Circulatory failure in Intensive Care

1. Circulatory failure in Intensive Care Dr….

2. Circulatory System • Ensures adequate blood flow to supply metabolic demands of the tissues • Regulation via cardiac pump and peripheral vascular system • Pump control varies the cardiac output • PVS control regulates intravascular volume, vascular resistance, perfusion pressure and appropriately distributes flows to vascular beds

3. Circulatory failure = shock ‘Tissue perfusion is inadequate for the metabolic needs of the patient’

4. Inadequate O2 delivery • Inadequate O2 delivery represents an imbalance of delivery relative to need • This imbalance between supply and demand leads to the development of tissue hypoxia • Changes in systemic perfusion are always present in shock

5. Classification of Shock • Cardiogenic • Infarction/ischaemic VSD/myocarditis • Valvular abnormalities/PE/Tamponade • Hypovolaemic • Haemorrhage • Excessive fluid loss from GI/Renal tracts/Burns • Septic • Neurogenic • Anaphylactic

6. Oxygen delivery (DO2) • Amount of O2 delivered to peripheral tissues • Dependent on arterial O2 content and cardiac output • In health this is about 1005ml/min • DO2 is reduced in cardiogenic and hypovolaemic shock (impaired contractility and reduced myocardial preload respectively)

7. Oxygen transport Cardiac output 1.34 SaO2 CO DO2 [Hba] = x x x Arterial oxygen saturation Arterial haemoglobin concentration Oxygen content of 1g fully saturated haemoglobin Arterial Oxygen Content Oxygen Transport

8. Oxygen uptake (VO2) • Amount of O2 taken up by the tissues • It is the difference between DO2 and O2 returned to lung in mixed venous blood • In health this is about 760 ml/min • An oxygen debt occurs when uptake exceeds delivery (as occurs in shock) and severity can be monitored by rising blood lactate (anaerobic metabolism)

9. Septic Shock • Soluble cell bound receptors recognize microbial components or their toxins and stimulate release of pro-inflammatory and anti-inflammatory cytokines, complement, coagulation activation and platelet aggregation. • This results in vasodilatation and reduced intra-vascular volume (due increased vascular permeability) • Despite reduced contractility cardiac output is often increased in septic shock due to reduced afterload

10. Septic Shock • Initially DO2 is elevated in septic shock primarily due to increased CO • However, VO2 is also raised due to increased metabolic activity of the tissues • When VO2 exceeds DO2 a lactic acidosis results • Untreated this leads to multi-organ failure

11. Clinical presentation of septic shock • Hyperdynamic (unless significant hypovolaemia) • Proven source of infection • Hypotension • Signs of systemic inflammation (tachycardia, tachypnoea, hypo/perthermia, leuko-cytosis/paenia) • Confused, tachycardic, tachypnoeic, oliguric • Bounding pulses and warm peripheries

12. Hypovolaemic and cardiogenic shock • Low cardiac output • BP can initially be normal due to compensatory sympathetic and neuro-hormonal mechanisms • Patients will be confused, pale, tachycardic, tachypnoeic, poor perfusion and oliguric • CVP low in HV shock • CVP high in CG shock with associated pulmonary oedema

13. Investigations • Tailor to history and clinical findings. • FBC, Clotting, Electrolytes, Cr, Ur, Clotting, CRP, ABGs, lactate, troponin and blood cultures. • ECG, CXR. • ECHO (ventricular function, wall motion abN, valvular dysfunction, Tamponade, PE (spiral CT and pulmonary angiography)). • DPL, abdo USS, CT (concealed haemorrhage).

14. Management • General measures for all patients with shock. • Specific appropraiate to aetiology.

15. Target areas for treatment • Reduction of metabolic demands • Adequate O2 provision • Normalisation of filling • Manipulation of vasculature with Vasoactive agents • Normalization of SV • Manipulation of pump with Inotropes

16. CAN WE REDUCE DEMAND? DO WE EVER DO IT?

17. Yes! Yes!

18. Management - Respiratory • High flow O2 (improve SaO2 and tissue DO2). • Ventilatory support or mechanical ventilation (reduces VO2 by resp muscles). • Early intubation facilitates invasive haemodynamic monitoring.

19. VO2resp = Oxygen consumed by work of breathing • VO2tot = Total oxygen consumption

20. VO2resp as percentage of VO2tot Intensive Care Med. 1995 Mar;21(3):211-7.

21. So ventilatory support reduces oxygen demands In COPD, PS by mask can reduce this to almost zero

22. Ventilatory support • CPAP: • Recruits alveoli • Improves V/Q • Improves oxygenation • Reduces work of breathing • BIPAP???

23. Adequate sedation reduces oxygen demand Crit Care Med. 2003 Mar;31(3):830-3.

24. 32 post- oesophagectomy/ head and neck malignancies • All buprenorphine -> Midazolam • light • mod • heavy sedation

25. OXYGEN CONSUMPTION ml/min/m2

26. Paralysis reduces muscle oxygen consumption Chest. 1996 Apr;109(4):1038-42.

27. 8 patients • Mean age 63 years • Benzodiazipine + morphine • Then doxacurium paralysis • Mandatory ventilation • O2 consumption measured

28. OXYGEN CONSUMPTION ml/min/m2 25% reduction

29. Cooling reduces oxygen consumption Am J Resp Crit Care Med 1995 Jan;151(1):10-4

30. 12 febrile, critically ill, mechanically ventilated patients • T down from 39.4 +/- 0.8 -> 37.0 +/- 0.50C OXYGEN CONSUMPTION ml/min

31. HOW DO WE IMPROVE DELIVERY?

32. 3 ways • Optimize O2 supplementation to patient • Optimization of Filling • Optimization of SV • Volume • Vasoactive drugs • Inotropes

33. MANAGEMENT OF SHOCK • A: RECOGNISE WHAT TYPE OF SHOCK YOU • ARE DEALING WITH • B: CORRECT THE FILLING STATUS • Empty as a primary cause eg haemorrhage • Empty in sepsis due to increased capacitance • C: ONLY THEN USE VASO-ACTIVE AGENTS: • BETA-1 AGONISTS TO DRIVE THE HEART • ALPHA-1 AGONISTS OR COOLING TO VASOCONSTRICT • GTN OR WARMTH TO VASODILATE

34. Targets? HISTORY • What BP is ‘normal’? CLINICAL • Cerebration • Peripheral perfusion MONITORING • Urine (0.5ml/kg/hr minimum) • ABG (degree of acidosis, trend) AIM FOR INDICES OF ADEQUATE ORGAN PERFUSION, NOT BP

35. What is the type of shock? • Cardiogenic shock – pump failure • ischaemic / trauma / drugs • Hypovolaemic shock • haemorrhage • Low resistance circulatory / distributive shock • drugs / sepsis

36. Bleed Diarrhoea Volume loss PE Fall in filling Tension PTx Tamponade Fall in cardiac contractility Burns FALL IN FLOW

37. Basic Physiology PRESSURE = FLOW X RESISTANCE BLOOD PRESSURE = CARDIAC OUTPUT X RESISTANCE

38. THE RESPONSE IS THE SAME… Efferent activity to Medulla falls Aortic arch and carotid sinus baroreceptors detect a drop in pressure Sympathetic efferents

39. INCREASED SYMPATHETIC ACTIVITY CAUSES • VENOCONSTRICTION • INCREASES FILLING PRESSURE AND SUSTAINS • STROKE VOLUME • POSITIVE INOTROPIC EFFECT • SUSTAINS STROKE VOLUME • TACHYCARDIA • INCREASES CARDIAC OUTPUT • VASOCONSTRICTION • INCREASES RESISTANCE • PRESSURE = FLOW (UP) X RESISTANCE (UP)

40. Management - Fluids • Optimize preload. • Restore circulating volume. • Large vols in HV/septic shock (latter - aim SvO2 >70% / Hb >10g/dl reduce hosp mort by 16%). • Judicious vols in CG shock (PAoP/CI).

41. Under filled Well filled Over filled >3mmHg 20mmHg 3mmHg <3mmHg Filling 200ml COLLOID CHALLENGE Stroke volume PAWP Blood volume Blood volume

42. LVF: Physiology Pulmonary Veins Pulmonary Capillaries LA MV At end-diastole, MV is open, flow has ‘ceased’ SO LVEDP = LAP = PVP = PCP = HYDROSTATIC PCP LV

43. Management - Fluids • CVP surrogate for preload • Oesophageal doppler better measure of filling • Fluid should be used to replace that lost • Aim Hb 7-9 g/dl • Higher mortality if aim Hb 10-12 g/dl.

44. Management - Fluids • Crystalloid vs Colloid….. • Colloids restore circ vol more efficiently, but no worse outcome with crystalloid only • Systematic review colloid use – 4% increase in mortality (esp HAS) • SAFE study • Hypertonic solutions may be useful in pts with cerebral oedema requiring fluid resuscitation and may reduce fluid and Blood Tx requirements.

45. Management - Inotropes • HV shock – rarely needed – fluids alone restore CO and BP • CG shock – fluids not helpful, inotropes needed • Septic shock – fluids needed as well as inotropes • Both require vasoactive drugs to improve tissue perfusion and reverse tissue hypoxia.

46. Inotropic support RV SV (ml) LV 60 5 10 Filling pressure (mmHg)

47. Management - Inotropes • CG shock – (low CO/BP and elevated SVR). • Inodilator (Dobutamine/Milrinone) if BP not too low. • Inodilator plus inoconstrictor (Adrenaline/Dopamine) or vasopressor (NorAdr) if BP compromised. • Adr S/E – hyperglycaemia/hypokalaemia/hyperlactataemia (interpret Lactate levels with caution).

48. Management - Inotropes • Septic shock – (high CO low BP from peripheral vasodilatation). • Firstly optimize preload. • Then use vasopressor (NorAdr) • If CO is reduced consider adding Dobutamine. • Dopamine (inoconstrictor) could be used but associated with adverse effects on pituitary (reduced prolactin/GH/TRH), T-cell function, gut mucosa perfusion and renal medullary VO2.

49. Doses • Dobutamine (5-20µg/kg/min) • adjust by 2.5µg/kg/min increments • Adrenaline (start at 0.05µg/kg/min) • adjust by 0.02µg/kg/min increment • GTN to lower resistance

50. Hypovolaemic shock • In case of haemorrhagic shock – stop the bleeding (surgery/radiology/endoscopy) • Fluid resuscitation • Correct hypovolaemia/hypoxia/anaemia and increase DO2 prior to surgery to reduce peri-operative mortality