Elastic Volume-Pressure Relationship of Lung and Chest Wall in Children
I. The Concept of Elastic Recoil
The respiratory system's mechanical properties are determined by the interaction between two opposing elastic forces:
- Lungs: Have a natural tendency to collapse (inward elastic recoil) due to surface tension and elastic fibers.
- Chest Wall: Has a natural tendency to expand (outward recoil) at low lung volumes.
II. The Volume-Pressure Diagram
The relationship is best understood by plotting Lung Volume (Y-axis) against Transmural Pressure (X-axis).
Explanation of the Curves:
- Lung Curve: Always requires positive distending pressure. As pressure increases, volume increases (slope = Compliance).
- Chest Wall Curve:
- At low volumes (residual volume), it generates negative pressure (tends to expand).
- At high volumes (~70% TLC), it generates positive pressure (resists expansion).
- Combined (Total Respiratory System) Curve: The algebraic sum of the lung and chest wall pressures.
- FRC (Functional Residual Capacity): The point where the inward recoil of the lung exactly balances the outward recoil of the chest wall. Airway pressure is zero (atmospheric).
III. Pediatric Specifics: The "Floppy" Chest Wall
In infants and young children, this relationship differs significantly from adults.
1. High Chest Wall Compliance
- The pediatric chest wall is highly compliant ("floppy") due to cartilaginous ribs and weak musculature.
- Result: The outward elastic recoil (spring-out force) of the chest wall is very weak.
2. Impact on FRC (The Critical Difference)
- Because the outward pull of the chest wall is weak, it cannot effectively counterbalance the inward pull of the lungs.
- Static FRC is Lower: The equilibrium point (relaxation volume) settles at a much lower lung volume (~10β15% of TLC) compared to adults (~40% of TLC).
- Closing Capacity > FRC: The relaxation volume in infants is often below the Closing Capacity (the volume at which small airways collapse).
3. Maintenance of "Dynamic FRC"
To prevent alveolar collapse (atelectasis) due to this low static FRC, infants maintain a Dynamic FRC higher than their static equilibrium via:
- Rapid Respiratory Rate: Inspiration begins before expiration is complete.
- Laryngeal Braking: Partial closure of the glottis during expiration (grunting) to generate intrinsic PEEP.
- High Diaphragm Tone: Post-inspiratory diaphragmatic activity.
IV. Clinical Implications
- Risk of Atelectasis: Due to low FRC and unstable alveoli, children are prone to rapid desaturation and lung collapse during apnea or anesthesia (loss of muscle tone).
- Requirement for PEEP: In mechanical ventilation, Positive End-Expiratory Pressure (PEEP) is mandatory to artificially replace the "missing" chest wall recoil and maintain FRC above closing capacity.