Post Hypercapnia Respiratory Alkalosis (PHRA)

Post-hypercapnia respiratory alkalosis is an important ICU acid-base phenomenon that occurs when chronic hypercapnia is corrected rapidly, leading to alkalemia due to persistently low serum bicarbonate despite normalization of PaCO₂. It is especially relevant in COPD exacerbations, neuromuscular respiratory failure, obesity hypoventilation syndrome, and prolonged mechanical ventilation weaning.


🔷 Definition

Post-hypercapnia respiratory alkalosis (PHRA) refers to:

Development of metabolic alkalosis and alkalemia after rapid correction of chronic respiratory acidosis (hypercapnia).


🔷 Pathophysiology (Stepwise Mechanism)

 Step 1 – Chronic Hypercapnia State

Occurs in diseases causing long-standing hypoventilation:

  • Severe COPD
  • Obesity hypoventilation syndrome
  • Neuromuscular weakness
  • Chronic chest wall disorders

Compensation Mechanism

Kidneys attempt to normalize pH by:

Increasing bicarbonate reabsorption
Increasing hydrogen ion excretion
Generating new bicarbonate

👉 Result:

  • High PaCO₂
  • High serum HCO₃⁻
  • Near-normal pH

This compensation takes 3–5 days to reach maximal effect.


Step 2 – Rapid Correction of Hypercapnia

Occurs when:

  • Mechanical ventilation initiated
  • NIV started aggressively
  • Airway obstruction relieved
  • Sedation/paralysis reversed

What Happens?

PaCO₂ falls rapidly CO₂ is eliminated quickly.

However:

  • Renal compensation persists
  • Kidneys cannot excrete bicarbonate immediately
  • Excess bicarbonate remains


 Step 3 – Development of Metabolic Alkalosis

Now the patient has:

  • Normal/low PaCO₂
  • Persistently elevated bicarbonate
  • Result alkalemia


🔷 Acid-Base Pattern

Typical ABG Evolution

Before Correction (Chronic Hypercapnia)

Parameter

Value

pH

Near normal or slightly low

PaCO

High

HCO₃⁻

High


After Rapid Ventilation Correction

Parameter

Value

pH

High (alkalemia)

PaCO

Normal or low

HCO₃⁻

Still high

👉 This is PHRA

🔷 Why Kidneys Cannot Correct Quickly?

Renal bicarbonate excretion requires:

  • Reduced proximal reabsorption
  • Increased distal secretion
  • Volume and chloride availability

These changes take several days.


🔷 Clinical Importance in ICU

1️⃣ Respiratory Drive Suppression

Alkalemia decreases respiratory drive ventilator weaning difficulty.


2️⃣ Neurological Effects

  • Confusion
  • Seizures (rare)
  • Reduced cerebral blood flow


3️⃣ Cardiovascular Effects

  • Arrhythmias
  • Reduced coronary perfusion


4️⃣ Electrolyte Disturbances

Often associated with:

  • Hypokalemia
  • Hypocalcemia
  • Hypophosphatemia


5️⃣ Oxygen-Hemoglobin Dissociation

Alkalosis shifts curve leftward impaired oxygen delivery.


Recommended Approach

  • Allow permissive hypercapnia
  • Gradual PaCO₂ normalization

Target:

  • Maintain near baseline PaCO₂ initially
  • Avoid sudden normalization


2️⃣ Correct Volume and Chloride Deficiency

Metabolic alkalosis often chloride-responsive.

Treatment:
Isotonic saline
Potassium chloride


3️⃣ Correct Electrolytes

Particularly:

  • Potassium
  • Magnesium
  • Phosphate


4️⃣ Consider Acetazolamide

Mechanism:

  • Carbonic anhydrase inhibitor
  • Promotes bicarbonate excretion

Used in:

  • Difficult ventilator weaning
  • Persistent metabolic alkalosis


5️⃣ Avoid Excess Diuretics

They worsen:

  • Chloride depletion
  • Volume contraction
  • Alkalosis severity