticulous examination of titles and abstracts for adherence to predetermined inclusion and exclusion criteria, followed by a thorough assessment of the full texts of potentially eligible articles by two independent reviewers.

Inclusion criteria

  • Male football players;

  • Studies published in English;

  • Studies aimed at determining the effects of the aquatic therapy approach on player performance.

Exclusion criteria

  • Studies conducted on post-injury football players.

To evaluate the quality of selected articles, the researchers used the PEDro scale [13,14], which comprises 11 questions and evaluates internal validity and statistical information. Articles that scored ≥5 out of 10 were considered to be of high methodological quality. The studies were analyzed independently by two investigators using the PEDro scale.

Screening and data extraction were conducted independently by two investigators. Data included year of authorship, study subjects, age, interventions, study duration, outcome measures, and results. Discrepancies between investigators were resolved through discussion.

Literature review results

The inclusion and exclusion criteria led to the retrieval of articles from various databases: Google Scholar (1,440 articles), PubMed (69 articles), and PEDro (3 articles). Of these, 1,050 articles were repeated, therefore 460 abstracts were screened. Subsequently, 450 articles were excluded due to reasons such as unavailability in full text, lack of objectivity failure to meet inclusion criteria, or absence of a control group or non-aquatic therapy intervention. Finally, 10 articles were selected for quality assessment as seen in Figure 1.

Figure 1

Flow diagram showing the screening and selection of articles

/f/fulltexts/HPC/52321/HPC-18-52321-g001_min.jpg

Quality assessment of the study

As shown below in Tables 1 and 2, seven selected articles scored 8/10 [2-4,6,9-11] one scored 7/10 [7], and one scored 6/10 [5] on the PEDro scale. The studies were found to be of high methodological quality when they scored ≥5. One article with a moderate risk of bias had unclear allocation concealment and failed to meet blinding criteria [5].

Table 1

Quality assessment of articles included in systematic review

Authors//CriteriaMurugave et al. [2]Gokul et al. [3]Ajayaghosh et al. [4]Roopchand et al. [5]Daniel et al. [6]Kate et al. [7]Jurado Lavanant et al. [8]Chomani et al. [9]Esayas Hailu et al. [10]Poonyanat Nualona et al. [11]
Article No.12345678910
Random allocation?YesYesYesYesYesYesYesYesYesYes
Concealed allocation?YesYesYesYesYesYesYesYesYesYes
Baseline comparability?YesYesYesYesYesYesYesYesYesYes
Blind participants?YesYesYesNoYesYesYesYesYesYes
Blind therapists?NoNoNoNoNoNoNoNoNoNo
Blind assessors?NoNoNoNoNoNoNoNoNoNo
Follow-up?YesYesYesYesYesNoYesYesYesYes
Intentiontotreat analysis?YesYesYesYesYesYesYesYesYesYes
Group comparisons?YesYesYesNoYesYesYesYesYesYes
Point and variability measures?YesYesYesYesYesYesYesYesYesYes
Cumulative score8886878888
Table 2

Risk of bias assessment table

Article No.Adequate sequence generationAllocation concealmentBlindingIncomplete outcome data addressedFree of selective reportingConclusion
1YesYesYesYesYesLow risk of bias
2YesYesYesYesYesLow risk of bias
3YesYesYesYesYesLow risk of bias
4YesUnclearNoYesYesModerate risk of bias
5YesYesYesYesYesLow risk of bias
6YesYesUnclearYesYesLow risk of bias
7YesYesYesYesYesLow risk of bias
8YesYesYesYesYesLow Risk of bias
9YesYesYesYesYesLow risk of bias
10YesYesYesYesYesLow risk of bias

General data of included studies

Table 3 gives a summary of all the articles included in this systematic review. The selected articles, published between 2012 and 2022, included male football players with ages ranging from 12 to 30. Total subjects (n) in the studies varied from 18 to 65. The intervention duration ranged from one-time studies to three months. The outcome measures included lower limb power, strength, endurance, speed, agility, and cardiovascular endurance.

Table 3

Summary of all articles included in the systematic review

Article No./YearStudy designSubjects/ ageInterventionStudy durationOutcome measureResult
1/Feb 2022Experimental studyn=40
Age:
20-23 years
Group 1: Aqua aerobics
Group 2: Control group
12 weeksStrength endurance- Burpee test, leg explosive
power-standing broad jump test
Improvement – strength
endurance and leg explosive power – Group 1.
Group 1:
Aquatic training
n=60
2/2022Experimental studyAge:Group 2: Nonaquatic training8 weeksSpeed and agilityAquatic group showed improvement.
18-25 years
Group 3: Control group
Group 1:
3/2017Experimental studyn=30
Age:
20-25 years
Aquatic plyometric training
Group 2: Control group
12 weeksSpeed and explosive leg power by 50 meters, Dash and Sargent JumpAquatic plyometric training showed improvement.
n=18
4/2018Experimental studyMean age: 20.89 yearsAquatic plyometric training6 weeksAgility – Illinois Agility Test, lower limb power – vertical jump testSignificant improvement
± 1.78 years
5/2018Experimental studyn=20
Age:
18-30 years
Group 1: Aquatic training
Group 2: Control group
8 weeksVertical stiffness- unilateral hop test, jump performance- jump test, and athletic performance- sprint testImprovement – jump performance and athletic performance in group 1.
6/2013RCTn=29
Age: Adult Club team
Group 1: Aquatic exercise
Group 2:
Contrast therapy shallow water treadmill running
One time studyVertical jump height, visual analog scale (VAS), squeeze test for adductor
strength, sit and reach test, ankle and hip range of movement.
AE program is effective in improving the parameters.
Group A:
Aquatic plyometric training
7/2014Experimental studyn=65
Age: Adult Club team
Group B:
Land plyometric training
10 weeksDrop Jump test and Repeated Jump testAPT showed improvement.
Group C:
Control group
8/2020Experimental studyn=40
Age: Adult Club team
Group 1: Aquatic therapy
Group 2: Control group
2 monthsAgility test, 30 m speed test, vertical jump test, wide jump testAquatic plyometric training – significant improvement.
Group 1:
9/2015Experimental studyn=24
Age: Adult Club team
Land-based exercises
Group 2:
3 months600-yard running, barbell squat, 12 mins runningWater-based exercise group showed better improvement.
Water-based exercises
10/2013RCTn=47
Age: Adult Club team
Group 1: Hydrotherapy group
Group 2:
6 weeksSingle leg hopping testHydrotherapy showed greater improvement.
Land group

[i] Notes: RCT Randomized Control Trial, AE aquatic exercise, APT – aquatic plyometric training.

Outcome measures

Speed was assessed using various sprint tests, agility using the Illinois agility and T-test, lower limb power through vertical jump tests, and cardiovascular endurance using a 12-minute running test and Burpee test for strength-endurance [2-6,9-11]. One of the articles assessed pain using the visual analogue scale (VAS), adductor strength by squeeze test, flexibility using the sit-and-reach test, and range of movement in the ankle and hip [7].

Discussion of the review results

This systematic review aimed to evaluate the effectiveness of aquatic therapy on football players’ performance. It included 10 articles, consisting of eight experimental studies and two Randomized Control Trials (RCTs), all rated high in methodological quality. The studies explored different aquatic training protocols and their effects on football players’ performance parameters, such as speed, agility, leg power, and endurance.

Three studies showed significant improvements in speed and agility following aquatic therapy [3-5,9,10], while five studies reported significant enhancements in leg power [2,4-7]. An RCT conducted as a one-time study concluded that aquatic exercises improve leg strength and flexibility compared to a control group undergoing contrast therapy with shallow water treadmill running [7]. Another RCT showed that six weeks of hydrotherapy significantly improved single-leg tests [11].

Various intervention protocols were employed across the studies, which included aqua aerobics, aqua plyometrics, and aquatic exercises, all of which resulted in performance measure improvements. The variability in sample sizes, ranging from 18 to 60 subjects, as well as the wide array of outcome measures, highlighted the diversity in study design.

Despite variations in methodology, most studies demonstrated significant improvements in football player performance parameters after aquatic therapy, reinforcing its effectiveness as an intervention protocol.

Conclusions

In summary, the examination of aquatic therapy exercises has demonstrated a notable improvement in leg power, speed, and agility among football players. Nevertheless, it is noteworthy to mention that the review of the literature did not identify any studies exploring the impact of aquatic therapy on core strength and kick velocity in football players. Kick velocity is an important component in football that influences the effectiveness of goal scoring, passes, and overall performance. The presence of a research gap in the relationship between kick velocity and aquatic therapy and core strength and aquatic therapy leaves scope for future research to explore its potential impact. Addressing these concerns will help to understand the benefits and applications of aquatic therapy in the field of football training.

Disclosures and acknowledgements

The authors declare no conflicts of interest with respect to the research, authorship, and/or publication of this article.

This research received no specific grant from any funding agency in the public, commercial, or not-for-profit sectors.

Artificial intelligence (AI) was not used in the creation of the manuscript.

Notes

[2] Doctor Rusi A, Rathod P. Effectiveness of aquatic therapy on football players’ performance: a systematic review. Health Prob Civil. 2024; 18(3): 320-327. https://doi.org/10.5114/hpc.2024.134771

References

1 

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2 

Murugavel K, Kodeeswaran N, Prabakaran G, Udhayakumar P. Footballer’s corporeal capability as a result of aqua aerobic exercises: an experimental study. International Research Journal of Modernization in Engineering Technology and Science. 2022; 4(2): 883-889.

3 

Ajayaghosh MV. Training sequel of aquatic plyometric training on selected physical parameters among male soccer players. Training. 2017; 2(6).

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7 

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8 

Jurado-Lavanant A, Alvero-Cruz JR, Pareja-Blanco F, Melero-Romero C, Rodríguez-Rosell D, Fernandez-Garcia JC. The effects of aquatic plyometric training on repeated jumps, drop jumps and muscle damage. InternationalJournalofSportsMedicine.2018;39(10):764-72.10.1055/s-0034-1398574

9 

Chomani SH, Dzai AM, Khoshnaw KK, Joksimovic M, Lilic A, Mahmood A. Effect of aquatic plyometric training on motor ability in youth football players. Health, Sport, Rehabilitation. 2021; 7(1): 66-76. 10.34142/HSR.2021.07.01.06

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Hailu E, Sangeeta RA, Deyou M. Effects of land versus water based fitness program in improving aerobic fitness, muscular strength and speed among young male beginner soccer players. Turkish Journal of Kinesiology. 2015; 1(1): 15-9.

11 

Nualona P, Piriyaprasartha P, Yuktanandanab P. The role of 6-week hydrotherapy and land-based therapy plus ankle taping in a preseason rehabilitation program for athletes with chronic ankle instability. Asian Biomed. 2013; 7(4): 553-559.

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Moseley AM, Herbert RD, Sherrington C, Maher CG. Evidence for physiotherapy practice: a survey of the Physiotherapy Evidence Database (PEDro). Australian Journal of Physiotherapy. 2002; 48(1): 43-9. 10.1016/S0004-9514(14)60281-6

Copyright: © 2024 Pope John Paul II State School of Higher Education in Biała Podlaska. This is an Open Access article distributed under the terms of the Creative Commons Attribution-NonCommercial-ShareAlike 4.0 International (CC BY-NC-SA 4.0) License (http://creativecommons.org/licenses/by-nc-sa/4.0/), allowing third parties to copy and redistribute the material in any medium or format and to remix, transform, and build upon the material, provided the original work is properly cited and states its license.
 
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