Successful treatment of tissue hypoxia requires early recognition. This can be difficult because the clinical features are often non-specific and include altered mental state, dyspnea, cyanosis, tachypnea, arrhythmias, and coma. Hyperventilation due to carotid chemoreceptor stimulation becomes pronounced when the arterial partial pressure of oxygen (Pao₂) falls to 40 mmHg. Peripheral vasodilation with consequent systemic hypotension and eventually coma occurs if the Pao₂ falls below 30 mmHg.

Indications for acute oxygen

In acutely ill patients oxygen delivery relies on maintaining a patent airway. This should always be checked first. Give oxygen empirically in patients with cardiac or respiratory arrest or when there is respiratory distress or hypotension. Arterial blood gases should be analyzed as soon as possible to assess the degree of hypoxemia, partial pressure of carbon dioxide (Pco₂), and acid-base state.

Increasing the fraction of inspired oxygen (Fio₂) increases oxygen transport by ensuring that blood hemoglobin is fully saturated and by raising the quantity of oxygen normally carried in solution in the plasma. However, the solubility of oxygen in blood is low. Even when the inspired oxygen concentration is 100%, dissolved oxygen provides only one third of resting tissue oxygen requirements. Therefore, oxygen treatment must be aimed at correcting arterial hypoxemia; when tissue hypoxia occurs in the absence of arterial hypoxemia treatment should always be directed at correcting the underlying cause (that is, heart failure, anemia).

In the acute situation the dose of oxygen administered may be critical. Inadequate oxygen accounts for more deaths and permanent disability than can be justified by the relatively small risks associated with high dose oxygen. In many acute conditions (for example, asthma, pulmonary embolus), inspired oxygen concentrations of 60-100% for short periods may preserve life until more specific treatment can be instituted. Thereafter oxygen should be given at a dose that will correct hypoxemia and minimize side effects (increase the Pao₂ to 60-80 mmHg). When necessary, oxygen must be given continuously.

High dose oxygen given to patients with chronic obstructive pulmonary disease who have type II respiratory failure can reduce the hypoxic drive to breathe and increase ventilation-perfusion mismatching. This causes carbon dioxide retention and a respiratory acidosis that may be lethal. In these patients initial treatment with low oxygen concentrations (24-28%) should be progressively increased on the basis of repeated blood gas analysis with the aim of correcting hypoxemia to a Pao₂>50 mmHg without decreasing arterial pH below 7.26. Non-invasive positive pressure ventilation and respiratory stimulants may help achieve adequate oxygenation and prevent carbon dioxide retention by raising minute ventilation in patients with type II respiratory failure. It is more effective and safer than respiratory stimulation and should be used when available. Type II respiratory failure occurs in 10-15% of patients with chronic obstructive pulmonary disease. In patients without type II respiratory failure the risk of hypercapnia is often overstressed, and under treatment of serious hypoxemia can result in unnecessary death.

Oxygen delivery systems

A wide variety of cheap oxygen delivery systems are available. The mask and valve design and oxygen flow rate allows delivery of an inspired oxygen of 24-90% (Fio₂ 0.26-0.90). The concentration of oxygen that patients inspire depends on the ventilatory minute volume (MV) and the flow rate of oxygen. The greater the ventilation, the lower the Fio₂ for a given flow rate of supplemental oxygen. It is impossible to provide a fixed Fio₂ to a patient with a varying ventilatory requirement unless the total ventilatory minute volume is provided at the required Fio₂.  

There are two basic types of oxygen mask which deliver either the entire (high flow mask) or a proportion (low flow mask) of the ventilatory requirement. High flow systems deliver about 40 l/min of gas through the mask, which is usually sufficient to meet the total respiratory demand. This ensures that the breathing pattern will not affect the FiO₂. The masks contain venturi valves, which use the principle of jet mixing (Bernoulli effect). When oxygen passes through a narrow orifice it produces a high velocity stream that draws a constant proportion of room air through the base of the venturi valve. Air entrainment depends on the velocity of the jet (the size of orifice and oxygen flow rate) and the size of the valve ports. It can be accurately controlled to give inspired oxygen levels of 24-60%.

Oxygen masks

Although many different designs of high and low flow systems are available, only a few are used regularly.

High flow, jet mixing masks are useful for accurately delivering low concentrations of oxygen (24-35%). They provide the total ventilatory requirement unaffected by the pattern of ventilation. In patients with chronic obstructive pulmonary disease and type II respiratory failure these masks reduce the risk of carbon dioxide retention while improving hypoxemia. They are loose fitting and comfortable to wear. Rebreathing of expired gas is not a problem because the mask is flushed by the high flow rates.

Low flow masks A concentration of up to 60% can be achieved with moderate oxygen flow rates (6-10 l/min), and these masks are used mainly in type I respiratory failure (for example, pulmonary edema, pulmonary embolus). At low oxygen flow rates (<5 l/min) significant rebreathing may occur because exhaled air is not adequately flushed from the face mask. This makes it difficult to achieve a low inspired oxygen concentration and prevent retention of carbon dioxide. These masks are generally not suitable for patients with type II respiratory failure.

Rebreathing and anesthetic type oxygen masks Partial rebreathing masks incorporating non-rebreathing valves and reservoir bags are not in common use but can provide concentrations greater than 60% at low oxygen flow rates. In cardiac or respiratory arrest, tight fitting anesthetic-type masks can achieve 100% oxygen, but prolonged use risks oxygen toxicity and reabsorption atelectasis.

Nasal Cannulas are simple and convenient to use. The Fio₂ depends on the flow rate of oxygen (1-6 l/min) and varies according to ventilatory minute volume. At an oxygen flow rate of 2 l/min the oxygen concentration in the hypopharynx of a resting subject is 25-30%. Nasal cannulas prevent rebreathing, are comfortable for long periods, and allow oxygen to be continued during talking and eating. Local irritation and dermatitis may occur with high flow rates.

Non-invasive assisted ventilation Supplemental oxygen may be provided through tight fitting nasal or full face masks during nasal intermittent positive pressure ventilation and continuous positive airways pressure. These techniques have been used to support ventilation in sleep associated hypoventilation, during weaning from mechanical ventilation, and in respiratory failure associated with chronic obstructive pulmonary disease.

Other delivery systems
Hyperbaric oxygenation At a pressure of 2280 mmHg the small quantity of oxygen in solution in the blood can be increased by up to 300% and diffusion through tissues may be improved. Advice is best sought on an individual basis from the specialist centers providing this service.

Humidification of oxygen When oxygen is delivered at a flow rate of 1-4 l/min by mask or nasal cannula, the oropharynx or nasopharynx provides adequate humidification. At higher flow rates or when oxygen is delivered directly to the trachea humidification is necessary.

Monitoring oxygen treatment

Oxygen treatment can be monitored by blood gas measurements or non-invasively by pulse oximetry. Blood gas analysis provides accurate information on the pH, Pao₂, and Paco₂. Oximetry provides continuous monitoring of the state of oxygenation.

Stopping oxygen treatment

Oxygen should be stopped when arterial oxygenation is adequate with the patient breathing room air (Pao₂>60 mmHg, Sao₂>90%). In patients without arterial hypoxemia but at risk of tissue hypoxia, oxygen should be stopped when the acid-base state and clinical assessment of vital organ function are consistent with resolution of tissue hypoxia.

 Summary

Oxygen is a life saving treatment. It should be treated like any other drug; it should be prescribed in writing, with the required flow rate and the method of delivery clearly specified. Failure to correct hypoxemia (PaO₂>60 mmHg) for fear of causing hypoventilation and carbon dioxide retention is unacceptable clinical practice. Careful monitoring of treatment is essential and will detect those patients at risk of carbon dioxide retention.  

Acknowledgments

N T Bateman is consultant physician, Department of Respiratory Medicine, St Thomas's Hospital, London.

The ABC of Oxygen is edited by Richard M Leach, consultant physician, and John Rees, consultant physician, Guy's and St Thomas's Hospital Trust, London. It will be published as a book later this year

N T Bateman,  R M Leach.