Volume 9, Issue 4 (Autumn 2019)                   PTJ 2019, 9(4): 193-202 | Back to browse issues page


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Mohammadi H, Ghaeeni S. Prevalence of Neuromuscular Deficiencies Associated With Non-Contact Anterior Cruciate Ligament Injury in Healthy Collegiate Student-Athletes. PTJ. 2019; 9 (4) :193-202
URL: http://ptj.uswr.ac.ir/article-1-408-en.html
1- Department of Physical Education and Sports Sciences, Faculty of Humanities and Social Sciences, University of Kurdistan, Sanandaj, Iran.
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1. Introduction
The prevalence of sports injuries in college athletes (from 2009-2010 to 2014-2015) in 25 sports suggested that the most common injured body part is the knee (32.9%). Moreover, in indoor sports, like women’s volleyball, ˃50% of the injuries occur in the knee joint [1]. Additionally, the most common injury is sprains (32.9%); in indoor sports, like women’s soccer, ˃50% of the injuries is sprain [1]. Anterior Cruciate Ligament (ACL) tear is the most frequent severe injury in women’s lacrosse (28.1%), women’s soccer (25.9%), women’s volleyball (25.7%), women’s basketball (20.8%), men’s lacrosse (17.4%), softball (14.8%), men’s football (14.0%), women’s gymnastics (13.9%), and men’s basketball (12.0%) [1]. The proportion of severe injuries is higher in women, compared to men for overuse and noncontact mechanisms [1]. Investigating gender differences in the incidence of ACL, Medial Collateral Ligament (MCL), and meniscal injuries in collegiate and high school sports (from 2009-2010 to 2013-2014) revealed that ACL injury in female athletes is higher than that of male athletes at both levels; however, there was no distinct gender disparity in MCL and meniscal injuries [2]. Furthermore, ACL injuries had the highest number of cases treated with surgery with high treatment costs, the loss of sports participation, and the creation of secondary injuries, including osteoarthritis [3].
For example, the incremental cost-effectiveness ratio of ACL reconstruction, compared with physical therapy, was $22702 per quality-adjusted life-years in competitive athletes [4]. Besides, at least two-thirds of ACL sprains occur during noncontact situations and their peak incidence is between 19 and 25 years of age [3]. Therefore, the present study investigated the prevalence of neuromuscular deficiencies associated with non-contact ACL injury in the female and male athletes aged 18 to 25 years. Probably, there is a multi-factorial mechanism behind this gender differences in ACL injury incidence. However, among the intrinsic risk factors for ACL injury (anatomic, hormonal, and neuromuscular abnormalities), only the neuromuscular control is modifiable [5]. Neuromuscular dysfunction increases the load on the lower extremities joints during sports activities; therefore, it is the leading risk factor for noncontact ACL injuries [5]. Numerous studies have investigated the neuromuscular deficiencies, mechanisms, and the impact of intervention exercises on ACL injury [5-7]. 
Conventionally, 3-dimensional motion capture during high impact activities, such as directional changes and landing is used to assess kinematic variables and to identify knee and ACL injury risks [8, 9]. However, using such analysis for assessments is time consuming and costly; thus, it is impractical in most clinical settings. The ability to maintain dynamic knee stability during landing and jumping generates from sufficient neuromuscular control [9]. Various measures have been created to test for neuromuscular deficiencies correlated with an increased ACL injury rate. There are several jumping and landing 2-dimensional tests, including the Landing Error Scoring System (LESS) [10], the Drop Vertical Jump (DVJ) test [11] and the Tuck Jump Assessment (TJA) [12]. The LESS and DVJ inventories only require three jumps; however, in the TJA, athletes must perform consecutive jumps for 10 seconds. The TJA is a full effort plyometric jump task and may better reflect sport-specific jumping and landing activities. Therefore, the TJA might highlight unobservable landing defects in three non-consecutive jumps [10-12]. Because TJA is very practical and efficiently performed, the researchers can use it to screening neuromuscular imbalances in athletes [12].
Moreover, using a double-leg jump task in TJA may allow to detect side-to-side asymmetries. In this study, male and female youth athletes were assessed applying the modified TJA [13]. Changing the scoring system from the original scale (0-1) to a modified scale (0-2) results in providing further objective information about ACL injury risk in athletes [13]. Vanmeerhaeghe et al. reported good to excellent intra- and inter-rater reliability for most items of the modified TJA [13]. 
Hewett et al. in a video analysis on the athlete injury risk during tuck jump identified 4 neuromuscular imbalances as the underlying mechanisms of non-contact ACL injuries [5]. Jumps and landings during the TJA were analyzed with 10 items, used to assess these 4 neuromuscular imbalances (ligament, quadriceps, leg, and trunk dominance) [5]. Most of the deviations from the desired movement pattern were caused by impaired neuromuscular control strategies. Six different neuromuscular deficits may contribute to lower extremity and especially ACL pathomechanics during high impact activities, such as jumping and landing [14]. These 6 neuromuscular deficits include the following: 1. dynamic valgus or ligament dominance (increased reliance on the frontal plate control relative to the sagittal plane); 2. quadriceps dominance (lower contributions of hamstring muscles resulting in quadriceps dominant strategy to stabilize the knee joint); 3. leg dominance (greater strength, balance, and coordination in the dominant leg); 4. trunk dominance (decreased stability and proprioception of the trunk); 5. neuromuscular fatigue; and 6. feed-forward mechanisms deficits [13, 15]. Accordingly, the present study investigated the prevalence of neuromuscular deficiencies during TJA (ligament dominance, quadriceps dominance, leg dominance, trunk dominance, and neuromuscular fatigue) in female and male physical education and sports science collegiate students.
2. Materials and Methods
All female and male undergraduate students of Physical Education and Sports Science faculty at the University of Kurdistan in 2018-2019 academic year comprised the study population. The students (N=132) who met the inclusion criteria were selected as study subjects (77 female and 55 male). Inclusion criteria consisted of being undergraduate students of Physical Education and Sports Science at the University of Kurdistan in 2018-2019 academic year, being aged 18-25 year, conducting ≥3 sessions of exercise per week, having normal Body Mass Index (BMI). Exclusion criteria were having a history of surgery in the trunk and ACL injury or severe lower extremity injury during the past year, chronic trunk and lower extremity injuries (e.g. chronic ankle instability), having any injury (overuse or acute) at the time of testing, and participation in ACL injury prevention exercise programs. All study participants received an explanation regarding the nature, purpose, and risks of the research. Then, they were given the opportunity to ask questions regarding the research. Demographic data, medical history, and sports history of the subjects were collected using a questionnaire. Next, the anatomical and anthropometric variables were measured. Accordingly, upon introducing and describing the TJA tests, the subjects performed 10 minutes of warm-up, and TJA data were recorded. Table 1 provides the study subject’ demographic characteristics. All study participants were healthy and without prior tuck jump training. All measurements were conducted in Physical Education and Sports Science Research Laboratory of the University of Kurdistan. All study participants signed an informed consent approved by the Academic Committee Ethics in Biomedical Research of the University of Kurdistan before participating in the study.
A week before conducting the TJA test, the study subjects were familiarized with the testing procedure and anatomical and anthropometric variables were measured. A video presentation consisting of representative images from sagittal and frontal views of a TJA was played. Then, a live demonstration of correct tuck jump technique was presented to the samples. The TJA test consists of a 10-second continuous maximal height tuck jump with maximal effort level [13, 15]. The study subjects were instructed to place their feet in the middle of the rectangle marked on the floor consisting of 4 smaller rectangles (Figure 1).
Initial set up for the TJA required 2 two-dimensional video cameras (Casio Japan, model CASIO-Ex-ZR1000, with the ability to shoot 1000 frames per second) on tripods to provide the sagittal and frontal views of the participants in the height marked at the athletes’ waist. The camera was aligned three meters away in the sagittal plane and frontal plane.
The TJA test was performed using instructions from previous studies [16-19]. Necessary instructions were provided to the samples about how to perform the TJA test. Such information included lifting knees up as high as possible so both thighs were parallel with the ground, attempting to landing softly in the same footprint in each jump with their feet shoulder-width apart, and then immediately begin the next jump. Then, the study subjects were allowed to perform 3-5 practice trials to ensure the accurate performance of the TJA test. The study subjects performed a 10-minute neuromuscular warm-up in the testing session. This warm-up consisted of multidirectional movements, strength and dynamic stretching, the change of directions, jumps, and acceleration/deceleration movements. 
Prior to data collection, all study subjects were allowed to perform no more than two TJA trials. After warm-up, each subject performed 10 seconds of continuous tuck jumps on the designated location. While performing TJA test, no feedback was provided to the study subjects; after 10 seconds, the jumping and cameras recording stopped.
Each study subject’s recorded TJA performance was independently scored across 10 criteria. Table 2 and Figure 2 present the individual scoring criteria for each item of the modified TJA. Table 3 demonstrates the categorization of neuromuscular deficiencies based on these 10 items. The films recorded by two cameras (sagittal and frontal views) were evaluated using the free video software (Kinovea). Kinovea allowed videos to be played at various speeds and frame-by-frame; also, the two cameras were synchronized. Scoring TJA performance by advancing the videos was conducted on a frame by frame basis. If the study subjects met the criteria, score zero was assigned and if subjects failed to meet the criteria scores one or two were given. In the original TJA test, a lower score indicates a better performance. The researcher was allowed to independently watch the videos as many times as necessary and at whatever speeds required to score each test. Then, the statistical analysis of the data was performed (the scores of the 10 items). 
The obtained data were analyzed in SPSS at a significance level of 0.5. Descriptive statistics were performed on all data, e.g. the frequency and percentage of neuromuscular deficiencies (Figure 3 & Table 4). The Mean±SD scores of all variables were calculated (Table 4). The outcome measurements of tuck-jump deficits were scored by the researcher in both gender groups. The 10 criteria were analyzed for each subject from frontal and sagittal video views. We ensured the homogeneity of variance by Levene’s test (Table 4) and the normal distribution of data by Shapiro–Wilk test. To determine the differences between the mean values of tuck jump in male and female athletes and to examine the effects of the groups, one-way Analysis of Variance (ANOVA) was used (Table 4). 
3. Results
Descriptive data analysis results suggested that ligament dominance is most common neuromuscular deficiencies (64.4%), and ˃50% of the subjects had the leg dominance and trunk dominance (53.8%); however, the prevalence of neuromuscular fatigue (9.2%) and quadriceps dominance (15.2%) was small. One-way ANOVA results revealed a significant difference between the tuck jump score in male and female athletes (P<0.01). The gender difference was not significant in neuromuscular fatigue and quadriceps dominance. However, there was a significant gender-wise difference in ligament dominance, trunk dominance, and leg dominance (P<0.01). The prevalence of leg dominance in males (65.5%) was higher than that of females (45.5%). However, the prevalence of ligament dominance in female (81.8%) was higher than that of males (40%). Additionally, the prevalence of trunk dominance in females (72%) was higher than that of males (26.3%). In both groups, the prevalence of neuromuscular fatigue and quadriceps dominance was <16%.


4. Discussion 
The present study investigated the prevalence of neuromuscular deficits in female and male collegiate athletes during a 10-second tuck jump with a modified scoring system (0-2). The higher TJA scores indicated weakened neuromuscular control and high-risk movement patterns; these are associated with an increased risk of lower extremity injury [5]. The modified TJA is a user-friendly clinical option that requires minimal equipment, takes only minutes to administer, and could help to detect reductions high-risk movement patterns after a prevention exercise program [13]. Furthermore, modified TJA has excellent between-session and good inter-rater reliability for its total score [12, 13]. Therefore, the achieved results could be beneficial for coaches and clinicians as a prevention exercise program. It could be used for injury prevention to target deficits associated with ACL injury risk in male and female athletics, as well as the differences between them. The tested hypothesis was supported by the finding of the significant gender difference between the tuck jump score (P<0.01). In females, the prevalence of ligament dominance (81.80%), trunk dominance (72%), neuromuscular fatigue (14.3%), and quadriceps (20%) dominance was higher, compared to males. However, in males, only the prevalence of leg dominance (65.5%) was higher than that of the females. 
The ligament dominance is among the most essential mechanisms of non-contact ACL injury. Where muscles insufficiently absorb the ground reaction forces, knee ligaments must absorb this force and the knee collapses into dynamic knee valgus position, i.e., called ligament dominance [5]. High level of force sustained over a short period of time may result in ligament rupture; it is more frequent in females, than males [5]. Increased dynamic knee valgus (ligament dominance) during landing was also introduced as a critical risk factor for ACL injury [5, 20]. The collected results also revealed that ligament dominance was the most common neuromuscular defect (64.4%) during the TJA test in the subjects. More than 80% of females and 40% of males have the knee valgus; therefore, many studies have investigated the effect of interventional exercises on the reduction of knee valgus. Significant improvement in ligament dominance (knee valgus) has been reported in some of these studies [21-24]; however, many other studies reported that the exercise interventions failed to improve knee valgus [25-27]. Most of these studies mainly focused on plyometric or balance interventional exercises; regardless of whether the subjects had or not had ligament dominance or other neuromuscular impairments, like trunk dominance, the interventional exercise program was applied. Females usually have a higher rate of ACL injury than males (8.9), and 76.6% of ACL injuries resulted in surgical treatment [28]. Therefore, considering the neuromuscular impairment gender-wise differences in prevention exercise programs is vital. The achieved results suggested that to prevent ACL injury, correction ligament dominance and correction trunk dominance, as well as leg dominance should be targeted in interventional exercise programs.
Moreover, interventional exercise programs for females should focus on the ligament dominance, trunk dominance, and leg dominance, respectively; however, for males, leg dominance should be the top priority. In addition, ACL injury is among the most devastating injuries requiring surgical treatment and extensive rehabilitation. It also has a potential for long-term health problems, like osteoarthritis and is not limited to female athletes [28]. Participation in sports will always be associated with a specific level of ACL injury in both genders. Thus, preventing this injury is necessary for both genders. As a result, both groups were examined in this study.
The trunk dominance occurs when athletes fail to adequately feel their trunk position in a 3-dimensional plan, and allow greater movement following a perturbation of their trunk; therefore, athletes are unable to precisely control the trunk [5]. Previous studies reported that impaired core stability is a risk factor for the development of lower extremity injuries [29]. For example, reduced core strength is predictive for ACL injuries [30], increased lateral trunk displacement is the strongest predictor of knee injuries [30], and impaired proprioception of the core predicts knee injury risk [30]. Trunk displacement predicted knee ligament injury with 91% sensitivity and 68% specificity and is higher in athletes with ACL injuries than the uninjured ones [31]. Although trunk displacements predicted ACL injury risk in female athletes with 89% and 91% accuracy, only a history of low back pain was a significant predictor of knee ligament injury risk in male athletes [31]. The collected results indicated that trunk dominance was among the most common neuromuscular deficits (53.8%) during the TJA test, especially in female athletes. This is probably because ˃70 of the females have trunk dominance, while only 27.3% of the males have it.
In tasks such as landing that typically requires side-to-side symmetry of the lower extremities, athletes with leg dominance tend to be leaner on one-leg. Because there is a difference between limbs in muscle recruitment patterns, muscle strength, and muscle flexibility, athlete’s limbs are asymmetric [5]. Female skiers usually demonstrated a 2-fold higher risk of suffering ACL ruptures of their non-dominant leg, compared to male skiers [32]. Non-contact ACL injury in soccer female athletes often occurs in the supporting leg (non-dominant); whereas it often occurs in the kicking leg (dominant) among the males [33]. In other words, in soccer, 74.1% of ACL injuries in males occurs on the dominant leg; however, 32% of ACL injury occurs on the dominant leg of females [33]. The study results suggested that leg dominance is among the most common neuromuscular deficits (53.8%) during the TJA test, especially in male athletes because ˃65% of the males had leg dominance, while only 45.5% of the females had that.
In female colligate athletes, the incidence of the ligament dominance is equal to 81.8%; thus, trunk dominance is 72.7% and leg dominance is 45.5%. Accordingly, it is recommended that ACL injury prevention exercise programs for females emphasize on the correction of ligament dominance and trunk dominance defects. However, for the male colligate athlete’s, the correction of leg dominance deficiency followed by ligament dominance is a priority. That is because in male colligate athletes, the incidence of the leg dominance is 65.5%, the ligament dominance is 40%, and trunk dominance is 27.3%. 
5. Conclusion 
The prevalence rate of neuromuscular deficits during tuck jump in female and male subjects revealed that ˃50% of the study subjects had the ligament dominance (64.4%), leg dominance (53.8%), and trunk dominance (53.8%). Thus, it is recommended that preventive exercise programs mainly emphasize on the correction of these defects. However, the correction of leg dominance deficiency is a priority for males; the correction of ligament dominance and trunk dominance is a priority for females.
Ethical Considerations
Compliance with ethical guidelines
All athletes read and signed a written informed consent before testing and provided a detailed injury history. The study participants were informed about the research purpose and its implementation stages; they were also assured about the confidentiality of their obtained information. Moreover, they were allowed to leave the study whenever they wished, and if desired, the research results would be available to them.
Funding
The authors received grant (Code: 97.11.22/907) from the University of Kurdistan.
Authors' contributions
Conceptualization, Methodology, Investigation, Resources, Data gathering, Writing – Original draft, Preparation, Project administration: Hemn Mohammadi; Statistical Analysis, and Editing:  Saeed Ghaeeni.
Conflict of interest
The authors declared no conflict of interest.
Acknowledgments
The authors express their thanks to all of the undergraduate students in 2018-2019 academic year of Physical Education and Sports Science at the University of Kurdistan. Thanks are also extended to the staff of in the same faculty in the University of Kurdistan, Physical Education and Sports Science Research Laboratory of the University of Kurdistan and all others who contributed to this study.


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Type of Study: Research | Subject: Special
Received: 2019/04/12 | Accepted: 2019/08/5 | Published: 2019/10/1

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