Respiratory Failure

Aetiology

• Respiratory centre depression
  • Overdose of drugs (opioids!), intoxications
  • A disease in the central nervous system
  • Unconsciousness from various causes
  • Incautious oxygen therapy for a patient with chronic hypoventilation
• Nerve impulse is not transmitted to respiratory muscles
  • Spinal cord injury
  • Myelitis
  • Infections (tetanus, poliomyelitis, botulism)
  • Neurolomuscular diseases (myasthenia gravis, motoneuron diseases, muscular dystrophies): usually chronic hypoventilation with an acute exacerbation, e.g. during a respiratory infection
  • Polyradiculitis
• Impaired ventilation mechanics
  • Crush injury of the thorax, tears of the diaphragm
  • (Pressure) pneumothorax Pneumothorax, haemothorax
  • Severe kyphoscoliosis ( usually chronic hypoventilation with an acute exacerbation, e.g. during a respiratory infection)
  • Severe obesity (obesity hypoventilation syndrome, also known as Pickwickian syndrome; usually chronic respiratory failure which is acutely worsened e.g. during a respiratory tract infection)
• Airway obstruction
  • Foreign object Foreign Body in the Respiratory Passages
  • Obstructing tumour or mucus
  • Severe asthma attack or acute exacerbation of chronic obstructive pulmonary disease Treatment of Acute Exacerbation of Asthma
• Parenchymal pulmonary disease
  • Severe pneumonia Pneumonia
  • Acute respiratory distress syndrome (ARDS)
  • Pulmonary oedema Acute Heart Failure and Pulmonary Oedema
  • Acute interstitial pneumonia
• Insufficient pulmonary circulation
  • Pulmonary embolism Pulmonary Embolism
• Decreased oxygen saturation in blood
  • Severe anaemia
  • Carbon monoxide poisoning
• Prolonged convulsions

Signs and symptoms

• Subjective difficulty breathing (dyspnoea)
• Restlessness, confusion, and disturbances of consciousness
• Increased breathing workload, use of accessory respiratory muscles, increased respiration rate

Investigations

• Peripheral oxygen saturation with a pulse oximeter (SpO₂) Pulse Oximetry
  • Good in detecting hypoxaemia but does not detect hypercapnia caused by hypoventilation
  • The treatment goal must be adjusted according to the patient and to the situation.
  • Usually values > 90% are sufficient. In acute situations, the goal is in the range of 94-98% if the patient is not prone to carbon dioxide retention (NB patients with COPD).
  • Note: a patient receiving supplemental oxygen may have severe hypoventilation and high concentration of arterial carbon dioxide (aB-pCO₂) even though peripheral oxygen saturation is > 90%.
• Arterial blood gas analysis
  • Provides a more accurate estimate of oxygenation (pO₂> 8 kPa is usually sufficient).
  • Essential in recognition of hypoventilation (pCO₂ level)
  • In acute hypoventilation, pCO₂ rises to > 6 kPa and the patient has concomitant respiratory acidosis.
  • Acidosis with pH < 7.35 calls for treatment measures.
• Investigations required to identify the cause of the respiratory failure

• The primary therapeutic aim is to maintain adequate tissue oxygenation. Keep in mind all the following aspects: oxygenation of arterial blood, cardiac output and the oxygen carrying capacity of the blood (haemoglobin concentration).
• Always ensure unobstructed airways.
• At the same time, start without delay causal treatment for the condition underlying the respiratory failure (e.g., medication for pneumonia, heart failure, airway obstruction).

Treatment options Corticosteroids for Acute Respiratory Distress Syndrome (Ards) in Adults, Positive Pressure Airway Support for Cardiogenic Pulmonary Oedema, Noninvasive Positive-Pressure Ventilation for Acute Exacerbation of Chronic Obstructive Pulmonary Disease, Noninvasive Positive Pressure Ventilation as a Weaning Strategy for Intubated Adults with Respiratory Failure

Aetiology

• Long-term or permanent disturbance in the functions of the respiratory centre, the nerves controlling respiration, respiratory muscles, thorax, or the lungs.
• Chronic hypoventilation often gets acutely worse during respiratory infections.
• The most common diseases leading to chronic hypoventilation include
  • COPD
  • neuromuscular diseases (e.g., ALS, muscular dystrophies, dysfunction of the diaphragm)
  • diseases that restrict the mobility of the thorax (kyphoscoliosis and other deformities of the thorax, sequela of polio, severe ankylosing spondylitis, morbid obesity)
  • severe sleep apnoea and hypoventilation associated with obesity (obesity hypoventilation syndrome, or Pickwickian syndrome).

Diagnostics

• Symptoms and signs
  • Dyspnoea, cyanosis, polycythaemia, symptoms and signs of right cardiac load
• Symptoms that point to night-time hypoventilation
  • Restless sleep, morning headache and drowsiness
  • Day-time tiredness and fatigue
  • Deterioration of memory and concentration
  • Recurrent acute episodes of respiratory failure
• Investigations
  • Arterial blood gas analysis
    • In awake state: oxygen (pO₂) < 8 kPa and/or carbon dioxide (pCO₂) > 6 kPa, pH normal, BE and HCO₃ increased
  • Night-time oxygen saturation (SpO₂) recording with pulse oximeter, and recording of skin carbon dioxide concentration (PtcCO₂). The following values suggest night-time hypoventilation:
    • night-time oxygen saturation at least 20% of the time < 90%, and the lowest values < 85%
    • night-time PtcCO₂ increased (> 7-8 kPa).
  • Spirometry (in sitting and recumbent position)
  • Maximal inspiratory and expiratory pressures
  • Respiratory rate at rest

General treatment principles

• Oxygen therapy used alone may make the hypoventilation worse.
• The primary treatment is assisted ventilation using a ventilator (BiPAP ventilation).
• Assisted ventilation is required primarily during sleep/night-time, and night-time only ventilator support with mask often is sufficient therapy.
• The aim of BiPAP treatment is to prevent respiratory depression during sleep, to relieve symptoms associated with night-time hypoventilation, to improve the quality of sleep, to positively affect day-time performance and to reduce acute episodes of respiratory failure.
• Supplemental oxygen may be combined with BiPAP treatment, as necessary.
• Introduction of the treatment should be elective.

Treatment options Nocturnal Positive Pressure Ventilation for COPD, Nocturnal Mechanical Ventilation for Chronic Hypoventilation in Patients with Neuromuscular and Chest Wall Disorders

• BiPAP ventilation, when assisted ventilation during night-time/sleep is sufficient.
• Invasive ventilator treatment through tracheostomy, when assisted ventilation is required for at least 15 h/24 hours (for example, sequela of a high-level spinal cord injury) or the mask ventilation is not suitable or is no more sufficient.
  • The arrangement of a long-term invasive ventilator treatment at home may require some kind of formal health authority decision of respiratory paralysis.
• Other treatment options
  • Phrenic nerve pacing
    • In central hypoventilation when the functions of diaphragm and phrenic nerve are intact and the mobility of the thorax is good.
  • Respiratory stimulators
    • An option when home ventilator treatment is not suitable
    • Most experience and evidence has been gathered about medroxyprogesterone (respiratory failure in postmenopausal women), acetazolamide and almitrine.