The Nervous System and Range of Motion

While the previous lesson covered the physical tissues that influence range of motion, the nervous system is often the most important and rapidly modifiable factor. Your brain and spinal cord ultimately decide how much range of motion they will permit, regardless of what your tissues are physically capable of. Understanding this neural regulation is key to making faster, safer, and more sustainable mobility gains.

The Stretch Reflex

How It Works

The stretch reflex (myotatic reflex) is a protective mechanism that resists sudden changes in muscle length:

1. Muscle spindles within the muscle detect changes in length and rate of length change
2. When a rapid stretch is detected, spindles send signals via sensory neurons to the spinal cord
3. The spinal cord immediately activates motor neurons to contract the stretched muscle
4. This reflexive contraction opposes the stretch, protecting the muscle from potential damage

This entire loop occurs in milliseconds without conscious thought. It is the reason you cannot simply force yourself into new ranges of motion quickly.

Implications for Stretching

The stretch reflex has direct implications for how you should approach flexibility work:

• Slow entry into stretches: Moving slowly into stretched positions minimizes stretch reflex activation
• Relaxation techniques: Conscious breathing and relaxation can reduce reflex activity
• Sustained holds: The stretch reflex diminishes with sustained holds (stress relaxation), allowing greater range over time
• Ballistic stretching risks: Rapid, bouncing stretches strongly activate the stretch reflex, increasing muscle tension rather than reducing it

The Golgi Tendon Organ

Function and Location

Golgi tendon organs (GTOs) are sensory receptors located at the muscle-tendon junction. Unlike muscle spindles, GTOs detect changes in tension rather than length.

When tension becomes excessive, GTOs trigger an inhibitory response:

1. GTOs detect high tension at the muscle-tendon junction
2. They send inhibitory signals to the spinal cord
3. Motor neurons to the agonist muscle are inhibited, reducing contraction
4. This protective mechanism prevents the tendon from being overloaded

Leveraging GTOs for Flexibility

The GTO response can be harnessed for mobility gains through specific techniques:

• PNF stretching (contract-relax): Contracting a muscle at its stretched position activates GTOs, which then inhibit the muscle, allowing a deeper stretch when relaxed
• Isometric stretching: Sustained isometric contractions in stretched positions trigger GTO-mediated relaxation
• Post-contraction relaxation: After a strong contraction, the subsequent period of reduced muscle tone allows greater range

This is why PNF and isometric stretching methods often produce faster flexibility gains than passive stretching alone.

Reciprocal Inhibition

The Principle

When an agonist muscle contracts, the nervous system simultaneously inhibits its antagonist. This is called reciprocal inhibition and is coordinated at the spinal cord level.

For example:

• When you contract your quadriceps, your hamstrings are neurally inhibited
• When you contract your hip flexors, your hip extensors receive inhibitory signals
• When you contract your biceps, your triceps are inhibited

Application to Mobility Training

Reciprocal inhibition is a powerful tool for improving active range of motion:

• Active flexibility drills: Contracting the muscles opposite to those being stretched promotes relaxation of the target muscles
• Active leg raises: Contracting the hip flexors facilitates hamstring relaxation
• Active shoulder flexion: Contracting the shoulder flexors facilitates lat and posterior shoulder relaxation

This principle is why active mobility drills can immediately improve range of motion: the nervous system reduces tension in the target muscles through reciprocal inhibition.

Stretch Tolerance

What Is Stretch Tolerance?

Stretch tolerance is your nervous system's willingness to allow a given range of motion. It is the primary determinant of day-to-day flexibility and the first factor to change when you begin stretching consistently.

Research has shown that the majority of flexibility gains in the first few weeks of stretching are due to increased stretch tolerance rather than structural tissue changes. The tissues themselves may not lengthen significantly, but the nervous system learns to permit greater range without triggering protective reflexes.

Factors Affecting Stretch Tolerance

Several factors influence how much range your nervous system permits:

• Perceived threat: If the nervous system perceives a stretch as dangerous, it will restrict range. This is why stretching in a relaxed, comfortable environment produces better results than stretching while stressed or anxious
• Previous injury: A history of injury at a joint or muscle increases neural guarding and reduces stretch tolerance
• Temperature: Warm tissues feel less threatening to the nervous system, which is why warming up before stretching improves range
• Fatigue: Physical and mental fatigue can either increase or decrease stretch tolerance depending on the individual
• Consistency: Regular exposure to stretched positions gradually teaches the nervous system that the range is safe

Training Stretch Tolerance

To improve stretch tolerance:

• Practice consistently: Daily short sessions are more effective than infrequent long sessions
• Breathe deeply: Diaphragmatic breathing activates the parasympathetic nervous system, reducing protective muscle tension
• Progress gradually: Small, incremental increases in range build nervous system confidence
• Use relaxation techniques: Progressive muscle relaxation and visualization can reduce neural guarding
• Stay in the stretch: Time under stretch (30-120 seconds) is more important than intensity

The Role of the Brain

Cortical Regulation

The brain plays a central role in mobility through:

• Motor planning: The brain decides which movements to permit based on stored movement patterns
• Pain processing: The brain interprets stretch sensations and determines whether they are threatening
• Emotional regulation: Anxiety, stress, and fear increase muscle tension and reduce range
• Movement memory: The brain stores patterns of what ranges are "normal" and resists deviations

The Threat-Response Model

A useful framework for understanding neural regulation of mobility is the threat-response model:

• When the nervous system perceives a position as safe and familiar, it permits full range with minimal resistance
• When a position is perceived as unfamiliar but non-threatening, moderate resistance is generated, and range can be improved with practice
• When a position is perceived as threatening or dangerous, strong protective responses are triggered, severely limiting range

This model explains why:

• People are more flexible in warm environments
• Relaxation techniques improve range immediately
• Injury and pain create lasting range restrictions
• Consistent practice (building familiarity) gradually increases range

Autonomic Nervous System and Mobility

Sympathetic vs. Parasympathetic

The autonomic nervous system has a profound effect on muscle tone and mobility:

• Sympathetic dominance (fight-or-flight): Increases muscle tension, heightens reflexes, and reduces range of motion. This is the body preparing for action, not relaxation
• Parasympathetic dominance (rest-and-digest): Reduces muscle tension, dampens reflexes, and improves range of motion. This is the optimal state for stretching

Practical Implications

To optimize the neural environment for mobility work:

• Timing: Schedule mobility work during low-stress periods when possible
• Breathing: Box breathing (4 seconds in, 4 seconds hold, 4 seconds out, 4 seconds hold) or extended exhale breathing shifts toward parasympathetic dominance
• Environment: A calm, comfortable environment reduces sympathetic activation
• Music: Slow, relaxing music can shift autonomic balance toward parasympathetic
• Mindfulness: Present-moment awareness reduces anticipatory tension

Neural Adaptations to Mobility Training

Short-Term Adaptations (Minutes to Hours)

• Post-stretch tolerance: Immediately after stretching, tolerance is increased for approximately 30-60 minutes
• Reciprocal inhibition effects: Fade within minutes after stopping agonist contraction
• Temperature-related gains: Lost as tissues cool

Medium-Term Adaptations (Days to Weeks)

• Increased baseline stretch tolerance: The nervous system recalibrates what it considers normal range
• Improved motor control: Better coordination at end ranges
• Reduced reflexive guarding: Decreased stretch reflex sensitivity at familiar ranges

Long-Term Adaptations (Weeks to Months)

• Permanent stretch tolerance changes: New range becomes the default setting
• Improved proprioception: Enhanced body awareness at end ranges
• Movement pattern integration: New ranges become incorporated into movement skills

Conclusion

The nervous system is both the primary limiter and the most rapidly modifiable factor in your range of motion. By understanding stretch reflexes, GTO responses, reciprocal inhibition, and stretch tolerance, you can choose techniques that work with your nervous system rather than against it. The most effective mobility training combines tissue preparation with neural strategies: relaxation techniques, consistent exposure, gradual progression, and building familiarity with new ranges. In the next module, we will use this knowledge to perform a comprehensive mobility assessment.