The Influence of the Lower Limb Components on Genu Varum in Football Players

Completed

• Conditions: Genu Varum; Football Players
• Interventions: Diagnostic Test: Magnetic Resonance Imaging; Other: Isokinetic Strength

• Registration Number: NCT06606964
• Lead Sponsor: Tuba Melekoğlu

Brief Summary

Objectives: To evaluate lower extremity alignments in football players with and without genu varum using magnetic resonance imaging (MRI), to determine the mechanisms underlying malalignment and the factors contributing to it.

Methods: This is a prospective case-control study with football players with/without lower extremity malalignment. Full-length lower extremity MRI was used to evaluate the lower extremity alignment parameters. In addition, the isokinetic strength of the concentric knee extensor-flexor and concentric hip abductor-adductor muscles was measured using an isokinetic dynamometer at two different angular velocities: 60˚/sec and 180˚/sec. The investigators created a logistic regression model to investigate whether the alignment parameters used to evaluate lower extremity alignment in football players are risk factors for the development of genu varum.

Detailed Description

Genu varum deformity is a common condition among football players, occurring in 73% of cases . Previous studies have shown that football players are at a higher risk of developing genu varum than athletes in other sports . Genu varum can have a negative impact on an athlete\'s physical abilities by disrupting static and dynamic balance through alterations in the gravitational axis of the lower extremities. In addition, genu varum can damage the tibiofemoral articular cartilage, increasing the risk of knee osteoarthritis later in life . It is also associated with several intra-articular pathologies, including meniscal lesions, anterior knee pain, and anterior cruciate ligament injuries . Therefore, it is important to understand the cause of this deformity and take protective-corrective measures for football players.

In recent years, researchers have studied the relationship between genu varum and football participation. Researchers have used various methods, including the caliper, goniometer, and photographic technique, to analyze deformities. However, these methods have limitations, making it difficult to examine etiological factors and differences in anthropometric components . In a study conducted by Colyn, Arnout, Verhaar and Bellemans 6, a comparison was made between football players and other athletes and non-athletes using digital radiology measurements. The findings indicated that male football players exhibited genu varum, with the proximal tibia identified as the primary factor determining this. Similarly, Krajnc and Drobnič studied lower limb alignment in asymptomatic adult professional football players and found that the proximal tibia was the source of varus deformity. However, it has been suggested that additional research is required to fully comprehend the involved mechanisms. Furthermore, Witvrouw, Danneels, Thijs, Cambier and Bellemans 9proposed that an imbalanced strength distribution between the adductor and abductor muscles may result in genu varum in football players. This is because kicking, a frequent activity in football, often strengthens the adductor muscles, which can alter the average adductor/abductor strength ratio. However, the authors note that no data on the adductor/abductor strength of football players is available in the literature. They suggest further research to address this knowledge gap.

Asymmetrical movements in football, resulting from the difference between the kicking and supporting legs, may lead to different mechanisms causing genu varum formation in the dominant and non-dominant legs. It is crucial to acknowledge that not all football players exhibit varus knee alignment. Consequently, in order to ascertain the mechanisms that contribute to the formation of genu varum, it is essential to conduct a comparative analysis between football players exhibiting and those lacking a varus deformity. This comparison can assist in identifying the mechanisms that cause genu varum in football players and the factors likely to contribute to these mechanisms. The study had three objectives: (i) to evaluate lower extremity alignments in football players with and without genu varum using magnetic resonance imaging (MRI), (ii) to determine the mechanisms underlying malalignment and the factors contributing to it; and (iii) to investigate the relationship between lower extremity alignment and isokinetic strength.

Study Timeline

• Study Start: 2021-12-01
• Primary Completion: 2022-12-30
• Study Completion: 2022-12-30
• Status Verified: 2024-09
• Study First Submitted: 2024-09-16
• Study First Submitted QC: 2024-09-18
• Last Update Submitted: 2024-09-18
• Study First Posted: 2024-09-23
• Last Update Posted: 2024-09-23

Recruitment & Eligibility

• Status: COMPLETED
• Sex: Male
• Target Recruitment: 36

Inclusion Criteria

• Healthy football players who currently play for a professional football club
• Aged 16-19
• Have at least five years of football experience
• Train five days a week
• Participating in official matches.

Exclusion Criteria

• History of musculoskeletal disease
• History of postural disorders
• History of previous surgery for lower extremity sports injuries
• History of fractures of the long bones of the lower extremity

Study & Design

• Study Type: OBSERVATIONAL
• Study Design: Not specified

Arm && Interventions

Group	Intervention	Description
Football players with genu varum	Magnetic Resonance Imaging	Football players with genu varum leg alignment
Football players with genu varum	Isokinetic Strength	Football players with genu varum leg alignment
Football players without genu varum	Magnetic Resonance Imaging	Football players with normal lower extremity alignment
Football players without genu varum	Isokinetic Strength	Football players with normal lower extremity alignment

Primary Outcome Measures

Name	Time	Method
Mechanical axis deviation (MAD)	From enrollment to the end of measurements at 3 weeks	The mechanical axis is a line connecting the center of the femoral head to the center of the ankle (center of the dome of the talus). A line was drawn from the center of the femoral head to the center of the ankle and the intersection of this line with the knee joint line was marked. The perpendicular distance from this intersection point to the center of the patella was measured as MAD.
Femoral anteversion (FA)	From enrollment to the end of measurements at 3 weeks	On the axial images of the hip/pelvis covering the femoral head and neck, a line is drawn between the center of the femoral head and center of the femoral neck to calculate the uncorrected femoral anteversion angle. To correct for distal femoral rotation, another line is drawn along the posterior border of the femoral condyles to calculate the angle. Positive degrees between the femoral neck and the distal femoral axis are called femoral antetorsion; negative values were considered as femoral retrotorsion.
Medial proximal tibial angle (MPTA)	From enrollment to the end of measurements at 3 weeks	The MPTA was defined as the medial angle between the proxsimal tibial joint line and the mechanical axis of the tibia. The proximal joint orientation line of tibia was drawn. A line was also drawn from the midpoint of the ankle to the midpoint of the knee on the tibial joint line. The angle between these two lines was measured.
Tibial torsion (TT)	From enrollment to the end of measurements at 3 weeks	Proximal tibial axis (PTA) was placed along the posterior cortex of the tibial head at the level of condyls proximal to the fibular head. Distal tibial axis (DTA) was placed to the articular aspects of the medial and the lateral malleolus below the talar surface. The tibial torsion was calculated as the angle between the PTA and the DTA.
Tibial tubercle-trochlear groove (TT-TG) distance	From enrollment to the end of measurements at 3 weeks	Firstly, transverse image that depicted a complete cartilaginous trochlea was used to determine the deepest point within the trochlear groove. A line was drawn through the deepest point of the trochlear groove, perpendicular to the posterior condylar tangent. Another line was drawn in parallel to the trochlear line through the most anterior portion of the tibial tubercle. Tibial tuberosity-trochlear groove distance was measured as the distance between these 2 lines.
Tibial tubercle-posterior cruciate ligament (TT-PCL)	From enrollment to the end of measurements at 3 weeks	The TT-PCL distance was measured on axial images between the patellar tendon insertion midpoint and the medial border of the posterior cruciate ligament at its tibial insertion, parallel to the dorsal tibia condylar line.
Joint line convergence angle (JLCA)	From enrollment to the end of measurements at 3 weeks	The mechanical axis line of femur was drawn, and then the knee joint line in the frontal plane was determined. The angle between these two lines was measured.
Hip-knee-ankle angle (HKA)	From enrollment to the end of measurements at 3 weeks	The measurement was taken of the angle formed between the mechanical axis of the femur and tibia.
Mechanical lateral distal femoral angle (mLDFA)	From enrollment to the end of measurements at 3 weeks	The distal joint orientation line of femur was drawn. A second line was drawn from the center of hip to the knee\'s midpoint at the femoral knee joint line (femoral mechanical axis). The angle between these two lines was measured.
Quadriceps femoris angle (Q angle)	From enrollment to the end of measurements at 3 weeks	The angle between the lines connecting the anterior superior iliac spine (ASIS) to the midpoint of the patella, and from there to the tibial tubercle was measured.

Secondary Outcome Measures

Name	Time	Method
Isokinetic strength	From enrollment to the end of measurements at 3 weeks	The strength of the concentric knee extensor-flexor and concentric hip abductor-adductor muscles was measured using an isokinetic dynamometer at two different angular velocities: 60˚/sec and 180˚/sec.

Trial Locations

Locations (1)

Akdeniz University Faculty of Sport Sciences; 🇹🇷 Antalya, Turkey