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Hamstrings are dangerous for sport and sport is dangerous for hamstrings

 

– Written by Cristiano Eirale, Qatar and Jan Ekstrand, Sweden

 

Analysis of epidemiological studies assessing sports constantly rank hamstring injuries as one of the most prevalent factors resulting in missed playing time by athletes1-3. One could therefore conclude that hamstrings are dangerous for sport. Identifying the real incidence of hamstring injury in each sport is difficult due to the varying definitions used by different researchers. However, it seems universally accepted that hamstring lesions make up a substantial percentage of acute, sports-related musculoskeletal injuries with a prevalence of 6 to 25%, depending on the sport4.

 

Hamstring injuries can occur in a variety of sports and movements. A high number occur in sports where the hamstrings are stretched eccentrically at high speed such as athletics5, and in running contact sports such as Australian Rules football (AFL)6, American football7 and soccer1,3,8. Hamstring injuries can also occur in recreational sports such as water-skiing and bull riding, where the knee is forcefully fully extended during injury9,10. Within individual sports different positional roles dictate different physical demands, and it’s seen that hamstring strains are far more common in positions in which sprinting is more often required7,8,11, such as strikers in football.

 

HAMSTRINGS IN SOCCER: THE MAIN INJURY

Generally, muscle injuries are common in soccer8. Surveillance of injuries in the UEFA Champions League showed that muscle injuries make up more than 30% of all player injuries and cause about 1/4 of total time lost due to injury12. Over 90% of muscle injuries seen in this study involved four major muscle groups of the lower extremity: hamstrings, adductors, quadriceps and gastrocnemius8. Injury to the hamstring muscle group is reported to be the most common injury subtype representing 12% of all injuries and more than 1/3 of all strains8. These normally occur with an acute onset (70%) and in a non-contact situation (96%)8. The incidence of hamstring injury during matches and training sessions are 0.43 and 3.70/1000 hours of exposure, respectively. Accordingly, a professional male soccer team with 25 players may expect about five hamstring injuries each season, equivalent to more than 80 lost football days and 14 missed matches8. Despite a massive amount of recent research and consequent prevention programmes, hamstring injury incidence is not decreasing. These injuries undoubtedly have an impact on the performance of the team and consequently, on a club’s economy. These considerations aside, when the injured hamstring belongs to Lionel Messi and the lesion occurs in a crucial period of the Champions League, the influences become widespread and significant.

 

HAMSTRINGS IN AUSTRALIAN FOOTBALL: AN EXAMPLE OF HOW THE RULES OF THE GAME AFFECTS INJURIES

As with the other football codes, hamstring injuries are responsible for the highest number of matches missed (20 per season per club on average), and sprinting is seen to be the main mechanism of injury. On average, each AFL club may expect six hamstring strains per season11. The recurrence rate (26% on average) has shown a steady drop over the last 21 years (P <0.01), declining from over 40% to an average of 13.5% in the last 3 years. Speculatively, this may be the result of more cautious return to play strategies.

 

Interestingly, AFL is a good example of how the rules of the game can affect the risk of injury. In 2006 the rules of AFL were changed in order to improve the spectacle of the event such that the breaks in play, and therefore rest time for players, were reduced13. Moreover, rule-makers have tried to reduce the amount of ‘dead time’, in order to achieve an effective 80 minutes of time ‘in play’. The rule changes also effected an increase in the number of player interchanges from an average of around 30 to more than 100 per team, per game. An analysis of the effect of these rule changes on injury rate showed them to be protective against hamstring injuries. It seemed that the athletes benefited from the increased number of interchange ‘rests’ – players who had seven or more interchanges in the previous 3 weeks had approximately 25% less hamstring injuries. On the other hand, increased interchanges by one team gave the opposing team a higher number of hamstring injuries: when a team made 60 or more interchanges during a game, the opposition had approximately 40% increased incidence of hamstring injury. We can interpret this data to mean that when players get more breaks during the game, as opposed spending the game chasing ‘fresher’ players, they are less likely to get a hamstring injury. The sum of these opposing forces are that hamstring injury rates have not fallen, rather their distribution has changed relative to these interchanges. This may point to the role of fatigue in hamstring injury, already hypothesised in soccer, where the rate of hamstring strains are seen to increase toward the end of each half12.

 

HAMSTRINGS AND TRACK AND FIELD: WATCH OVER THE SPRINTERS

Thigh strain was the most common diagnosis (16%) in sports injury surveillance studies at the 2007, 2009 and 2011 IAAF (International Association of Athletics Federations) World Athletics Championships14-16. In a recent prospective study the most frequent diagnosis in sprinters was hamstring strain17. In athletics, the most common mechanism of hamstring injury is sprinting18 and the most common injury site is the long head of the biceps femoris5. Biomechanical studies have shown that a powerful eccentric contraction in the late swing phase is the likely time when the hamstrings are most prone to injury19 although others argue that hamstrings are at higher risk of injury in the early phase of sprinting20.

 

HAMSTRINGS IN AMERICAN FOOTBALL: MIND THE PRE-SEASON

Muscle injuries are a cause of con-siderable disability in American football both at senior and high school level21. The injury rate per 1000 hours of exposure is 0.47 for trainings and 2.7 for matches, with relative match-training risk of 5.74.

 

While the impact of hamstring strains in American Football7 is similar to other sports such as soccer and AFL, their temporal distribution is worthy of review, particularly from a prevention point of view.    

 

The pre-season is seen to be a high risk period. Muscle strains account for 46% of practice injuries and 22% of pre-season game injuries. They are the second most common pre-season injury, with an injury rate of 1.79 per 1,000 athlete-exposures for practices and 4.07 per 1,000 athlete-exposures for games22. Furthermore, more than half (53.1%) of all hamstring injuries occurred in the 7-week pre-season, before the teams had even played their first regular-season game. This data is striking when compared with the 16-week regular season, in which only 45% of injuries occurred, and the post-season, in which only 1.1% of injuries occurred7.

 

Almost 4/5 (78.9%) practice injuries occurred in the pre-season, with more than 70% of those occurring in July, the first month of football participation. The first month of National Football League (NFL) pre-season games, August, is also the month with the highest incidence of game injuries7. These high pre-season injury incidences are devastating not only because of their immediate impact but also because primary hamstring lesions are associated with decreased performance upon return to competition and have a high risk of re-injury during the competitive season23. Elliott et al7 explain these results mainly with the relative deconditioning that occurs in the off-season. However, since this high incidence is not found in the pre-season period for other sports, training and match strategies should be reviewed in NFL. Moreover, sport-specific conditioning, particularly with regard to strengthening and maximum-velocity sprinting, is suggested7.

 

IT’S ALMOST ALWAYS THE BICEPS FEMORIS MUSCLE

In soccer, as in similar sports24, most (84%) hamstring strains affect the biceps femoris1; exactly the same results were found in AFL25. Interestingly, the percentage of hamstring lesions located at the semimembranosus (SM) and semitendinosus were almost identical (11% and 5% in soccer, 10% and 6% in AFL, respectively). In accordance with the findings in AFL26, Ekstrand et al1 found no relation between the specific muscles involved and lay-off time. There is no preferred leg for a hamstring lesion in soccer: Ekstrand et al8 found that exactly 50% of the injuries will occur in the kicking leg.

 

STRETCHING IS DIFFERENT

Dancers suffer different hamstring in-juries: their injuries mostly happen during stretching exercises, taking their limb out to an extreme joint position. These injuries most often involve the proximal free tendon of the SM muscle and require much more time to come back to the pre-injury level24,27,28 than the running type injury seen in football. This specific mechanism of injury with a combination of end range hip flexion and full knee extension can lead to a specific injury to the proximal part of the posterior thigh in other sports as well29, although in these sports the stretching to end range knee extension combined with full flexion is seen to happen at higher velocity. Clinically it is imperative to inform the athlete that this type of injury, despite its relatively mild initial symptoms, generally implies a longer return to play time.

 

HIGH RATE OF RECURRENCE

Together with its high incidence and important time lost from competition, hamstring injuries have a high recurrence rate. As previously stated, in AFL it has been estimated that 1/3 of all hamstring strains are a recurrence of a previous lesion although quite recently it appears that this trend is improving, possibly because of a more conservative management approach11. High rates of recurrence have also been reported for American football (16.5%)7, rugby union (21%)30 and soccer (16%)8.

 

In soccer, a study of elite professional football1 showed that all the re-injuries (n=30) were in the biceps femoris muscle and none to the semitendinous and semimembranosus.

 

A majority of studies show that re-injuries cause longer absence from sport than acute injury8,12,31 with just one recent paper showing no difference in lay-off time between re-injury and first injury1. The authors of this recent paper have speculated that this may indicate that top-level clubs in Europe have greater medical support, providing more individualised rehabilitation for injured players. These workers added that the frequently used radiological examinations for diagnostics and return-to-play decisions could possibly help to reduce the re-injury rate.

 

DO WE NEED IMAGING?

The majority of hamstring injuries occurring in players from European high-level professional football clubs were examined by MRI, US or a combination of these examinations. Imaging is frequently used to enhance the quality of the diagnosis in order to better prognosticate healing time and lay-off from football. At the elite level, the frequent use of imaging may also be justified by the scrutiny of the media and public of the health of these athletes. MRI has been the preferred modality in recent years and has offered a highly detailed imaging analysis of the extent of injury1,25,26. It seems logical that radiological severity is correlated to clinical severity, thus indicating that an MRI examination done 24 to 48 hours after a hamstring injury could provide information about what absence is to be expected. Several studies in AFL and soccer1,25,26,32,33 have shown the possibility of using MRI to predict lay-off time after hamstring injury. Clinically, proximity of the injury to the ischial tuberosity, as estimated both by palpation and MRI, is associated with longer time to return to pre-injury level24. The size of a strain, as seen on MRI, has the strongest association with recurrence25,26. While MRI seems to have similar potential to evaluate the prognosis as clinical examination32, further subgrouping into injury type, intramuscular location and dimension of pathology might be of additional value in prognosis33. Despite this data, it is our opinion that ultrasound is at least as valid as MRI for the evaluation of hamstring strains34.

 

PAIN DOESN’T ALWAYS MEAN STRAIN

Not all causes of posterior thigh pain are the result of a hamstring muscle strain35. Ekstrand et al1 have shown that 13% of MRIs performed for a suspected hamstring strain are negative.

 

A negative MRI finding in the context of clinically suspected hamstring strain is associated with shorter recovery time1,25,26. The actual cause of posterior thigh injury where MRI shows no pathology is unclear. It is possible that these injuries are subtle muscle injuries and below the sensitivity of MRI detection26. Another explanation is that these athletes in pain may have an alternative diagnosis such as back-related problem, neural tension or muscle spasm25.

 

SURGERY IS RARE

Surgical repair is normally reserved for ruptures (mainly proximal avulsion injuries) but these are rarely seen in football: the UEFA Champions League hamstrings sub-study has shown an incidence of 3%1. Complete avulsions are more common with sports such as water-skiing, dancing, weight lifting, and ice-skating. In this case, the mechanism of injury is commonly through an eccentric contraction with the hip flexed and the knee extended10,36.

 

HAMSTRINGS IN QATAR

The incidence of hamstrings strain in professional football in the Qatar Stars League (QSL)3 is almost identical to the UEFA Champions League (UCL)12 (0.927 vs 0.924/1000 hours). However, the percentage of hamstrings strains in the total number of injuries is a little higher (18% compared with 12% in Europe). More than half of the observed muscle strains are located in the hamstrings.

 

This difference is due to the fact that the total injury incidence in Qatar is lower than in Europe, both in training (3.2 vs 4/1000 hours) and in matches (18.9 vs 25.0/1000 hours) (Figure 2).

 

Similarities between QSL and UCL have also been found for hamstring strain severity (18±18 vs 19±17 days), while the recurrence rate in Qatar is slightly lower (12 vs 16%), also implying a lower impact in total days lost due to hamstring injury in Qatar.

 

NOT JUST “A LITTLE HAMMY TEAR”

The deeper we have delved into hamstring injury over the last few decades, the more we have learnt as clinicians. However, we are clearly still some distance away from being able to say that we have solved this problem. Time has been spent researching novel treatment approaches but hamstring management hasn’t (objectively) gotten much better. Maybe therefore this is an injury we need to prevent rather than treat. The first step in a systematic approach needed to build an evidence base for prevention of sports injury is valid and reliable injury surveillance methods37. No doubt more dead ends await us, but we can hope that this information is feeding back into management and resulting in reducing the burden of this complex and difficult injury.

 

Cristiano Eirale M.D.

Sports Medicine Physician

Aspetar – Orthopaedic and Sports Medicine Hospital

Doha, Qatar

 

Jan Ekstrand M.D., Ph.D.

Football Research Group

Department of Medical and Health Sciences

Linköping University

Linköping, Sweden

Member of UEFA Medical Committee

 

Contact: cristiano.eirale@aspetar.com

 

References

  1. Ekstrand J, Healy JC, Walden M, Lee JC, English B, Hagglund M. Hamstring muscle injuries in professional football: the correlation of MRI findings with return to play. Br J Sports Med 2012; 46:112-117.
  2. Orchard JW. Intrinsic and extrinsic risk factors for muscle strains in Australian football. Am J Sports Med 2001; 29:300-303.
  3. Eirale C, Farooq A, Smiley FA, Tol JL, Chalabi H. Epidemiology of football injuries in Asia: a prospective study in Qatar. J Sci Med Sport 2013; 16:113-117.
  4. Heiderscheit BC, Sherry MA, Silder A, Chumanov ES, Thelen DG. Hamstring strain injuries: recommendations for diagnosis, rehabilitation, and injury prevention. J Orthop Sports Phys Ther 2010; 40:67-81.
  5. Malliaropoulos N, Mendiguchia J, Pehlivanidis H, Papadopoulou S, Valle X, Malliaras P et al. Hamstring exercises for track and field athletes: injury and exercise biomechanics, and possible implications for exercise selection and primary prevention. Br J Sports Med 2012; 46:846-851.
  6. Orchard JW, Seward H. Epidemiology of injuries in the Australian Football League, seasons 1997-2000. Br J Sports Med 2002; 36:39-44.
  7. Elliott MC, Zarins B, Powell JW, Kenyon CD. Hamstring muscle strains in professional football players: a 10-year review. Am J Sports Med 2011; 39:843-850.
  8. Ekstrand J, Hagglund M, Walden M. Epidemiology of muscle injuries in professional football (soccer). Am J Sports Med 2011; 39:1226-1232.
  9. Radford AJ, Baggoley C, Crompton O, Joyner P. Waterskiing injury. Aust Fam Physician 1987; 16:1661-1663.
  10. Chakravarthy J, Ramisetty N, Pimpalnerkar A, Mohtadi N. Surgical repair of complete proximal hamstring tendon ruptures in water skiers and bull riders: a report of four cases and review of the literature. Br J Sports Med 2005; 39:569-572.
  11. Orchard JW, Seward H, Orchard JJ. Results of 2 decades of injury surveillance and public release of data in the Australian football league. Am J Sports Med 2013; 41:734-741.
  12. Ekstrand J, Hagglund M, Walden M. Injury incidence and injury patterns in professional football: the UEFA injury study. Br J Sports Med 2011; 45:553-558.
  13. Orchard JW, Driscoll T, Seward H, Orchard JJ. Relationship between interchange usage and risk of hamstring injuries in the Australian Football League. J Sci Med Sport 2012; 15:201-206.
  14. Alonso JM, Junge A, Renstrom P, Engebretsen L, Mountjoy M, Dvorak J. Sports injuries surveillance during the 2007 IAAF World Athletics Championships. Clin J Sport Med 2009; 19:26-32.
  15. Alonso JM, Tscholl PM, Engebretsen L, Mountjoy M, Dvorak J, Junge A. Occurrence of injuries and illnesses during the 2009 IAAF World Athletics Championships. Br J Sports Med 2010; 44:1100-1105.
  16. Alonso JM, Edouard P, Fischetto G, Adams B, Depiesse F, Mountjoy M. Determination of future prevention strategies in elite track and field: analysis of Daegu 2011 IAAF Championships injuries and illnesses surveillance. Br J Sports Med 2012; 46:505-514.
  17. Jacobsson J, Timpka T, Kowalski J, Nilsson S, Ekberg J, Renstrom P. Prevalence of musculoskeletal injuries in Swedish elite track and field athletes. Am J Sports Med 2012; 40:163-169.
  18. Malliaropoulos N, Papacostas E, Kiritsi O, Papalada A, Gougoulias N, Maffulli N. Posterior thigh muscle injuries in elite track and field athletes. Am J Sports Med 2010; 38:1813-1819.
  19. Chumanov ES, Schache AG, Heiderscheit BC, Thelen DG. Hamstrings are most susceptible to injury during the late swing phase of sprinting. Br J Sports Med 2012; 46:90.
  20. Orchard JW. Hamstrings are most susceptible to injury during the early stance phase of sprinting. Br J Sports Med 2012; 46:88-89.
  21. Shankar PR, Fields SK, Collins CL, Dick RW, Comstock RD. Epidemiology of high school and collegiate football injuries in the United States, 2005-2006. Am J Sports Med 2007; 35:1295-1303.
  22. Feeley BT, Kennelly S, Barnes RP, Muller MS, Kelly BT, Rodeo SA. Epidemiology of National Football League training camp injuries from 1998 to 2007. Am J Sports Med 2008; 36:1597-1603.
  23. Hagglund M, Walden M, Ekstrand J. Risk factors for lower extremity muscle injury in professional soccer: the UEFA Injury Study. Am J Sports Med 2013; 41:327-335.
  24. Askling CM, Tengvar M, Saartok T, Thorstensson A. Acute first-time hamstring strains during high-speed running: a longitudinal study including clinical and magnetic resonance imaging findings. Am J Sports Med 2007; 35:197-206.
  25. Koulouris G, Connell DA, Brukner P, Schneider-Kolsky M. Magnetic resonance imaging parameters for assessing risk of recurrent hamstring injuries in elite athletes. Am J Sports Med 2007; 35:1500-1506.
  26. Verrall GM, Slavotinek JP, Barnes PG, Fon GT, Esterman A. Assessment of physical examination and magnetic resonance imaging findings of hamstring injury as predictors for recurrent injury. J Orthop Sports Phys Ther 2006; 36:215-224.
  27. Askling CM, Tengvar M, Saartok T, Thorstensson A. Acute first-time hamstring strains during slow-speed stretching: clinical, magnetic resonance imaging, and recovery characteristics. Am J Sports Med 2007; 35:1716-1724.
  28. Askling C, Saartok T, Thorstensson A. Type of acute hamstring strain affects flexibility, strength, and time to return to pre-injury level. Br J Sports Med 2006; 40:40-44.
  29. Askling CM, Tengvar M, Saartok T, Thorstensson A. Proximal hamstring strains of stretching type in different sports: injury situations, clinical and magnetic resonance imaging characteristics, and return to sport. Am J Sports Med 2008; 36:1799-1804.
  30. Brooks JH, Fuller CW, Kemp SP, Reddin DB. Incidence, risk, and prevention of hamstring muscle injuries in professional rugby union. Am J Sports Med 2006; 34:1297-1306.
  31. Walden M, Hagglund M, Ekstrand J. Injuries in Swedish elite football – a prospective study on injury definitions, risk for injury and injury pattern during 2001. Scand J Med Sci Sports 2005; 15:118-125.
  32. Schneider-Kolsky ME, Hoving JL, Warren P, Connell DA. A comparison between clinical assessment and magnetic resonance imaging of acute hamstring injuries. Am J Sports Med 2006; 34:1008-1015.
  33. Gibbs NJ, Cross TM, Cameron M, Houang MT. The accuracy of MRI in predicting recovery and recurrence of acute grade one hamstring muscle strains within the same season in Australian Rules football players. J Sci Med Sport 2004; 7:248-258.
  34. Kellis E, Galanis N, Natsis K, Kapetanos G. Validity of architectural properties of the hamstring muscles: correlation of ultrasound findings with cadaveric dissection. J Biomech 2009; 42:2549-2554.
  35. Woods C, Hawkins RD, Maltby S, Hulse M, Thomas A, Hodson A. The Football Association Medical Research Programme: an audit of injuries in professional football-analysis of hamstring injuries. Br J Sports Med 2004; 38:36-41.
  36. Sallay PI, Friedman RL, Coogan PG, Garrett WE. Hamstring muscle injuries among water skiers. Functional outcome and prevention. Am J Sports Med 1996; 24:130-136.
  37. van Mechelen W, Hlobil H, Kemper HC. Incidence, severity, aetiology and prevention of sports injuries. A review of concepts. Sports Med 1992; 14:82-99.

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Targeted Topic - Hamstring Injuries
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