Arterial blood gas

	WikiDoc Resources for Arterial blood gas
Articles
Most recent articles on Arterial blood gas Most cited articles on Arterial blood gas Review articles on Arterial blood gas Articles on Arterial blood gas in N Eng J Med, Lancet, BMJ
Media
Powerpoint slides on Arterial blood gas Images of Arterial blood gas Photos of Arterial blood gas Podcasts & MP3s on Arterial blood gas Videos on Arterial blood gas
Evidence Based Medicine
Cochrane Collaboration on Arterial blood gas Bandolier on Arterial blood gas TRIP on Arterial blood gas
Clinical Trials
Ongoing Trials on Arterial blood gas at Clinical Trials.gov Trial results on Arterial blood gas Clinical Trials on Arterial blood gas at Google
Guidelines / Policies / Govt
US National Guidelines Clearinghouse on Arterial blood gas NICE Guidance on Arterial blood gas NHS PRODIGY Guidance FDA on Arterial blood gas CDC on Arterial blood gas
Books
Books on Arterial blood gas
News
Arterial blood gas in the news Be alerted to news on Arterial blood gas News trends on Arterial blood gas
Commentary
Blogs on Arterial blood gas
Definitions
Definitions of Arterial blood gas
Patient Resources / Community
Patient resources on Arterial blood gas Discussion groups on Arterial blood gas Patient Handouts on Arterial blood gas Directions to Hospitals Treating Arterial blood gas Risk calculators and risk factors for Arterial blood gas
Healthcare Provider Resources
Symptoms of Arterial blood gas Causes & Risk Factors for Arterial blood gas Diagnostic studies for Arterial blood gas Treatment of Arterial blood gas
Continuing Medical Education (CME)
CME Programs on Arterial blood gas
International
Arterial blood gas en Espanol Arterial blood gas en Francais
Business
Arterial blood gas in the Marketplace Patents on Arterial blood gas
Experimental / Informatics
List of terms related to Arterial blood gas

Editor-In-Chief: C. Michael Gibson, M.S., M.D. [1]; Associate Editor(s)-in-Chief: Priyamvada Singh, M.B.B.S. [2] Mohammed Abdelwahed M.D [3] Template:Arterial blood gas

Overview

An arterial blood gas is a blood test that is performed specifically on arterial blood, to determine the concentrations of carbon dioxide, oxygen and bicarbonate, as well as the pH of the blood. Its main use is in pulmonology, to determine gas exchange levels in the blood related to lung function, but it is also used in nephrology, and used to evaluate metabolic disorders such as acidosis and alkalosis. As its name implies, the sample is taken from an artery, which is more uncomfortable and difficult than venipuncture.

Physiological bases

PH (potential of hydrogen) is a numeric scale used to specify the acidity or basicity of a solution.
It is the base 10 logarithm of the activity of the hydrogen ion.
Solutions with a pH less than 7 are acidic and solutions with a pH greater than 7 are basic.
The pH of the blood plasma is normally tightly regulated between 7.32 and 7.42.

Hydrogen Ion Regulation

The body maintains a narrow pH range by 3 mechanisms:

Rapid lung compensation:

CO2 elimination is controlled by the lungs. The decrease in pH results in decreases in PCO2. Increase in pH results in increases in PCO2.
A metabolic acidosis excites the chemoreceptors and initiates a prompt increase in ventilation and a decrease in arterial PCO2.
A metabolic alkalosis silences the chemoreceptors and produces a prompt decrease in ventilation and increase in arterial PCO2.

Slow kidney compensation:

The renal compensation takes three to five days for completion.
Renal compensations are mediated by increased hydrogen ion secretion in respiratory acidosis and decreased hydrogen ion secretion and urinary HCO3 loss in respiratory alkalosis.
Chemical buffers react instantly to compensate for the addition or subtraction of H+ ions.
Renal excretion of acid from tissues is achieved by combining hydrogen ions with urinary buffers to form titratable acid such as:
Phosphate (HPO4- + H+ → H2PO4-)
Ammonia to form ammonium (NH3 + H+ → NH4+)
HCO3 elimination is controlled by the kidneys. Decreases in pH result in increases in HCO3-. Increases in pH result in decreases in HCO3-.
Acid-base status is usually assessed by measuring the components of the bicarbonate and carbon dioxide in blood:

CO2 + H2O ↔ H2CO3 ↔ HCO3- + H+

The partial pressure of CO2 and the pH are each measured using electrodes. The serum bicarbonate (HCO3-) concentration is then calculated with the Henderson-Hasselbalch equation.

pH = 6.10 + log ([HCO3-] ÷ [0.03 x PCO2])

The Henderson-Hasselbalch equation shows that the pH is determined by the ratio of the serum bicarbonate (HCO3) concentration and the PCO2, not by the value of either one alone.
The degree of compensation is usually defined by the decrease or increase in arterial PCO2 from its normal range or the decrease or increase in serum HCO3 from its normal range.

Video shows physiology of acid-base balance

Indications of ABG

Identification of acid-base disturbances
Measurement of the partial pressures of oxygen and carbon dioxide
Assessment of the response to therapeutic interventions
Collection of a blood sample when venous sampling is not feasible

Contraindications of ABG

Radial samples are contraindicated in abnormal modified Allen's test
Abnormal anatomy at the puncture site such as:
Congenital malformations
Burns
Aneurysm
Arteriovenous fistula
Active Raynaud's syndrome

Extraction and Analysis

Arterial blood for blood gas analysis is usually extracted by a phlebotomist, nurse, or respiratory therapist.^[1]
Blood may be taken from an easily accessible artery (typically the radial artery, but during unusual or emergency situations the brachial or femoral artery may be used), or out of an arterial line.
The syringe is pre-packaged and contains a small amount of heparin, to prevent coagulation or needs to be heparinised, by drawing up a small amount of heparin and squirting it out again.
Once the sample is obtained, care is taken to eliminate visible gas bubbles, as these bubbles can dissolve into the sample and cause inaccurate results.
The sealed syringe is taken to a blood gas analyzer.
If the sample cannot be immediately analyzed, it is chilled in an ice bath in a glass syringe to slow metabolic processes which can cause inaccuracy.
Samples drawn in plastic syringes should not be iced and should always be analyzed within 30 minutes.^[2]
The machine used for analysis aspirates this blood from the syringe and measures the pH and the partial pressures of oxygen and carbon dioxide. The bicarbonate concentration is also calculated. These results are usually available for interpretation within five minutes.
Standard blood tests can also be performed on arterial blood, such as measuring glucose, lactate, hemoglobins, dys-haemoglobins, bilirubin and electrolytes.
Contamination with room air will result in abnormally low carbon dioxide and (generally) normal oxygen levels. Delays in analysis (without chilling) may result in inaccurately low oxygen and high carbon dioxide levels as a result of ongoing cellular respiration.
Lactate level analysis is often featured on blood gas machines in neonatal wards, as infants often have elevated lactic acid.
Allen test is a medical sign used in the physical examination of arterial blood flow to the hands. It was named for Edgar Van Nuys Allen, who described the original version of the test in 1929. An altered test, first suggested by Irving S Wright in 1952, has almost universally replaced the original method in contemporary medical practice. The alternative method is often referred to as the modified Allen's test or modified Allen test.

By Rhcastilhos - Gray1237.png, Public Domain, https://commons.wikimedia.org/w/index.php?curid=1618923

Radial ABG sampling

Allen test for radial artery vasculatures

Sources of error

When the sample is left for prolonged periods at room temperature, consumption of oxygen may result in a falsely low PaO2. The sample should be analyzed within 15 minutes.
On the other side, air bubbles exist in the sample can cause a falsely high PaO2 and a falsely low PaCO2. Remove the bubbles after the sample has been withdrawn can minimize this effect.
If acidic heparin is used, heparin can decrease the pH. Heparin amount should be minimized.
If compared to pulmonary artery catheter, arterial pH is higher and PaCO2 was lower in peripheral ABG.

Reference Ranges and Interpretation

Interpretation

Arterial blood gas is interpreted in the following sequence for alkalosis and acidosis:

Step 1

Normal pH is 7.35 - 7.45.
pH < 7.35 is acidosis and > 7.45 alkalosis

Step 2

Normal CO2 is 4.7 to 6.0 kPa or 35 -45 mm Hg.
Check for CO2 whether acidosis (> 45) or alkalosis (< 35)

Step 3

Normal HCO3 (bicarbonates) 22 - 28 mmoL/liter.
HCO3 < 22 acidosis, Hco3 > 28 alkalosis

Step 4

Match whether pH is matching with carbondioxide or bicarbonate to determine the primary defect.
If pH matches CO2 the primary defect is respiratory, whereas if pH matches HCO3 the primary defect is metabolic

Step 5

After determining the primary defect check the opposite factor to see whether the defect is uncompensated, partially or fully compensated. For instance, the primary defect is respiratory acidosis then check the opposite factor i.e. HCO3 for compensation.

Step 6

Check for oxygen saturation to see if hypoxemia is present or not

Acid-base disturbances

Mixed disorders

Some patients have two, three, or more relatively independent acid-base disorders.
These mixed disorders include:
combinations of metabolic disorders (eg, vomiting-induced metabolic alkalosis plus hypovolemia-induced lactic acidosis)
mixed metabolic and respiratory disorders (eg, metabolic acidosis and respiratory alkalosis in salicylate intoxication)
As discussed in the preceding section, the evaluation of patients with acid-base disorders initially requires identification of the major disorder, and then determination of whether or not the degree of compensation is appropriate. If the compensation is not appropriate, then this is indicative of a second acid-base disorder (ie, a mixed acid-base disorder is present). The following examples are illustrative:
If metabolic acidosis is the primary disorder, an arterial PCO2 substantially higher than the expected compensatory response defines the mixed disorder of metabolic acidosis and respiratory acidosis, while an arterial PCO2 substantially lower than expected defines the mixed disorder of metabolic acidosis and respiratory alkalosis (which could be produced by acute hyperventilation due to the discomfort of obtaining the blood sample).
If respiratory acidosis is a major disorder, then the serum HCO3 should be appropriately increased. If the serum HCO3 is not as high as expected, then metabolic acidosis also exists and the arterial pH may be substantially reduced.
By contrast, if the serum HCO3 is higher than expected, then metabolic alkalosis complicates the respiratory acidosis and the arterial pH may be inappropriately "normal."

Video shows mixed disorders

Anion gap

The anion gap is a value calculated from the results of multiple individual medical lab tests. It may be reported with the results of an Electrolyte Panel, which is often performed as part of a Comprehensive Metabolic Panel. The anion gap is the difference between the measured cations (positively charged ions) and the measured anions(negatively charged ions) in serum, plasma, or urine. The magnitude of this difference (i.e., "gap") in the serum is often calculated in medicine when attempting to identify the cause of metabolic acidosis, a lower than normal pH in the blood. If the gap is greater than normal, then high anion gap metabolic acidosis is diagnosed.

Determination of the serum anion gap is an important step in the differential diagnosis of acid-base disorders and especially metabolic acidosis.
The serum AG represents the difference between the primarily measured cation (Na) and the primarily measured anions (Cl and HCO3):

Serum AG = Na - (Cl + HCO3)

normal range of 3 to 9 mEq/L[6,7].

Albumin, which is negatively charged, is the single largest contributor to the AG. the AG must be adjusted downward in patients with hypoalbuminemia. [2,8].
Conversely, the expected baseline value for the AG must be adjusted upward using the same correction factor in patients with hyperalbuminemia [8].

The serum AG is elevated in those metabolic acidoses that are due to the accumulation of any strong acid other than hydrochloric acid.
The most common causes of acute, high AG acidosis are lactic acidosis and ketoacidosis.
The degree to which the AG rises in relation to the fall in HCO3 varies with the cause of the metabolic acidosis.
This represents the delta AG/delta HCO3 ratio.

Video shows anion gap

Examples

Example 1

pH = 7.01, CO2 = 28 mm Hg, HCO3 = 10 mmol/L, Oxygen saturation = 95%, pO2 = 95
Step 1 - pH = 7.01, acidosis
Step 2 - CO2 = 28 mm Hg, alkalosis
Step 3 - HCO3 = 10 mmoL/L, acidosis
Step 4 - Match the pH - pH is acidosis and HCO3 is acidosis so the primary defect is metabolic acidosis
Step 5 - Since the primary defect is metabolic, check CO2 for compensation. Since CO2 is opposite to the pH it is trying to compensate. However, the pH is still acidosis and not normal so the compensation is only partial.
Step 6 - Oxygen saturation is normal so no hypoxemia.
Conclusion - Partially compensated metabolic acidosis without hypoxemia

Example 2

pH = 7.50, CO2 = 40 mm Hg, HCO3 = 32 mmol/L, Oxygen saturation = 95%, pO2 = 90
Step 1 - pH = 7.50, alkalosis
Step 2 - CO2 = 40 mm Hg, normal
Step 3 - HCO3 = 32 mmoL/L, alkalosis
Step 4 - Match the pH - pH is alkalosis and HCO3 is alkalosis so the primary defect is metabolic alkalosis
Step 5 - Since the primary defect is metabolic, check CO2 for compensation. Since CO2 is normal so it is uncompensated as CO2 is not trying to compensate.
Step 6 - Oxygen saturation is normal but pO2 is low so hypoxemia.
Conclusion - Uncompensated metabolic alkalosis with hypoxemia

Example 3

pH = 7.44, CO2 = 20 mm Hg, HCO3 = 10 mmol/L, Oxygen saturation = 95%, pO2 = 95%
Step 1 - pH = 7.44, normal
Step 2 - CO2 = 20 mm Hg, alkalosis
Step 3 - HCO3 = 10 mmoL/L, acidosis
Step 4 - Match the pH - pH is normal but a pH of 7.44 is more inclined towards CO2 (alkalosis) so the primary defect is respiratory alkalosis
Step 5 - Since the primary defect is respiratory, check HCO3 for compensation. Since pH is normal so it is fully compensated.
Step 6 - Oxygen saturation is normal but pO2 is low so hypoxemia.
Conclusion - Fully compensated respiratory alkalosis without hypoxemia.

Reference Ranges

Oxygen Partial Pressure (pO2)
Arterial pO2	70-100 mm Hg
Venous pO2	35-40 mmHg
Oxygen Saturation (SO2)
Arterial SO2	< 95%
Venous SO2	70-75%
Carbon Dioxide Partial Pressure (pCO2)
Arterial pCO2	35-45 mmHg
Venous pCO2	40-50 mmHg
Serum Bicarbonate (HCO3)
Arterial HCO3	20-27 mmol/l
Venous HCO3	19-28 mmol/l
pH
Arterial pH	7.35-7.45
Venous pH	7.26-7.46
Base Excess (BE)
Arterial BE	-3.4 - +2.3 mmol/l
Venous BE	-2 - -5 mmol/l

These are typical reference ranges, although various analysers and laboratories may employ different ranges.

Analyte	Range	Interpretation
pH	7.35 - 7.45	The pH or H⁺ indicates if a patient is acidemic (pH < 7.35; H⁺ >45) or alkalemic (pH > 7.45; H⁺ < 35).
H⁺	35 - 45 nmol/l (nM)	See above.
pO₂	9.3-13.3 kPa or 80-100 mmHg	Normal pO₂ is 80-100 mmHg (age-dependent).
pCO₂	4.7-6.0 kPa or 35-45 mmHg	The carbon dioxide and partial pressure (PCO₂) indicates a respiratory problem: for a constant metabolic rate, the PCO₂ is determined entirely by ventilation.^[3] A high PCO₂ (respiratory acidosis) indicates underventilation, a low PCO₂ (respiratory alkalosis) hyper- or overventilation.
HCO₃^-	22 - 26 mmol/l	The HCO₃^- ion indicates whether a metabolic problem is present (such as ketoacidosis). A low HCO₃^- indicates metabolic acidosis, a high HCO₃^- indicates metabolic alkalosis.
SBC_e	21 to 27 mM	the bicarbonate concentration in the blood at a CO₂ of 5.33kPa, full oxygen saturation and 37 degrees Celcius.^[4]
Base excess	-2 to +2 mmol/l	The base excess indicates whether the patient is acidotic or alkalotic. A negative base excess indicates that the patient is acidotic. A high positive base excess indicates that the patient is alkalotic.
HPO₄²⁻	0.8 to 1.5^[5] mM
total CO₂ (tCO₂ (P)_c)	25 to 30 mM	This is the total amount of CO₂, and is the sum of HCO₃^- and pCO₂ by the formula: tCO₂ = [HCO₃^-] + α*pCO₂, where α=0.226 mM/kPa, HCO₃^- is expressed in molars (M) and pCO₂ is expressed in kPa^[6]
total O₂ (tO_2e)		This is the sum of oxygen solved in plasma and chemically bound to hemoglobin.^[7]

References

↑ Aaron SD, Vandemheen KL, Naftel SA, Lewis MJ, Rodger MA (2003). "Topical tetracaine prior to arterial puncture: a randomized, placebo-controlled clinical trial". Respir Med. 97 (11): 1195–1199. PMID 14635973.
↑ Mahoney JJ, Harvey JA, Wong RL, Van Kessel AL (1991). "Changes in oxygen measurements when whole blood is stored in iced plastic or glass syringes". Clin Chem. 37 (7): 1244–1248. PMID 1823532.
↑ Baillie K, Simpson A. "Altitude oxygen calculator". Apex (Altitude Physiology Expeditions). Retrieved 2006-08-10. - Online interactive oxygen delivery calculator
↑ Acid Base Balance (page 3)
↑ Walter F., PhD. Boron. Medical Physiology: A Cellular And Molecular Approaoch. Elsevier/Saunders. ISBN 1-4160-2328-3. Page 849
↑ CO2: The Test
↑ Hemoglobin and Oxygen Transport. Charles L. Webber, Jr., Ph.D.

{WH}} Template:WS

[1] Aaron SD, Vandemheen KL, Naftel SA, Lewis MJ, Rodger MA (2003). "Topical tetracaine prior to arterial puncture: a randomized, placebo-controlled clinical trial". Respir Med. 97 (11): 1195–1199. PMID 14635973.

[2] Mahoney JJ, Harvey JA, Wong RL, Van Kessel AL (1991). "Changes in oxygen measurements when whole blood is stored in iced plastic or glass syringes". Clin Chem. 37 (7): 1244–1248. PMID 1823532.

[02_calc-3] Baillie K, Simpson A. "Altitude oxygen calculator". Apex (Altitude Physiology Expeditions). Retrieved 2006-08-10. - Online interactive oxygen delivery calculator

[4] Acid Base Balance (page 3)

[boron849-5] Walter F., PhD. Boron. Medical Physiology: A Cellular And Molecular Approaoch. Elsevier/Saunders. ISBN 1-4160-2328-3. Page 849

[6] CO2: The Test

[7] Hemoglobin and Oxygen Transport. Charles L. Webber, Jr., Ph.D.

[1]

[2]

[3]

[4]

[5]

[6]

[7]