Cerebral Physiology and the Effects of Anesthetic Drugs

Functional state

CMR decreases during sleep and increases during sensory stimulation, mental tasks, or arousal of any cause. During epileptic activity, increases in the CMR may be extreme, whereas regionally, after brain injury and globally with coma, the CMR may be substantially reduced.

Anesthetic drugs

The effect of individual anesthetic drugs on the CMR is presented in greater detail in the second section of this chapter. In general, anesthetic drugs suppress the CMR, with the exception of ketamine and nitrous oxide (N ₂ O). The component of the CMR on which they act is electrophysiologic function. With several anesthetics, including barbiturates, isoflurane, sevoflurane, desflurane, propofol, and etomidate, increasing plasma concentrations cause progressive suppression of EEG activity and a concomitant reduction in the CMR. However, increasing the plasma level beyond what is required to first achieve suppression of the EEG results in no further depression of the CMR. The component of the CMR required for the maintenance of cellular integrity, the “housekeeping” component, is unaltered by anesthetic drugs (see Fig. 11.2 ).

When the complete suppression of EEG is achieved, the cerebral metabolic rate of oxygen (CMRO ₂ ) is similar irrespective of the anesthetic agent used to achieve EEG suppression. Yet anesthetic-induced EEG suppression is not a single physiologic state and is influenced by the drug used to produce suppression. When barbiturates are administered to the point of EEG suppression, a uniform depression in the CBF and CMR occurs throughout the brain. When suppression occurs during the administration of isoflurane and sevoflurane, the relative reductions in the CMR and CBF are more intense in the neocortex than in other portions of the cerebrum. Electrophysiologic responsiveness also varies. Cortical somatosensory evoked responses to median nerve stimulation can be readily recorded at doses of thiopental far in excess of those required to cause complete suppression of the EEG but are difficult to elicit at concentrations of isoflurane associated with a burst-suppression pattern (∼1.5 minimum alveolar concentration [MAC]). In addition, the EEG characteristics of the burst-suppression states that occur just before complete suppression differ among anesthetic drugs. These differences may be of some relevance to discussions of differences in the neuroprotective potential of drugs that can produce EEG suppression.

Temperature

The effects of hypothermia on the brain have been reviewed in detail. The CMR decreases by 6% to 7% per degree Celsius of temperature reduction. In addition to anesthetic drugs, hypothermia can also cause complete suppression of the EEG (at approximately 18°C-20°C). However, in contrast to anesthetic drugs, temperature reduction beyond that at which EEG suppression first occurs does produce a further decrease in the CMR ( Fig. 11.5 ). This decrease occurs because anesthetic drugs reduce only the component of the CMR associated with neuronal function, whereas hypothermia decreases the rate of energy utilization associated with both electrophysiologic function and the basal component related to the maintenance of cellular integrity. Mild hypothermia preferentially suppresses the basal component of the CMR. The CMRO ₂ at 18°C is less than 10% of normothermic control values, which may explain the brain’s tolerance for moderate periods of circulatory arrest at these and colder temperatures.

Hyperthermia has an opposite influence on cerebral physiologic function. Between 37°C and 42°C, CBF and CMR increase. However, above 42°C, a dramatic reduction in cerebral oxygen consumption occurs, an indication of a threshold for a toxic effect of hyperthermia that may occur as a result of protein (enzyme) denaturation.

PaCO ₂

CBF varies directly with Pa co ₂ ( Fig. 11.6 A ), especially within the range of physiologic variation of Pa co ₂ . CBF changes 1 to 2 mL/100 g/min for each 1 mm Hg change in Pa co ₂ around normal Pa co ₂ values. This response is attenuated at a Pa co ₂ less than 25 mm Hg. Under normal circumstances, the sensitivity of CBF to changes in Pa co ₂ (ΔCBF/ΔPa co ₂ ) is positively correlated with resting levels of CBF. Accordingly, anesthetic drugs that alter resting CBF cause changes in the response of the cerebral circulation to CO ₂ . The magnitude of the reduction in CBF caused by hypocapnia is more intense when resting CBF is increased (as might occur during anesthesia with volatile agents). Conversely, when resting CBF is reduced, the magnitude of the hypocapnia-induced reduction in CBF is decreased slightly. It should be noted that CO ₂ responsiveness has been observed in normal brain during anesthesia with all the anesthetic drugs that have been studied.

The role of MAP in the CO ₂ responsiveness of the cerebral circulation is further highlighted by the impact of modest and severe hypotension. With the former, the increase in CBF attendant upon hypercarbia is significantly reduced, whereas hypocapnia-induced vasoconstriction is only modestly affected. When hypotension is severe, a cerebrovascular response to changes in Pa co ₂ is not observed ( Fig. 11.6 A ). The level of Pa co ₂ also modulates cerebral autoregulation. With hypercarbia, cerebral autoregulatory response to hypertension is attenuated. By contrast, with the induction of hypocapnia, CBF is autoregulated over a wider MAP range ( Fig 11.6 B ).

The changes in CBF caused by Pa co ₂ are dependent on pH alterations in the extracellular fluid of the brain. NO, in particular NO of neuronal origin, is an important although not exclusive mediator of CO ₂ -induced vasodilation. The vasodilatory response to hypercapnia is also mediated in part by prostaglandins. The changes in extracellular pH and CBF rapidly occur after Pa co ₂ adjustments because CO ₂ freely diffuses across the cerebrovascular endothelium and the BBB. In contrast with respiratory acidosis, acute systemic metabolic acidosis has little immediate effect on CBF because the BBB excludes H ⁺ from the perivascular space. The CBF changes in response to alterations in Pa co ₂ rapidly occur, but they are not sustained. Despite the maintenance of an increased arterial pH, CBF returns toward normal over a period of 6 to 8 hours because the pH of CSF gradually returns to normal levels as a result of extrusion of bicarbonate (see Fig. 57.6). Consequently, a patient who has had a sustained period of hyperventilation or hypoventilation deserves special consideration. Acute restoration of a normal Pa co ₂ value will result in a significant CSF acidosis (after hypocapnia) or alkalosis (after hypercapnia). The former results in increased CBF with a concomitant increase in ICP that depends on the prevailing intracranial compliance. The latter conveys a theoretic risk for ischemia.

PaO ₂

Changes in Pa o ₂ from 60 to more than 300 mm Hg have little influence on CBF. A reduction in Pa o ₂ below 60 mm Hg rapidly increases CBF ( Fig. 11.7 A ). Below a Pa o ₂ of 60 mm Hg, there is a rapid reduction in oxyhemoglobin saturation. The relationship between oxyhemoglobin saturation, as evaluated by pulse oximetry, and CBF is inversely linear (see Fig. 11.7 B ). The mechanisms mediating cerebral vasodilation during hypoxia may include neurogenic effects initiated by peripheral and neuraxial chemoreceptors, as well as local humoral influences. A reduction in arterial oxygen content, and therefore cerebral oxygen delivery, can be achieved either by a reduction in Pa o ₂ (hypoxemic hypoxia) or by a reduction in hemoglobin concentration (anemia, hemodilution). Both hemodilution and hypoxemic hypoxia lead to cerebral vasodilation and an increase in CBF. Of the two variables, however, hypoxemic hypoxia is a far more potent variable in CBF augmentation than hemodilution. Cerebral oxygen delivery is better maintained during hypoxia when arterial content is equivalently reduced by hypoxia or hemodilution (see Fig. 11.7 C ). Deoxyhemoglobin plays a central role in hypoxia-induced increases in CBF by causing the release of NO and its metabolites, as well as ATP. Hypoxia-induced opening of ATP-dependent K ⁺ channels in vascular smooth muscle leads to hyperpolarization and vasodilation. The rostral ventrolateral medulla (RVLM) serves as an oxygen sensor within the brain. Stimulation of the RVM by hypoxia results in an increase in CBF (but not CMR), and lesions of the RVLM suppress the magnitude of the CBF response to hypoxia. The response to hypoxia is synergistic with the hyperemia produced by hypercapnia and acidosis. At high Pa o ₂ values, CBF modestly decreases. At 1 atmosphere of oxygen, CBF is reduced by approximately 12%.

α ₁ -Agonists

Will the administration of α ₁ -agonists (phenylephrine, norepinephrine) reduce CBF?

Studies in humans and nonhuman primates do not confirm this concern. Intracarotid infusions of norepinephrine in doses that significantly increase the MAP result in no change in CBF. Norepinephrine can increase CBF, but such increases might occur if autoregulation were defective or its limit exceeded. β-Mimetic drugs (norepinephrine has β ₁ activity) may cause activation of cerebral metabolism with a coupled increase in CBF. This effect is more apparent when these drugs can gain greater access to the brain parenchyma via a defective BBB (see Table 11.2 ). Administration of phenylephrine to patients undergoing cardiopulmonary bypass does not decrease CBF. In spinal cord–injured patients with relative hypotension, the administration of the α ₁ -agonist midodrine increased perfusion pressure and increased flow velocity in the middle cerebral artery (MCA) and the posterior cerebral artery. In healthy patients, and in those undergoing surgery in the beach chair position, the administration of phenylephrine maintains or augments MCAfv. Collectively, these data suggest that norepinephrine and phenylephrine maintain cerebral perfusion.

The traditional view that CBF can be maintained by the administration of α ₁ -agonists without any adverse effect on cerebral oxygenation has been challenged. In anesthetized patients, phenylephrine administration by bolus modestly reduced regional cerebral oxygen saturation (rSO ₂ ), measured by near-infrared oximetry. Ephedrine, although increasing arterial blood pressure to a similar extent as phenylephrine, did not reduce rSO ₂ , presumably because of its ability to maintain cardiac output. In human volunteers, a norepinephrine-induced increase in arterial blood pressure slightly reduced MCAfv and cerebral oxygen saturation (S co ₂ ) and SjV o ₂ . By contrast, although phenylephrine decreased rSO ₂ , MCAfv was increased and SjV o ₂ was unchanged. These data have led to the question of whether phenylephrine and norepinephrine administration negatively impact cerebral oxygenation. Several factors argue against this possibility. The first concern is methodology. Near-infrared spectroscopy (NIRS) measures oxygenated and deoxygenated blood in a defined region of brain and is a composite of arterial, capillary, and venous blood. Vasopressors affect both arterial and venous tone. Even a minor change in the volume of arterial and venous volumes within the region of the brain can affect the rSO ₂ measurement. Moreover, extracranial contamination is a significant component of the rSO ₂ values reported by the currently available NIRS monitors. This contamination is more important than the slight reduction in S co ₂ observed in these investigations. In the absence of direct measurement of brain tissue oxygenation, a modest reduction in S co ₂ in the face of increasing arterial blood pressure cannot be taken as evidence of impairment of cerebral oxygenation. In addition, phenylephrine did not decrease SjV o ₂ , a more global measurement of cerebral oxygenation. Although norepinephrine decreased SjV o ₂ by approximately 3% (a mild reduction at best), its administration has been previously shown to increase the CMRO ₂ . Finally, the minor reduction in rSO ₂ effected by phenylephrine is no longer apparent when an increase in the CMRO ₂ is concurrent. Phenylephrine apparently does not prevent an increase in CBF when such an increase is warranted by increased brain metabolism.

These studies were conducted in patients with a normal central nervous system (CNS). Although unlikely, the concern is that α ₁ -agonists might reduce cerebral perfusion in the injured brain. In patients with a head injury, the administration of phenylephrine increased CPP and did not reduce regional CBF. Transient changes may occur in CBF and rSO ₂ (on the order of 2-5 minutes) in response to bolus doses of phenylephrine; however, with a continuous infusion, α ₁ -agonists have little direct influence on CBF and cerebral oxygenation in humans. Thus maintenance of CPP with these vasopressors does not have an adverse effect on the brain.

α ₂ -Agonists

α ₂ -Agonists have both analgesic and sedative effects. This class of drugs includes dexmedetomidine and clonidine, with the latter being a significantly less specific and less potent α ₂ -agonist. Two investigations in human volunteers have confirmed the ability of dexmedetomidine to decrease CBF. Dexmedetomidine dose-dependently decreased MCAfv, with the maximum reduction being approximately 25%. Dexmedetomidine (1 μg/kg loading dose and infusion at either 0.2 or 0.6 μg/kg/hr) decreased CBF by approximately 30% in healthy human volunteers. In both these investigations, the CMR was not measured; whether the reduction in CBF was due to a direct vasoconstrictor activity of dexmedetomidine or to suppression of the CMR with a corresponding reduction in CBF is not clear. In a more recent study of dexmedetomidine during which both MCAfv and the CMR were measured in healthy humans, dexmedetomidine decreased MCAfv in parallel with a reduction in the CMR. Similarly, in healthy patients and those with traumatic brain injury undergoing sedation with dexmedetomidine, the reduction in CBF was matched by a parallel reduction in CMR. Thus the effects of dexmedetomidine on CBF were primarily mediated by its ability to suppress the CMR; the reduction in CBF is commensurate with the reduction in CMR, and there is no evidence that dexmedetomidine causes cerebral ischemia. However, the well-known effect of dexmedetomidine in decreasing arterial blood pressure merits careful consideration if used in patients who are critically dependent on collateral perfusion pressure, especially in the recovery phase of an anesthetic.

β-Agonists

β-receptor agonists, in small doses, have little direct effect on the cerebral vasculature. In larger doses and in association with physiologic stress, they can cause an increase in the CMR with an accompanying increase in CBF. The β ₁ -receptor is probably the mediator of these effects. In doses that do not result in substantial changes in the MAP, intracarotid epinephrine does not change CBF in nonanesthetized humans. However, with larger doses that lead to an increase in the MAP, both CBF and CMRO ₂ can increase by approximately 20%. A recent investigation has demonstrated that the administration of epinephrine in patients undergoing surgery under hypotensive epidural anesthesia can increase MCAfv, presumably by augmenting cardiac output (as discussed previously).

Dobutamine can increase CBF and CMR by 20% and 30%, respectively. Dobutamine can increase CBF independent of its effect on blood pressure; the increase in CBF has been attributed to the augmentation of cardiac output by dobutamine.

Evidence suggests that a defect in the BBB enhances the effect of β-agonists. Intracarotid norepinephrine, which does not normally affect CBF and CMR, increases CBF and CMR when BBB permeability is increased with hypertonic drugs. Epinephrine caused an elevation in the CMRO ₂ , but only when the BBB was made permeable. These observations beg the interpretation that β-agonists will increase CBF and CMR only when the BBB is injured. However, when epinephrine was given in doses that did not significantly increase the MAP, increases in CBF and CMR occurred. Accordingly, BBB injury may exaggerate but is not a necessary condition in humans for the occurrence of β-mediated increases in CBF and CMR.

β-Blockers

β-Adrenergic blockers either reduce or have no effect on CBF and CMR. In two investigations in humans, propranolol, 5 mg intravenously, and labetalol, 0.75 mg/kg intravenously, had no effect on CBF and cerebral blood flow velocity (CBFV), respectively. Modest reductions in CBF occur after the administration of labetalol to patients undergoing craniotomy who become hypertensive during emergence from anesthesia. Esmolol shortens seizures induced by electroconvulsive therapy (ECT), which suggests that esmolol does cross the normal BBB. Catecholamine levels at the time of β-blocker administration or the status of the BBB (or both) may influence the effect of these drugs. β-Adrenergic blockers are unlikely to have adverse effects on patients with intracranial pathology, other than effects secondary to changes in perfusion pressure.

Dopaminergic agents

Dopamine can be used for the treatment of hemodynamic dysfunction. It also augments the function of the normal cardiovascular system when an increase in the MAP is desired as an adjunct to the treatment of focal cerebral ischemia, especially in the setting of vasospasm. Nonetheless, its effects on CBF and CMR have not been defined with certainty. The likely predominant effect of dopamine in the normal cerebral vasculature, when administered in small doses, is probably slight vasodilation with a minimal change in the CMR. Increased CMR in discrete regions of the brain, such as the choroid plexus and basal ganglia, can occur. However, overall cortical blood flow is not influenced. Vasoconstriction of the cerebral circulation is not observed even when dopamine is administered in doses of up to 100 μg/kg/min. Fenoldopam is a dopamine agonist with activity at the DA ₁ -receptor and α ₂ -receptor. The administration of fenoldopam leads to systemic vasodilation and a decrease in arterial blood pressure. In humans, fenoldopam decreased systemic blood pressure to a level that was above the LLA; however, a modest (≈15%) reduction was observed in CBF that did not increase to normal levels when systemic blood pressure was supported. The reason for the reduction of CBF is not clear.

Calcium channel blockers

CCBs are frequently used to treat acute hypertension in the neurologically injured patient population. Cerebral vessels are richly endowed with calcium channels, in particular the L-type calcium channel. CCBs therefore induce vasodilation of the pial and cerebral arteries. In healthy humans, intravenous administration of nimodipine does not change CBF; however, when the slight decrease in MAP and changes in Pa co ₂ are taken into consideration, CBF increased by approximately 5% to 10%. CMR and CO ₂ reactivity are maintained. Nimodipine in human subjects does, however, blunt autoregulation moderately. Intraarterial nimodipine for the treatment of cerebral vasospasm after subarachnoid hemorrhage increased regional CBF significantly provided MAP was maintained, indicating that nimodipine is a cerebral vasodilator.

Nicardipine is perhaps the most commonly used CCB for perioperative blood pressure control because of its short half-life and easy titratability. Nicardipine is a modest cerebral vasodilator and has repeatedly been shown to increase CBF or CBFV while reducing systemic MAP. Cerebral CO ₂ reactivity appears to be well preserved in the presence of nicardipine.

Clevidipine is a third generation dihydropyridine CCB that has an ultrashort half-life because it undergoes rapid esterase-mediated metabolism. Its use in both the cardiac and neurologic patient populations has increased significantly given its rapid titratability. In healthy volunteers, clevidipine did not increase MCAfv. However, a substantial reduction in MAP of approximately 25% occurred. The lack of increase in MCAfv in the face of hypotension suggests that clevidipine is a cerebral vasodilator and, like nicardipine, probably attenuates autoregulation to a moderate extent. CO ₂ reactivity is preserved.

The available data indicate that CCBs are moderate cerebral vasodilators. Their net impact on CBF is therefore dependent on the extent of systemic vasodilation and MAP. When MAP is maintained, increases in CBF should be expected.

Angiotensin II, Angiotensin-Converting Enzyme Inhibitors, and Angiotensin Receptor Antagonists

There has been a renaissance of the use of angiotensin II (AII) for the treatment of vasodilatory shock that is refractory to conventional vasopressor agents. In these shock states, AII increased MAP and reduced the need for other vasopressors including norepinephrine and vasopressin. The acute effect of AII on the cerebral circulation has received only modest attention. Acute administration of AII increases cerebral microvascular constriction without affecting CBF; this effect precedes its impact on blood pressure. However, AII attenuates regional hyperemia that occurs with an increase in regional metabolism, thereby adversely impacting neurovascular coupling. Given that CBF is maintained in the face of increased blood pressure, autoregulation and CO ₂ responsivity appear to be maintained.

Both ACE inhibitors and angiotensin-receptor blockers (ARBs) are commonly used to treat hypertension. In the surgical setting and in the neurocritical care unit, these drugs are administered to control arterial blood pressure acutely. ACE inhibitors and ARBs reduce arterial blood pressure when hypertension is present. However, they do not affect resting CBF, and autoregulation is maintained. However, acute administration of ACE inhibitors and ARBs decreases the LLA (left shift of the autoregulatory curve in experimental animals); the significance of this finding in humans is not clear. In patients with acute stroke, ACE inhibitors and ARBs reduce arterial blood pressure but do not acutely affect CBF. Apparently, these drugs do not reduce CBF when arterial blood pressure is modestly decreased.