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Permissive hypoxaemia – key issues

Permissive hypoxaemia – key issues. How much oxygen do you need? “natural experiments” “critical care research” Is oxygen toxic?. Origins of mitochondria – ancient invasions > 1.5 billion years ago. -proteobacterium. Eukaryote. proto-mitochondria. gene transfer.

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Permissive hypoxaemia – key issues

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  1. Permissive hypoxaemia – key issues • How much oxygen do you need? • “natural experiments” • “critical care research” • Is oxygen toxic?

  2. Origins of mitochondria – ancient invasions > 1.5 billion years ago -proteobacterium Eukaryote proto-mitochondria gene transfer • genetic similarity to bacteria • What drove the union • protect anarobic host from oxygen tension

  3. Energy production in Mitochondria mitochondria glucose pyruvate O2 Pyruvate +O2 H2O & CO2 pyruvate + O2 2 ATP 30 ATP glycolysis Oxidative phosphorylation Inefficient process Very efficient process

  4. Energy production in Mitochondria Outer membrane Inner membrane H+ H+ H+ O2 e 2H2O H+ ADP ATP matrix

  5. Ascent without oxygen All 8000+ m peaks have been climbed without O2

  6. Altitudes

  7. What is the alveolar PO2 at altitude? Alveolar PO2 PIO2 -PaCO2 Everest summit PAO2 = 5.0 -5.0 = 0!!

  8. What is the alveolar PCO2 at altitude? PACO2 CO2 output/alveolar ventilation

  9. Gas transfer at altitude Diffusion limited PaO2 3.5 kPa

  10. What is the arterial oxygen content at altitude?

  11. Oxygen delivery at altitude VO2 = cardiac output X arterial O2 content

  12. Supplemental oxygen and montaineer death rates on Everest and K2 - JAMA 2000

  13. How high can you go? • Two theories of the “vertical limit” • Oxygen delivery limit • Oxygen diffusion limit from capillary to mitochondria

  14. Adaptation to prolonged hypoxaemia • Cardiac output • Respiratory rate and MV • Haemoglobin • Skeletal muscle • ? Capillary/endothelial • ? Mitochondrial/OXPHOS

  15. Hypoxaemia & Metabolism Hypoxia Inducible factor Transduction factor > 100 genes Erythropoietin Metabolism Angiogenesis Cell differentiation

  16. Genetics & hypoxia Climbers Success

  17. Oxygen toxicity • Oxygen is bad for you! • Oxidative phosphorylation vs. ROS • Ubiquitous cellular defences against ROS • Marked depletion of these in critically ill • Many trials of “anti-oxidants” • No RCTs of limiting oxygen

  18. (Crit Care Med 2004; 32:2496 –2501)

  19. Additive effects of high TV and high oxygen Inflammatory cells permeability cytokines

  20. Oxygen toxicity in adult man • FIO2 75 – 100% • Tracheobronchitis • Loss of VC • Time & dose dependent • Single volunteer FIO2 100% for 100 hrs • Deteriorating respiratory function • Acute respiratory failure • Winter PA Anaesthesiology 1972;37:210

  21. O2 toxicity in healthy man

  22. O2 toxicity in adult ventilated patients • “Irreversible coma” • 100% O2 for a few days • Patchy pulmonary infiltrates & reduced gas exchange • Barber New Engl J Med 1970; 283:1478-84 • Five patients with neuromuscular disease • 85-100 % FIO2 for a few days • Patch chest radiology changes • Fever • Raised wbc • No infection • Hyde Ann Intern Med 1969;71;517-31

  23. High v lower PEEP in patients with ARDSNEJM 2004

  24. Permissive hypoxaemia in prolonged Mechanical Ventilation • Experimental evidence for O2 toxicity in the lung • Evidence for additive effect of hyperoxia on VILI • No evidence that survival is determined by oxygenation alone

  25. Hypothesis • Ventilation at a reduced FIO2 (accepting lower SaO2) will improve outcome in patients receiving prolonged (4+ day mechanical ventilation) in General ITUs

  26. Conclusions • We do not know how low we can allow oxygen delivery to fall • Our patients are not Mountaineers! • Increase CO • Increase RR • Increase Hb • Adapt by complex changes in gene expression • Good genes

  27. Conclusions • Oxygen toxicity occurs in small animals and neonates • Some but controversial evidence in healthy man • Little or no evidence in the critically ill • Shouldn't assume that oxygen is harmless (= a drug at FIO2 > 21%) • Need for more research

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