1 / 11

Formulas related to O2 transport

Formulas related to O2 transport. Fiona Campbell BS, RRT-NPS Spring 2008. Oxygen content of arterial blood (CaO2). Calculated by adding the volume of oxygen dissolved in the plasma and the volume of combined oxygen O2 Dissolved in Plasma PaO2 X solubility coefficient of O2

aderyn
Download Presentation

Formulas related to O2 transport

An Image/Link below is provided (as is) to download presentation Download Policy: Content on the Website is provided to you AS IS for your information and personal use and may not be sold / licensed / shared on other websites without getting consent from its author. Content is provided to you AS IS for your information and personal use only. Download presentation by click this link. While downloading, if for some reason you are not able to download a presentation, the publisher may have deleted the file from their server. During download, if you can't get a presentation, the file might be deleted by the publisher.

E N D

Presentation Transcript

  1. Formulas related to O2 transport Fiona Campbell BS, RRT-NPS Spring 2008

  2. Oxygen content of arterial blood (CaO2) • Calculated by adding the volume of oxygen dissolved in the plasma and the volume of combined oxygen • O2 Dissolved in Plasma • PaO2 X solubility coefficient of O2 • 100 mmHg X .003 vol%/mmHg = 0.3 vol% • O2 combined with Hb • Hb X 1.34 X SaO2 • 15 X 1.34 X .97 = 19.5 vol% • CaO2=O2 dissolved in Plasma+O2 combined with Hb • CaO2 = 0.3 vol % + 19.5 vol % = 19.8 vol %

  3. Oxygen content of mixed venous blood (CvO2) • Blood returning to the heart will have a lower content • Normally PvO2 is approx 40 mmHg and SvO2 is normally 75% • The most accurate PvO2 is drawn from the pulmonary artery • CvO2 = (PvO2 X .003) + (Hb X 1.34 X SvO2) • CvO2 = (40 mmHg X .003)+(15 X 1.34 X .75)=15.2 vol%

  4. Arterial-Venous O2 content difference C(a-v)O2 • The C(a-v)O2 measures oxygen consumption of the tissues • C(a-v)O2 = CaO2 – CvO2 • C(a-v)O2 =20 vol% - 15 vol% = 5 vol% • C(a-v)O2 difference will when CvO2 & indicates a cardiac output

  5. Factors that effect C(a-v)O2

  6. Alveolar Gas Equation (PAO2) Partial Pressure of O2 in the Alveoli • PAO2=[(PB – PH2O)FiO2] –[PaCO2/(RQ)] • PAO2 = [(760 – 47).21] – [40 /(0.8)] • PAO2 = [149.73] – [50] • PAO2 = 99.73 mmHg

  7. Alveolar-arterial oxygen gradient P(A-a)O2 • The difference between the amount of O2 that enters the alveoli and the amount that gets to the blood stream • Non-invasive bedside tool used to quantitate the efficiency of oxygen loading • An increase in P(A-a)O2 indicates an increase in shunt • PAO2 – PaO2 = P(A-a)O2

  8. a/A ratio • Represents the percent of alveolar O2 that reaches the blood stream • a/A ratio = PaO2/PAO2 • a/A ratio = 55/100 = 0.55 or 55% • An a/A ratio of 75% is considered acceptable

  9. Predicted PaO2 • Comparisons of O2 in the lung and O2 in the bloodstream can be formulated using P(A-a)O2 and a/A ratio • These formulas can also be used to predict a PaO2 when the FiO2 needs to be altered • By understanding the relationship of the PAO2 and PaO2, one can properly treat the patient • Selecting an incorrect FiO2 one can over-correct or under-correct hypoxemia

  10. Predicted PaO2 • Formula: Current PaO2 = Desired PaO2 Current FiO2 = Desired FiO2 • This formula works only if other factors that effect his ventilation or metabolism are not involved • Solve for X 72 torr = 86 torr .30 X 72X = .30(86) X = .36 or 36% * The FiO2 must be increased to achieve the desired PaO2 of 86 torr

  11. Predicted PaO2 • This formula can be proven with other formulas learned: • With given PaO2 = 76 torr, PCO2 = 40 torr, FiO2 30% : • PAO2 = 163.9 torr • a/A = 72 torr/163.9 torr = 0.44 or 44% • Now with the FiO2 raised to 36% the PAO2 rises to 206.68 mmHg, 44% of O2 will get to the bloodstream and the predicted PaO2 is approx. 90 mmHg • NOTE: The ratio is for estimations and not absolute, by being aware of this relationship, one can quickly asses the oxygen requirement for the patient

More Related