Alveolar–arterial gradient

From WikiMD's Wellness Encyclopedia

Alveolar–arterial gradient (A-a gradient) is a measure used in medicine to assess the difference between the alveolar concentration of oxygen and the arterial concentration of oxygen. It is a useful indicator of the efficiency of gas exchange in the lungs. The A-a gradient helps in diagnosing the cause of hypoxemia (low blood oxygen levels) and is particularly important in the evaluation of patients with respiratory failure.

Calculation[edit | edit source]

The A-a gradient is calculated using the following formula:

PAO2 = (FiO2)(Patm - PH2O) - (PaCO2/RQ)
A-a gradient = PAO2 - PaO2

where:

  • PAO2 = alveolar oxygen pressure
  • FiO2 = fraction of inspired oxygen
  • Patm = atmospheric pressure
  • PH2O = water vapor pressure at body temperature
  • PaCO2 = arterial carbon dioxide pressure
  • RQ = respiratory quotient (usually assumed to be 0.8)
  • PaO2 = arterial oxygen pressure

The normal A-a gradient varies with age and the FiO2 (fraction of inspired oxygen). Generally, a gradient of less than 10-15 mmHg is considered normal for a young adult breathing room air.

Clinical Significance[edit | edit source]

An increased A-a gradient suggests a problem with oxygen transfer from the alveoli to the blood. This can be due to several reasons, including pulmonary fibrosis, pulmonary edema, or pulmonary embolism. In contrast, a normal A-a gradient in the presence of hypoxemia suggests a problem with the overall oxygen content of the air or issues with the circulation of blood in the lungs, such as right-to-left shunt or hypoventilation.

Uses[edit | edit source]

The A-a gradient is particularly useful in the differential diagnosis of hypoxemia. By determining whether the gradient is increased or normal, healthcare providers can narrow down the potential causes of a patient's respiratory distress. It is also used to monitor the progress of lung diseases and the response to treatment.

Limitations[edit | edit source]

The A-a gradient calculation assumes a constant respiratory quotient and does not account for variations in individual physiology or the presence of other gases in the blood. Additionally, accurate measurement requires arterial blood gas analysis, which is invasive.


Contributors: Prab R. Tumpati, MD