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Injuries, risk factors and prevention initiatives
in youth sport
Anne Frisch†‡§, Jean-Louis Croisier§, Axel Urhausen‡, Romain Seil‡,and Daniel Theisen†*
†Sports Medicine Research Laboratory, Public Research Centre for Health, 1a-b, rue ThomasEdison, L-1445 Strassen, Grand-Duchy of Luxembourg; ‡Centre de l’Appareil Locomoteur, deMedecine du Sport et de Prevention du Centre Hospitalier de Luxembourg, Luxembourg, and§Departement des Sciences de la Motricite, Faculte de Medecine, Universite de Liege, Belgium
Background: Sports injuries in young athletes are a public health issue which
deserves special attention. Effective prevention can be achieved with training
programmes originating from the field of physical therapy and medicine.
Sources of data: A systematic literature search on injury prevention in youth
sport was performed in the MEDLINE database.
Areas of agreement: For prevention programmes to reduce sports injuries,
critical factors must be considered, such as training content, duration and
frequency, as well as athlete compliance.
Areas of controversy: Home-based programmes could be inferior to supervised
training, but are efficient if compliance is high. So far prevention programmes
have focused on team sports and their efficiency in individual sports remains to
be proven.
Growing points: Active prevention programmes focusing specifically on the
upper extremity are scarce. Initiatives enhancing the awareness of trainers,
athletes and therapists about risk factors and systematic prevention measures
should be encouraged.
Keywords: sports injuries/young athlete/prevention strategies/compliance/risk factors
British Medical Bulletin 2009; 92: 95–121
DOI:10.1093/bmb/ldp034
& The Author 2009. Published by Oxford University Press. All rights reserved.
For permissions, please e-mail: [email protected]
Accepted: August 20,
2009
*Correspondence to:
Daniel Theisen, Sports
Medicine Research
Laboratory, CRP-Sante,
1a-b, rue Thomas Edison,
L-1445 Strassen, Grand-
Duchy of Luxembourg.
E-mail: daniel.theisen@
crp-sante.lu
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Introduction
Promotion of a physically active lifestyle is encouraged worldwide, par-ticularly with regard to the many health benefits.1 In children and adoles-cents, regular sports practice facilitates the development of fundamentalmovement skills,2 helps prevent obesity and its long-term consequences3
and has long-lasting benefits on bone health.4 Unfortunately, increasedintensity and volume of sport practice lead to a higher rate of acute andoveruse injuries. For the young athlete, the consequences of sports inju-ries could be numerous, ranging from re-injury to career-ending.5
Long-term impacts of sports injuries are frequently found in adulthood,such as an accelerated development of osteoarthritis.6
In addition to the potentially long-term outcomes of sports injurieson later life, the related healthcare costs constitute a substantial econ-omic burden. In a recent study, Cumps et al.7 showed that the ensuingtotal direct medical costs of sports injuries in Flandren (i.e. rehabilita-tion, medical care, hospitalization, medication, bandages, transport,crutches) amounted to 15 027 423.00], which represents 0.07–0.08%of the total budget spent on health care. In the USA, the estimatedtotal hospital charges for sports injury hospitalizations among 5–18-year-olds were $485 million over a period of 4 years, with a steadyincrease each year.8 The highest medical costs are mostly found forknee injuries, especially for anterior cruciate ligament (ACL) injuries.7,8
The costs for one ACL surgery plus rehabilitation were estimated to upto $17 000. Gianotti et al.9 analysed knee ligament injuries in NewZealand and found that the mean treatment costs were $885 for non-surgical knee injuries, $11 157 for ACL surgeries and $15 663 forother knee ligament surgeries. The socio-economic impact should alsobe viewed under the light of indirect costs of sports injuries, such asabsence from work and long-term health consequences, which add tothe direct costs.7
Reduction of only a moderate proportion of all sports injuries is ofsignificance for the young athletes’ health and could have a long-termeconomic impact regarding health-care costs.10 It is therefore importantto convince medical doctors, physical therapists, trainers and coaches,as well as the athletes themselves, of the necessity to implement activeprevention measures into their therapy and training programmes, thusdecreasing the (re-)injury rate and enhancing athletic performance.Indeed, recent scientific literature based on a systematic injury preven-tion approach suggests that well-designed programmes do have positiveeffects, provided that a number of conditions are fulfilled.
Van Mechelen et al.11 proposed a general four-step model (Fig. 1) forsports injury surveillance. The first step comprises the description and
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the extent of the injury problem. In a second phase, the aetiology andmechanisms of sports injury are being investigated. A third stage con-cerns the introduction of preventive measures, which will then beassessed regarding their effectiveness by repeating step 1. The purposeof this paper is to review the state-of-the-art knowledge on injury pre-vention in child and youth (,19 years) sports based on that model. Inthe first part, the incidence and frequency of particular sports injurieswill be briefly recalled, highlighting the specificities of the young agegroup related to biological maturation. The second part will discussintrinsic risk factors of that population, with special emphasis on thosewhich are modifiable and can be targeted by intervention. In the lastpart, active prevention programmes will be critically presented regard-ing their implementation, characteristics and efficiency. This analysiswill make it possible for practitioners of different areas to draw rel-evant recommendations for their work.
Search strategy and methods
A systematic search of relevant publications was performed for thesection on active prevention strategies via the MEDLINE database(1966–May 2009). The keywords used were adolescent OR youthAND sports injury AND prevention, yielding a total of 1953 hits.Additional searches were performed in the authors’ personal databases.Relevant papers were selected on the basis of the following criteria:
† exclusive focus on organized sports;
† separate results for young athletes under the age of 19 years;
† longitudinal studies: only prospective designs;
† major focus on intrinsic risk factor;
Fig. 1 Sequence of prevention in four steps, adapted from Van Mechelen et al.11
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† intervention studies using active prevention programmes;
† search limited to English papers only.
Figure 2 provides an overview of the search strategy used. On the basisof these selection criteria, 14 studies were retained for further analysis.
Injuries in youth sport
Before investigating the effectiveness of prevention measures, it is man-datory to get a global overview of the injury problem. This is, however,a difficult task for any person confronted with the considerableamount of literature that has accumulated in recent years. It appearsthat the sports injury issue can be addressed from multiple points ofviews (Fig. 3). Most studies12–24 have focused on one specific sport dis-cipline highlighting injuries related to the inherent characteristics of thesport in question. Other investigations25–28 have addressed a particularbody region or injury type, which again only provides a rather limitedview of the sports injury problem. The aim of this section is thereforeto briefly summon up the main acute and chronic injuries related toyouth sports to present a general picture, taking into account the speci-ficity of this population, the sport-specific context and the anatomicallocation. Previous reports have shown rates of injury per 1000exposure hours between 0.5 and 34.4, with highest rates for boys in icehockey (5–34.4 injuries/1000 h), rugby (3.4–13.3 injuries/1000 h) andsoccer (2.3–7.9 injuries/1000 h), and for girls in soccer (2.5–10.6injuries/1000 h), basketball (3.6–4.1 injuries/1000 h) and gymnastics(0.5–4.1 injuries/1000 h).5,29 For a more detailed analysis of injury
Fig. 2 Flow-chart illustrating the search strategy used for investigations dealing with activeprevention strategies.
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incidence rates in different sport disciplines, the reader is kindlyreferred to some excellent reviews that have been recently pub-lished.5,29–31
When analysing different studies on sports injury prevention, somemethodological issues arise, the most important being the way ofreporting injuries (e.g. absolute number of injuries, injury proportionor injury incidence) as well as injury definition.32 The latter mayexplain part of the sometimes large variations in the reported injuryrates.33 The time of sports practice has been frequently used in the lit-erature with minor distinctions,33,34 such that some caution is war-ranted when interpreting the results presented here (Tables 1 and 2).Recently, consensus statements on injury definitions and data collectionprocedures have been published for soccer35 and rugby.36
Epidemiology of acute injuries
The main acute injuries in youth sports are sprains, strains, fractures,dislocations and contusions. Overall, sprains account for 27–48% ofall injuries in the young athlete,19–21,37 with the ankle and knee beingthe two most common anatomical locations for sprains.20 Ankle andknee sprain rates are particularly high in sports involving sharp cuttingmanoeuvres, running and pivoting movements, stopping and startingmovements or jumps and landings on one foot. Typically, disciplinessuch as tennis, volleyball, handball, basketball and soccer are especiallyconcerned here.18,23,37,38 In youth soccer, ankle sprain incidencereaches up to 1.50/1000 h.39 These results are comparable to the 1.56ankle sprains/1000 h found in youth basketball.40 Considering kneesprains, higher incidences were found for females compared withmales, both in soccer39 (0.72/1000 h versus 0.14/1000 h) and in
Fig. 3 Multiple perspectives to analyse the sports injury problem.
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basketball41 (0.09/1000 h versus 0.02/1000 h). Finger injuries,especially finger sprains, are frequent in team ball sports such asnetball42 (15%), basketball16 (4.9%) and handball21 (10–18%).Strains are very common in adolescent soccer, where they account for17–53% of all injuries.17,20,34,37 The groin region seems to be mostoften concerned (0.57 strains/1000 h), followed by the thigh region(0.36 strains/1000 h) and the calf and back regions (both 0.21 strains/1000 h).39 For some sports, concussions are relatively frequent. Forsoccer, the incidence found was 0.36 concussions/1000 h,39 whereasfor ice hockey, it was �0.74 concussions/1000 h,15 thus representingthe most common specific injury type (18% of all injuries).
Fractures were found to represent between 2% and 37% of all inju-ries related to soccer,17,20,34,37,43,44 mostly at the wrist, foot and ankleregion.20 A similar large proportion was found in basketball (17–36%),43 volleyball (7–21%)43 and gymnastics (2–40%).12,19,43
Dislocations accounted for 29–39% of all injuries in basketball,43 for14–35% in volleyball,43 for 1–35% in gymnastics19,43 and for 0.3–30% in soccer.17,20,43 In the young athlete, dislocations are often recur-rent and can lead to post-traumatic instability.26,45 Contusions are alsorelatively frequent, especially in team sports and gymnastics (up to over50%).43
Epidemiology of chronic injuries
Overuse injuries are due to repetitive stress on a biological tissue,which leads to microtrauma in this specific body region. In adolescentsoccer, overuse injuries account for 10–34% of all reported inju-ries.20,22,37,39,46 In youth basketball, 38% overuse injuries werereported,16 whereas in youth handball, they represented 7–21% oftotal injury number.21,24 Many overuse injuries in adolescents are dueto traction apophysitis.47
Some chronic injuries are specifically associated with children andadolescents. Concerning the upper extremity, the main overuse injuriesare the little leaguer’s shoulder, the rotator cuff tendinopathy and thelittle leaguer’s elbow. The former is a stress fracture of the proximalepiphyseal plate,45 which is specific to young overhead sports athleteswith open growth plates, involved in sports such as baseball, volleyballand tennis.48 Shoulder impingement and rotator cuff tendinopathiesare frequent in swimmers due to excessive internal shoulder rotation.Rotator cuff tendinopathy also occurs as a result of chronic repetitivehitting and overhead serving in young tennis players.49 Little leaguer’selbow is a traction apophysitis of the flexor/pronator muscles origin on
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the medial epicondyle and can be found in young baseball players, per-forming excessive throwing training.50
Regarding the lower extremity, a common cause for anterior kneepain in young athletes is the Osgood–Schlatter lesion, a traction apo-physitis of the tibial tuberosity. It is mostly found in children who arein a growth spurt and engaged in cutting and jumping sports, such assoccer, basketball, gymnastics and volleyball.48,50,51 In elite juniorfigure skating, the Osgood–Schlatter disease was found in 9% of allthe girls and 14% of all the boys.14 Kujala et al.27 showed that 21% ofthe active student population suffered from Osgood–Schlatter and thatthe knee pain caused complete cessation of training for an average of3.2 months over a 5-year period. At the ankle, Sever’s disease is fre-quent in young athletes participating in basketball, soccer, track andother running activities.48 This calcaneal apophysitis affects the inser-tion of the Achilles tendon and the plantar fascia50 and is secondary torepetitive microtrauma or overuse of the heel. Sever’s disease is thesecond most common osteochondrosis found in the younger athleteafter the Osgood–Schlatter lesion. Investigating young soccer playersaged 9–19 years, Price et al.52 reported that Osgood–Schlatter’s andSever’s disease accounted for 5% of all injuries. In the age group of11–13 years, these two conditions accounted even for 14% of all inju-ries. Another specific chronic injury at the knee joint in adolescence isthe Sinding–Larsen–Johansson disease, a tensile stress that affects theproximal attachment of the patella tendon.51
Stress fractures also belong to the overuse injury category. Owing tomechanical overloading the balance between osteoclastic resorption andbone formation is disrupted. In tennis, stress fractures are often foundat the lower extremity, more precisely at the foot, where the fifth meta-tarsal, the metatarsal diaphysis and navicular neck are most often con-cerned.49 In gymnastics, most stress fractures were found at the spine(42%), followed by the lower extremity (35%) and the upper extremity(23%).13 Stress fractures at the lumbosacral spine are also called spon-dylolysis. They are often secondary to repetitive hyperextension of thespine, as found in gymnastics, ballet, volleyball, diving and serving intennis.45 In basketball, stress fractures of the lower limb were found tobe the third most frequent diagnosis (5.4%) after lateral ankle sprainsand patellar tendinitis.16 In elite junior skating, all stress fractures werelocated at the lower limb, except one that was found at the lumbarspine.14 Stress fractures were the most frequent overuse injury in femaleskaters with 19.8%,14 whereas in male skaters they amounted to13.2%, the third most frequent diagnosis of overuse injuries. Generally,female athletes could potentially be more prone to stress fractures thanmales,13,14,47 an aspect that will be further addressed below.
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Long-term consequences of sports injuries
The immediate outcome of a serious acute or chronic injury is theinterruption of sports practice. A severe injury immobilizes the athleteup to several months and may require surgery or/and intensive and pro-longed rehabilitation. On a long-term basis, the consequences of asports injury may include decreased sports participation in later life, aswell as loss of function and chronic pain, as discussed below. However,the literature on long-term consequences of injuries in youth sports isscarce, most investigations having focused on the adult population.Furthermore, only few types of injuries have been followed up on along-term basis, which precludes any detailed analysis in relation to thedifferent types of injuries specific to the younger population.
The injury type that has received most attention is the knee sprain,resulting in ACL or meniscus tears. Gonarthrosis, as diagnosed by radi-ography, is significantly increased after all knee injuries compared withthe uninjured joint of the same patient.53 Half of the patients with adiagnosed ACL or meniscus lesion have osteoarthritis with associatedpain and functional impairment 10–20 years after the diagnosis.54 Inoperatively treated handball players, the rate of return to sport at pre-injury levels was relatively good (58%), but the re-injury rate was ashigh as 22%, with half of the players reporting pain, instability orreduced range of motion 6–11 years after their ACL injury.55 A recentstudy56 showed that on an average 11.5 years after ACL reconstruction,14–27% of the patients suffered severe loss of function and some 16%declared having rigorously modified their lifestyle. Among a group ofnon-operated children (average age 10.1 years) with ACL injury, 35%had not returned to their pre-injury activity level after an average of3.9 years.57
The consequences of ankle sprains and shoulder dislocations havealso been investigated on a long-term basis, but not as frequently asknee injuries. In a group of young patients (mean age 20 years) fol-lowed up 2.5 years after inversion ankle injury without surgery, 74%were found to have persisting symptoms such as pain, perceivedinstability, weakness or swelling, and 16% were unable to return totheir original sport.58 No relation was found between age, sex and typeof sport with respect to long-term consequences in that study. Another5-year follow-up of the functional outcome after surgery of chronicankle instability revealed that only half of the patients regained theirpre-injury ankle function.59 A major long-term risk after anteriorshoulder dislocation is chronic instability. Re-dislocation rate afterprimary traumatic dislocation ranges from 14%60 to 67%61 after 12and 5 years follow-up, respectively, often associated with functionalimpairment.
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From the preceding discussion, it appears that the long-term conse-quences of a severe injury can be substantial. Although most resultspresented above stem from the young adult population, it is likely thatthey also apply to children and adolescents. It should be noted,however, that the literature lacks systematic long-term prospectivefollow-ups of sports injuries in the younger population. Furthermore,concerning chronic injuries in youth sports, long-term impacts on laterlife do not seem to have been investigated and could represent a fruitfularea for future research.
Intrinsic risk factors
The second step of van Mechelen’s sequence of prevention consists inthe description of the aetiology and mechanisms of injury (cf. Fig. 1),which are population-specific. Risk factors that could increase thepotential for sports injuries may be qualified as extrinsic (environment-dependent) or intrinsic (athlete-dependent). Extrinsic factors that influ-ence sports injury risk include sports context, protective equipment,rules and regulations, playing surface and coaching education andtraining.30,31 They will not be further developed here, because ourmain focus is on intrinsic risk factors. Some intrinsic risk factorscannot be changed and will only be addressed briefly hereafter. Othersare potentially modifiable, which is of specific interest in the injury pre-vention context. The identification of intrinsic factors which could bepotentially altered forms the basis for designing effective preventionprogrammes.
Non-modifiable risk factors
The risk factor most consistently associated with a greater injury risk isprevious injury. Considering all injuries, soccer players with a historyof injury had a 1.739 to 3.044 times greater risk to sustain a new injury.When specifically looking at ankle sprains in youth soccer, Tyleret al.62 found an even greater relative risk of 6.5 associated with pre-vious injury. Across different sport disciplines, McHugh et al.63
reported that the association between previous injury and injury occur-rence was significant, but only for male athletes.
The young athlete is particularly vulnerable to sports injuries becauseof the physical and physiological processes of growth.50 Body areasespecially affected in adolescents compared with adults are the bonetissue and the muscle-tendon units. The muscle-tendon units elongatesecondarily in response to bone growth leading to tightness of the
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muscles, especially those muscles which cross two joints, such as therectus femoris and gastrocnemius.47 Even if the metaphysis of longbones is more flexible and elastic in children than in adults, resulting ingreater bone deflection without fracture,45 there are two areas whichare especially susceptible to fractures. First, there is the line of weak-ness between the epiphyseal plate and the formed bone. Second, thereis the apophyseal cartilage, which is often exposed to high pullingaction from the muscle-tendon unit, resulting either in acute avulsionfracture or in traction apophysitis, depending on whether the musculartraction applied is sudden and intense or chronic and repetitive.47
Growth plates in the epiphyseal regions may be injured by repetitivephysical loading and stress. These physeal injuries could produce per-manent injury to the cells in the zone of hypertrophy resulting ingrowth disturbance.64 Bailey et al.25 demonstrated that the incidence offracture of the distal end of the radius was highest at the time of peakvelocity of growth in both sexes. Thus, they concluded that during theadolescent growth spurt, there is a discrepancy between bone growthand bone mineralization, which results in a temporary period of rela-tive weakness of the bone. In a recent study, Sugimori et al.28 alsoshowed that the incidence of fractures in a large cohort of Japanesechildren was highest at the age of growth spurt.
Considering the influence of gender, girls seem to be more prone forsome injuries than boys. For example, in figure skating, the relativenumber of stress fractures (with respect to the numbers of athletes) was11% in girls, but only 8% in boys.14 In gymnastics, an even greaterdifference was found, with 30% for girls versus 21% for boys,13 whichcould reflect different practice patterns. Unfortunately, none of the twostudies reported whether these differences were statistically significant,so the answer is not definite. Regarding knee injuries, especially ACLinjuries, girls were found to have a significantly higher incidence thanboys [0.43 injuries/1000 athlete’s exposures (AE) versus 0.09 injuries/1000 AE].65 Other studies further suggest that ankle injuries are morefrequent in girls than in boys.66,67 Possible reasons for higher injuryrisk in girls have been put forward, such as greater joint laxity,68 lowermuscle strength30,67 and poorer proprioception and coordination.38
Finally, there are maturity-associated variations that may influencesports injury risk.64 The adolescent athlete is more susceptible to injurythan the prepubescent athlete because circulating androgens promotethe fast development of muscle mass and enhance movement velocityand power. These rapid changes are likely to influence self-control andrisk perception. Additionally, because of the non-linear growthprocess, children of the same chronological age may vary considerablyin biological maturity status. As a consequence, there are early and latematurity children. As classification for participation in youth sport still
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relies on chronological age, great variations with respect to height andweight can be found within a team, which increases the risk of sportsinjuries.64
Modifiable risk factors
Beside the non-modifiable risk factors, some authors have pointed outspecific risk factors in children and adolescents that can be modified byprevention.29–31 Potentially implicated factors are fitness level, flexi-bility, muscle strength, joint stability, balance, coordination, psycho-logical and social factors.30 Concerning cardiovascular fitness, Heidtet al.69 showed that preseason conditioning significantly lowered injuryincidence in female adolescent soccer players. Regarding muscle flexi-bility, it has been found that inflexible muscles can produce pain onthe opposite side of a joint; in competitive swimmers, tightness of theposterior shoulder muscles was associated with anterior impinge-ment.47 Moreover, as previously discussed, inflexible muscles couldcause episodes of traction apophysitis and of overuse syndromes relatedto excessive strain, but this hypothesis still remains to be tested.47
Flexibility deficits, which are particularly common in adolescents suf-fering from overuse injuries, could be improved by regular stretchingexercises. Stretching following appropriate warm-up prior to athleticactivity may also prevent muscular injuries as was concluded in arecent review article.70
The high incidence of ACL injuries in females has lead Hewettet al.38 to evaluate neuromuscular control and joint loads in 205 youngfemale athletes participating in soccer, basketball or volleyball. Theyused three-dimensional kinematics and kinetics to evaluate perform-ance during a standardized jump-landing task. Those athletes whoacquired a confirmed ACL injury during the 13-month follow-up hadsignificantly different pre-study knee posture and loading character-istics compared with the athletes who did not develop an ACL rupture.The knee abduction angle during landing was significantly greater inACL-injured compared with uninjured players. Moreover, ACL-injuredathletes had a 2.5 times greater knee abduction moment and 20%higher ground reaction force than their uninjured counterparts. Hence,female athletes with increased dynamic valgus and high abductionloads are at increased risk for ACL injury.
Balance and coordination have been evaluated in high-school basket-ball players in a prospective follow-up study.40 Subjects who demon-strated poor balance (high postural sway scores) had nearly seven timesas many ankle sprains as subjects who had good balance (low posturalsway scores). As a result, the authors concluded that preseason balance
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measurement (postural sway) could serve as a predictor of ankle sprainsusceptibility. Similar conclusions were reached in another study,71
where ankle injuries were more commonly found in physical educationstudents with decreased postural control.
Considering the influence of psychological factors on sports injuries,several studies suggest that life stress could be a significant predictor ofinjury.72–75 For example, major life events, such as the death of a closefriend or family member, or the separation from girl/boy-friend, couldincrease the risk for a sports injury by up to 70%.72 Steffen et al.72
showed that injured soccer players had undergone significantly morestressful life events than the uninjured players. Beside life stress, copingresources, personality traits and competitive anxiety could have aneffect on sports injuries, as discussed in a recent review.74 Williams andAnderson76 have shown that the response to life stress is modulated bythe personality of the athlete, the history of stressors and the copingresources. These factors could be easily evaluated by means of standar-dized questionnaires. Although athlete personality and history of stres-sors cannot be modified, psychological interventions could be useful inimproving the athlete’s attitude and coping resources. This discussionis however beyond the scope of the present review.
Interventions for sports injury prevention
The previous section has described a series of intrinsic risk factors thatare potentially modifiable. They are the specific focus of interventionsaiming at preventing sports injuries and appear in step 3 of vanMechelen’s prevention model (Fig. 1). The efficiency of such preventionprogrammes must, of course, be evaluated using injury statistics from along-term prospective follow-up (step 4 of the injury preventionmodel).
Basically, there are two different kinds of prevention strategies, thepassive and the active. Passive strategies do not require active adap-tations from the athlete during practice. Once the prevention strategy isadopted (e.g. compliance with new rules or wearing protective equip-ment),77,78 the athlete is automatically protected. In contrast, activestrategies imply that the athlete cooperates and modifies his behaviourwithin the sports context. An example of an active prevention pro-gramme is the ‘11’-programme, designed by the FIFA-MedicalAssessment and Research Centre (F-MARC).79 This intervention hasbeen developed in cooperation with international experts. It promotesfair play and encompasses 10 sets of exercises which focus on corestabilization, eccentric training of thigh muscles, proprioceptivetraining, dynamic stabilization and plyometrics with straight leg
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alignment. More recently, a revised version of this programme (‘11þ’)has been successfully applied on young female soccer players,37 as willbe detailed later on.
In this paper, only studies dealing with active prevention strategiesare presented based on our systematic literature search (cf. introduc-tion). Before describing different programmes in greater detail, it isworthwhile to discuss a number of issues related to the implementationof such programmes into the athlete’s training schedule.
Challenges to implement injury prevention strategies
The effectiveness of an injury prevention programme depends not onlyon its content but also on the success of its more or less permanentacceptance and implementation within the sports community. Greatefforts are sometimes required to convince trainers and coaches toadopt a specific prevention programme over longer periods of time.Compliance to prevention training at the level of the team as well asthe level of the individual athlete is critical. Therefore, the organizationof large-scale randomized controlled trials demands a long preparationtime and many resources.
One of the first premises for an effective prevention programme is thecooperation from trainers. The latter must be fully briefed with respectto programme duration and content, correct execution of exercises, fre-quency and the importance of athlete compliance. The interventionprogramme should be designed in such a way that it does not interferetoo heavily with the usual training activities. Furthermore, additionallyrequired material (exercise books and DVDs, balance mats, wobbleboards etc.) should be made available taking into account the financialimplications.
In some studies, teams are supplied with instructional videotapes atthe beginning of the intervention training, demonstrating the correctexecution of the prevention exercises.37,55,65,80 Sometimes the athletesare asked to control each other by watching the accomplished exerciseand giving each other feedback.37,81,82 Regular checks from the studyinstructors are nevertheless needed to verify the appropriate executionof the programme, the implementation of which can take up to 1.5months.82
The success of an injury prevention programme also greatly dependson compliance of the individual athletes to the intervention, as will bediscussed hereafter. Adherence can be influenced by the sport- orstudy-specific context, since in team sports the trainer or coach bearsgreater responsibility, whereas in individual sports the athlete’s owncommitment is critical. Another difficulty of evaluating the role of
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compliance results from the fact that some studies do not specify whatkind of compliance was evaluated. Different indexes have beenreported, such as the percentage of training sessions in which the pro-gramme was used (training session compliance),37,82 compliance ofparticipants to the training sessions (participant compliance)37,65,82–84
or the percentage of teams adhering to the programme (team compli-ance)80,81 (Tables 1 and 2). None of these variables necessarily reflectthe compliance of the individual athletes to the entire intervention pro-gramme. These aspects are of particular importance when interpretingthe results of sports injury prevention initiatives. Close collaborationwith the study group is also needed regarding data collection and deter-mines, what has been termed, the ‘collecting data compliance’.85 Thelatter is also important regarding the gathering of information aboutsports injuries, which requires prior briefing or even training of one orseveral local contact persons.
Outcome of prevention initiatives
Injury prevention programmes focusing on the young athlete have beenmainly tested in the context of team sports, such as soccer,37,80,82,86–88
basketball,83 handball81,89,90 and multiple sports.65,84,85 To theauthors’ knowledge, no prevention programmes for individual sportshave been presented in the literature. This could have practical reasons,in that implementation and high compliance are easily achieved inteam sports compared with individual disciplines. Furthermore, inteam sports, more athletes can be targeted at one time.
Tables 1 and 2 summarize the main results from studies investigatingthe effects of different prevention programmes. In Table 1, only resultswith a significant positive effect on sports injuries are reported,whereas Table 2 reviews observations with no significant reduction ofinjuries. Regarding content, it appears that injury prevention in youthsports has mainly focused on the lower extremity and the trunk.Components which often appear in successful programmes are plyo-metrics,37,65,69,80 functional strength24,37,65,69,80,81,86,89,90 or condition-ing exercises,69 sport-specific agility drills,37,69,80 activities to improvebalance and body control37,81,83–85,87–90 and flexibility exer-cises.65,69,80 Great emphasis is generally placed on neuromuscularcontrol, core stability, lower limb alignment, hip control and properlanding technique (e.g. ‘knee over toe’ position, decreased impactforces, bilateral landing). Close supervision and feedback (oral andvisual via ordinary video analysis) by a proficient trainer or at least bypeers seem to be of particular importance to guarantee properexecution of the exercises.37,81 This critical aspect may put home-based
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Table 1. Summary of studies reporting on successful active prevention programmes.
First author Sport Age
(years)
Sex Injury definition Prevention programme Injuries in the
control group
Injuries in the
intervention
group
Compliance
Content Frequency/
duration
Emery83 (CRCT) Basketball 12–18 m þ f All injuries
occurring during
basketball that
required medical
attention and/or
caused a player to
be removed from
that current
session and/or miss
a subsequent
session
Sport-specific
balance training
warm-up for practice
sessions
5 min during one
basketball season
(5 times/week)
Acute-onset
injuries: 3.83/
1000 player
hours
2.77/1000 player
hours*,
RR ¼ 0.71 (95%
CI: 0.50–0.99)
100% of
participants
for
sport-specific
training
Home exercise
programme using a
wobble board
20 min (frequency
NR).
60.3% of
participants
for wobble
board activities
(participant
compliance)
Emery85 (CRCT) Multiple 14–19 m þ f Any injury
occurring during a
sporting activity
that required
medical attention
(i.e. visit to an
emergency
department or
physician’s office,
chiropractic,
physiotherapy or
athletic therapy)
or resulted in the
loss of at least 1
day of sporting
activity, or both
A progressive,
home-based,
proprioceptive
balance-training
using a wobble
board
Daily training for
6 weeks and then
weekly for
maintenance for
the rest of the
6-month study
period
17%
participants
with injury
3% participants
with injury,
RR ¼ 0.20 (95%
CI: 0.05–0.88),
OR ¼ 0.15 (95%
CI: 0.03–0.72)
(multiple logistic
regression)
43.3%
(collecting
data
compliance)
Heidt69 (RCT) Soccer 14–18 f An injury that
caused the athlete
to miss a game or
a practice session
Cardiovascular
conditioning,
plyometrics, sport
cord drills, strength
training and
flexibility exercises
to improve speed
and agility
7-week training
programme
before the start
of the season (20
sessions)
33.7%
participants
with injury
14.3%
participants with
injury*
NR
Continued
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Table 1. Continued
First author Sport Age
(years)
Sex Injury definition Prevention programme Injuries in the
control group
Injuries in the
intervention
group
Compliance
Content Frequency/
duration
Hewett65 (CNRCT) Multiple
(soccer
basketball
volleyball)
14–18 f A serious knee
injury was defined
as a knee ligament
sprain or rupture
that caused the
player to seek care
by an athletic
trainer and that
led to at least 5
consecutive days of
lost time from
practice and
games
Neuromuscular
training programme,
incorporating
flexibility,
plyometrics and
weight training to
increase muscle
strength and
decrease landing
forces
6-week preseason
training sessions
that lasted 60–
90 min a day, 3
days a week, on
alternating days;
1 season
follow-up
0.43 knee
injuries/1000
AE (untrained
females) 0.09
knee injuries/
1000 AE (male
athletes)
0.12 knee
injuries/1000
AE*
4 weeks:
100%; 6
weeks: 70%
(participant
compliance)
Junge86 (CNRCT) Soccer 14–19 m Any physical
complaint caused
by soccer that
lasted for more
than 2 weeks or
resulted in absence
from a subsequent
match or training
session
Improvement of
warm-up, regular
cooldown, taping of
unstable ankles,
adequate
rehabilitation,
application of the
‘11’
two 1-year season
intervention (no
other details
indicated)
low-skill
group: 11.1/
1000 h
6.95/1000 h* NR
Malliou87 (CRCT) Soccer 15–18 NR An injury was
defined as any
mishap occurring
during scheduled
games or practices
causing an athlete
to miss a
subsequent game
or practice session
Proprioceptive
balance training
program, which
included
sport-specific
exercises on the
‘Biodex Stability
System’, on the
mini-trampoline and
on the balance
boards
20-min balance
training twice a
week during the
competition
period
88 lower limb
injuries
60 lower limb
injuries*
NR
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Mandelbaum80
(non-randomized
prospective cohort
study)
Soccer 14–18 f Non-contact ACL
tear was
confirmed by
history, physical
examination by a
physician and MRI
and/or
arthroscopic
procedure
Proprioceptive and
neuromuscular
programme,
including warm-up,
stretching,
strengthening,
plyometrics and
soccer-specific agility
drills
20-min warm-up
before each
athletic activity
during two
one-season
interventions
Season 1: 0.47
ACL injuries/
1000 AE;
Season 2: 0.51
ACL injuries/
1000 AE
0.05 ACL
injuries/1000
AE*, RR ¼ 0.114
(95% CI ¼ NI);
0.13 ACL
injuries/1000
AE*, RR ¼ 0.259
(95% CI ¼ NI)
96.52100%
(team
compliance)
McGuine84 (CRCT) Multiple
(soccer
basketball)
16 m þ f An ankle sprain
was defined as a
trauma that (i)
disrupted the
ligaments of the
ankle, (ii) occurred
during a
coach-directed
competition,
practice or
conditioning
session and (iii)
caused the athlete
to miss the rest of
a practice or
competition or
miss the next
scheduled
coach-directed
practice or
competition
Balance exercises on
a flat surface or on a
board such as
single-leg stance
with eyes open and
closed; performing
functional sport
activities such as
throwing, catching
and dribbling on
one leg; maintaining
double-leg stance
while rotating the
balance board
Progressive
five-phase
balance training
program; phases
1– 4: five exercise
sessions/week for
4 weeks before
the start of the
season; in phase 5
(maintenance
phase), three
10-min sessions/
week
1.87 ankle
sprains/1000
AEs
1.13 ankle
sprains/1000 AEs;
the rate of ankle
sprains was
significantly
lower in the
intervention
group as shown
by Kaplan–
Meier survival
analysis,
RR ¼ 0.56 (95%
CI: 0.33–0.95)
91.2%
(participant
compliance)
McHugh88
(prospective
cohort study)
Soccer 15–18 NR An inversion ankle
sprain was defined
as an ankle injury
with an inversion
mechanism
requiring the
player to miss at
least one game or
practice
Single-limb balance
training on a foam
stability pad
Balance training
was performed
for 5 min on each
leg, 5 days/week
for 4 weeks in
preseason and 2
times/week for 9
weeks during the
season
2.2 ankle
sprains/1000
exposures
0.5 ankle
sprains/1000
exposures*
91% (training
session
compliance)
Continued
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Table 1. Continued
First author Sport Age
(years)
Sex Injury definition Prevention programme Injuries in the
control group
Injuries in the
intervention
group
Compliance
Content Frequency/
duration
Olsen81 (CRCT) Handball 15–17 m þ f Any injury
occurring during a
scheduled match
or training session,
causing the player
to require medical
treatment or miss
part of the next
match or training
session
Exercises with the
ball, including the
use of the wobble
board and balance
mat to improve
running, cutting and
landing technique as
well as
neuromuscular
control, balance and
strength
During an
8-month season,
15–20-min
programme at the
beginning of
every training
session for 15
consecutive
sessions and then
1/week during the
rest of the season
1.8 acute
injuires/1000
player hours
(0.6 in
training 10.3
in match)
0.9 acute
injuries/1000
player hours*,
RR ¼ 0.51 (95%
CI: 0.39–0.66)
(0.4 in training
4.7 in match*)
87% (team
compliance)
Soligard23 (CRCT) Soccer 13–17 f An injury occurred
during scheduled
match or training
session, causing
the player to be
unable to fully
take part in the
next match or
training session
Application of ‘11þ’ 20-min
programme at all
training sessions
and prior to
matches for one
8-month season
4.8/1000 h 3.2/1000 h*,
RR ¼ 0.68 (95%
CI: 0.56–0.84)
77% (training
session
compliance);
58%
(participant
compliance)
Wedderkopp90
(CRCT)
Handball 16–18 f Any injury
occurring during
scheduled games
or practices,
causing the player
to either miss the
next game,
practice session or
being unable to
participate
without
considerable
discomfort
Ankle disc practice
and two or more
functional strength
activities for all
major muscle groups
10–15-min
programme at all
training sessions
for one 10-month
season
1.17/1000 h of
practice,
23.38/1000 h
of match
0.34/1000 h of
practice*,
OR ¼ 0.17 (95%
CI: 0.089–0.324);
4.68/1000 h of
match*
NR
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Wedderkopp89
(CRCT)
Handball 14–16 f Any injury
occurring during
scheduled games
or practices,
causing the player
to either miss the
next game,
practice session or
being unable to
participate
without
considerable
discomfort
Ankle disc practice
and two or more
functional strength
activities for all
major muscle groups
10–15-min
programme at all
training sessions
for one 10-month
season
0.6/1000 h of
practice,
OR ¼ 4.8
(95% CI: 1.9–
11.7); 6.9/
1000 h of
match
0.2/1000 h of
practice*; 2.4/
1000 h of
match*
NR
AE, athlete’s exposure; NR, not reported; m, male; f, female; CNRCT, cluster-non randomized controlled trial; CRCT, cluster randomized controlled trial; RCT, randomized
controlled trial.
*Significantly different from the control group (P , 0.05).
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Table 2. Summary of studies reporting on unsuccessful active prevention programmes.
First
author
Sport Age
(years)
Sex Injury definition Prevention programme Injuries in
the control
group
Injuries in the
intervention
group
Compliance
Content Frequency/Duration
Emery83
(CRCT)
Basketball 12–18 m þ f All injuries occurring
during basketball that
required medical
attention and/or
caused a player to be
removed from that
current session and/or
miss a subsequent
session
Sport-specific balance
training warm-up for
practice sessions
5 min during one
basketball season (5
times/week)
All injuries:
4.03/1000
player
hours
3.3/1000 player
hours,
RR ¼ 0.80 (95%
CI: 0.57–1.11)
100% of
participants for
sport-specific
training
Home exercise
programme using a
wobble board
20 minutes (frequency
NR)
60.3% of
participants for
wobble board
activities
(participant
compliance)
Junge86
(CNRCT)
Soccer 14–19 m Any physical complaint
caused by soccer that
lasted for more than 2
weeks or resulted in
absence from a
subsequent match or
training session
Improvement of
warm-up, regular
cooldown, taping of
unstable ankles,
adequate
rehabilitation,
application of the ‘11’
Two 1-year season
intervention
high-skill
group:
6.78/1000 h
6.35/1000 h NR
Steffen82
(CRCT)
Soccer 13–17 f An injury was
registered if it caused
the player to be
unable to fully take
part in the next match
or training session
Application of the
‘11’
During one soccer
season (8 months),
20-min warm-up
programme (including
5 min of jogging before
starting the exercises)
every training session
for 15 consecutive
sessions and thereafter
1/week for the rest of
the season
3.7/1000 h 3.6/1000 h,
RR ¼ 1.0 (95%
CI: 0.8–1.2)
52% (training
session
compliance) 67%
(participant
compliance)
AE, athlete’s exposure; NR, not reported; m, male; f, female; CNRCT, cluster-non randomized controlled trial; CRCT, cluster randomized controlled trial; RCT, randomized
controlled trial.
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interventions at a disadvantage, since the quality of the execution (andthe compliance—see below) cannot be easily verified. Another factor toconsider is the possibility for variation and progression in the exerciseset, which will avoid ceiling effects, enhance motivation among trainersand athletes and favour compliance.81 Indeed, the ‘11’-programmeapplied by Steffen et al.82 in a group of young soccer players did notprovide the possibility for variation and progression, was characterizedby a low compliance and had no significant effect on injury incidence.Similarly, Junge et al.86 did not find significant improvements in injurystatistics with this prevention method in already skilled soccer players(cf. Table 2), only the low-skilled group had a decreased injury inci-dence (cf. Table 1). On the other hand, the revised ‘11þ’ versionincluding additional exercises to provide variation and progression,plus a new set of structured running exercises, reduced the risk ofsevere injuries, overuse injuries and injuries overall in young femalesoccer players.37
Globally, there is a strong tendency of interventions with a high com-pliance to bring about significant reductions in injury inci-dence,37,65,80,81,84,88 whereas studies in which compliance to theprogramme was low showed only marginal effects.82,83 It should benoted here that a home exercise programme may be less motivatingand result in poorer compliance than a supervised and structured train-ing agenda followed in a group of peer athletes. Considering the factthat the young athlete’s behaviour can be easily influenced by theenvironment, the attitude of the trainers and probably also of theparents may be of particular importance here. The investigation ofMandelbaum et al.80 had a team compliance of almost 100%, whichlead to an 88% reduction in ACL injuries in female soccer players.Similarly, in the study of Olsen et al.,81 87% of the participating clubsapplied the proposed intervention programme throughout the studyperiod, which yielded a 50% decrease in acute injuries in young hand-ball players. Hewett et al.65 found a 72% reduction in knee injuries infemale athletes from team sports after a specific 6-week preseasonpreparation. All the girls from the intervention group followed the pre-vention programme for 4 weeks, and 70% of them accomplished thefull training programme. McGuine and Keene84 reported a complianceof 91%, which lead to a 38% reduction in ankle sprains in male andfemale high-school basketball and soccer players. In the study ofMcHugh et al.88 91% of the athletes followed the entire balance train-ing. The authors observed an overall reduction in injury incidence of77%. In contrast to the previous studies, Steffen et al.82 noted a lowtraining session compliance among young soccer players (52%),despite regular contacts with the coaches during the study period andencouragements to continue the intervention programme. Accordingly,
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the results did not reveal the expected training effects of reduced sportsinjury risk (cf. Table 2).
Given the previous findings, it appears that appropriate content andhigh compliance are critical, yet insufficient factors for a successfulintervention. Another important aspect seems to be the frequency andduration of the prevention sessions, for which some fundamental differ-ences can be noted (cf. Tables 1 and 2). Some programmes with signifi-cant reductions in injury statistics have encompassed an initial highvolume phase of prevention exercises, i.e. 15–40 sessions of 15–20 min, performed either daily or in every practice, followed by oneweekly session for maintenance.81,85 Another successful approach hasbeen to introduce a pre-season preparation programme of 18–20 ses-sions over 6–7 weeks, with durations of up to 90 min.65,69 Finally, astrategy of continuous, moderate volume prevention training of 10–20 min in each practice session (e.g. during warm-up) also yielded posi-tive results.37,80,89,90 From these results, it can be concluded that fre-quency and duration of preventive training sessions should guaranteecertain minimal criteria. All in all, the final choice will depend on prac-tical considerations of feasibility and acceptance by trainers andathletes.
Conclusion
Acute injuries and overuse syndromes in the young athlete deservespecific consideration. Detailed knowledge about injury incidence,injury type and modifiable and non-modifiable risk factors makes itpossible to design pertinent prevention programmes. Their effectivenessdepends on a number of characteristics related to content, compliance,duration and frequency. Practical issues regarding implementation ofand adherence to these prevention exercises require special attention.The proposed programmes should be time-efficient for the trainers andmotivating for the athletes.
There seem to be no systematic analyses about the effectiveness ofinjury prevention programmes directed to the upper extremity, despitewell-described injury patterns. The latter are rather sport-specific andconcern, e.g. the young overhead athlete. The reasons why this areamay have raised less interest in the field of sports medicine are notclear. Attention should be drawn here to interventions aiming atdecreasing muscle dysbalances and restoring appropriate ranges ofmotion. The modalities and efficiency of such training programmes areyet to be investigated by long-term prospective follow-ups.
Finally, it is important to take into account the education of trainersand coaches. Indeed, few coaches consider sports injuries as an issue
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they can impact on.37 It is also regrettable that injury prevention seemsto have a rather low priority and has been cited by some trainers as areason for non-participation in injury prevention studies.37 This indi-cates the necessity to include the topic of injury prevention in the curri-cula of trainers and coaches. Furthermore, information and educationof the parents and the young athletes themselves should be reinforced.Only an uninjured athlete is able to perform at his/her best.
Funding
The present work has been financially supported by the ministerialdepartment of sports of the Grand-Duchy of Luxembourg.
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