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INDUCED HYPOTENSION

INDUCED HYPOTENSION. Dr. Emeni Ophrii. University College of Medical Sciences & GTB Hospital, Delhi. Induced Hypotension Definition and objectives Historical background Purpose Indications Techniques with physiological basis, drugs Contraindications Limitations

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INDUCED HYPOTENSION

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  1. INDUCED HYPOTENSION Dr. EmeniOphrii University College of Medical Sciences & GTB Hospital, Delhi

  2. Induced Hypotension Definition and objectives Historical background Purpose Indications Techniques with physiological basis, drugs Contraindications Limitations Post-operative care Specific applications Current status

  3. Definition • A technique that lowers blood pressure (BP) to reduce blood loss and the need for transfusion during surgery and to improve the quality of surgical field • Also known as deliberate hypotension / controlled hypotension / hypotensive anaesthesia

  4. Objectives • Fall in systolic BP to 80-90 mmHg • Fall in mean arterial pressure(MAP) to 50-65 mmHg • Fall in 30% of MAP in hypertensive patients In majority of cases, optimum operating conditions are the goal, not a specific pressure → good communication between anaesthetist and surgeon is essential

  5. Historical background Harvey Cushing proposed in 1917 Gardner practised first in 1946 Griffith and Gillies used high spinal analgesia Enderby used ganglionic blockers Trimetaphan Sodium nitroprusside(SNP)-1962 Halothane β-adrenergic blockers Nitroglycerine and labetalol-1970

  6. Purpose Reduction in blood loss Haemodynamic and metabolic stability Lesstransfusion requirements Less infection transmission Improvement of surgical field Improved visualization → better and faster surgery Facilitation of vascular surgery Prevention of progressive stretching of thin walls of vessels → easier suturing and clipping (aortic surgery, AVM, intracranial aneurysm clipping )

  7. Indications Neurosurgery (AVM, intracranial aneurysm, vascular tumours, trans-sphenoidalhypophysectomy) Major orthopaedic surgery (spinal surgery, shoulder/hip arthroplasty) ENT surgery (middle ear surgery) Head and neck (faciomaxillarytumours, block dissection of neck, laryngectomy)

  8. Indications… • Ophthalmic surgery (intraocular tumours, vitrectomy, orbital surgery) • Pelvic (Major gynaecological or rectal surgery) • Plastic and reconstructive surgery • Jehovah’s witness

  9. Techniques Physical measures a) Postural manoeuvers - keeping operated area higher than heart Risk: Air embolism b) Artificial ventilation - lowers BP secondary to decreased venous return Pharmacological agents

  10. Effects of posture on local blood pressure

  11. Pharmacological agents Characteristics of an ideal agent Easy to administer Short onset time Effect should disappear quickly on discontinuation Rapid elimination No toxic metabolites Negligible effects on vital organs Predictable effect Dose dependent effect No ideal hypotensive pharmacological agent exists

  12. Classification Used alone • Inhalational anaesthetics • Sodium nitroprusside • Nitroglycerine • Trimetaphan • Prostaglandin E1 (Alprostadil) • Adenosine • Remifentanil • Spinal/epi anaesthesia Alone or as adjunct • Calcium channel blockers(nicardipine) • β-blockers (propanolol,esmolol) • Fenoldopam As adjunct only • ACE inhibitors • Clonidine

  13. Principle of Induced Hypotension BP = Cardiac Output (CO) x Peripheral Vascular Resistance (PVR) CO = HR x SV PVR α 1/r4 Reduction in CO should be avoided as organ perfusion may be compromised Induce a low pressure, vasodilated circulation

  14. Physiological effects of induced hypotension Marked physiological response designed to restore BP back to within normal range Central neuronal reflexes • Arterial baroreceptors • Cardiopulmonary receptors Hormonal changes • Renin-angiotensin system • Catecholamines

  15. Physiological effects... Reflex rise in HR, myocardial contractility, vasomotor tone → Low pressure, hyperdynamic circulation • May result in increasing vasodilator doses • May require use of adjuncts

  16. Anaesthetic Agents

  17. Vasodilators

  18. Autonomic nervous system inhibitors

  19. ACE inhibitors

  20. Cyanide Toxicity - Mechanism

  21. Cyanide toxicity - Manifestations Resistance to high infusion rates of SNP Metabolic acidosis, raised lactate levels Elevated venous oxygen saturation Progressive hypotension unresponsive to fluids & vasopressors but responsive to thiosulphate Cardiovascular collapse No specific laboratory test but lethal cyanide level in blood is approx 500 μg/dl

  22. Cyanide toxicity - Management Sodium thiosulphate Bolus injection - 30mg/kg Continuous infusion - 60mg/kg/hr Hydroxocobalamine (B12) Prevents ↑ in CN conc. in erythrocytes Bolus - 50mg/kg Infusion - 100mg/kg/hr Fluid replacement Acidosis correction

  23. Monitoring during induced hypotension • ECG – myocardial perfusion, drug effects • Accurate BP monitoring Gold standard is direct intra-arterial measurement • Capnography – disconnection alarm, indicator of air embolism Value as an index of PaCO2 is limited due to ↑dead space • Pulse oximetry – allows adjustment of FiO2 to compensate for V/Q mismatch • EEG/evoked potential – reserved for neurosurgery, CPB, severe hypotension • Transcranialdopplervelocimetry

  24. Safe conduct of induced hypotension Onset & degree of hypotension A reliable intravenous line Horizontal position Monitoring Initiate only after intubation & steady anaes state Hypotension to be induced slowly over 10-15 min Proper posture and optimal venous drainage Adequate fluids but prevent overhydration

  25. Safe conduct… Maintenance of near normal PaCO2 & acid base balance • Hypocapnia – vasoconstriction • Alter blood PH • Increase oxygen consumption • Inhibit hypoxic pulmonary vasoconstriction

  26. Safe conduct… Oxygenation • Increased intrapulmonary shunt • Decreased cardiac output A high FiO2 (0.4-0.5 or higher) during induced hypotension is recommended

  27. Contraindications Inexperience Infants Pregnancy Fixed cardiac output Coronary artery, renal, cerebral disease Hypovolemia Severe anaemia

  28. Limitation Risk of tissue hypoxia by reducing microcirculatory autoregulation of vital organs and by inhibiting ANS The goal is to maintain a pressure sufficiently low to allow reduction of bleeding without suppressing microcirculatory autoregulation of vital organs

  29. Complications Coronary artery thrombosis Cerebral thrombosis Cardiac arrest Temporary & permanent neurologic deficit Failure of technique Resistance & rebound Post-operative reactionary haemorrhage Tissue trauma

  30. Post-operative care Maintenance of airway Provision of supplemental oxygen Analgesia Warm environment Respiratory & cardiovascular monitoring Adequacy of blood volume Positioning

  31. Specific applications • Neurosurgery - Cerebral aneurysm surgery • Spinal surgery- scoliosis correction • Ophthalmic surgery • ENT surgery • Pregnancy

  32. Cerebral aneurysm surgery Low pressure circulation Reduces blood loss → improves visualisation Reduces aneurysm transmural pressure Safe application of clip Reduces risk of intra-operative rupture If aneurysm ruptures → less bleeding, rapid identification & control of bleeding point Vasodilators started after opening dura to avoid ↑in ICP Avoid the technique in presence of preoperative vasospasm and if a feeding artery is to be temporarily clipped

  33. Scoliosis surgery General anaesthesia Monitoring of spinal cord function using wake-up test or somatosensory evoked potential Blood loss is massive → BP to be reduced slowly (preferably under SSEP monitoring) and only to the point at which operating conditions become satisfactory

  34. Ophthalmic surgery Uveal dissection - prevention of bleeding into vitreous Choroidal melanoma - requires period of choroidalischaemia ENT surgery High level of difficulty and impossibility of controlling bleeding by using clamps on afferent vessels, vertebral-basilar artery and external carotid artery makes induced hypotension a choice in ENT surgery

  35. Pregnancy • ↓BP →↓ uterine blood flow → fetal asphyxia • Hypotension not to be induced unless considered as life saving measure. • Nitroglycerine - least toxic • Close fetal heart rate monitoring mandatory – serves as a guide to safe level for hypotension and hyperventilation

  36. Current status Surgeries with low/moderate bleeding potential e.g. middle ear, eye, neurosurgery Induced hypotension used in light of benefit/risk ratio Surgeries with moderate bleeding potential e.g. vascular, major orthopaedic surgery Benefit from combination of hemodilution with autologous transfusion with induced hypotension Surgeries with high bleeding potential e.g. cardiac surgery/liver transplantation Use of induced hypotension has decreased

  37. Current status… The best efficacy combined with ease of use and lack of toxicity belongs to techniques of hypotensive anaesthesia that associate analgesia and hypotension at clinical concentration • Epidural anaesthesia – not always practical • Remifentanil along with propofol or inhalational agents at clinical concentration are preferred techniques because of their safety and ease of use

  38. References Wylie and Churchill Davidson’s ‘A Practice of Anaesthesia’ 6th edition Wylie and Churchill Davidson’s ‘A Practice of Anaesthesia’ 7th edition Miller’s Anesthesia 5th edition International Practice of Anaesthesia by Prys-Roberts and Brown Degoute CS. Controlled hypotension. Drugs 2007; 67(7): 1053-1076

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