Uncover the complexity of hamstring injuries

Hamstring injuries are a persistent challenge in football, with high recurrence rates and rising annual injury trends. These injuries not only impact player performance but also lead to significant financial strain for teams.

Recovery requires more than strengthening exercises, it demands deeper insights into coordination, stability, and postural control to address the root causes and optimize outcomes.

A holistic approach to hamstring rehabilitation

ORYX motion capture systems go beyond traditional rehabilitation by addressing the complexity of hamstring injuries. Instead of focusing solely on strength and flexibility, ORYX provides insights into:

  • Postural Control: Understand how the hamstrings interact with the pelvis and surrounding structures.
  • Interlimb coordination: Identify inefficiencies in movement patterns that contribute to recurring injuries.
  • Data-Driven Interventions: Tailor rehabilitation strategies based on real-world movement analysis to rebuild stability and optimize recovery.


Our multifactorial approach helps you address inefficiencies at their core, ensuring athletes return stronger, more resilient, and ready to perform.

Key metrics analyzed: Actionable data for hamstring recovery

ORYX motion capture systems provide precise, dynamic insights into movement patterns under real-world conditions. By focusing on key metrics, we help you address the underlying factors that influence hamstring recovery and performance.

Coordination patterns

Understand how the hamstrings work with surrounding muscles, such as the glutes and quadriceps, to create efficient, stable movement. Identify compensatory strategies and imbalances that may hinder recovery or increase the risk of reinjury.

Pelvis control

Assess pelvic stability during dynamic activities to evaluate its impact on hamstring function and overall movement efficiency. Poor pelvic control often leads to excessive strain on the hamstrings, making it a critical factor in injury prevention and rehabilitation.

Load Symmetry (Exclusive to ORYX GO)

Measure asymmetries in load distribution between limbs to uncover imbalances that traditional methods might miss. Load symmetry analysis helps guide tailored interventions to restore balance and reduce strain during athletic activities.

Track overload and control under stress

Assess how the hamstrings, hip flexors and pelvis interact and perform under dynamic conditions, helping detect compensatory patterns, early signs of overload, and inefficiencies before they lead to reinjury.

Deliver targeted, actionable insights

Get clear, data-driven feedback on coordination, stability, and asymmetries to design tailored rehabilitation strategies that improve patient outcomes.

Assess Return-to-Play Readiness

Monitor progress objectively to ensure patients are not only recovering but are ready to safely resume high-performance activities with reduced reinjury risk.

Choose the right system for your needs:

ORYX Hamstring Control

Assess how the hamstrings, hip flexors and pelvis interact and perform under dynamic conditions, helping detect compensatory patterns, early signs of overload, and inefficiencies before they lead to reinjury.

ORYX Gait Observation

Assess how the hamstrings, hip flexors and pelvis interact and perform under dynamic conditions, helping detect compensatory patterns, early signs of overload, and inefficiencies before they lead to reinjury.

Both systems provide actionable data to support better decision-making and help you guide athletes toward faster recovery and improved performance.

Ecological validity ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Overground (indoor & outdoor)
Treadmill
Hardware ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Motion Data Hub
4G Tablet
Shoe clips

2 Qty

IMU sensors

4 Qty

4 Qty

8 Qty

Base Straps

4 Qty

4 Qty

5 Qty

Over Straps

4 Qty

4 Qty

4 Qty

Setup fee

€4.499

€5.499

€7.499

Walking / Running gait analysis ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Stride duration
Cadence / stride frequency
Ground contact time
Duty factor*
Propulsive velocity (hamstring function)*

* Running analysis only

ROM (+ symmetry) ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Pelvis
Hip
Knee
Ankle
Foot
Micro (Local attractors) ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Core stability
Hip lock
Knee stability (Q/H coordination)
Ankle stiffness
Coordination Landscape (varibility)
Meso (Global attractors) ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Hamstrings
Joint coupling (Hip – Knee)
Scissors
Macro (Total attractors) ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
Pendulum
Foot plant projection
Squat (Double & single leg) ORYX Knee Stability - Static ORYX Knee Stability - Dynamic ORYX-GO
ROM joints + LSI
Variability