Email updates

Keep up to date with the latest news and content from BMC Medicine and BioMed Central.

Journal App

google play app store

This article is part of the series Advances in Sports Nutrition, Exercise and Medicine.

Open Access Highly Accessed Research article

The effectiveness of neuromuscular warm-up strategies, that require no additional equipment, for preventing lower limb injuries during sports participation: a systematic review

Katherine Herman, Christian Barton, Peter Malliaras and Dylan Morrissey*

Author affiliations

Centre for Sports and Exercise Medicine, William Harvey Research Institute, Bart's and the London School of Medicine and Dentistry, Queen Mary University of London, Mile End Hospital, Bancroft road, London, E1 4DG, UK

For all author emails, please log on.

Citation and License

BMC Medicine 2012, 10:75  doi:10.1186/1741-7015-10-75

The electronic version of this article is the complete one and can be found online at: http://www.biomedcentral.com/1741-7015/10/75


Received:17 February 2012
Accepted:19 July 2012
Published:19 July 2012

© 2012 Herman et al; licensee BioMed Central Ltd.

This is an Open Access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Background

Lower limb injuries in sport are increasingly prevalent and responsible for large economic as well as personal burdens. In this review we seek to determine which easily implemented functional neuromuscular warm-up strategies are effective in preventing lower limb injuries during sports participation and in which sporting groups they are effective.

Methods

Seven electronic databases were searched from inception to January 2012 for studies investigating neuromuscular warm-up strategies and injury prevention. The quality of each included study was evaluated using a modified version of the van Tulder scale. Data were extracted from each study and used to calculate the risk of injury following application of each evaluated strategy.

Results

Nine studies were identified including six randomized controlled trials (RCT) and three controlled clinical trials (CCT). Heterogeneity in study design and warm-up strategies prevented pooling of results. Two studies investigated male and female participants, while the remaining seven investigated women only. Risk Ratio (RR) statistics indicated 'The 11+' prevention strategy significantly reduces overall (RR 0.67, confidence interval (CI) 0.54 to 0.84) and overuse (RR 0.45, CI 0.28 to 0.71) lower limb injuries as well as knee (RR 0.48, CI 0.32 to 0.72) injuries among young amateur female footballers. The 'Knee Injury Prevention Program' (KIPP) significantly reduced the risk of noncontact lower limb (RR 0.5, CI 0.33 to 0.76) and overuse (RR 0.44, CI 0.22 to 0.86) injuries in young amateur female football and basketball players. The 'Prevent Injury and Enhance Performance' (PEP) strategy reduces the incidence of anterior cruciate ligament (ACL) injuries (RR 0.18, CI 0.08 to 0.42). The 'HarmoKnee' programme reduces the risk of knee injuries (RR 0.22, CI 0.06 to 0.76) in teenage female footballers. The 'Anterior Knee Pain Prevention Training Programme' (AKP PTP) significantly reduces the incidence of anterior knee pain (RR 0.27, CI 0.14 to 0.54) in military recruits.

Conclusions

Effective implementation of practical neuromuscular warm-up strategies can reduce lower extremity injury incidence in young, amateur, female athletes and male and female military recruits. This is typically a warm-up strategy that includes stretching, strengthening, balance exercises, sports-specific agility drills and landing techniques applied consistently for longer than three consecutive months. In order to optimize these strategies, the mechanisms for their effectiveness require further evaluation.

Keywords:
neuromuscular training; lower limb; injuries; prevention

Background

Historically, stretching as part of a warm-up strategy before exercise has been strongly advocated to prevent injury [1]. However, current evidence suggests that stretching alone may confer no injury prevention benefit [2-5]. More recently, researchers and sports medicine practitioners have developed and investigated multi-factorial neuromuscular training strategies targeting injury prevention for a variety of sports and athletic levels. The importance of musculoskeletal injury prevention is highlighted by estimates that 22 million sports injuries occur in the UK each year [6]. Furthermore, sixty to seventy percent of the population in the UK are considered to be physically inactive. Physical inactivity is currently estimated to cost the UK economy £8.3 billion per annum and is more prevalent than obesity, alcohol misuse and smoking combined [7]. It is more important than ever to encourage people to engage in some form of physical activity [8] and the recent Chief Medical Officer report 2009 described physical activity as a 'wonder drug' or 'miracle cure' with huge potential benefits [6]. However, an inevitable consequence of increasing physical activity is an increased incidence of musculoskeletal injury. To reduce the resultant personal and economic burden, there is a need for practical, time efficient and cost-effective injury prevention strategies.

Neuromuscular training programmes are hypothesized to improve joint position sense, enhance joint stability and develop protective joint reflexes, ultimately preventing lower limb injuries. Hübscher et al. [9] recently completed a high quality systematic review on neuromuscular training programmes for sports injury prevention. A meta-analysis indicated that multi-intervention programmes may reduce lower limb, acute knee and ankle injuries and that balance programmes may reduce ankle injuries [9]. However, the practicality of these findings for many individuals, teams and clubs may be limited due to the need for equipment purchases (for example, balance boards) and the requirement of additional training sessions to normal practice and competition. In these cases, a more practical solution would be to encompass neuromuscular training programmes which do not require additional equipment and which can be incorporated into warm-up or current routines. A number of neuromuscular warm-up strategies which fit these criteria have been proposed, evaluated and published in the literature. Just two of these programmes were included by the Hübscher et al. [9] systematic review. Therefore, an up-to-date systematic review of the literature related to neuromuscular warm-up strategies which can be easily incorporated into warm-up or current routines and do not require the acquisition of additional equipment is needed to further guide recommendations for effective lower limb injury prevention.

The aims of this systematic review were: (1) to evaluate the efficacy of functional neuromuscular warm-up strategies which do not require additional equipment in preventing lower limb injury in order to guide clinical and sporting practice; and (2) to identify the common elements of successful strategies in order to guide future research.

Methods

Search and evaluation strategy

Embase, SPORTDiscus, Google Scholar, PubMed, ISI Web of Knowledge, Scirus and PEDro were searched for articles from inception to June 2011 and updated in January 2012. Search terms included (movement training OR neuromuscular OR proprioceptive OR proprioception OR plyometric) AND (training OR program OR programme) AND prevent* AND (injury OR injuries). Limits included English language (due to the cost of translation) and human studies. The reference list of retrieved articles was manually checked for potentially relevant studies.

Inclusion and exclusion criteria

Inclusion/exclusion criteria are shown in Table 1.

Table 1. Study selection criteria.

Quality Assessment

A modified version of the nine item van Tulder et al. [10] was used to assess the methodological quality of each study. The van Tulder et al. [10] criteria focus on the internal validity of clinical trials and recent evidence suggests it is reliable and has good face and content validity [11]. Two independent reviewers (KH and CB) scored each criterion. Any disagreement with scoring the methodological criteria was solved by consensus and a third reviewer (DM) was available if necessary, but was not needed.

Data extraction and analysis

Details of study design, participant characteristics, interventions, statistical analysis, results and study limitations were extracted and tabulated from each included study by one reviewer (KH). Additionally, two reviewers (KH and CB) extracted data related to participant numbers and injury incidence for the various types of lower limb injuries reported. Review Manager version 5.0 was used to calculate risk ratios (RR) and their 95% Confidence Intervals (CI) for all comparisons as well as to produce forest plots to represent this data visually. The number needed to treat (NNT) was calculated only for variables producing a statistically significant RR (that is, 95% confidence intervals did not cross 1.0). Sensitivity analysis was completed to identify if the use of equipment improved injury prevention. To complete this, the effectiveness of a selection of eight studies, five randomized controlled trials (RCTs) [12-16] and three cohort studies [17-19] which utilized equipment in their programmes and, hence, were excluded from the primary review were evaluated using the same analytical approach.

Results

Literature search

The initial search identified 766 articles (Figure 1). Duplicates were excluded. Many studies were excluded because they involved use of additional equipment not readily available at training or competition venues (see Table 2). Relevant titles and abstracts were selected based on the inclusion criteria, yielding 15 articles. Application of inclusion/exclusion criteria to the full text left nine articles and excluded six articles; five studies because injury prevention was not the primary outcome [20-24] and one study because it lacked a control [25].

thumbnailFigure 1. Flowchart to demonstrate the literature search.

Table 2. Reasons for exclusion of studies.

Methodological quality

Table 3 shows the results of the methodological quality assessment for the nine included studies. All nine studies scored a minimum of five points on the scale indicating they were of reasonable quality [10]. The following study weaknesses were noted: failure to blind participants to the intervention [26-33], unacceptable, inadequate or absent randomization [26,27,29], failure to blind researchers to the intervention [26-28,30], no intention to treat analysis [28,30], different group values at baseline [30], high drop-out rate [32] and poor compliance [32].

Table 3. Assessment of methodological quality for each included study.

Description of Studies

Details of each study are summarized in Table 4 including study design, participants, neuromuscular warm-up strategy evaluated, control intervention, and outcomes evaluated. Studies included an average of 1,500 participants (range 1,020 to 2,020). Two studies [33,34] investigated male and female participants, while the remaining seven investigated females only [26-32]. The age range of participants was 13 to 26 years. Five studies evaluated amateur football players [26,28,29,31,32], two studies evaluated army recruits [33,34], one study evaluated amateur football and basketball players [30] and one study evaluated amateur football, basketball and volleyball players [27]. Three studies evaluated primarily ACL injury [26-28], two studies assessed all lower extremity injury risk which included the foot, ankle, leg, knee, thigh, groin and hip [31,32], one study assessed lower extremity injuries which included knee and ankle [30], one study evaluated injuries to the knee including collateral ligament, ACL, meniscal and patella injuries [29], one study measured general overuse injuries [34] and one specifically anterior knee pain (AKP)[33]. Studies quantified injury incidence per 1,000 player hours [29,31,32], per 1,000 athlete exposures [26-28,30] and by cumulative incidence [33,34].

Table 4. Summary of details regarding each included study.

Undefined lower limb injuries

RRs for the effectiveness of neuromuscular warm-up strategies in preventing undefined lower limb injuries are shown in Figure 2. 'The 11+' [31] and 'KIPP' [30] were found to significantly reduce the risk of overall lower limb injuries (RR 0.67, CI 0.54 to 0.84, NNT 18; and RR 0.50, CI 0.33 to 0.76, NNT 24, respectively) and lower limb overuse injuries (RR 0.45, CI 0.28 to 0.71, NNT 31; and RR 0.44, CI 0.22 to 0.86, NNT 49, respectively). Similar to studies without equipment, the sensitivity analysis indicated a mixture of effective and ineffective warm-up programmes which used additional equipment.

thumbnailFigure 2. Forest plot graph demonstrating risk ratios for the effectiveness of neuromuscular warm-up strategies in preventing undefined lower limb injuries.

Hip and thigh injuries

None of the strategies evaluated were able to produce significant reductions in hip or thigh injuries, with calculated risk ratios shown in Figure 3. A strong trend was indicated for the 'The 11' programme [32] to reduce groin injuries (RR 0.39, CI 0.15 to 1.02, NNT 77). Similarly, the sensitivity analysis failed to identify any warm-up programmes using equipment which were able to reduce the risk of hip and thigh injuries.

thumbnailFigure 3. Forest plot graph demonstrating risk ratios for the effectiveness of neuromuscular warm-up strategies in preventing hip and thigh injuries.

Knee injuries

RRs for the effectiveness of neuromuscular warm-up strategies in preventing knee injuries are shown in Figure 4. The 'HarmoKnee' [29] and 'The 11+' [31] programmes significantly reduced the risk of knee injuries (RR 0.22, CI 0.06 to 0.76, NNT 72; and RR 0.48, CI 0.32 to 0.72, NNT 28). Additionally, the PEP [26] strategy was the most effective at reducing ACL injuries (RR 0.18, CI 0.08 to 0.42, NNT 70). The PEP [28] also significantly reduced the risk of recurrence in those with previous non-contact ACL injuries (P = 0.046). The AKP PTP [33] was able to reduce the incidence of anterior knee pain (RR 0.27, CI 0.14 to 0.54, NNT 28). Similar to studies without equipment, the sensitivity analysis indicated a mixture of effective and ineffective warm-up programmes which used additional equipment to prevent knee injuries.

thumbnailFigure 4. Forest plot graph demonstrating risk ratios for the effectiveness of neuromuscular warm-up strategies in preventing knee injuries.

Lower leg and ankle injuries

RRs for the effectiveness of neuromuscular warm-up strategies in preventing lower leg and ankle injuries are shown in Figure 5. A strong trend was indicated for the 'KIPP' [30] strategy to reduce non-contact ankle sprains (RR 0.42, CI 0.18 to 1.01, NNT 77). However, none of the neuromuscular warm-up programmes evaluated produced a significant reduction in lower leg or ankle injuries. Contrary to this, five of the eight programmes using equipment which were evaluated in the sensitivity analysis significantly reduced the risk of ankle injury. Additional equipment used in successful studies included balance boards [13-15,17], sticks [16] and medicine balls [17].

thumbnailFigure 5. Forest plot graph demonstrating risk ratios for the effectiveness of neuromuscular warm-up strategies in preventing lower leg and knee injuries.

Discussion

This systematic review investigated the effectiveness of neuromuscular warm-up strategies for injury prevention. Based on available data a number of strategies appear to be effective in preventing lower limb injuries. Specifically, 'The 11+' [31] strategy may reduce overall and overuse lower limb injuries in young amateur female footballers; the 'KIPP' [30] strategy may reduce non-contact overall and overuse lower limb injuries in young amateur female basketball and volleyball players, the PEP strategy [26,28] may reduce ACL injuries in young amateur female footballers; and the AKP PTP [33] may reduce the incidence of overuse anterior knee pain in young male and female military recruits.

Study Analysis

The quality assessment criteria revealed that the studies had various methodological weaknesses affecting their internal validity. Firstly, sample sizes were often too low to evaluate specific injuries (for example, ankle sprains). If evaluating the effectiveness of neuromuscular warm-up programmes on more specific injuries, sample size calculations prior to commencement and recruitment of larger samples are recommended. Additionally, future studies should ensure blinding of assessors, concealment of treatment allocation, intention to treat analysis and more adequate randomization procedures to reduce the impact of issues relating to internal validity. External validity was also limited, in particular the applicability of the findings to age groups other than between 13 and 26 years.

There is also a need to determine the mechanism of effectiveness of neuromuscular warm-up strategies and determine whether injury reduction is the result of each individual component or due to a combination of exercises. No studies were identified which compared two different components or combinations of neuromuscular warm-up strategies and, in general, programmes targeted varying risk factors associated with a variety of specific injuries. Addressing this through further research will enable more emphasis on effective components of injury-specific interventions and facilitate the development of more successful neuromuscular warm-up strategies for injury prevention, specifically in reference to specific lower limb injuries.

There is limited homogeneity between the prevention strategies and the methods of recording injury incidence, making data pooling for meta-analysis inappropriate. Injury incidence was reported by a certified athletic trainer [28], a coach [26,27,30-32], an author [29,34] and participant self-reporting [33]. This may have led to a difference in the incidence of injury reporting due to the individuals' medical understanding of an injury. For example, the participants who are self-reporting may be less likely to complain of an injury perhaps due to a lack of medical insurance, compared to the author who, incidentally, is an orthopaedic consultant. The duration of the prevention strategies were 12 weeks [27,28,34], 14 weeks [33], eight months [31,32], nine months [29], and one [30] and two years [26]. Currently, it is unclear how these differences may have impacted outcomes. Further research is needed to determine the minimum participation period needed to provide protection against injury. The prevention strategies were not performed before every training session in the studies by Steffen et al. [32], Gilchrist et al. [28], LaBella et al. [30], Kiani et al. [29] and Brushøj et al. [34]. This potentially allowed other warm up strategies to confound any benefits of the neuromuscular training exercises and conversely for optimal effects not to be realized.

Adverse effects were only noted in four studies [26,28,31,33] and should be recorded more frequently in future studies. Those mentioned include muscle soreness at the introduction of the study [26], one minor hamstring strain [31] and one fractured tibia/fibula from falling over a ball while jumping over it [28]. It is important for studies to directly question participants about adverse effects so that safe, as well as effective, strategies are established.

Total incidence of lower limb injuries

The effectiveness of three neuromuscular warm-up strategies in preventing the total number of lower limb injuries was evaluated in studies included in this review. Of these, only 'The 11+' [31] and KIPP [30] were found to be effective, both reducing the risk of undefined lower limb and overuse lower limb injuries. The two strategies found to be ineffective were 'The 11' [32] and the PTP [34]. In the case of the 'The 11' [32] lack of effectiveness may be explained by poor compliance. 'The 11' [32] was only used in 52% of training sessions, most likely because of a seven-week summer break during the study. The training may have had an additive effect that was lost when detraining over this period and the number of teams using the strategy after this period dropped from 60% to 44%. The authors concluded that better compliance was needed for sufficient training effects to reduce injuries.

The PTP [34] may have been ineffective at reducing lower limb injuries in military recruits due to the sudden increase in intensity of participants' training, the low load of the participants' training and the lack of supervision/training of the soldiers. Additionally, the strategy was of a short duration (12 weeks) and used less technically demanding exercises (including no warm-up, agility or plyometric exercises).

Hip and thigh injuries

Hip and thigh injuries were recorded during the evaluation of two neuromuscular warm-up strategies, 'The 11+' [31] and 'The 11' [32]. Neither strategy significantly reduced hip or thigh injury rates, most likely because they were not powered to do so. Highlighting this, 'The 11' [32] programme indicated a strong trend toward reduced risk of groin injuries. This would likely have been a significant finding had more participants been recruited. In addition to study power, the components of the strategies may not have been adequate to reveal protection against hip and thigh injuries. A recent review of hamstring injury prevention demonstrates that isometric warm-up exercises, hamstring flexibility and concentric and eccentric strength training may be protective against hamstring injuries [35]. Additionally, core strength is a recognized factor in reducing the risk of injury. Evidence suggests that core muscle weakness may increase the risk of groin strain injuries [36]. Both 'The 11+' [31] and 'The 11' [32] incorporated Nordic hamstring curls for hamstring strength training and plank exercises for core stability. However, the number of repetitions or the frequency of these exercises may have been inadequate to reduce injury rate.

Knee injuries

Knee injury rates were recorded in all of the nine studies, with six of these recording ACL injuries. Based on available data, four neuromuscular warm-up strategies were found to be effective in preventing knee injuries. These included individual studies showing 'The 11+' [31] and 'HarmoKnee' [29] programmes to reduce the risk of undefined knee injuries, the PEP to reduce significantly the risk of both ACL injuries [26] and their recurrence [28] and the AKP PTP [33] to reduce the risk of anterior knee pain development.

Success of the AKP PTP [33] may relate to strategy frequency as it was performed an average of seven times per week, totalling 105 minutes, a higher frequency compared to other studies. In comparison, the PTP [34] demonstrated no reductions in anterior knee pain, and this was used only three times a week totalling 45 minutes.

Despite investigating the same warm-up strategy (that is, the PEP strategy), Mandelbaum et al. [26] demonstrated a highly significant reduction in ACL injuries while Gilchrist et al. [28] showed only a trend toward risk reduction; a significant risk reduction in ACL injuries during practice, but the overall risk remaining unchanged. Reasons for this are likely to be the result of the study design and methodology. The study undertaken by Mandelbaum et al. [26] was a CCT with inherent methodological limitations, while Gilchrist et al. [28] performed a RCT providing gold standard evidence. In the study by Mandelbaum et al. [26] there was no blinding or randomization which introduced the potential for subject and allocation bias, respectively. Additionally, the authors in the study by Mandelbaum et al. [26] informed the intervention football clubs that they would be receiving a strategy to reduce injury and enhance performance. Participants and trainers were, therefore, not blinded and were likely to have been influenced by motivational bias. Of those remaining, one study informed participants of its purpose but did not disclose to which group they had been randomly allocated [27] while the others informed subjects of the purpose in a similar way to Mandelbaum et al. [26,28-34].

The PTP [34], and KLIPP [27] programmes did not convey any significant protection against knee injuries. As previously discussed, this may relate to lack of advice, sudden increase in training and less demanding exercises in the PTP programme [34]. Additionally, the strategy components did not include any running or agility drills, which provide a comprehensive warm-up, and have been included in successful strategies such as 'The 11+' [31]. The KLIPP [27] did incorporate such exercises but their study had inherent methodological limitations. This strategy had the lowest frequency (two times per week) and this may partly explain its lack of effectiveness. The most successful strategies ('The 11+' [31], PEP [26,28] KIPP [30] and AKP PTP [33]) were performed at every training/match session suggesting that the effectiveness of neuromuscular warm-up strategies may depend on a dose-response relationship.

The 'HarmoKnee' [29] programme significantly reduced the risk of knee injuries. However, findings did not indicate a significant reduction in the risk of specific injuries including ACL, MCL, LCL or medial meniscus injuries, despite the intervention group injury numbers being zero for each. This is due to the very low number of injuries identified in the control group, with the number being five or below for each of these specific injuries and NNTs ranging from 146 (ACL injuries) to 729 (medial meniscus injuries). Until larger studies are completed evaluating the 'HarmoKnee' [29] programme, these results must be interpreted with caution. Considering the high costs associated with surgery and rehabilitation following injuries such as an ACL tear, these reduced rates may still be clinically meaningful.

Lower leg and ankle injuries

The effectiveness of four neuromuscular warm-up strategies which did not require additional equipment in preventing lower leg and ankle injuries were evaluated in studies from this review. Based on the results, no neuromuscular warm-up programme was able to reduce lower limb injury risk significantly. However, it should be considered that the KIPP [30] indicated a strong trend toward reduction of the incidence of ankle sprains, with an NNT of 77. Reasons for the prevention of ankle sprain injuries in the KIPP [30] strategy rather than the PTP [34] include the more comprehensive neuromuscular warm-up programme which took longer to perform and included lower repetitions of many more elements as well as dynamic exercises. Additionally, the study by Brushøj et al. [34] which evaluated the PTP programme had fundamental methodological flaws as mentioned earlier. No other strategies report significant reductions in lower leg or undefined ankle injuries. The '11+' [31] results showed a trend towards reduced risk of MTSS and undefined ankle injury; however, these were not convincing enough to conclude their effectiveness in injury prevention.

A previous systematic review comparing balance work (using balance boards) and neuromuscular exercises (without balance boards) revealed that ankle sprains were reduced by 36% and 50%, respectively [17]. Additionally, the sensitivity analysis completed in this review indicated that the addition of equipment, in particular balance boards, to warm-up programmes may be effective in reducing ankle injuries. This provides evidence that neuromuscular strategies can reduce ankle injuries. However, the practicality of these programmes may be questioned due to the need for acquisition of additional equipment requiring funding, maintenance and storage. Therefore, many sporting clubs and individuals, particularly in an amateur setting where most sports participation occurs, may consider that implementing such a programme is not worth the effort. In fact, this is the reason studies in our review were excluded if additional equipment were required. To impact on ankle injury prevention across all sports participation to a greater extent, design and evaluation of warm-up programmes which focus on dynamic balance and strengthening without the need for equipment such as balance boards is needed. If successful, this may provide a more practical and cost-effective alternative to using balance boards. Examples may include single leg balance exercises including throwing a ball with a partner and resisting a push from partners, hopping, and squat exercises including with heels raised and one leg squats.

Recommendations

According to the present systematic review, several practical neuromuscular warm-up strategies which do not require additional equipment that is not readily available at the usual amateur competition or training venues are effective to varying degrees at preventing lower limb injuries. However, in some instances a large number of participants would need to undertake a strategy before one injury is prevented. This is the case with the PEP [26] strategy requiring 70 participants to prevent one injury. 'The 11+' [31], 'KIPP' [30] and 'AKP PTP' [33] appear to provide more reasonable NNT values, requiring less than 35 participants to undertake the neuromuscular warm-up strategy to prevent one injury. Of these strategies, the KIPP [30] and '11+' [31] strategies prevent the most injuries with NNTs for overall lower limb injuries being just 18 and 24, respectively.

Importantly, this systematic review highlights several areas that may account for significantly better injury prevention when incorporating neuromuscular warm-up strategies. These include: (1) incorporation of stretching, strengthening and balance exercises, sports-specific agility drills and landing techniques; (2) completing the strategy for longer than three consecutive months; and (3) completing of the strategy at all training sessions. In addition to these programme specifics, further evaluation of the '11+' [31] programme has highlighted the importance of compliance, with high compliance being linked significantly to reduced lower limb injury risk [37].

Directions for Future Research

Further studies need to determine whether 'The 11+' [31], KIPP [30], 'HarmoKnee' [29], AKP PTP [33] and PEP [26,28] programmes are also effective in men, other age groups, and other sports as our review incorporated mainly women and involved only football, basketball, volleyball and military training. It is important to determine whether injury prevention programmes would also be effective if taught to older players who might possess more engrained poor motion patterns. In addition, healthcare professionals are encouraging middle-aged individuals to engage in sports and so research needs to include older individuals who are at a higher risk of sustaining an injury due to changed activity levels. It would also be beneficial to see if 'The 11+' [31], 'KIPP' [30], 'HarmoKnee' [29], PEP [26,28] strategy and AKP PTP [33] could be successfully combined to ultimately recommend a single injury prevention strategy. Finally, we need to know more about the mechanisms of injury prevention of neuromuscular warm-up strategies in order to optimize their effectiveness.

Conclusions

The current systematic review identified five practical neuromuscular warm-up strategies which do not require additional equipment and which may effectively reduce the risk of lower limb injuries. Specifically 'The 11+' reduced overall and overuse lower limb injuries and knee injuries in young amateur female football players, the 'KIPP' reduced non-contact overall and overuse lower limb injuries in young amateur female football and basketball players, the 'HarmoKnee'[29] programme reduced the risk of knee injuries, the 'PEP' strategy reduced the risk of non-contact ACL injury in young amateur female football players and the 'AKPPTP' reduced the risk of anterior knee pain in male and female military recruits. Further research evaluating the effectiveness of these strategies in more varied populations, particularly men and older individuals is now needed. To provide the greatest potential for reduced lower limb injury rates, it is recommended that neuromuscular warm-up strategies incorporate stretching, strengthening and balance exercises, sports-specific agility drills and landing techniques, and are completed for a duration of longer than three consecutive months at all training sessions. Identification of which neuromuscular warm-up strategy components are most beneficial and the mechanisms behind their effectiveness is needed to further reduce lower limb injury risks.

Competing interests

The authors declare that they have no competing interests.

Authors' contributions

KH and CB were the primary initiators of the study while all authors made substantial contributions to data analysis and interpretation. All authors were involved in drafting and revising the manuscript and approved the penultimate version. The final version was approved and submitted by DM.

References

  1. Shehab R, Mirabelli M, Gorenflo D, Fetters MD: Pre-exercise stretching and sports related injuries: knowledge, attitudes and practices.

    Clin J Sport Med 2006, 16:228-231. PubMed Abstract | Publisher Full Text OpenURL

  2. Witvrouw E, Mahieu N, Danneels L: Stretching and injury prevention: an obscure relationship.

    Sports Med 2004, 34:443-449. PubMed Abstract | Publisher Full Text OpenURL

  3. Thacker SB, Gilchrist J, Stroup DF: The impact of stretching on sports injury risk: a systematic review of the literature.

    Med Sci Sports Exerc 2004, 36:371-378. PubMed Abstract | Publisher Full Text OpenURL

  4. Andersen JC: Stretching before and after exercise: effect on muscle soreness and injury risk.

    J Athl Train 2005, 40:218-220. PubMed Abstract | PubMed Central Full Text OpenURL

  5. Pope RP, Herbert RD, Kirwan JD: A randomized trial of preexercise stretching for prevention of lower-limb injury.

    Med Sci Sports Exerc 2000, 32:271-277. PubMed Abstract | Publisher Full Text OpenURL

  6. Barclays survey reveals sports injury rate in the UK [http:/ / www.personal.barclays.co.uk/ BRC1/ jsp/ brccontrol?task=popup1group&value=1 1147&target=_blank&site=pfs] webcite

  7. Chief Medical Officer: 2009 Annual Report of the Chief Medical Officer. London: Department of Health; 2010.

  8. James PT, Rigby N, Leach R: The obesity epidemic, metabolic syndrome and future prevention strategies.

    Eur J Cardiovasc Prev Rehabil 2004, 11:3-8. PubMed Abstract | Publisher Full Text OpenURL

  9. Hübscher M, Zech A, Pfeifer K: Neuromuscular training for sports injury prevention: a systematic review.

    Med Sci Sports Exerc 2010, 42:413-421. PubMed Abstract | Publisher Full Text OpenURL

  10. van Tulder M, Furlan A, Bombardier C, Bouter L: Editorial Board of the Cochrane Collaboration Back Review Group. Updated method guidelines for systematic reviews in the Cochrane collaboration back review group.

    Spine 2003, 28:1290-1299. PubMed Abstract | Publisher Full Text OpenURL

  11. Olivo SA, Macedo LG, Gadotti IC, Fuentes J, Stanton T, Magee DJ: Scales to assess the quality of randomized controlled trials: a systematic review.

    Phys Ther 2008, 88:156-175. PubMed Abstract | Publisher Full Text OpenURL

  12. Olsen OE, Mykelbust G, Engebretsen L, Holme I, Bahr R: Exercises to prevent lower limb injuries in youth sports: cluster randomized controlled trial.

    BMJ 2005, 330:449-452. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  13. Emery CA, Rose MS, McAllister JR, Meeuwisse WH: A prevention strategy to reduce the incidence of injury in high school basketball: a cluster randomized controlled trial.

    Clin J Sport Med 2007, 17:17-24. PubMed Abstract | Publisher Full Text OpenURL

  14. Pasanen K, Parkkari J, Pasanen M, Hiilloskorpi H, Mäkinen T, Järvinen M, Kannus P: Neuromuscular training and the risk of leg injuries in female floorball players: cluster randomised controlled study.

    BMJ 2008, 337:a295. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  15. Emery CA, Meeuwisse WH: The effectiveness of a neuromuscular prevention strategy to reduce injuries in youth soccer: a cluster-randomised controlled trial.

    Br J Sports Med 2010, 44:555-562. PubMed Abstract | Publisher Full Text OpenURL

  16. Parkkari J, Taanila H, Suni J, Mattila VM, Ohrankämmen O, Vuorinen P, Kannus P, Pihlajamäki H: Neuromuscular training with injury prevention counselling to decrease the risk of acute musculoskeletal injury in young men during military service: a population-based, randomised study.

    BMC Med 2011, 9:35. PubMed Abstract | BioMed Central Full Text | PubMed Central Full Text OpenURL

  17. Wedderkopp N, Kaltoft M, Lundgaard B, Rosendahl M, Froberg K: Prevention of injuries in young female players in European team handball. A prospective intervention study.

    Scand J Med Sci Sports 1999, 9:41-47. PubMed Abstract OpenURL

  18. Heidt RS, Sweeterman LM, Carlonas RL, Traub JA, Tekulve FX: Avoidance of soccer injuries with preseason conditioning.

    Am J Sports Med 2000, 28:659-662. PubMed Abstract | Publisher Full Text OpenURL

  19. McHugh MP, Tyler TF, Mirabella MR, Mullaney MJ, Nicholas SJ: The effectiveness of a balance training intervention in reducing the incidence of noncontact ankle sprains in high school football players.

    Am J Sports Med 2000, 35:1289-1294. OpenURL

  20. Verhagen EA, van Tulder M, van der Beek AJ, Bouter L, van Mechelen W: An economic evaluation of a proprioceptive balance board training programme for the prevention of ankle sprains in volleyball.

    Br J Sports Med 2005, 39:111-115. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  21. Steffen K, Bakka HM, Myklebust G, Bahr R: Performance aspects of an injury prevention program: a ten-week intervention in adolescent female football players.

    Scand J Med Sci Sports 2008, 18:596-604. PubMed Abstract | Publisher Full Text OpenURL

  22. Eisen TC, Danoff JV, Leone JE, Miller TA: The effects of multiaxial and uniaxial unstable surface balance training in college athletes.

    J Strength Cond Res 2010, 24:1740-1745. PubMed Abstract | Publisher Full Text OpenURL

  23. Lim BO, Lee YS, Kim JG, An KO, Yoo J, Kwon YH: Effects of sports injury prevention training on the biomechanical risk factors of anterior cruciate ligament injury in high school female basketball players.

    Am J Sports Med 2009, 7:1728-1734. OpenURL

  24. Kaminski TW, Buckley BD, Powers ME, Hubbard T, Ortiz C, Mattacola C: Eff:ct of strength and proprioception training on eversion to inversion strength ratios in subjects with unilateral functional ankle instability.

    Br J Sports Med 2003, 37:410-415. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  25. Myklebust G, Engebretsen L, Braekken IH, Skjølberg A, Olsen OE, Bahr R: Prevention of anterior cruciate ligament injuries in female team handball players: a prospective intervention study over three seasons.

    Clin J Sport Med 2003, 13:71-78. PubMed Abstract | Publisher Full Text OpenURL

  26. Mandelbaum BR, Silvers HJ, Watanabe DS, Knarr JF, Thomas SD, Griffin LY, Kirkendall DT, Garrett W: Effectiveness of a Neuromuscular and Proprioceptive Training Program in Preventing Anterior Cruciate Ligament Injuries in Female Athletes: 2-Year Follow-up.

    Am J Sports Med 2005, 33:1003-1010. PubMed Abstract | Publisher Full Text OpenURL

  27. Pfeiffer RP, Shea KG, Roberts D, Grandstrand S, Bond L: Lack of effect of a knee ligament injury prevention program on the incidence of noncontact anterior cruciate ligament injury.

    J Bone Joint Surg Am 2006, 88:1769-74. PubMed Abstract | Publisher Full Text OpenURL

  28. Gilchrist J, Mandelbaum BR, Melancon H, Ryan GW, Silvers HJ, Griffin LY, Watanabe DS, Randall WD, Dvorak J: A randomized controlled trial to prevent noncontact anterior cruciate ligament injury in female collegiate soccer players.

    Am J Sports Med 2008, 36:1476-83. PubMed Abstract | Publisher Full Text OpenURL

  29. Kiani A, Hellquist E, Ahlqvist K, Gedeborg R, Michaélsson K, Byberg L: Prevention of soccer-related knee injuries in teenaged girls.

    Arch Intern Med 2010, 170:43-9. PubMed Abstract | Publisher Full Text OpenURL

  30. LaBella CR, Huxford MR, Grissom J, Kim KY, Peng J, Christoffel KK: Effect of neuromuscular warm-up on injuries in female soccer and basketball athletes in urban public high schools: cluster randomized controlled trial.

    Arch Pediatr Adolesc Med 2011, 165:1033-40. PubMed Abstract | Publisher Full Text OpenURL

  31. Soligard T, Myklebust G, Steffen K, Holme I, Silvers H, Bizzini M, Junge A, Dvorak J, Bahr R, Anderson TE: Comprehensive warm-up programme to prevent injuries in young female footballers: cluster randomised controlled trial.

    BMJ 2008, 337:a2469. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  32. Steffen K, Myklebust G, Olsen OE, Holme I, Bahr R: Preventing injuries in female youth football--a cluster-randomized controlled trial.

    Scand J Med Sci Sports 2008, 18:605-14. PubMed Abstract | Publisher Full Text OpenURL

  33. Coppack RJ, Etherington J, Wills AK: The effects of exercise for the prevention of overuse anterior knee pain: a randomized controlled trial.

    Am J Sports Med 2011, 39:940-8. PubMed Abstract | Publisher Full Text OpenURL

  34. Brushøj C, Larsen K, Albrecht-Beste E, Nielsen MB, Løye F, Hölmich P: Prevention of Overuse Injuries by a Concurrent Exercise Program in Subjects Exposed to an Increase in Training Load A Randomized Controlled Trial of 1020 Army Recruits.

    Am J Sports Med 2008, 36:663-670. PubMed Abstract | Publisher Full Text OpenURL

  35. Petersen J, Holmich P: Evidence based prevention of hamstring injuries in sport.

    Br J Sports Med 2005, 39:319-323. PubMed Abstract | Publisher Full Text | PubMed Central Full Text OpenURL

  36. Maffey L, Emery C: What are the Risk Factors for Groin Strain Injury in Sport?: A Systematic Review of the Literature.

    Sports Medicine 2007, 37:881-894. PubMed Abstract | Publisher Full Text OpenURL

  37. Soligard T, Nilstad A, Steffen K, Myklebust G, Holme I, Dvorak J, Bahr R, Andersen TE: Compliance with a comprehensive warm-up programme to prevent injuries in youth football.

    Br J Sports Med 2010, 44:787-93. PubMed Abstract | Publisher Full Text OpenURL

Pre-publication history

The pre-publication history for this paper can be accessed here:

http://www.biomedcentral.com/1741-7015/10/75/prepub