Medicine

Respiratory Acidosis

Respiratory acidosis is a condition characterized by decreased alveolar ventilation leading to carbon dioxide retention (hypercapnia) and a resultant drop in blood pH.

Epidemiology and Risk Factors

Anatomy and Physiology of CO₂ Homeostasis

To understand respiratory acidosis, you need to understand the entire chain of ventilation:

Etiology (with Focus on Hong Kong)

The aetiologies map directly onto the ventilatory chain described above. Think systematically: where in the chain has something gone wrong?

Classification by Anatomical Level

Pathophysiology

Classification

Clinical Features

Differential Diagnosis of Respiratory Acidosis

Systematic Differential Diagnosis

Below is the full differential, organised by the anatomical level of failure along the ventilatory chain. This mirrors the Type 2 respiratory failure aetiology framework directly from the GC lecture and senior notes [1][6]:

References

[1] Lecture slides: GC 023. A cyanotic, dyspneic elderly man_respiratory failure.pdf (Slide on ABG interpretation) [3] Senior notes: Block A - Electrolyte and Acid-Base Disorders.pdf (pp. 3–4) [6] Senior notes: Ryan Ho Fundamentals.pdf / Ryan Ho Respiratory.pdf (Section 2.5 / 3.2.5 Respiratory Failure, pp. 29–30 / 230) [7] Senior notes: Maksim Medicine Notes.pdf (Respiratory medicine, pp. 280, 302) [8] Lecture slides: GC_Interactive tutorial (Resp-COPD case) student copy.pdf (p. 1) [9] Senior notes: Ryan Ho Chemical Path.pdf (Section E. Salicylate, p. 42) [10] Lecture slides: GC 204. The newborn baby cannot breathe Oesophageal atresia, diaphragmatic hernia, and other surgery of lung.pdf (p. 10) [11] Senior notes: Adrian Lui Pediatrics Notes.pdf (pp. 299, 463)

Diagnostic Criteria for Respiratory Acidosis

Diagnostic Algorithm

Investigation Modalities with Key Findings and Interpretations

Treatment Modalities — Detailed

2. Non-Invasive Ventilation (NIV) / BiPAP

NIV is the single most important intervention for respiratory acidosis in COPD. "BiPAP" = bi-level positive airway pressure: "bi" = two, meaning two different pressures for inspiration and expiration.

  • IPAP (Inspiratory Positive Airway Pressure): augments tidal volume during inspiration → ↓work of breathing → ↑alveolar ventilation → reduces CO₂ [7]
  • EPAP (Expiratory Positive Airway Pressure): maintains airway patency during expiration → prevents upper airway obstruction, counteracts intrinsic PEEP in COPD [7]

4. Treatment of the Underlying Cause (Cause-Specific)

This is the most important long-term management step. All ventilatory support is buying time for this.

Complications of Respiratory Acidosis

The complications of respiratory acidosis arise from two interrelated pathological processes: (1) the direct effects of hypercapnia (↑CO₂) and acidaemia (↓pH) on organ systems, and (2) the consequences of the underlying disease process itself. Additionally, (3) complications of treatment (iatrogenic) must be considered, as they are commonly examined.

Think of it this way: CO₂ is both a vasodilator and a CNS depressant. Acidaemia impairs enzyme function, disrupts electrolyte balance, and depresses myocardial contractility. Every organ system is affected once pH falls below ~7.2.


6. Iatrogenic Complications (Complications of Treatment)

These are extremely high-yield for exams because they test understanding of pathophysiology:

References

[2] Senior notes: Ryan Ho Urogenital.pdf (Section 2.4 Disorders of Acid-base Balance, pp. 34, 39) [3] Senior notes: Block A - Electrolyte and Acid-Base Disorders.pdf (pp. 2–3, 7, 9) [6] Senior notes: Ryan Ho Fundamentals.pdf / Ryan Ho Respiratory.pdf (Section 2.5 / 3.2.5 Respiratory Failure, pp. 29–30 / 230) [7] Senior notes: Maksim Medicine Notes.pdf (Respiratory medicine, pp. 284–286, 300–302) [18] Senior notes: Ryan Ho Respiratory.pdf (Footnote 84 on hypoxic drive, p. 116) [22] Senior notes: Block A - Introduction to Renal Investigations (RFT, urine tests and US kidneys).pdf (p. 6 — K+ lethal consequences) [23] Senior notes: Ryan Ho Urogenital.pdf (Section on CKD metabolic acidosis consequences, p. 106) [24] Lecture slides: GC 041. Cough in a chronic smoker_COPD; smoking cessation.pdf (p. 25 — COPD complications management) [25] Senior notes: MBBS Final MB (Medicine) (Felix PY Lai).pdf (Asthma complications — pneumothorax, infections, T2RF, p. 213) [26] Lecture slides: Handbook of Internal Medicine 2024.pdf (p. 302 — NaHCO₃ risks and paradoxical acidosis warning)

High Yield Summary

Definition: Respiratory acidosis = primary ↑pCO₂ (> 45 mmHg / > 6 kPa) due to alveolar hypoventilation, resulting in ↓pH.

Most common cause in HK: COPD acute exacerbation.

Core pathophysiology: Any failure along the ventilatory chain (CNS drive → spinal cord → NMJ → respiratory muscles → chest wall → airways → alveoli) → ↓alveolar ventilation → CO₂ retention.

Compensation: Kidneys retain HCO₃⁻ — acute: +1 mEq/L per 10 mmHg rise in pCO₂; chronic: +3.5 mEq/L per 10 mmHg.

Key clinical features of hypercapnia: headache, flushing, flapping tremor, papilloedema, drowsiness → CO₂ narcosis/coma.

Danger sign in acute asthma: "normalising" pCO₂ = impending respiratory arrest.

O₂ therapy in COPD: Target SpO₂ 88–92% to avoid abolishing hypoxic drive.

Type 2 RF causes (mnemonic: D-N-T-G = Drive, Nerves/NMJ, Thoracic cage, Global lung hypoventilation): sedative OD / CNS depression / hypothyroidism; GBS / MG / spinal cord; kyphoscoliosis / flail chest / OHS; COPD / severe asthma / upper airway obstruction.

High Yield Summary — Diagnosis of Respiratory Acidosis

  1. ABG is the only way to diagnose respiratory acidosis — pH < 7.35 with pCO₂ > 6 kPa (45 mmHg).
  2. 3-step GC lecture approach: pH → pCO₂ → HCO₃⁻ (metabolic status / compensation / chronicity).
  3. 1-2-3-4 rule: Acute resp acidosis +1; acute resp alkalosis −2; chronic resp acidosis +3; chronic resp alkalosis −4 (mmol/L HCO₃⁻ change per 10 mmHg pCO₂ change).
  4. A-a gradient distinguishes extrapulmonary (normal) from intrapulmonary (widened) causes.
  5. Mixed disorders are identified when measured HCO₃⁻ deviates from expected compensation.
  6. CXR + spirometry are essential ancillary tests for intrapulmonary causes (COPD, asthma).
  7. Repeat ABG at 30–60 min after starting O₂ or NIV to assess response.

High Yield Summary — Management of Respiratory Acidosis

  1. ABC first — airway, breathing, circulation. Intubate if GCS < 8 or arrest.
  2. Controlled O₂: target SpO₂ 88–92% in COPD; start with 1–2 L/min nasal cannula or 24% Venturi mask.
  3. NIV (BiPAP) is the key intervention for moderate respiratory acidosis (pH 7.25–7.35): IPAP 8–20 cmH₂O, EPAP 4–5 cmH₂O. Check ABG at 30–60 min.
  4. Intubation + IPPV if NIV fails, GCS < 8, haemodynamically unstable, or arrest.
  5. Treat the underlying cause: COPD → bronchodilators + steroids + Abx (if indicated); opioid OD → naloxone; GBS → IVIg/plasmapheresis.
  6. Do NOT give bicarbonate for respiratory acidosis — the treatment is ventilation.
  7. Do NOT rapidly normalise pCO₂ in chronic retainers — risk of post-hypercapnic metabolic alkalosis.
  8. Antibiotics for AECOPD: only if ≥2 cardinal symptoms including ↑purulence, or requiring mechanical ventilation. Choice: Augmentin.
  9. Long-term: LTOT ≥ 15 h/day if criteria met; domiciliary NIV; smoking cessation; pulmonary rehab.

High Yield Summary — Complications of Respiratory Acidosis

Acute complications (directly from hypercapnia + acidaemia):

  • CNS: CO₂ narcosis, cerebral oedema, headache, confusion → coma
  • CVS: arrhythmias, ↓contractility, ↓catecholamine response, hypotension
  • Electrolyte: hyperkalaemia (H⁺/K⁺ shift)
  • Respiratory arrest if not treated

Chronic complications (from long-standing respiratory acidosis, typically COPD):

  • Cor pulmonale (the "3Ps": peripheral oedema, P pulmonale, polycythaemia)
  • Secondary polycythaemia → ↑thromboembolism risk
  • Bone loss / osteoporosis
  • Muscle wasting

Iatrogenic complications (from treatment — very exam-relevant):

  • Post-hypercapnic metabolic alkalosis (rapid correction of chronic CO₂)
  • O₂-induced hypercapnia (excessive O₂ in COPD)
  • NIV complications: skin necrosis, gastric distension/aspiration, hypotension
  • Ventilator complications: VAP, barotrauma, VIDD

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