Background: Several screening tools are available for use in a clinical setting to predict injury. However, there is a lack of evidence regarding the accuracy of these tools to predict soccer-specific injuries.

Objectives: The purpose of this systematic literature review was to determine the psychometric properties or accuracy of screening tools for common soccer injuries.

Methods: A systematic review of diagnostic test accuracy was undertaken based on the Joanna Briggs Institute (JBI) procedure for conducting systematic reviews. Databases such as SPORT Discus, Cinahl, Medline, Science Direct, PubMed and grey literature were searched in order to access suitable studies.

Results: A total of 10 studies were included for the analysis – three were analysed quantitatively whilst the remaining seven were analysed qualitatively. The screening tools were of high reliability, sensitivity and specificity (calculated as intraclass correlation coefficient [ICC] (0.68 95% confidence interval [CI]: 0.52–0.84 and 0.64 95% CI: 0.61–0.66, respectively).

Conclusion: The screening tools assessed for the prediction of common soccer injuries that emerged from this systematic review include the Functional Movement Screening (FMS™), the Landing Error Scoring System (LESS), the Tuck Jump Assessment, the Soccer Injury Movement Screening (SIMS) and the conventional hamstrings to quadriceps ratio; all with good evidence of predicting common soccer injuries. These tools were of high sensitivity and specificity thus reliable for soccer screening.

Clinical implications: The validity of these tools is acceptable and therefore the authors recommend that these tools be included in an injury prevention programme for soccer players.

Keywords: common soccer injuries; common injury risk factors; screening tools prevention and prediction; screening tools accuracy; sensitivity and specificity.

Introduction

Van Mechelen et al.’s sequence of prevention model states that by constant assessment, injury mechanisms and risk factors are identified, highlighting the fact that collecting and recording of data is a core approach for preventing injuries (Van Mechelen, Hlobil & Kemper 1992). A similar proposal states that assessing epidemiological information in teams with similar characteristics, initiating management plans, estimating and assessing risk may help prevent injuries (Clarsen, Myklebust & Bahr 2012; Fuller et al. 2007). Several screening tools are available for use in the clinical setting; these include: the Functional Movement Screening (FMS™) tools, Landing Error Scoring System (LESS), Y-Balance Test, Star Excursion Balance Test, Drop Jump Screening Test and the Tuck Jump Analysis (Chimera & Warren 2016; Lai et al. 2017). These screening tools only recently received researchers’ attention, hence there is a dearth of data regarding their applicability, validity and reliability (Chimera & Warren 2016). For example, the Y-Balance Test (YBT) used alone is reported by Lai et al. (2017) as not being capable of predicting injury to the lower extremities and recommends caution by rehabilitation professionals in its use as a standalone screening tool for injuries. However, the YBT is touted as being capable of identifying at-risk soccer players when included in physical examinations (Gonell, Aurelio & Romero 2015).

Several systematic reviews related to common soccer injuries have been conducted mostly in high-income countries. However, none of them addressed the screening tools for common soccer injuries. The focus of the reviews was on the risk factors for hamstring and groin injuries (Foreman et al. 2006; Maffey & Emery 2007; Shadle & Cacolice 2016; Van Beijsterveldt et al. 2013). The only review that explores the screening tools to predict injury to the lower extremities is not specific to soccer as it involved a wide range of team sports, namely hockey, football, soccer, volleyball and basketball (Dallinga, Benjaminse & Lemmink 2012).

The systematic review of Dallinga et al. (2012) on the screening apparatus for lower limb injuries, did however make a clinical contribution to recognise tests, which may foresee injuries in sport by employing a search technique that comprised articles from the nineties. They followed a set of incorporated criteria and analysed methodological positioning.

A need to conduct a systematic review to establish the validity and reliability of screening tools in soccer was therefore identified. This was further supported by a statement by Bahr (2016) who reports scepticism about the effectiveness of risk factor screening tools in predicting injury to a satisfactory level of accuracy for reducing injury risk, mainly because of a lack of research evidence.

The validity and reliability (accuracy) of screening tools used in soccer, in the context of soccer-specific epidemiology and risk factors, therefore need to be established to determine the effectiveness of their clinical use. Applicability can then be determined by the evaluation of the tests’ properties in pertinent populations using factual statistical tools (Bahr 2016). The purpose of our study was to conduct a systematic review on screening tools for common soccer injuries and the accuracy of the available screening tools to determine injuries in soccer players.

Method

Our systematic review of diagnostic test accuracy was performed based on the Joanna Briggs Institute (JBI) guidelines (Campbell et al. 2020) (see Appendix 1) with a meta-analysis (forest plot) to increase analytic precision in the quantitative systematic reviews. The population involved was soccer players, male and/or female. The context entailed the inclusion of professional, elite and social players. The context of the studies included screening tools and accuracy of screening tools. The index tests included screening tools for common soccer injuries, whilst the outcomes referred to the validity and reliability of the included tests. Non-English studies, those published before 2000, and animal studies, were excluded. Observational, prospective and retrospective cohort, case-control, cross-sectional studies, case series and case reports, as well as clinical studies such as randomised clinical trials and other comparative studies were included.

Data sources and searches

In order to access the relevant literature for our review, the search procedure was accomplished by three distinct steps:

Selection of studies and methodological quality

Relevant studies were selected based on their abstracts and titles. It also involved critical appraisal of the selected studies using the JBI quality appraisal tool (Campbell et al. 2020). The items of the appraisal tool used consists of study, author, sample type, method of recruiting participants, sample size, settings, analysis, outcome measurement, measurement validity, statistical analysis, important differences accounted for, subpopulation objective criteria and the decision for inclusion or exclusion with an additional option of providing further information. The selection of studies and the critical appraisal of the studies were conducted blindly by the first author and an assistant (RC and JA). Inconsistencies in the data reviewed were resolved through discussion with the second author (CB).

Risk of bias

The risk of bias (ROB) was assessed by the three authors and followed the guidelines stated in the risk of bias of Non-Randomised Studies (ACROBAT-NRSI version 1.0.0) tool. The ROB assessment for each study has seven domains.

The domains are described as: bias because of confounding, selection bias of participation, bias in measurement of interventions, bias because of departures from intended interventions, missing data bias, outcome measurement bias and selective reporting bias. These domains were judged using the ‘low’, ‘moderate’, ‘serious’ and ‘critical’ scale.

Grade of evidence

The grade of evidence was based on 10 recommended key items (Mueller et al. 2018). Ten key recommendations were observed for the class of evidence for the review, namely protocol development, research question, search strategy, study eligibility, data extraction, study designs, risk of bias assessment, publication bias, heterogeneity and statistical analysis. Five domains (risk of bias, inconsistency, indirectness, impression and publication bias) as described by Guyatt et al. (2008) were also considered to determine the confidence in the overall estimates and recommendations.

Data extraction

We used a standardised data extraction tool to extract the significant data from the included articles. This was independently undertaken by the first author (RC) and an assistant (JA) and unresolved inconsistencies were resolved by the second author (CB). The data extracted included social, demographic, seasonal and other factors, dates of survey or intervention, definitions of conditions and populations, inclusion and exclusion criteria, mean age, sex, sample size, statistical methods used to analyse data in the identified studies, specificity and sensitivity.

Data analysis

Data were analysed using Stata statistical software, version 15.1. Incidence rates and odds ratios, and sensitivity and specificity were analysed with their respective 95% confidence intervals. I ² statistic was used to determine the proportion of variation across studies. The forest plot area summarises the results of the test for heterogeneity that was performed.

Results

Characteristics of included studies

Database searches returned a total of 95 related studies. Of these 95 studies, 24 were duplicates, whilst 17 studies were retrieved for inclusion based on the selection criteria, population, context and outcome (Figure 1). Fifty-four studies did not meet the population, context and outcome of our review and seven full text studies were excluded as shown in Table 1. Ten studies were therefore included in our review. The characteristics of these studies are shown in Table 2.

Risk of bias

The overall judgements showed that out of 10 studies, 7 studies (70%) were graded low risk and 3 studies (30%) were graded moderate risk. One study (Silva et al. 2017) showed bias in confounding, whilst Hammes et al. (2016) also showed selection bias. The source of funding was not reported by any study (Table 3).

Methodology quality

This checklist has three scoring systems, namely, include, exclude or seek further information. The items of the checklist are sample size, sample type, aim, follow-up duration, dependent variables, outcome, outcome measurements, data analysis and identification of objectives. ‘Yes’ or ‘No’ was used to tell if one of the items on the checklist was present or not. A study with a score less than seven was excluded. Of 17 full texts studies, only 10 met the score for inclusion as seen in Table 4.

Meta-analysis of findings

For the sensitivity and specificity of screening tools and their accuracy, only three studies reported the estimates with 95% confidence intervals and were therefore suitable to be included in the meta-analysis. These studies are summarised in Table 5. There was considerably high intraclass correlation coefficient (ICC) for sensitivity and specificity (0.68, 95% confidence interval [CI] [0.52–0.84] and 0.64, 95% CI [0.61–0.66], respectively).

In Figures 2 and 3, the horizontal axis on the forest plot represents the estimates with 95% confidence intervals of the included studies` sensitivity and specificity, respectively. Studies with wider confidence intervals were assigned a lower weighting. Grygorowicz et al. (2017) had a weighting of 18.31, Chorba et al. (2010) a weighting of 49.98 and Padua et al. (2015) a weighting of 31.71. The vertical line, namely the ‘line of null effect’, was used to interpret the significance of the statistic. The diamond represents overall estimate and confidence intervals when considering the combined results (Reid 2006). A significant overall estimate (sensitivity ICC 0.68, 95% CI [0.52–0.84] and specificity ICC 0.64 95% CI [0.61– 0.66]) of the combined studies was found as the diamond did not cross the line of null effect (Figures 2 and 3). To determine the proportion of variation across the studies, the I² statistic was used to quantify the heterogeneity from 1% to 100%. The heterogeneity was statistically insignificant (p = 0.316 and 0.253) as indicated by I ² < 40% and the overlap of the 95% CIs on the forest plots (Figures 2 and 3).

Narrative analysis

Screening tools

Four studies discussed FMS™ scores and tests as potential tools for predicting or preventing common soccer injuries. The FMS™ tools used by Silva et al. (2017) included test items such as the deep squat, hurdle step, in-line lunge, shoulder mobility, active straight-leg raise, trunk stability push-up, rotary stability, three clearing examinations, jump performance, instep kick speed (shot speed) and anaerobic performance to determine associations with FMS™ individual scores and overall FMS™ scores. The results suggest that FMS™ is suitable to determine the physical performance of soccer players and should not be used for downgrading their functional performance. This is because individual FMS™ scores may be a better determinant of performance than the FMS™ total score. In addition, the authors established minimal association between FMS™ scores and physical variables.

Lehance et al. (2009) compared pre-season muscular strength and power profiles in professional and junior elite soccer players, using functional performance, squat jump and 10-m sprints. The results showed that there was no significant difference in isokinetic muscle strength performance between the three groups in the study when considering normalised body mass parameters. Individual isokinetic profiles enabled the identification of 32 out of 57 (56%) participants presenting with lower limb muscular imbalance. Thirty-six out of 57 players were identified as having sustained a previous major lower limb injury. Of these 36 players, 23 still showed significant muscular imbalance (64%).

Hammes et al. (2016) showed that screening tools such as FMS™ are limited in predicting common soccer injuries in veteran football. The results showed that the potential risk factors for injuries in veteran football are age, lower body mass and a longer career.

To evaluate the inter- and intra-rater reliability of the test battery on a group of male elite soccer players, Frohm et al. (2012) used an FMS™ tool, which included the following items: one-legged squat, two-legged squat, straight-leg raise test, seated rotation test, in-line lunge test and active hip flexor test. The test battery was used to predict injuries caused by stability and mobility of the lower limb. The results of the study showed good inter-rater and intra-rater reliability and a strong need for future validation.

Accuracy of screening tools

Padua et al. (2015) showed that the LESS can be used to predict and prevent anterior cruciate ligament injuries, whilst Chorba et al. (2010) showed that anterior cruciate ligament rupture injuries can be predicted using the FMS™ tools. Grygorowicz et al. (2017) investigated conventional hamstring to quadriceps ratio to predict and prevent hamstring injuries. It was shown to be significant; however, because of the different threshold values, it was also shown to be highly biased. Gabbe et al. (2004) discussed musculoskeletal tests in his study, which demonstrated an excellent overall reliability (ICC 0.88–0.97) and an intra-rater reliability (ICC) of 0.63–0.99. The results showed that the sit and reach test, lumbar spine extension ROM, active hip internal ROM, active hip external ROM, passive straight-leg raise, active knee extension test and active slump test are reliable to use as pre-participation screening tools for sport participants.

To analyse the within-subject variation of the tuck jump screening assessment in elite male youth soccer players, Read et al. (2017) used the tuck jump assessment tool, which proved to be reliable in assessment. The assessments included elite male soccer players and showed that caution should be applied when solely interpreting the composite score because of the high within-subject variation in a number of individual criteria.

McCunn et al. (2017) assessed the intra- and inter-rater reliability of the SIMS using five sub-tests: the anterior reach (AR), single-leg deadlift (SLDL), in-line lunge (ILL), single-leg hop for distance (SLHD) and tuck jump (TJ). The action of the movement was filmed using an iPhone 4 device to obtain scores, which were compared individually as participants were blinded. The five sub-tests show to have acceptable landmarks with an odds ratio of 3.850 (CI 95% [0.980, 15.130]).

Discussion

The pooled result from this review showed that there is a high sensitivity (ICC 0.68, 95% CI [0.52–0.84]) and high specificity (ICC 0.64, 95% CI [0.61–0.66]) amongst the included screening tools for preventing and predicting common injuries in soccer players. The screening tools included the FMS™, LESS and the conventional hamstring to quadriceps ratio. Chorba et al. (2010) showed that anterior cruciate ligament ruptures can be predicted using the FMS™ tool. The LESS, which is a variation of the drop jump test (DJT), used for evaluating landing patterns also emerged in this systematic review as a screening tool with high specificity and sensitivity. One of the included studies in the review (Padua et al. 2015) investigated the LESS as a screening tool for an anterior cruciate ligament injury-prevention programme in elite-youth soccer athletes. It shows that the LESS tool can be used to predict and prevent anterior cruciate ligament injuries. Studies on the accuracy of the LESS tool posit the tool as a valid and reliable screening tool for predicting and preventing soccer injuries irrespective of the skill sets of the rater. The construct validity of the LESS was established and the inter-rater reliability and intra-rater reliability of LESS were given as ICC = 0.84 and ICC = 0.91, respectively (Onate et al. 2010; Padua et al. 2009, 2011). Studies related to determining the accuracy of the LESS have largely been conducted by the same group of researchers; however, the emergent result from this systematic review is supportive of the conclusion that the LESS has high accuracy as a screening tool to predict and prevent common soccer injuries.

The findings of the study by Grygorowicz et al. (2017) on the use of conventional hamstrings to quadriceps ratio to predict and prevent hamstrings injuries amongst professional male soccer players were also significant. The findings were, however, biased because of the different threshold values. Therefore, caution must be exercised when utilising it for the purpose of predicting and preventing common soccer injuries and use in the clinical situation.

Similar to the meta-analysis for the accuracy of screening tools for common soccer injuries, the studies included in the qualitative discussion reported high accuracy of the included screening tools. The risk of bias shows 70% of studies with low risk and 30% with moderate risk.

Seven studies with a combined participant number of 335 were included in the objective to identify screening tools for soccer. These studies discussed functional screening scores and tests (FMS™) as potential tools for predicting and preventing common soccer injuries, but used different variations of the tests. The good reliability of the FMS™ could be the reason for its dominance amongst the included studies in this section of the systematic review. For example, Lehance et al. (2009) investigated the muscular strength, functional performances (squat jump and 10 metre sprint) and injury risk in professional and junior elite soccer players to compare pre-season muscular strength and power profiles in professional and junior elite soccer players. Studies show that the FMS™ has good reliability especially amongst American elite soccer players (Chimera & Warren 2016; Smith et al. 2013). An included study by Frohm et al. (2012) on reliability for a nine-test screening battery for male elite soccer players involved the use of FMS™ comprising one-legged squat, two-legged squat, straight-leg raise test, seated rotation test, in-line lunge test and active hip flexor test to predict injuries that are caused by stability and mobility of the lower limb. The study by Silva et al. (2017) included the deep squat, hurdle step, in-line lunge shoulder mobility, active straight-leg raise, trunk stability push-up and rotary stability, three clearing examinations, jump performance, in-step kick speed (shot speed) and anaerobic tests as part of functional assessment. The results from the study by Silva et al. (2017) suggest that FMS™ is suitable to determine the physical performance of soccer players for injury prediction and prevention. The study further suggested that FMS™, on the other hand, is not suitable for determining the weakness in the functional performance of soccer players as identified by individual FMS™ scores. Hammes et al. (2016), in determining the injury prediction in veteran football players using the FMS™, further strengthened the conclusion by Silva et al. (2017) that a screening tool like the FMS™ is limited to predict common soccer injuries especially amongst veteran soccer players.

Grade of evidence

Ten key recommendations were observed for the class of evidence for our review according to Mueller et al. (2018): the protocol was developed at the initial stage of this systematic review; a research question was developed , followed by the study search strategy as defined in the protocol; the database to be searched and keywords were identified; the study eligibility had inclusion and exclusion criteria that were stated in the protocol; data extraction and the method of data extraction were performed by two blinded researchers; the study design was initially specified; the risk of bias was carried out; heterogeneity was observed; statistics were undertaken. Publication bias, however, needs to be considered as studies were only included from the year 2000–2018.

Considering the five domains of the GRADE system (Guyatt et al. 2008) and the types of studies included in the meta-analysis, there is only level 2 evidence available on the accuracy of screening tools to predict common soccer injuries.

Limitations and recommendations

The limitation of our study is based on the extraction of data from included studies. Most studies did not give the specificity and sensitivity of screening tools, and therefore only a limited number of three studies were included in the meta-analysis. It does however indicate the need for studies to determine the accuracy of screening tools.

It is also important to note that although evidence exists on screening tools for injuries, many of the studies were generic and not focused on soccer injuries. Many of the available studies also have low methodological quality, which prevented many of them from meeting the inclusion criteria of our study. Hence, there is a need for sport professionals and scholars to focus more on conducting well-designed studies to determine the accuracy of screening tools for common soccer injuries.

Conclusion

The screening tools assessed for the prediction of common soccer injuries that emerged from this systematic review include the FMS™, the LESS, the Tuck Jump Assessment, the Soccer Injury Movement Screening (SIMS) and the conventional hamstrings to quadriceps ratio with high evidence of predicting common soccer injuries. These tools were of high sensitivity and specificity and can thus be recommended for use in clinical practices.

Acknowledgements

The work is a dissertation submitted to the Faculty of Health Sciences at the University of the Witwatersrand, in fulfilment of the requirements for the degree of Master of Science in Physiotherapy. The authors thank the staff of the Department of Physiotherapy of the University of the Witwatersrand for contributing to the success of this work.

The authors declare that they have no financial or personal relationships which may have inappropriately influenced them in writing this paper.

All authors contributed equally to this work. All authors read and approved the final article.

Ethical waiver for this study was obtained from the Human Research Ethics Committee of the University of the Witwatersrand, Johannesburg, South Africa. Reference number: W-CBP-180917-3.

This study received no specific grant from any funding agency in the public, commercial or non-profit sectors.

Data sharing is not applicable to this article as no new data were created or analysed during this study.

The views and opinions expressed in this article are those of the authors and do not necessarily reflect the official policy or position of any affiliated agency of the authors.

References

Amin, D., 2013, ‘Functional screening of semi-professional footballer: A case study,’ sportEX medicine 57(July), 7–11.

Armstrong, R. & Greig, M., 2018, ‘The functional movement screen and modified star excursion balance test as predictors of T-test agility performance in university rugby union and netball players’, Physical Therapy in Sports 31(May), 15–21. https://doi.org/10.1016/j.ptsp.2018.01.003

Bahr, R., 2016, ‘Why screening tests to predict injury do not work-and probably never will. A critical review’, British Journal of Sports Medicine 50(13), 776–780. https://doi.org/10.1136/bjsports-2016-096256

Campbell, J.M., Kulgar, M., Ding, S., Carmody, D.P., Hakonsen, S.J., Jadotte, Y.T. et al., 2020, ‘Diagnostic test accuracy systematic reviews’, in E. Aromataris & Z. Munn (eds.), JBI manual for evidence synthesis, JBI, viewed June 2018 from https://synthesismanual.jbi.global. https://doi.org/10.46658/JBIMES-20-10.

Chalmers, S., Fuller, J.T., Debenedictis, T.A., Townsley, S., Lynagh, M., Gleeson, C. et al., 2016 ‘Asymmetry during preseason functional movement screen testing is associated with injury during a junior Australian football season’, Journal of Science and Medicine in Sport. Sports Medicine Australia 20(7), 653–657. https://doi.org/10.1016/j.jsams.2016.12.076

Chimera, N.J. & Warren, M., 2016, ‘Use of clinical movement screening tests to predict injury in sport’, World Journal of Orthopedics 7(4), 202. https://doi.org/10.5312/wjo.v7.i4.202

Chorba, R.S., Chorba, D.J., Bouillon, L.E., Overmyer, C.A. & Landis, J.A., 2010, ‘Use of a functional movement screening tool to determine injury risk in female collegiate athletes’, North American Journal of Sports Physical Therapy. NAJSPT 5(2), 47–54.

Clarsen, B., Myklebust, G. & Bahr, R., 2012, ‘Development and validation of a new method for the registration of overuse injuries in sports injury epidemiology’, British Journal of Sports Medicine 47(8), 495–502. https://doi.org/10.1136/bjsports-2012-091524

Dallinga, J.M., Benjaminse, A. & Lemmink, K.A.P.M., 2012, ‘Which screening tools can predict injury to the lower extremities in team sports? A systematic review’, Sports Medicine 42(9), 791–815. https://doi.org/10.2165/11632730-000000000-00000

Foreman, T.K., Addy, T., Baker, S., Burns, J., Hill, N. & Madden, T., 2006, ‘Prospective studies into the causation of hamstring injuries in sport. A systematic review’, Physical Therapy in Sport 7(2), 101–109. https://doi.org/10.1016/j.ptsp.2006.02.001

Frohm, A., Heijne, A., Kowalski, J., Svensson, P. & Myklebust, G., 2012, ‘A nine-test screening battery for athletes. A reliability study’, Scandinavian Journal of Medicine and Science in Sports 22(3), 306–315. https://doi.org/10.1111/j.1600-0838.2010.01267.x

Fuller, C.W., Molloy, M.G., Bagate, C., Bahr, R., Brooks, J.H.M., Donson, H. et al, 2007, ‘Consensus statement on injury definitions and data collection procedures for studies of injuries in rugby union’, Clinical Journal of Sport Medicine 17(3), 177–181. https://doi.org/10.1097/JSM.0b013e31803220b3

Gabbe, B.J., Bennell, K.L., Wajswelner, H. & Finch, C.F., 2004, ‘Reliability of common lower extremity musculoskeletal screening tests’, Physical Therapy in Sport 5(2), 90–97. https://doi.org/10.1016/S1466-853X(04)00022-7

Gonell, A.C., Aurelio, J. & Romero, P., 2015, ‘Relationship between the y balance test scores and soft tissue injury incidence in a soccer team’, International Journal of Sports Physical Therapy 10(7), 955–966.

Grygorowicz, M., Michałowska, M., Walczak, T., Owen, A., Grabski, J.K., Pyda, A. et al., 2017, ‘Discussion about different cut-off values of conventional hamstring-to-quadriceps ratio used in hamstring injury prediction among professional male football players’, PLoS One 12(12), 1–18. https://doi.org/10.1371/journal.pone.0188974

Guyatt, G.H., Oxman, A.D., Kunz, R., Vist, G.E., Falck-Ytter, Y. & Schunemann, H.J., 2008, ‘What is ‘quality of evidence’ and why is it important to clinicians?’, British Medical Journal (Clinical research ed) 336(7651), 995–998. https://doi.org/10.1136/bmj.39490.551019.BE

Hammes, D., Der Funten, K., Bezzini, M. & Meyer, T., 2016, ‘Injury prediction in veteran football players using the functional movement screen^TM’, Journal of Sports Sciences 34(14), 1371–1379. https://doi.org/10.1080/02640414.2016.1152390

Hartley, D., 2016, ‘Considerations to reduce injury rates in the professional football setting Injury surveillance and screening,’ Co-Kinetic Journal 69(July), 25–30.

Lai, W.C., Wang, D., Chen, J.B., Vail, J., Rugg, C.M. & Hame, S.L., 2017, ‘Lower quarter y-balance test scores and lower extremity injury in NCAA division i athletes’, Orthopaedic Journal of Sports Medicine 5(8), 1–5. https://doi.org/10.1177/2325967117723666

Lehance, C., Binet, J., Bury, T. & Croisier, J.L., 2009, ‘Muscular strength, functional performances and injury risk in professional and junior elite soccer players’, Scandinavian Journal of Medicine and Science in Sports 19(2), 243–251. https://doi.org/10.1111/j.1600-0838.2008.00780.x

Lichtenstein, M.B., Christiansen, E., Bilenberg, N. & Støving R. K., 2014, ‘Validation of the exercise addiction inventory in a Danish sport context’, Scandinavian Journal of Medicine & Science in Sports 24(2), 447–453. https://doi.org/10.1111/j.1600-0838.2012.01515.x

Maffey, L. & Emery, C., 2007, ‘What are the risk factors for groin strain injury in sport?’, Sports Medicine 37(10), 881–894. https://doi.org/10.2165/00007256-200737100-00004

McCunn, R., Der Fünten, K., Govus, A., Julian, R., Schimpchen, J. & Meyer, T., 2017, ‘The intra- and inter-rater reliability of the Soccer Injury Movement Screen (Sims)’, International Journal of Sports Physical Therapy 12(1), 53–66. https://doi.org/10.1177/1352458511422926

Moher, D., Liberati, A., Tetzlaff, J. & Altman, D.G., 2009, ‘The PRISMA Group (2009). Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement’, PLoS Medicine 6(6), e1000097. https://doi.org/10.1371/journal.pmed1000097

Mueller, M., D’Addario, M., Egger, M., Cevallos, M., Dekkers, O., Mugglin, C. et al., 2018, ‘Methods to systematically review and meta-analyse observational studies: A systematic scoping review of recommendations’, BMC Medical Research Methodology 18(1), 44. https://doi.org/10.1186/s12874-018-0495-9

Onate, J., Onate, J., Cortes, N., Welch, C. & Lunen, B.V., 2010, ‘Expert versus novice interrater reliability and criterion validity of the landing error scoring system’, Journal of Sport Rehabilitation 19(1), 41–56. https://doi.org/10.1123/jsr.19.1.41

Padua, D.A., Boling, M.C., Distefano, L.J., Onate, J.A., Beutler, A.I. & Marshall, S.W., 2011, ‘Reliability of the landing error scoring system-real time, a clinical assessment tool of jump-landing biomechanics’, Journal of Sport Rehabilitation 20(2), 145–56. https://doi.org/10.1123/jsr.20.2.145

Padua, D.A., DiStefano, L.J., Beutler, A.I., Motte, S.J., DiStefano, M.J. & Marshall, S.W., 2015, ‘The landing error scoring system as a screening tool for an anterior cruciate ligament injury-prevention program in elite-youth soccer athletes’, Journal of Athletic Training 50(6), 589–595. https://doi.org/10.4085/1062-6050-50.1.10

Padua, D.A., Marshall, S.W., Boling, M.C., Thigpen, C.A., Garret,t W.E. Jr & Beutler, A.I., ‘The landing error scoring system (LESS) is a valid and reliable clinical assessment tool of jump-landing biomechanics: The JUMP-ACL study’, The American Journal of Sports Medicine 37(10), 1996–2002. https://doi.org/10.1177/0363546509343200.

Read, P., Oliver, J.L., De Ste Croix, M.B.A., Myer, G.D. & Lloyd, R.S., 2017, ‘Reliability of the tuck jump injury risk screening assessment in elite male youth soccer’, Journal of Strength and Conditioning Research 30(6), 1510–1516. https://doi.org/10.1519/JSC.0000000000001260

Reid, K., 2006, ‘Interpreting and understanding meta-analysis graphs. A practical guide’, Australian Family Physician 35(8), 635–638.

Shadle, I.B. & Cacolice, P.A., 2016, ‘Eccentric exercises reduce hamstring strains in elite adult male soccer players. A critically appraised topic’, Journal of Sport Rehabilitation 26(6), 573–577. https://doi.org/10.1123/jsr.2015-0196

Silva, B., Clemente, F.P., Camões, M. & Bezerra, P., 2017, ‘Functional movement screen scores and physical performance among youth elite soccer players’, Sports 5(1), 16. https://doi.org/10.3390/sports5010016

Smith, C.A., Chimera, N.J., Wright, N.J. & Warren, M., 2013, ‘Interrater and intrarater reliability of the functional movement screen’, Journal of Strength and Conditioning Research 27(4), 982–987. https://doi.org/10.1519/JSC.0b013e3182606df2

Smith, J. & Hetzler, R., 2017, ‘Prospective functional performance testing and relationship to lower extremity injury’, The International Journal of Sports Physical Therapy 12(2), 206–218.

The PRISMA Group, 2009, ‘Preferred reporting items for systematic reviews and meta-analyses: The PRISMA statement’, PLoS Medicine 6(6), e1000097. https://doi.org/10.1371/journal.pmed1000097

Van Beijsterveldt, A.M.C., Van de Port, I.G.L., Vereijken, A.J. & Backx, F.J.B., 2013, ‘Risk factors for hamstring injuries in male soccer players. A systematic review of prospective studies’, Scandinavian Journal of Medicine and Science in Sports 23(3), 253–262. https://doi.org/10.1111/j.1600-0838.2012.01487.x

Van Mechelen, W., Hlobil, H. & Kemper, H., 1992, ‘Incidence, severity, aetiology and prevention of sports injuries. A review of concepts’, Sports Medicine 14(2), 82–99. https://doi.org/10.2165/00007256-199214020-00002

Original Research

Systematic review of screening tools for common soccer injuries and their risk factors

Raphael Christopher, Corlia Brandt, Natalie Benjamin-Damon

Abstract

Introduction

Method

Data sources and searches

Selection of studies and methodological quality

Risk of bias

Grade of evidence

Data extraction

Data analysis

Results

Characteristics of included studies

Risk of bias

Methodology quality

Meta-analysis of findings

Narrative analysis

Screening tools

Accuracy of screening tools

Discussion

Grade of evidence

Limitations and recommendations

Conclusion

Acknowledgements

Competing interests

Authors’ contributions

Ethical consideration

Funding information

Data availability statement

Disclaimer

References

Appendix 1