Smoke Inhalation Injury

Smoke inhalation injury is a three-component insult — supraglottic thermal injury, tracheobronchial chemical injury, and systemic toxicity (carbon monoxide and cyanide) — and is an independent predictor of mortality in fire victims, capable of doubling mortality when combined with cutaneous burns. [1] Approximately 15% of burn patients have concomitant inhalation injury, and 20–30% of severe burns are associated with it. [2-3]

The following algorithm from Sheridan's NEJM review outlines the early management decision framework:

1. History

• Exposure context: Enclosed vs. open space, duration of exposure, type of materials burning (plastics, synthetics, wood — nitrogen-containing products release cyanide) [5-6]
• Symptom characterization: Cough, hoarseness, dyspnea, throat tightness, chest tightness, wheezing
• Timing: Symptoms may be delayed up to 24–48 hours for lower airway and parenchymal injury; upper airway edema typically worsens over the first 12–24 hours, especially with concurrent fluid resuscitation [3][7]
• Associated symptoms: Headache, confusion, nausea, syncope (suggest CO/cyanide toxicity); facial/oral burns, singed hair [4-5]
• Important negatives: Loss of consciousness at scene (suggests significant CO/cyanide exposure), seizures, chest pain, hemoptysis

2. Alarm Features

• Stridor, progressive hoarseness, drooling — impending airway obstruction; intubate early as upper-airway edema makes reintubation extremely difficult [3-4]
• Altered mental status, syncope, or GCS <10 — suspect significant CO and/or cyanide poisoning [8-9]
• Persistent lactic acidosis (lactate >10 mmol/L) despite hemodynamic normalization — strongly associated with cyanide toxicity [4][8]
• COHb >30–40% — severe CO exposure [1]
• Extensive facial/neck burns or >20% TBSA cutaneous burns — anticipate progressive airway edema with resuscitation; low threshold for intubation [3-4]
• Cardiac arrest at scene — high suspicion for cyanide co-poisoning [9]
• Cyanosis, severe hypoxemia, respiratory failure

3. Medications

Treatments:

• 100% high-flow O₂ via NRB mask — first-line for all smoke inhalation; reduces COHb half-life from 3–4 hours to <1 hour [1][4]
• Nebulized beta-agonists (albuterol) — for bronchospasm [2][4]
• Nebulized racemic epinephrine — for severe mucosal edema [2]
• Nebulized heparin (5,000–10,000 IU q2–4h) alternating with nebulized N-acetylcysteine (20%, 3 mL q2–4h) — for fibrin cast prevention and mucus clearance; supported by limited evidence [10-11]
• Hydroxocobalamin (5 g IV in adults) — first-line antidote for suspected cyanide poisoning; preferred over sodium nitrite in smoke inhalation because it does not reduce oxygen-carrying capacity [6][12]

Contraindicated/Not recommended:

• Prophylactic antibiotics — not recommended [2][4][13]
• Empirical corticosteroids — associated with increased mortality and pneumonia in burn patients; contraindicated [2][4][13]
• Sodium nitrite — avoid in concurrent CO poisoning (induces methemoglobin, further reducing O₂ carrying capacity) [6]

4. Diet

• NPO initially if airway intervention is anticipated
• Early enteral nutrition is a priority in admitted burn/inhalation injury patients to support the hypermetabolic response
• Adequate hydration is critical, but fluid resuscitation must be carefully titrated (over-resuscitation worsens pulmonary edema)

5. Review of Systems

• Respiratory: Cough, dyspnea, wheezing, stridor, sputum production (carbonaceous?), hemoptysis
• Neurologic: Headache, confusion, dizziness, syncope, seizures (CO/cyanide)
• Cardiovascular: Chest pain, palpitations (CO-induced cardiac ischemia at COHb 30–50%) [4]
• GI: Nausea, vomiting (CO toxicity)
• Ophthalmologic: Eye irritation, corneal injury from chemical irritants
• Dermatologic: Facial burns, singed nasal/facial hair, soot deposits

6. Collateral History and Family History

• Bystander/EMS information is critical: Was the patient in an enclosed space? Duration of exposure? Loss of consciousness? Materials burning?
• Prehospital O₂ administration — COHb levels drop rapidly with O₂; a "normal" level on arrival may mask severe exposure [1][4]
• Pre-existing pulmonary disease (COPD, asthma) — increases vulnerability to bronchospasm and respiratory failure
• Pregnancy — fetal hemoglobin binds CO 2.5–3× more avidly than maternal hemoglobin; stronger indication for aggressive treatment and consideration of hyperbaric O₂ [14]
• Family history is generally less relevant acutely

7. Risk Factors

• Enclosed-space exposure — the single most important risk factor [1][5]
• Prolonged exposure duration
• Combustion of synthetic materials (plastics, vinyl, wool, silk) — higher cyanide and toxic gas yield [6]
• Concurrent cutaneous burns — lung damage is much more severe when combined with major body-surface burns [1]
• Extremes of age — children and elderly have worse outcomes
• Pre-existing cardiopulmonary disease
• Altered consciousness at time of exposure (intoxication, disability) — prolongs exposure

8. Differential Diagnosis

• Thermal upper airway injury without chemical inhalation (flash burns from propane/butane — typically no smoke inhalation injury) [1]
• Acute asthma/COPD exacerbation triggered by irritant exposure
• Anaphylaxis — if acute airway edema and bronchospasm without clear exposure history
• Foreign body aspiration
• Toxic gas exposure without fire (CO from furnace, industrial cyanide)
• Acute epiglottitis — if isolated supraglottic edema
• Pulmonary contusion — if concurrent blast/trauma
• ARDS from other causes (aspiration, sepsis)

9. Past Medical History

• Asthma/COPD — lower threshold for bronchospasm, higher risk of respiratory failure
• Coronary artery disease — CO-induced cardiac ischemia occurs at COHb 30–50% [4]
• Prior intubation/tracheostomy — may complicate airway management (subglottic stenosis)
• Smoking history — baseline elevated COHb (3–10%)
• Pregnancy — see above

10. Physical Exam

Vital signs:

• NEJM[1]

Focused exam:

• Airway: Facial/oral burns, singed nasal vibrissae, soot in nares/oropharynx, oropharyngeal edema/erythema, hoarseness, stridor [4-5]
• Lungs: Wheezing, rales, rhonchi; may be initially clear despite significant injury [15]
• Skin: Extent and depth of cutaneous burns, circumferential chest/neck burns (risk of compartment syndrome)
• Neuro: GCS, confusion, agitation, obtundation (CO/cyanide)
• Eyes: Conjunctival injection, corneal injury

Pearl: A normal initial lung exam does not exclude significant inhalation injury — deterioration over 24–48 hours is common. [3][15]

11. Lab Studies

• Co-oximetry (COHb level) — the only accurate test for CO; standard pulse oximetry and ABG PaO₂ are unreliable [1]
  • COHb 10–20%: headache, nausea
  • COHb 20–30%: weakness, impaired cognition
  • COHb >30–40%: severe exposure, cardiac ischemia, unconsciousness [4]
• Arterial blood gas — assess PaO₂/FiO₂ ratio (reliable indicator of injury severity and predictor of respiratory failure) [5][16]
• Lactate — elevated levels suggest tissue hypoxia; >10 mmol/L strongly associated with cyanide toxicity [8-9]
• CBC — baseline; leukocytosis expected
• BMP/CMP — renal function, electrolytes, anion gap metabolic acidosis
• Troponin — if cardiac ischemia suspected (CO-mediated)
• Cyanide levels — not available in real-time in most EDs; treatment is empirical [6][17]

12. Imaging

• Chest X-ray — often normal initially; may show diffuse infiltrates, atelectasis, or pulmonary edema as injury evolves [4]
• Chest CT — more sensitive for distal airway disease and pulmonary opacification; when combined with bronchoscopy, significantly improves prognostication [5]
• Imaging is not required for diagnosis — clinical evaluation and bronchoscopy are the principal diagnostic tools [4]
• Serial CXR useful for monitoring progression to ARDS/pneumonia

13. Special Tests

• Fiberoptic bronchoscopy — gold standard for diagnosis and grading of inhalation injury below the vocal cords; 86% accuracy with no false positives [5][18]
  • Findings: mucosal edema, erythema, soot deposition, carbonaceous material, ulceration, necrosis, cast formation [15][19]
  • Abbreviated Injury Score (AIS) is the most widely used grading system; grades 3–4 associated with higher pneumonia and ARDS risk [18]
  • Also therapeutic: suctioning of debris and casts [11]
• Nasolaryngoscopy — for supraglottic assessment; can guide intubation decisions [3][12]
• PaO₂/FiO₂ ratio — correlates with injury severity and predicts mortality [5][16]

14. ECG

• Obtain ECG in all patients with significant CO exposure
• CO-induced myocardial ischemia: ST changes, arrhythmias (at COHb >30%) [4]
• Cyanide toxicity: bradycardia progressing to asystole, wide-complex arrhythmias
• Continuous cardiac monitoring for all moderate-to-severe exposures

15. Assessment

Three zones of injury:

• Supraglottic (thermal) — direct heat injury causing edema of oropharynx, larynx; peaks at 12–24 hours; risk of complete obstruction [5][11]
• Tracheobronchial (chemical) — toxic particles (5–10 µm) penetrate lower airways causing epithelial necrosis, sloughing, fibrin cast formation, bronchospasm, and small-airway obstruction [1][15]
• Systemic (toxicologic) — CO and cyanide impair oxygen delivery and cellular respiration [4][8]

Severity stratification: Combination of TBSA, age, and PaO₂/FiO₂ ratio is highly predictive of mortality. [16] Inhalation injury adds approximately 20% mortality at the LA₅₀ for burn area; pneumonia (develops in two-thirds by day 7–8) adds up to 60% additional mortality. [5]

Complications to anticipate:

• Progressive airway obstruction (first 24–72 hours)
• Pneumonia (most common complication; two-thirds of intubated patients) [5]
• ARDS [1][5]
• Subglottic stenosis (long-term) [3]
• Delayed neurologic sequelae from CO (small percentage) [4]

16. Treatment Plan

Initial stabilization (0–72 hours):

• 100% O₂ via NRB for all patients; continue for minimum 6 hours if CO suspected [1][4]
• Airway management: Intubate for facial edema, hoarseness, stridor, GCS depression, or large cutaneous burns (>20% TBSA); secure ETT meticulously — reintubation is extremely difficult with upper-airway edema [3-4]
• Head of bed elevation, humidified air for non-intubated patients [4]

Bronchospasm:

• Lancet[2]

Airway clearance:

• Nebulized heparin (5,000–10,000 IU) alternating with nebulized NAC (20%, 3 mL) q2–4h — reduces fibrin cast formation [10-11]
• Serial bronchoscopy for cast removal and airway toilet [11][19]

Systemic toxicity:

• CO poisoning: 100% normobaric O₂ (standard); hyperbaric O₂ may be considered if no wheezing/airway debris and no cutaneous burns, though evidence is controversial [1][4]
• Cyanide poisoning: Hydroxocobalamin 5 g IV empirically if cardiac arrest at scene, GCS <10, lactate >10, or COHb >10% with enclosed-space exposure [6][9]

Mechanical ventilation (if needed):

• Lung-protective strategy: Vt ~6 mL/kg IBW, plateau pressure limits, adequate PEEP [1][20]
• High-frequency percussive ventilation is an option under investigation [12]

17. Disposition

Admit/ICU criteria:

• Any confirmed or suspected inhalation injury with respiratory symptoms
• Intubated patients
• COHb >25% or any neurologic symptoms
• Suspected cyanide toxicity
• Concurrent significant cutaneous burns (>20% TBSA)
• Patients requiring observation for progressive airway edema

Burn center transfer criteria:

• Inhalation injury is an ABA burn center referral criterion regardless of burn size
• Combined inhalation injury + cutaneous burns

Observation (minimum 4–6 hours):

• NEJM[4]

Discharge criteria:

18. Follow Up / Return Precautions

• Follow-up within 24–48 hours for all discharged patients — delayed pulmonary edema can develop up to 48–72 hours post-exposure [7]
• Return immediately for: worsening cough, dyspnea, stridor, voice changes, chest pain, confusion, or any new neurologic symptoms
• Delayed neurologic sequelae from CO exposure (cognitive deficits, personality changes) may develop days to weeks later in a small percentage of patients [4]
• Long-term laryngologic follow-up — patients with inhalation injury are at risk for granulation tissue, vocal cord immobility, subglottic stenosis, and laryngeal scarring [3]
• Counsel on smoke detector installation and fire safety

References

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