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Cerebral Pharmacology and Anesthesia for Supratentorial Craniotomy

Cerebral Pharmacology and Anesthesia for Supratentorial Craniotomy. Mani K.C Vindhya M.D Asst Prof of Anesthesiology Nova Southeastern University. Introduction to Cerebral Pharmacology. In addition to anesthetic agents and neuromuscular junction blockers, don ’ t forget:

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Cerebral Pharmacology and Anesthesia for Supratentorial Craniotomy

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  1. Cerebral Pharmacologyand Anesthesia for Supratentorial Craniotomy Mani K.C Vindhya M.D Asst Prof of Anesthesiology Nova Southeastern University

  2. Introduction to Cerebral Pharmacology. In addition to anesthetic agents andneuromuscular junction blockers, don’t forget: • Drugs to decrease brain interstitial fluid • Dexamethasone (edema around solid brain tumors) • Mannitol and hypertonic saline (osmotic diuretics) • Furosemide (loop diuretic) • Antibiotics – usually two for intracranial neuroanesthesia • Nafcillin or oxacillin (or vancomycin, if penicillin allergic) • Gentamicin

  3. Qualities of an Ideal Neuroanesthetic • Maintenance of mean arterial pressure and cerebral perfusion pressure • Decrease in intracranial pressure (ICP) • Decrease in cerebral metabolic rate coupled with decrease in cerebral blood flow • Decrease in CSF volume (production < reabsorption) • No inhibition of cerebral autoregulation • No expansion of closed air spaces • Rapid emergence • Anticonvulsant • Lack of toxicity to major organ systems • Cerebroprotective (or at least not harmful) • Compatibility with neuromonitoring (such as SSEP’s)

  4. Maintenance of Mean Arterial Pressure and Cerebral Perfusion Pressure CPP = MAP - ICP (or CVP, whichever is greater)

  5. Decrease in ICP and Cerebral Blood Flow • All inhaled anesthetics (in high concentrations) increase CBF. • All IV anesthetics (except ketamine) decrease CBF.

  6. The volatile agents have a biphasic effect on CBF in normal subjects

  7. Effects of volatile agents on CBF and CMR in normal subjects (coupling intact): CMR CBF

  8. Effects of volatile agents on CBF if coupling is impaired or if CMR is already suppressed: CBF CMR

  9. Decrease in Cerebral Metabolic Rate (CMRO2) coupled with decrease in Cerebral Blood Flow (CBF) • Decrease in Cerebral Metabolic Rate (CMRO2) • IV anesthetics – coupled with decreased CBF (metabolic effect) • Volatile inhaled anesthetics - “uncoupling” of CBF from CMRO2 in high concentrations • Only 2 anesthetics increase CMRO2 (coupled with an increase in CBF): • Ketamine • Nitrous oxide (N2O)

  10. Effects of Dexmedetomidine on CBF and CMR • Dexmedetomidine decreases CBF and CBF velocity in humans. • Dexmedetomidine did not reduce CMR in an animal model. • A 2008 study showed that dexmedetomidine decreases both • CBF velocity and CMR in humans

  11. Decrease in CSF Production Relative to Reabsorption. • A decrease in CSF volume would tend to decrease intracranial volume and ICP. • Effects of anesthetics on CSF secretion and absorption

  12. No Inhibition of Cerebral Autoregulation • Autoregulation is intact with IV agents (i.e. thiopental, propofol, fentanyl) • In high concentrations, all volatile inhaled anesthetics impair autoregulation

  13. No Expansion of Closed Air Spaces • N2O = the only anesthetic that expands closed air spaces • Intracranial air pockets • Pneumocephalus • Air emboli (venous or arterial) • Teaching Points: • Don’t turn on N2O at the end of case (but perhaps O.K. to leave it on during case). • Don’t use in patients after recent craniotomy (i.e., air pockets on CT scan).

  14. . Rapid Emergence from Anesthesia (Lower Blood:Gas Solubility)

  15. Anticonvulsant Activity = desirable property

  16. Numerous case reports of convulsion-like muscle activity during induction and emergence from anesthesia with: • Sevoflurane • Enflurane • Etomidate • Propofol • To prevent peri-operative drug-induced seizures in epileptic patients • Continue anticonvulsant therapy. • Consult with the patient’s neurologist to discuss management. • Avoid etomidate. • Do not use sevoflurane routinely in epileptic patients. • Limit maximum concentration to < 1.5 MAC.

  17. Lack of toxicity to major organ systems • 1. All of the volatile inhaled anesthetics can form toxic metabolites in CO2 absorbents (baralime > soda lime). • A = compound A (vinyl compound produced by sevoflurane) • B = BCDFE (vinyl compound produced by halothane) • C = carbon monoxide (formed by pungent volatile anesthetics in the following rank order) • D = desflurane > E = enflurane >F = Forane R (isoflurane) • Many anesthetics are associated with potential organ toxicity: • Sevoflurane – renal toxicity might be caused by: compound A from CO2 absorbents • fluoride ion from hepatic metabolism • Halothane > enflurane > isoflurane > desflurane • Hepatotoxicity in proportion to hepatic metabolism • Nitrous oxide – bone marrow toxicity • Etomidate • Adrenocortical suppression • Propylene glycol toxicity caused by diluent

  18. Cerebroprotective (or at least not harmful) • Thiopental = the “gold standard” for cerebral protection at the present time (i.e., during clipping of an intracranial aneurysm) • Three agents may be harmful so far as cerebral protection is concerned: • Ketamine • Nitrous oxide • Etomidate • Compatibility with Neuromonitoring (such as somatosensory evokedpotentials)

  19. Three kinds of evoked potentials:

  20. Effect of isoflurane on upper extremity SSEPs • Summary of effects of anesthetics on SSEPs: • Inhaled anesthetics – dose-related decrease in amplitude and • increase in latency • Less than 1 MAC volatile agent • Nitrous oxide – profound depressant effect on SSEPs, • especially when used in combination with volatile agent

  21. Intravenous agents: • Propofol and thiopental – small decrease in amplitude • and increase in latency. Propofol is commonly used for TIVA (total IV anesthetic) technique. • Opioids – negligible effect on SSEP’s • Ketamine and etomidate – increase SSEP amplitude. • (Etomidate is exceptional. It increases SSEP amplitude but decreases BAEP amplitude). • Summary. Six I’s that inhibit SSEP’s: • Inhaled anesthetics (isoflurane and nitrous oxide) • IV anesthetics (to a lesser extent than inhaled anesthetics). • Ketamine and etomidate are the exceptions; they increase amplitude. • Ischemia or hypoxia – anywhere from limb to cortex • Injury – anywhere from limb to cortex • Ice cold temperatures – < 34.5 oC “Incompetence”

  22. I.V. Induction of Anesthesia for Intracranial Neurosurgery • Typical induction agents • Thiopental, propofol, or etomidate =suitable I.V. induction agents • Fentanyl or sufentanil – as narcotic analgesics to supplement • Lidocaine IV – to blunt hypertensive and ICP response to intubation • Neuromuscular junction blockers – rocuronium, vecuronium, or succinylcholine (with prior defasciculating dose of a competitive NMJB)

  23. Succinylcholine for intracranial neurosurgery • 1. Increased CBF and ICP in dogs • 2. Succinylcholine has been postulated to increase ICP by causing muscle afferent activity and stimulation of muscle spindle fibers (innervated by A-gamma fibers).

  24. A more recent study in patients with neurologic injury showed that succinylcholine did not change ICP, CBF velocity, or EEG activity. • The increase in ICP induced by succinylcholine can be blocked with a defasciculating dose of NMJ blocker

  25. Teaching points: • Don’t use succinylcholine if it’s contraindicated (i.e., hemiplegia). • If OK, use succinylcholine if you’re at all worried about the airway. • Use a defasciculating dose of a competitive neuromuscular junction blocker if you plan to use succinylcholine

  26. Maintenance of Anesthesia: How do the anesthetics stack up? • Some agents we just don’t use: • Ketamine • Only cerebrovasodilating IV agent • Increases CSF volume • May cause neuronal damage due to its action on glutamate (N-methyl-D-aspartate, NMDA) receptors • Halothane • Most cerebrovasodilating inhaled agent (cortical CBF) • Hepatotoxicity limits use in adults • Enflurane – no longer in our O.R. • Second most cerebrovasodilating inhaled agent, after halothane • Increases CSF volume • Epileptogenic (esp. with hypocarbia)

  27. Isoflurane, Sevoflurane, & Desflurane • Bad Points: • Decrease MAP (high concentrations) • Increase CBF and ICP (high conc’s) • Decrease CPP (high concentrations) • Inhibit autoregulation (> 1% isoflurane) • Good Points: • Decrease CMRO2 • No expansion of closed air spaces • Easily titratable • Desflurane • Bad Points: • Decreases MAP (so former PDR’s prohibited its use in intracranial neurosurgery) • Maximum of 0.8 MAC recommended in current PDR • Increased lumbar CSF pressure in one study but not in another more recent study in the setting of hyperventilation. • ! Carbon monoxide (CO) production in CO2 absorbent is a concern. • Coughing and bucking on emergence • Very Good Point: • Rapid emergence (allows for rapid wake-up at end of case)

  28. Sevoflurane • Bad Points: • EEG seizure activity has led to recommendation that sevoflurane not be used routinely in epileptics • Possible nephrotoxicity is a concern: • Fluoride ion production from hepatic metabolism • Compound A production from CO2 absorbent • Should not use for > 10 MAC hours (i.e., long neuro cases) • Good Points: • Rapid emergence (perhaps use at end of case) • Pleasant odor (less coughing and bucking?) • Favorable regarding CBF and autoregulation

  29. Nitrous Oxide • Bad points: • Increases CBF more than isoflurane on a MAC to MAC basis • Increases CMRO2 (only I.A. that does) • Expands closed air spaces (only I.A. that does) • Tends to cause nausea and vomiting • May cause neuronal damage due to its action on glutamate (N-methyl-D-aspartate, NMDA) receptors • Good Points: • MAP is maintained. • Rapid emergence • Easily titratable • Many neuroanesthesiologists routinely used it in the past • ! No difference in outcome of elective supratentorial craniotomy

  30. Propofol • Good Points: • Decreases CBF • Decreases CMRO2 • Autoregulation is preserved. • Apparent antiemetic action • Bad Points: • Decreases MAP • May have delayed emergence relative to inhalational techniques

  31. Anesthetic Opioids (Fentanyl, sufentanil, alfentanyl, remifentanyl) • Good Points: • Little change in CBF • Less decrease in MAP • Little change in CBF • Autoregulation is preserved. • Bad Points: • Nausea and vomiting = a frequent S.E. • Fentanyl was thought to be better than sufentanil or alfentanyl, based on their effects on MAP and CPP • Sufentanil does not increase ICP in patients with brain injury so long as MAP is maintained

  32. Remifentanyl • Good Point: A logical choice for rapid emergence • Bad Points: • Severe hypertension on emergence (recommended to give MSO4 prior to DC’ing remifentanyl) • ? High incidence of post-op nausea and vomiting

  33. Anesthetic Management of Intracranial Neurosurgical Cases • Reasonable Maintenance Regimens for Intracranial Neuroanesthesia • (going from routine to desperate). • N2O + isoflurane (½%) + fentanyl • N2O = the first agent to go if there’s brain swelling or venous air emboli or ischemia danger (i.e. aneurysm or head trauma) • MAC equivalents of sevoflurane or desflurane might also be substituted for isoflurane. • Sufentanil could be substituted for fentanyl. • Isoflurane (1%) + fentanyl • Isoflurane (½%) + propofol + fentanyl • Volatile agents are next to go if intractable ICP or brain swelling • Total IV anesthetic: Propofol + fentanyl • Barbiturate coma -- for intractible brain swelling or cerebral protection during aneurysm clipping (titrated to EEG burst suppression): • Thiopental • Pentobarbital

  34. Reasonable Muscle Relaxants for Maintenance of NM Blockade • Vecuronium • Rocuronium • Pancuronium – increases HR • Cis-atracurium: • No histamine release (different from atracurium) • An epileptogenic metabolite, laudanosine

  35. Special Cases in Neuroanesthesia • The ways to decrease intracranial volume and pressure apply in typicalintracranial neuroanesthetic cases (i.e., supratentorial craniotomies).

  36. Transphenoidal Hypophysectomy = an exception. For resection of tumorconfined to pituitary: • No furosemide or mannitol • Dexamethasone (solid brain tumor) • Spinal drain (to put air or NSS in, not to take CSF out) • No hyperventilation

  37. Quirk of Anesthesia after Recent Craniotomy • Avoid N2O if air is inside skull on CT scan • Quirks of Head Trauma (ABC’s of TBI) • Airway. Safely get control. • Blood pressure. Avoid hypotension (SBP < 90 mm Hg) if possible, or correct it immediately. • CO2. Don’t routinely hyperventilate, only if necessary for “swollen” brain. • Diuretics or Dexamethasone? • Usually do give diuretics, particularly mannitol • Usually don’t give dexamethasone or steroids • Early decompressive craniectomy or temporal lobe decompression might be necessary in dire circumstances. • Fluids. Avoid hypovolemia. • Glucose. Treat hyperglycemia. • Hypothermia was “hot,” but now it’s not. Avoid hyperthermia. • IV and Inhaled Anesthetics

  38. Ruptured intracranial aneurysm or arteriovenous malformation (AVM) • Prevent sudden increases or decreases in MAP that predispose the aneurysm to rupture • Hyperventilation may depend on Hunt-Hess Grade: • Grade 0 – hyperventilation O.K. • Grades 1-2 – normocarbia or modest hypocarbia (paCO2 = 35) to prevent vasospasm • Grades 3-5 – hyperventilation may be necessary anyway • EEG monitoring if barbiturate coma is needed during temporary clipping. • Moderate induced hypothermia? The results of the completed IHAST trial indicate no better outcome with hypothermia (33.5 oC) than normothermia (36.5 oC) Induced hypotension might be requested if aneurysm ruptures. • Infratentorial (posterior fossa) surgery is unique in that it can be done indifferent positions – sitting, lateral decubitus, or prone.

  39. Thank you

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