Dr Xavier MONNET

1. Assessing volume responsiveness in spontaneously breathing patients Dr Xavier MONNET Medical Intensive Care Unit Bicêtre Hospital FRANCE

2. Conflicts of interest Lilly Arrow Deltex Medical Pulsion Medical Systems

3. Stroke volume b' a' b' a' A B A B Ventricular preload Prediction of fluid responsiveness Concept When we administer fluid, we expect an increase in SV All patients do not « respond » to fluid administration VE VE

4. Prediction of fluid responsiveness Concept 2 situations must be distinguished initial phase of septic shock hypovolemic shock a positive « response » to fluid is certain fluid must be administered immediately septic shock after the initial phase previous fluid administration lung injury fluid responsiveness is not certain

5. Prediction of fluid responsiveness Concept Stroke volume b' deleterious effects  lung edema gas exchange alteration in case of ARDS a' b'  interstitial edema alteration in tissue oxygenation a' ? How to predict fluid responsiveness  A B A B Ventricular preload

6. Prediction of fluid responsiveness CVP

7. Prediction of fluid responsiveness CVP  CVP does not enable predicting fluid responsiveness ?

8. Stroke volume b' a' b a CVP Ventricular preload Prediction of fluid responsiveness CVP impaired ventricular function effects on SV impaired ventricular function "fluid challenge"  preload

9. A B Prediction of fluid responsiveness respiratory variation of stroke volume

10. Prediction of fluid responsiveness pulse pressure variation

11. limitations Respiratory variation of stroke volume The respiratory variation of hemodynamic signals cannot be used in case of cardiac arrhythmias low Vt

12. limitations Respiratory variation of stroke volume PPmin PPmin PPmax PPmax

13. limitations Respiratory variation of stroke volume PPmax mmHg PPmin 110 90 70 50

14. limitations Respiratory variation of stroke volume The respiratory variation of hemodynamic signals cannot be used in case of cardiac arrhythmias low Vt spontaneous breathing

15. limitations Respiratory variation of stroke volume 100 PPV for predicting a 15% increase in cardiac index 31 patients with spontaneous breathing activity 80 60 sensitivity 40 PPV cannot be used in case of spontaneous breathing activity  20 PPV 0 0 20 40 60 80 100 100 - specificity

16. limitations Respiratory variation of stroke volume PPV for predicting a 15% increase in cardiac index 21 patients with spontaneous breathing activity

17. limitations Respiratory variation of stroke volume PPV for predicting a 15% increase in cardiac index 32 patients with SB

18. limitations Respiratory variation of stroke volume The respiratory variation of hemodynamic signals cannot be used in case of cardiac arrhythmias frequent in the ICU low Vt spontaneous breathing

19. How to predict fluid responsiveness ? cardiac arrhythmias, low Vt, spontaneous breathing ? no yes ? respiratory variation

20. 45° Passive leg raising hemodynamic effects  Blood shift toward the intrathoracic compartment

21. CVP PAOP base PLR base base PLR base Passive leg raising hemodynamic effects  Passive leg raising is enough for increasing right cardiac preload left cardiac preload

22. CVP PAOP base PLR base base PLR base Passive leg raising hemodynamic effects  PLR acts like a ″self volume challenge ″

23. Aortic blood flow (% change from baseline) 70 60 50 40 30 20 10 0 After fluid infusion After fluid infusion During PLR Monnet et al., Crit Care Med, 2006 Passive leg raising prediction of fluid responsiveness ? 76 ICU patients with acute circulatory failure esophageal Doppler monitoring non responders responders

24. Volume expansion PLR Passive leg raising prediction of fluid responsiveness ? ABF

25. Aortic blood flow (% change from baseline) 70 60 50 40 30 20 10 0 After fluid infusion After fluid infusion During PLR During PLR Monnet et al., Crit Care Med, 2006 Passive leg raising prediction of fluid responsiveness ? 76 ICU patients with acute circulatory failure esophageal Doppler monitoring non responders responders

26. * Cut-off 10% Se = 97 % Sp = 94 % Passive leg raising prediction of fluid responsiveness ? PLR-induced changes in ABF % 80 The PLR test allows a reliable prediction of fluid responsiveness  60 40 20 0 -20 NR R -40

27. PLR effects on ABF Passive leg raising prediction of fluid responsiveness ? 100 The PLR test remains reliable in case of SB  80 60 31 patients with spontaneous triggering of the ventilator sensitivity 40 20 PPV 0 0 20 40 60 80 100 100 - specificity

28. How to predict fluid responsiveness ? cardiac arrhythmias, low Vt, spontaneous breathing ? no yes respiratory variation indices PLR PLR

29. Passive leg raising ?  Which monitoring tool for assessing PLR effects

30. Passive leg raising which monitoring tool ? EDM 10 % increase in ABF 10 % increase in ABF 12 % increase in aoVTI echo 12 % increase in aoVTI PiCCO

31. Passive leg raising which monitoring tool ? EDM 10 % increase in ABF 10 % increase in ABF 12 % increase in aoVTI echo 12 % increase in aoVTI 10 % increase in PCCI PiCCO ?  Which method for performing PLR

32. 45° 45° semi-recumbent position PLR position 45° recumbent position PLR position PLR test method importance of the postural change

33. PLR test importance of the postural change 35 patients All responders to PLR % change in cardiac index from baseline 37.5 25 12.5 0

34. PLR test importance of the postural change

35. 35 patients (all responders to fluid administration) 35 responders 20 responders 15 non responders (not correctly classified) PLR test importance of the postural change

37. PLR test limitations PLR-induced changes in PP 80 false negative cases 60 40 * 20  0 PLR test effects cannot be assessed by arterial pressure changes -20 NR R -40

38. PLR test limitations  cannot be assessed with arterial pressure  cannot be used in the OR

39. How to predict fluid responsiveness ? cardiac arrhythmias, low Vt, spontaneous breathing ? no yes respiratory variation indices ? ? PLR PLR

40. Vasalva maneuver ? 30 patients without MV Prediction of a 15% increase in SV with fluid

41. Vasalva maneuver ?

42. Vasalva maneuver ?

43. Vasalva maneuver ? 9 pigs with SB Prediction of a 15% increase in SV with fluid Breathing against an I and/or E 7.5 cmH2O resistance

44.       OAP de sevrage de la ventilation mécanique mécanismes Mise en VS  pression intrathoracique  pression intrathoracique retour veineux systémique  pression transmurale VG  précharge VG  postcharge VG  postcharge cardiaque gauche  travail cardiaque POD OAP  retour veineux systémique

45. A B Tele-expiratory occlusion tele-expiratory occlusion

46. Tele-expiratory occlusion Tele-expiratory occlusion test 34 patients with SB or cardiac arrhythmias

47. Tele-expiratory occlusion test 34 patients with SB or cardiac arrhythmias

48. Tele-expiratory occlusion test Effects of end-expiratory pause on cardiac index Effects of end-expiratory pause on pulse pressure 50 50 40 40 30 30 20 20 increase  5% Se = 91% Sp = 100 % increase  5% Se = 87 % Sp = 100 % 10 10 0 0 -10 -10

49. How to predict fluid responsiveness ? cardiac arrhythmias, low Vt, spontaneous breathing ? no yes respiratory variation indices PLR PLR TEO TEO