Terminology of Reactive Training

Advanced Terminology in Reactive Training: Biomechanical Classifications and Performance Applications

Introduction

Reactive training, also known as plyometric training, represents a critical component in the development of power, speed, and athletic performance. The precise terminology used to describe these movements is essential for accurate programming, assessment, and communication among strength and conditioning professionals. This comprehensive guide expands upon the fundamental classifications of reactive movements to include their biomechanical underpinnings, neuromuscular demands, and practical applications in training prescription.

Reactive Training Movement Classifications

The following terminology provides a systematic framework for categorizing and understanding reactive training movements based on their takeoff and landing patterns, directional components, and execution characteristics:

Movement Type Biomechanical Description Key Performance Characteristics Primary Energy System Rate of Force Development
Linear Jump Bilateral takeoff and landing in sagittal plane • Symmetrical force distribution

• Vertical ground reaction forces predominate

• High triple extension coordination

 ATP-PC Very High
Lateral Jump Bilateral takeoff and landing in frontal plane • Medial-lateral stabilization demands<br>• Adductor/abductor engagement<br>• Frontal plane stability challenge ATP-PC High
Horizontal Jump Bilateral takeoff and landing with anterior displacement • Forward momentum generation<br>• Hip extensor emphasis<br>• Center of mass forward translation ATP-PC High
Linear Hop Unilateral takeoff and landing (same leg) in sagittal plane • Single-leg force absorption<br>• Asymmetrical loading pattern<br>• Increased joint stabilization demands ATP-PC Very High
Medial Hop Unilateral takeoff and landing with medial displacement • Frontal plane stabilization<br>• Pronation control<br>• Adductor complex loading ATP-PC Moderate-High
Lateral Hop Unilateral takeoff and landing with lateral displacement • Frontal plane stabilization<br>• Supination control<br>• Abductor complex loading ATP-PC Moderate-High
Linear Bound Alternating unilateral takeoff and landing in sagittal plane • Asymmetrical force production<br>• Contralateral coordination<br>• Increased horizontal propulsion ATP-PC Very High
Lateral Bound Alternating unilateral takeoff and landing in frontal plane • Complex frontal plane coordination<br>• High rotational stability demands<br>• Multi-planar control ATP-PC Very High

Advanced Movement Execution Variations

The following terms describe specific execution parameters that can be applied to modify the neuromuscular demands of the above movement classifications:

Execution Parameter Neuromuscular Demand Time Under Tension Stabilization Requirement
Skip • Rhythmic bilateral coordination<br>• Intermediate force production<br>• Enhanced elastic component utilization Moderate Moderate
Stick • Eccentric deceleration emphasis<br>• High stabilization demand<br>• Proprioceptive acuity challenge Extended Very High
Bounce • Short coupling time<br>• Stretch-shortening cycle optimization<br>• Elastic energy utilization Minimal Low-Moderate
Continuous • Series elastic component emphasis<br>• Reactive strength development<br>• Minimal amortization phase Minimal Moderate
Transverse Plane • Rotational force management<br>• Multi-planar coordination<br>• Increased proprioceptive challenge Variable Very High

Neurophysiological Basis of Reactive Training Movements

Understanding the underlying neurophysiological mechanisms that govern reactive training is essential for optimal programming and coaching. The following table outlines key physiological components involved in different reactive movement patterns:

Movement Classification Primary Muscle Groups Neural Adaptation Recovery Requirement Training Transfer
Bilateral Movements • Quadriceps<br>• Gluteus Maximus<br>• Gastrocnemius/Soleus • Motor unit synchronization<br>• Cross-education effect Moderate Team sports, Olympic lifting
Unilateral Movements • Single-leg stabilizers<br>• Gluteus Medius<br>• Intrinsic foot muscles • Improved intramuscular coordination<br>• Enhanced proprioception High Running sports, change of direction
Sagittal Plane Dominant • Hip extensors<br>• Knee extensors<br>• Ankle plantarflexors • Vertical force production<br>• Linear acceleration Moderate Sprinting, jumping
Frontal Plane Dominant • Hip abductors/adductors<br>• Lateral stabilizers<br>• Ankle invertors/evertors • Lateral force management<br>• Frontal plane stability High Court sports, multidirectional agility
Transverse Plane Dominant • Core rotators<br>• Hip rotators<br>• Oblique systems • Rotational force coupling<br>• Three-dimensional stabilization Very High Rotational sports (golf, tennis)

Progressive Programming Framework

Research by Verkhoshansky, Zatsiorsky, and contemporary scholars indicates the importance of systematic progression in reactive training. The following table presents a science-based progression model:

Training Phase Volume (Foot Contacts) Intensity Rest Intervals Primary Focus
Introductory 80-100 Low 1:5 work-to-rest ratio Technique development, landing mechanics
Developmental 100-120 Moderate 1:4 work-to-rest ratio Progressive loading, movement pattern expansion
Specialized 120-140 High 1:3 work-to-rest ratio Sport-specific adaptations, power development
Performance 100-120 Very High 1:5 work-to-rest ratio Peak power expression, competitive preparation

Practical Coaching Applications

Implementing precise reactive training terminology facilitates more effective coaching interventions:

  1. Assessment and Movement Screening
    • Utilize standardized reactive movement assessments to identify specific movement pattern deficiencies
    • Quantify reactive strength index (RSI) through specific jump tests
    • Screen for asymmetries using unilateral variations
  2. Technique Coaching
    • Focus on optimal foot positioning during takeoff and landing
    • Emphasize neutral spine alignment throughout movement execution
    • Maintain appropriate center of mass positioning relative to base of support
  3. Programming Considerations
    • Progressive integration from bilateral to unilateral movements
    • Systematic advancement from sagittal to frontal to transverse plane movements
    • Strategic manipulation of ground contact time (continuous vs. stick variations)
  4. Performance Monitoring
    • Track reactive strength index modifications across training phases
    • Monitor ground contact times during continuous variations
    • Assess force-velocity profiles through performance testing

References

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