Static vs dynamic compliance

Lung Compliance - The Stretch Factor

• Measure of lung and chest wall stretchability. Inverse of elastance (stiffness).
• Calculated as change in volume per unit change in pressure: $C = \Delta V / \Delta P$.

• Static Compliance
  • Measured during periods of no airflow (inspiratory pause).
  • Reflects pure elastic recoil of lung tissue.
• Dynamic Compliance
  • Measured during active breathing.
  • Reflects both elastic recoil and airway resistance.
  • Always ≤ static compliance.

⭐ In obstructive diseases like COPD/emphysema, compliance is pathologically high (loss of elastic recoil), making exhalation difficult. In restrictive diseases like fibrosis, compliance is low (stiff lungs).

Static Compliance - A Pause for Pressure

• Measures the pure elastic properties of the lung and chest wall without airflow resistance.
• Measurement requires a brief inspiratory pause (~0.5 sec) on a mechanical ventilator.
  • This pause allows alveolar pressure to equilibrate, revealing the plateau pressure ($P_{plat}$).
• Represents the "true" compliance of the respiratory system.
• Calculated as: $C_{stat} = \frac{\text{Tidal Volume}}{(P_{plat} - \text{PEEP})}$

⭐ In ARDS, a key lung-protective strategy is to keep plateau pressure < 30 cm H₂O to reduce the risk of barotrauma.

• ↓ Decreased in: Fibrosis, ARDS, pneumonia, pulmonary edema.
• ↑ Increased in: Emphysema, normal aging.

Dynamic Compliance - Going With the Flow

• Dynamic compliance ($C_{dyn}$) is the lung's compliance measured during active airflow, reflecting the total opposition to lung inflation.
• It is always lower than or equal to static compliance because it accounts for both elastic recoil (static compliance) and airway resistance.
• Calculated as: $C_{dyn} = \frac{ΔV}{PIP - PEEP}$
  • $PIP$: Peak Inspiratory Pressure
  • $PEEP$: Positive End-Expiratory Pressure
• A ↓ in $C_{dyn}$ with normal static compliance suggests ↑ airway resistance.
  • Common causes: Asthma, COPD, bronchospasm, foreign body.

⭐ In obstructive diseases, the gap between static and dynamic compliance widens as respiratory rate increases. This reflects frequency dependence due to incomplete alveolar filling and emptying (gas trapping).

Compliance Showdown - The Diagnostic Duel

• Static Compliance ($C_{st}$): True compliance of the lung and chest wall. Measured under no-flow conditions (inspiratory hold).
  • Formula: $C_{st} = \Delta V / (P_{plat} - PEEP)$
  • Reflects intrinsic elastic properties (parenchyma, chest wall).
• Dynamic Compliance ($C_{dyn}$): Overall compliance measured during active airflow.
  • Formula: $C_{dyn} = \Delta V / (PIP - PEEP)$
  • Reflects elastic properties AND airway resistance.

⭐ The gradient between Peak Inspiratory Pressure (PIP) and Plateau Pressure ($P_{plat}$) is a direct indicator of airway resistance. A large PIP-$P_{plat}$ gap points to issues like bronchospasm or obstruction.

High‑Yield Points - ⚡ Biggest Takeaways

• Static compliance reflects the lung's intrinsic elastic recoil at no airflow (measured with plateau pressure).
• Dynamic compliance is measured during active breathing and includes both elastic recoil and airway resistance (measured with peak pressure).
• Dynamic compliance is always less than or equal to static compliance.
• ↑ Airway resistance (e.g., asthma, COPD) causes a marked ↓ in dynamic compliance.
• The difference between peak and plateau pressures estimates airway resistance.
• Fibrosis ↓ both compliances; emphysema ↑ both.