Presentation is loading. Please wait.

Presentation is loading. Please wait.

Dr Vishram Buche Central India’s CHILD hospital & Research Institute, NAGPUR.

Published byVishram Buche Modified over 7 years ago

Similar presentations

Presentation on theme: "Dr Vishram Buche Central India’s CHILD hospital & Research Institute, NAGPUR."— Presentation transcript:

1

2 Dr Vishram Buche Central India’s CHILD hospital & Research Institute, NAGPUR

3 1.Clinical physiology of OXYGEN transport 2.Oxygenation status…... Parameters to d/d Hypoxia Severity of hypoxia 3.Improving Oxygenation (DO 2 )……… Interventions to improve Hypoxia Body compensates Therapeutics..O 2 therapy, Drugs

4 O2O2 CO 2 O2 CO 2 PO 2 = 100 PO 2 = 150 CO 2 O2O2 Pulmonary circulation Systemic circulation O2O2 O2O2 CO 2 O 2 CO 2 O 2

5 Functions……!!! …….. O 2 ……...CO 2 ……...?? GLOBInGLOBIn HAEmHAEm α2β2α2β2 α β β α Simple structure..??

6 1.Hb is a stereotactic molecule, when it combines with O2, it goes in to conformational changes. 2.It behaves different at different situations, 3.It has more affinity towards o2 in pulmonary Capillaries so binds more o2, 4.Less affinity towards o2 at systemic tissue capillaries so deliveries more o2 5.At higher Partial pressure it loves to bind more o2, at lower partial pressure it loves to deliver more o2. Moods of haemoglobin………

7 25 50 75 100 SaO 2 % 5 10 15 20 CaO 2 (ml/100ml) O2O2 O2O2 O2O2 O2O2 O2O2 O2O2 O2O2 O2O2

8 PaO 2 = 100 SaO 2 = 100% SO 2 = 75% O 2 = 95 CO 2 = 46 O2O2 CO 2 P A O 2 = 100 Atm = 760 FiO 2 = 21% PO 2 = 160 CO 2 = 40 O 2 = 100 CO 2 = 40 Pulmonary circulation Systemic circulation SO 2 = 75% PaO 2 = 95 SaO 2 = 97% PCO 2 = 40 O 2 = 40 After venous admixture O 2 = 40 CO 2 = 46 O 2 = 40 CO 2 = 46 External respiration Internal respiration

9 PaO 2 = 100 SaO 2 = 100% Content= 20.4 ml/dl SO 2 = 75% CaO 2 = 15 O 2 = 95 CO 2 = 46 O2O2 CO 2 = 40 P A O 2 = 100 Atm = 760 FiO 2 = 21% PO 2 = 160 CO 2 = 40 O 2 = 100 CO 2 = 40 Pulmonary circulation Systemic circulation SO 2 = 75% CaO 2 = 15 O2O2 PaO 2 = 95 SaO 2 = 97% Content= 20 ml/dl PCO 2 = 40 O 2 = 40 External respiration Internal respiration After venous admixture 2% 98% O 2 = 40 CO 2 = 46 O 2 = 40 CO 2 = 46

10 PO 2 SO 2

11 CaO 2 = Oxygen content 20 ml/100ml 2% Dissolved O 2 ( PaO 2  0.003 ml )  CaO 2 (20) = HbO 2 (19.7) + Dissol.O 2 (0.3) 98% O 2 is bound to Hb ( Hb  1.34  SaO 2 )

12 PaO 2 = 100 SaO 2 = 100% Content= 20.4 ml/dl SO 2 = 75% CaO 2 = 15 O 2 = 95 CO 2 = 46 O2O2 CO 2 = 40 P A O 2 = 100 Atm = 760 FiO 2 = 21% PO 2 = 160 CO 2 = 40 O 2 = 100 CO 2 = 40 Pulmonary circulation Systemic circulation SO 2 = 75% CaO 2 = 15 O2O2 PaO 2 = 95 SaO 2 = 97% Content= 20 ml/dl PCO 2 = 40 O 2 = 40 External respiration Internal respiration After venous admixture 2% 98% O 2 = 40 CO 2 = 46 O 2 = 40 CO 2 = 46

13 CaO2 DO2 PAO2 PaO2 SaO2 FiO2 OXYGEN 2 OXYGEN 2

14

15 100% 85% 50% 75% 50 40 25 100 20 15 10 5 CaO 2 tissue lung PaO 2 SaO2 0

16 100% 50% 75% 50 40 25 100 20 15 10 5 Content tissue lung PaO 2 SaO 2 0

17 100% 50% 75% 50 40 25 100 20 15 10 5 CaO 2 tissue lung PaO 2 SaO 2 0 15 tissue 10 18

18 100 0 25 4050100 75 10 50 20 15 10 5 ↑ CO2 ↑ H+ ↑ Temp ↑ 2,3 DPG 85 ↓CO2 ↓ H+ ↓ Temp ↓ 2,3 DPG

19 Oxygen Cascade……. Dry Atmosph: PO 2 160 Dry Atmosph: PO 2 160 Humidified Tracheal gas: 150 Alveolar gas P A O 2 : 100 Arterial blood: PaO 2 : 95 Capillary blood: 95 Mitochondria: 1-2 Venous blood: PO 2 40, sat 97% …… FiO 2 =21% Tissue 15-40 P (A-a) gradient

20 Alveolar-arterial O 2 Difference…….. FiO 2 = 21 % : (760-45) x.21= 150 mmHg O 2 CO 2 PAO 2 = 150 – 1.2 (PCO 2 ) = 150 – 1.2  40 = 150 – 50 = 100 mm Hg P a O 2 = 90 mmHg ………..PAO 2 – P a O 2 = ? PAO 2 – P a O 2 = 10 mmHg

21 Alveolar-arterial Difference… O 2 CO 2 Alveolar – arterial G. 100 - 45 = 55 ……………….Wide A-a Oxygenation Failure PCO 2 = 40 P A O 2 = 150 – 1.2 (40) = 150 - 50 = 100 PaO 2 = 45 Ventilation Failure PCO 2 = 80 PAO 2 = 150-1.2(80) = 150-100 = 50 PaO 2 = 45 Alveolar arterial G. 50 – 45 = 5 …………….Normal A-a

22 Measure Severe anemia V-Q mismatch High Altitude CO- poisoning PaO 2 SaO 2 CaO 2 N  N    N  

23 PaO 2 A-a gradient N  PCO2 Alveolar Hypoventilation  A-a gradient 100% O2 V-Q mismatch Diffusion Shunt Approach To Hypoxemia  Corrected PaO 2 Uncorrected PaO 2 Look for FiO2 PCO 2 N ↓FiO 2

24 CaO2 A…. Hb = 12 …..SaO 2 = 100% B…. Hb = 15 …..SaO 2 = 80% C…. Hb = 20……SaO 2 = 80%.. cyanotic D…. Hb = 7……..SaO 2 = 100%..acynotic WHO IS MORE CRITICAL ? normal

25 Master A …PICU.., breathing room air, monitored by pulse ox,blood drawn for ABG. ABG…..PaO2 = 77 Three SaO2 values…. 98%....... Pulse ox 95%....... Calculated from PaO2 85%....... Co-oximeter Why do these value disagree? Which is most reliable?

26 20 months…Persistant crying and irritable…2days No H/o respiratory infection, Refusal of feeds…day of admn O/E cynotic,vitals…normal, RS/CVS…WNL, O 2 inhaln ABG = pH-7.42, PaO 2 - 292, PCO 2 =33, SaO 2 =99% Pulse Ox=SpO2= 75%. Unexplained cyanosis, ↓SpO2, ↑↑ PaO2, RS/CVS….Ok MethHb 27%, Responded to Methylene blue METHMOGLOBINEMIA

27 PaO 2 SaO 2 O 2 bound Hb Dissolved O2 O. D. C. P A O 2 A.C.I. CaO 2 Content of oxygen Delivery Of Oxygen To Tissues DaO 2 O2O2 Cardiac output O2O2 FiO2

28 For any queries : vbuche@gmail.comvbuche@gmail.com Cell : 9823017254 www.authorstream.com www.slideshare.net Visit me on…………… There is no copyright on this material…. please copy for educational purposes….

Download ppt "Dr Vishram Buche Central India’s CHILD hospital & Research Institute, NAGPUR."

Similar presentations

Lectures on respiratory physiology Pulmonary Gas Exchange I.

Lectures on respiratory physiology Pulmonary Gas Exchange I.
DM SEMINAR FEBRUARY 27, 2004 OXYGEN - CARBON DIOXIDE TRANSPORT NAVNEET SINGH DEPARTMENT OF PULMONARY AND CRITICAL CARE MEDICINE PGIMER CHANDIGARH.

DM SEMINAR FEBRUARY 27, 2004 OXYGEN - CARBON DIOXIDE TRANSPORT NAVNEET SINGH DEPARTMENT OF PULMONARY AND CRITICAL CARE MEDICINE PGIMER CHANDIGARH.
Partial Pressures of O 2 and CO 2 Normal air pressure at sea level 760 mm Hg = 1 atm = 101.3 kPa airtracheaalveoliartery vein PO2159.6149.2104.0100.0 40.0.

Partial Pressures of O 2 and CO 2 Normal air pressure at sea level 760 mm Hg = 1 atm = kPa airtracheaalveoliartery vein PO
Formulas related to O2 transport Fiona Campbell BS, RRT-NPS Spring 2008.

Formulas related to O2 transport Fiona Campbell BS, RRT-NPS Spring 2008.
Exchange of Gases in the Lungs Exchange of Gases in the Lungs Week 3 Dr. Walid Daoud A. Professor.

Exchange of Gases in the Lungs Exchange of Gases in the Lungs Week 3 Dr. Walid Daoud A. Professor.
Transport of O2 and CO2 in blood and tissue fluids Dr. Walid Daoud MBBCh, MSc, MD, FCCP Director of Chest Department, Shifa Hospital, A. Professor of Chest.

Transport of O2 and CO2 in blood and tissue fluids Dr. Walid Daoud MBBCh, MSc, MD, FCCP Director of Chest Department, Shifa Hospital, A. Professor of Chest.
Blood Gas Transport Dr Taha Sadig Ahmed Physiology Dept College of Medicine King Saud University Riyadh.

Blood Gas Transport Dr Taha Sadig Ahmed Physiology Dept College of Medicine King Saud University Riyadh.
Dr Archna Ghildiyal Associate Professor Department of Physiology KGMU Respiratory System.

Dr Archna Ghildiyal Associate Professor Department of Physiology KGMU Respiratory System.
Dr. William R. Law Room 203A, CMW 6-7622

Dr. William R. Law Room 203A, CMW
Faisal Malmstrom, Critical Care Department SKMC

Faisal Malmstrom, Critical Care Department SKMC
Gas Exchange and Transport

Gas Exchange and Transport
OXYGEN EQUILIBRIUM AND TRANSPORT

OXYGEN EQUILIBRIUM AND TRANSPORT
Blood Gases: Pathophysiology and Interpretation

Blood Gases: Pathophysiology and Interpretation
Copyright © 2006 by Elsevier, Inc. Uptake of Oxygen in Lungs Alveolar Diffusing capacity 0 20 40 60 80 100 120 00.250.50.75 time in capillary (sec) P O2.

Copyright © 2006 by Elsevier, Inc. Uptake of Oxygen in Lungs Alveolar Diffusing capacity time in capillary (sec) P O2.
Respiratory Partial Pressure Primary determinant of diffusion and direction Describes the pressure of a particular gas within a mixture Equals the total.

Respiratory Partial Pressure Primary determinant of diffusion and direction Describes the pressure of a particular gas within a mixture Equals the total.
Gas Exchange and Transport

Gas Exchange and Transport
OXYGEN THERAPY Dora M Alvarez MD 2001. Oxygen Delivery Systems A-a Gradient Oxygen Transport Oxygen Deliver to Tissues.

OXYGEN THERAPY Dora M Alvarez MD Oxygen Delivery Systems A-a Gradient Oxygen Transport Oxygen Deliver to Tissues.
Transport of O 2 in blood: 1. Some dissolved  1.5% at normal atmospheric pressure 2. Most combined with hemoglobin  98.5%

Transport of O 2 in blood: 1. Some dissolved  1.5% at normal atmospheric pressure 2. Most combined with hemoglobin  98.5%
The Department of Pathophysiology Guo lirong

The Department of Pathophysiology Guo lirong
Chapter 11 Gas Exchange and Transport

Chapter 11 Gas Exchange and Transport

Similar presentations

Ads by Google