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Arterial blood gases - indications and interpretation

Medical Professionals

Professional Reference articles are designed for health professionals to use. They are written by UK doctors and based on research evidence, UK and European Guidelines. You may find the Arterial blood gases article more useful, or one of our other health articles.

Arterial blood gases (ABGs) are an important routine investigation to monitor the acid-base balance of patients1 . They may help make a diagnosis, indicate the severity of a condition and help to assess treatment. ABGs provide the following information:

  • Oxygenation

  • Adequacy of ventilation

  • Acid-base levels

Also see the full separate Acid-base Balance article.

Continue reading below

Blood pH

Blood pH has to be maintained within a tight normal range to avoid cellular death. This can be achieved by buffer mechanisms which can be either renal or respiratory in nature1 .

Metabolic problems will require respiratory compensation and this occurs rapidly - eg, by increasing ventilation to blow off CO2. On the other hand respiratory problems leading to acid-base abnormalities require renal compensation. This is slow and may need secretion of H+ ions or reabsorption/new production of HCO3- ions2 .

Indications

  • Respiratory failure - in acute and chronic states.

  • Any severe illness which may lead to a metabolic acidosis - for example:

    • Cardiac failure.

    • Liver failure.

    • Renal failure.

    • Hyperglycaemic states associated with diabetes mellitus.

    • Multiorgan failure.

    • Sepsis.

    • Burns.

    • Poisons/toxins.

  • Ventilated patients.

  • Sleep studies.

  • Severely unwell patients from any cause - affects prognosis.

Continue reading below

Procedure

  • Arterial blood can be obtained by direct arterial puncture most usually at the wrist (radial artery). Alternatives to the radial artery include the femoral and brachial artery - both of which are usually used in emergency settings. The dorsalis pedis artery and ulnar artery may also be used. It is important to ensure good collateral circulation (see below), as there is a theoretical risk of thrombus occlusion.

  • If multiple samples are required then an indwelling arterial cannula can be placed.

  • If the patient is on oxygen, allow them to titrate with the oxygen for 5-10 minutes (30 minutes if they have chronic obstructive pulmonary disease (COPD)) before taking a sample.

  • If the radial artery is to be used, perform Allen's test to confirm collateral blood flow to the hand.

    Allen's test

    • Elevate the hand and make a fist for approximately 30 seconds.

    • Apply pressure over the ulnar and the radial arteries occluding both (keep the hand elevated).

    • Open the hand which will be blanched.

    • Release pressure on the ulnar artery and look for perfusion of the hand (this takes under eight seconds).

    • If there is any delay then it may not be safe to perform radial artery puncture.

  • Explain the procedure to the patient - it is painful.

  • If there is time then local anaesthesia can be used.

  • ABG syringes usually come prepacked and are heparinised. Some contain a vacuum and thus the plunger does not always need to be pulled. (Check with your department as to which they use).

  • The wrist is extended - a pillow under the hand may improve comfort.

  • Palpate the artery and hold fingers firmly over the pulsation.

  • Then introduce the needle at a 45° angle slowly with the bevel facing upwards, aiming for the point of maximum pulsation.

  • Once you hit the artery, try to obtain at least a 1 ml sample.

  • Once you have taken your sample and withdrawn the needle, apply firm pressure for a minimum of two minutes (longer if the patient is on any antiplatelet medication or anticoagulants).

How to interpret arterial blood gases

The following indices should be looked at in the following order (see local laboratory for reference ranges):

  • Blood pH - high indicates alkalosis, low indicates acidosis and normal indicates either normal, mixed defect or a compensated defect.

  • PaCO2 level - is it a respiratory problem? If not, look at the bicarbonate level. High PaCO2 with an acidosis indicates a respiratory problem. If the PaCO2 is normal or low it indicates compensation.

  • Bicarbonate - if the bicarbonate fits with the pH it suggests a primary metabolic problem. If not, it indicates compensatory changes.

  • Look for any compensation - eg, low PaCO2 in severe metabolic acidosis.

  • Anion gap in metabolic acidosis - see below under 'Other useful information from arterial blood gases'.

  • O2 level - is hypoxaemia present?

Continue reading below

Other useful information from arterial blood gases

Alveolar-arterial oxygen gradient - (A-a)pO2; difference in oxygen partial pressures between the alveolar and arterial side3 . It provides a measure of oxygen diffusion across the alveoli into the blood. Thus, will be impaired in lung disease such as COPD4 . Raised (A-a)pO2 may also represent the presence of an intrapulmonary shunt, ie a lung that is perfused but not ventilated - for example, pneumonia. The following table provides a list of some of the causes in which (A-a)pO2 change:

(A-a) pO2

Normal (A-a)pO2 in type 2 respiratory failure

Raised (A-a)pO2

Central nervous system (CNS) depression.

Neuromuscular disorders.

Intrinsic lung disease - eg, COPD.

Anion gap - this is useful in any cause of metabolic acidosis. In plasma, the sum of the cations (sodium plus potassium) is normally greater than that of the anions (chloride plus bicarbonate) by approximately 14 mmol/L (normal range 10-18 mmol/L). This is known as the anion gap. In some disorders, either the positive or negative ions may increase, leading to a change in the anion gap. The following table lists the causes of an abnormal anion gap:

Causes of changes in anion gap

Raised anion gap metabolic acidosis

Normal anion gap (hyperchloraemia) metabolic acidosis

Accumulation of acids - for example:

Ketoacids in diabetic ketoacidosis (DKA).

Lactic acid - eg, shock, infection.

Drugs/toxins - eg, salicylates, ethylene glycol, methanol.

Loss of bicarbonate or ingestion of acid - for example:

Gastrointestinal tract causes - eg, diarrhoea, pancreatic fistula.

Renal tubular acidosis.

Addison's disease.

Drugs - eg, carbonic anhydrase inhibitors.

Causes of a raised anion gap metabolic acidosis can be recalled using the 'MUDPILES' mnemonic (methanol, uraemia, DKA, paraldehyde, infection/ischaemia/isoniazid, lactic acidosis, ethylene glycol/ethanol, salicylates/starvation).

Primary acid-base disturbances

  • Respiratory acidosis: low pH, high PaCO2, normal or high normal bicarbonate.
    Causes: neuromuscular weakness, intrinsic lung disease - eg, COPD.

  • Respiratory alkalosis: high pH, low PaCO2, normal or high normal bicarbonate.
    Causes: any cause of hyperventilation - eg, anxiety, pain.

  • Metabolic acidosis: low pH, normal or low normal PaCO2, low bicarbonate.
    Causes: see anion gap table, above.

  • Metabolic alkalosis: high pH, normal PaCO2, high bicarbonate.
    Causes: vomiting, burns, ingestion of base.

Mixed disorders

Mixed acid-base disorders occur when there is a combination of primary acid-base disturbances (but not combined respiratory acidosis and alkalosis). Usually the ABG result does not fit into one of the above four clinical pictures easily. The therapy is directed towards correction of each primary acid-base disturbance5 .

Further reading and references

  • Bijapur MB, Kudligi NA, Asma S; Central Venous Blood Gas Analysis: An Alternative to Arterial Blood Gas Analysis for pH, PCO2, Bicarbonate, Sodium, Potassium and Chloride in the Intensive Care Unit Patients. Indian J Crit Care Med. 2019 Jun;23(6):258-262. doi: 10.5005/jp-journals-10071-23176.
  • Castro D, Keenaghan M; Arterial Blood Gas
  1. Hopkins E et al; Physiology, Acid Base Balance. In: StatPearls. StatPearls Publishing, Treasure Island (FL); 2019.
  2. Hamilton PK, Morgan NA, Connolly GM, et al; Understanding Acid-Base Disorders. Ulster Med J. 2017 Sep;86(3):161-166. Epub 2017 Sep 12.
  3. Sarkar M, Niranjan N, Banyal PK; Mechanisms of hypoxemia. Lung India. 2017 Jan-Feb;34(1):47-60. doi: 10.4103/0970-2113.197116.
  4. Bruno CM, Valenti M; Acid-base disorders in patients with chronic obstructive pulmonary disease: a pathophysiological review. J Biomed Biotechnol. 2012;2012:915150. doi: 10.1155/2012/915150. Epub 2012 Feb 1.
  5. Seifter JL, Chang HY; Disorders of Acid-Base Balance: New Perspectives. Kidney Dis (Basel). 2017 Jan;2(4):170-186. doi: 10.1159/000453028. Epub 2016 Dec 10.

Article history

The information on this page is written and peer reviewed by qualified clinicians.

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