Various blood gas values, whether high or low, give a different diagnosis, such as the following imbalances.
Various blood gas values, whether high or low, give a different diagnosis.
In contrast to traditional blood tests, arterial blood gases (ABGs) provide the doctor with values of six different components that must be interpreted as a single result.
- pH
- 7.5 to 7.45 (a high pH often points to metabolic or respiratory alkalosis).
- pH value determines the presence of acidosis or alkalosis in the blood. If the pH is less than the normal range, it indicates acidosis, and a pH value above than normal range indicates alkalosis.
- PaCO2 (partial pressure of carbon dioxide)
- 35 to 45 mmHg (a high PaCO2 may indicate hypercapnia).
- The PaCO2 level represents the level of alveolar ventilation. A high PaCO2 indicates alveolar hypoventilation, whereas a reduced PaCO2 indicates alveolar hyperventilation.
- Acute fluctuations in PaCO2 will cause pH to shift. PaCO2 usually has a delayed reaction, so an increase in PaCO2 occurs slowly, and an extremely high PaCO2 indicates a long-standing condition related to lungs or metabolism. As a result, even when treated, PaCO2 levels may take a long time to recover.
- PaO2 (partial pressure of oxygen)
- 75 to 100 mmHg (a high PaO2 is often seen in intensive care units or ICU settings where external O2 is supplied).
- PaO2 indicates gas exchange in the lungs, and it determines the status of arterial blood oxygenation. A low PaO2 indicates hypoxemia (low oxygen in the blood), which may be caused by hypoventilation or a mismatch between ventilation and perfusion.
- The PaO2 generally falls with aging because the elderly have less elastic recoil in their lungs, resulting in a higher ventilation-perfusion mismatch. Therefore, a low PaO2 is concerning in a young individual, but it may be normal in older people.
- HCO3 (bicarbonate)
- 22 to 26 mEq/L (high bicarbonate is indicative of metabolic alkalosis).
- HCO3 (bicarbonate) acts as a buffer that regulates the pH balance of the blood and prevents the blood from becoming too acidic or alkaline. HCO3 is exhaled out as CO2, and even kidneys excrete or reabsorb HCO3 to maintain the proper pH balance of the blood.
- SpO2
- 94 to 100 percent.
- SpO2 indicates the amount of healthy hemoglobin that is carrying oxygen in the blood.
- Base excess (BE)
- −2 to +2 mEq/L (seen in metabolic disturbances).
- Base excess ranges from being negative to positive where the lower negative number is the base deficit, and the higher positive number is the base excess. The amount of HCO3 in the blood determines the BE. If the BE is excess indicating a positive number, then it indicates alkalosis, and if the number is low toward a negative side, it indicates acidosis.
An imbalance between oxygen and carbon dioxide in the blood results in various metabolic disorders. By knowing the values of these six components a doctor can diagnose respiratory diseases, functional disorders of major organs, such as kidneys and heart, drug overdose, and metabolic disorders.
Imbalances | Metabolic acidosis (serious electrolyte disordercharacterized by an imbalance in the body's acid-base balance) | Metabolic alkalosis | Respiratory acidosis (lungs cannot remove enough of the carbon dioxide produced by the body) | Respiratory alkalosis |
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pH | Decreases | Increases | Decreases | Increases |
PaCO2 | Decreases | Increases | Increases | Decreases |
HCO3 | Decreases | Increases | Increases | Decreases |
Base excess | Decreases | Increases | Normal or increases | Normal or increases |
Causes |
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2 types of blood gas tests
Blood gases test can be done with either arterial blood, which is called arterial blood gas, or venous blood gas, which is called venous blood gas.
- Venous blood gas (VBG): Done to study the gases, such as oxygen and carbon dioxide, that are dissolved in the blood.
- Arterial blood gases (ABG): Measures how effectively the lungs move oxygen into the blood and eliminate carbon dioxide from the blood, as well as how much hemoglobin can transmit oxygen throughout the body.
ABG is often done to detect any abnormalities because VBG contains less partial pressure of oxygen (PO2) than ABG.
Arteries carry oxygen-rich blood from the lungs to all the other organs and tissues in the body. Unlike conventional blood samples collected through veins, a blood sample is collected from arteries before the blood reaches the body tissues.
Such arteries include:
- Radial artery
- Brachial artery
- Femoral artery
An ABG is one of the most regularly used tests, which determines the amount of the buffer system's compensation, measures acid-base balance (pH), oxygen (O2) levels, and carbon dioxide (CO2) in arterial blood.
An ABG is a key indicator of a patient's clinical condition and proper interpretation of an ABG can lead to faster and more accurate adjustments in the plan of treatment.
A venous blood gas (VBG) can estimate pH and CO2 properly but cannot offer good O2 data. As a result, ABG has become the gold standard in patients who are ill and at a risk of rapid decompensation, have a respiratory component, or are admitted in hospital settings.
References
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American Thoracic Society. Interpretation of ABGs. https://www.thoracic.org/professionals/clinical-resources/critical-care/clinical-education/abgs.php
Saint Luke’s. Arterial Blood Gas (ABG). https://www.saintlukeskc.org/health-library/arterial-blood-gas-abg
Ambroz M, Prosen G. Arterial Blood Gas (ABG) Sampling. iEM. https://iem-student.org/arterial-blood-gas-abg-sampling/