Blood gas tension refers to the partial pressure of gases in blood.[1] There are several significant purposes for measuring gas tension;[2] the most common gas tensions measured are oxygen tension[3] (PxO2), the carbon dioxide tension[3] (PxCO2) and carbon monoxide tension[3] (PxCO). The subscript x in each symbol represents the source of the gas being measured; "a" meaning arterial,[3] "A" being alveolar,[3] "v" being venous,[3] "c" being capillary.[3]
Contents
- 1 Oxygen tension
- 2 Carbon dioxide tension
- 3 Carbon monoxide tension
- 4 Significance
- 5 Equations
- 5.1 Oxygen content
- 5.2 Oxygen saturation
- 6 See also
- 7 References
Oxygen tension
- Arterial blood oxygen tension (normal)
PaO2 — Partial pressure of oxygen at sea level (765 mmHg) in arterial blood is between 75 mmHg and 100 mmHg.[4][5][6]
- Venous blood oxygen tension (normal)
PvO2 — Oxygen tension in venous blood at sea level is between 30 mmHg and 40 mmHg.[6][7]
Carbon dioxide tension
Carbon dioxide is a by-product of food metabolism and in high amounts has toxic effects including: dyspnea, acidosis and altered consciousness.[8]
- Arterial blood carbon dioxide tension
PaCO2 — Partial pressure of carbon dioxide at sea level (765 mmHg) in arterial blood is between 35 mmHg and 45 mmHg.[9]
- Venous blood carbon dioxide tension
PvCO2 — Partial pressure of carbon dioxide at sea level in venous blood is between 40 mmHg and 50 mmHg.[9]
Carbon monoxide tension
- Arterial carbon monoxide tension (normal)
PaCO — Partial pressure of CO at sea level (765 mmHg) in arterial blood is approximately 0.02. It can be slightly higher in smokers and people living in dense urban areas.
Significance
The partial pressure of gas in blood is significant because it is directly related to ventilation and oxygenation.[10] When used alongside the pH balance of the blood, the PaCO2 and HCO3 (and Lactate) suggest to the health care practitioner which interventions, if any, should be made.[10][11] A survey of healthy individuals was done to measure the "normal" values of blood gas pressures and how it varies by age, sex, weight and height.[12] It was also found these values will depend on barometric pressure, and thus altitude. Online calculators exist that will compute the predicted normal values of blood gas tensions and pH based on a patient's age, height, sex, and weight as well as the barometric pressure.
Equations
Oxygen content
The constant, 1.36, is the amount of oxygen (ml at 1 atmosphere) bound per gram of hemoglobin. The exact value of this constant varies from 1.34 to 1.39, depending on the reference and the way it is derived. The constant 0.0031 represents the amount of oxygen dissolved in plasma. The dissolved-oxygen term is generally small relative to the term for hemoglobin-bound oxygen, but becomes significant at very high PaO2 (as in a hyperbaric chamber) or in severe anemia.[13]
Oxygen saturation
This is an estimation and does not account for differences in temperature, pH and concentrations of 2,3 DPG.[14]
See also
- Fick's laws of diffusion
- Alveolar air equation
References
- ^ Severinghaus JW, Astrup P, Murray JF (1998). "Blood gas analysis and critical care medicine.". Am J Respir Crit Care Med 157 (4 Pt 2): S114–22. doi:10.1164/ajrccm.157.4.nhlb1-9. PMID 9563770.
- ^ Bendjelid K, Schütz N, Stotz M, Gerard I, Suter PM, Romand JA (2005). "Transcutaneous PCO2 monitoring in critically ill adults: clinical evaluation of a new sensor.". Crit Care Med 33 (10): 2203–6. doi:10.1097/01.ccm.0000181734.26070.26. PMID 16215371.
- ^ a b c d e f g Yildizdaş D, Yapicioğlu H, Yilmaz HL, Sertdemir Y (2004). "Correlation of simultaneously obtained capillary, venous, and arterial blood gases of patients in a paediatric intensive care unit.". Arch Dis Child 89 (2): 176–80. doi:10.1136/adc.2002.016261. PMC 1719810. PMID 14736638.
- ^ Shapiro BA (1995). "Temperature correction of blood gas values.". Respir Care Clin N Am 1 (1): 69–76. PMID 9390851.
- ^ Malatesha G, Singh NK, Bharija A, Rehani B, Goel A (2007). "Comparison of arterial and venous pH, bicarbonate, PCO2 and PO2 in initial emergency department assessment.". Emerg Med J 24 (8): 569–71. doi:10.1136/emj.2007.046979. PMC 2660085. PMID 17652681.
- ^ a b Chu YC, Chen CZ, Lee CH, Chen CW, Chang HY, Hsiue TR (2003). "Prediction of arterial blood gas values from venous blood gas values in patients with acute respiratory failure receiving mechanical ventilation.". J Formos Med Assoc 102 (8): 539–43. PMID 14569318.
- ^ Walkey AJ, Farber HW, O'Donnell C, Cabral H, Eagan JS, Philippides GJ (2010). "The accuracy of the central venous blood gas for acid-base monitoring.". J Intensive Care Med 25 (2): 104–10. doi:10.1177/0885066609356164. PMID 20018607.
- ^ Adrogué HJ, Rashad MN, Gorin AB, Yacoub J, Madias NE (1989). "Assessing acid-base status in circulatory failure. Differences between arterial and central venous blood.". N Engl J Med 320 (20): 1312–6. doi:10.1056/NEJM198905183202004. PMID 2535633.
- ^ a b Williams AJ (1998). "ABC of oxygen: assessing and interpreting arterial blood gases and acid-base balance.". BMJ 317 (7167): 1213–6. doi:10.1136/bmj.317.7167.1213. PMC 1114160. PMID 9794863.
- ^ a b Hansen JE (1989). "Arterial blood gases.". Clin Chest Med 10 (2): 227–37. PMID 2661120.
- ^ Tobin MJ (1988). "Respiratory monitoring in the intensive care unit.". Am Rev Respir Dis 138 (6): 1625–42. doi:10.1164/ajrccm/138.6.1625. PMID 3144222.
- ^ Arterial Blood Gas Reference Values for Sea Level and an Altitude of 1,400 Meters ROBERT O. CRAPO, ROBERT L. JENSEN, MATHEW HEGEWALD, and DONALD P. TASHKIN American Journal of Respiratory and Critical Care Medicine 1999 160:5, 1525-1531
- ^ http://www-users.med.cornell.edu/~spon/picu/calc/oxycont.htm. Retrieved 7 October 2014.
- ^ Severinghaus, J. W. Simple, accurate equations for human blood O2 dissociation computations. J Appl Physiol. 46(3): 599-602. 1979.