Myocardial Function

The influence of volatile anesthetics on contractile function has been investigated extensively in several animal species and in humans using various in vitro and in vivo models. It is widely agreed that volatile agents cause dose-dependent depression of contractile function ( Box 7.1 ). Different volatile agents are not identical in this regard, and the preponderance of information indicates that halothane and enflurane exert equal but more potent myocardial depression than isoflurane, desflurane, or sevoflurane, in part because of reflex sympathetic activation with the latter agents. In the setting of preexisting myocardial depression, volatile agents have a greater effect than in normal myocardium. At the cellular level, volatile anesthetics exert their negative inotropic effects mainly by modulating sarcolemmal L-type Ca ²⁺ channels, the sarcoplasmic reticulum (SR), and contractile proteins. However, the mechanisms by which anesthetic agents modify ion channels are not completely understood.

Box 7.1

Volatile Anesthetic Agents

• 
  

  All volatile anesthetic agents cause dose-dependent decreases in systemic blood pressure, which for halothane and enflurane predominantly result from attenuation of myocardial contractile function; and which for isoflurane, desflurane, and sevoflurane predominantly result from decreases in systemic vascular resistance.

  
  
• 
  

  Volatile agents obtund all components of the baroreceptor reflex arc.

  
  
• 
  

  The effects of volatile agents on myocardial diastolic function are not well characterized and await the application of emerging technologies that have the sensitivity to quantitate indices of diastolic function.

  
  
• 
  

  Volatile anesthetics lower the arrhythmogenic threshold to catecholamines. However, the underlying molecular mechanisms are not well understood.

  
  
• 
  

  When confounding variables are controlled (eg, systemic blood pressure), isoflurane does not cause coronary steal by a direct effect on coronary vasculature.

  
  
• 
  

  The effects of volatile agents on systemic regional vascular beds and on the pulmonary vasculature are complex and depend on many variables, including the specific anesthetic, precise vascular bed, and vessel size, and whether endothelial-dependent or endothelial-independent mechanisms are being investigated.

Cardiac Electrophysiology

Volatile anesthetics reduce the arrhythmogenic threshold for epinephrine. For volatile agents, the order of sensitization is halothane > enflurane > sevoflurane > isoflurane = desflurane. The molecular mechanisms underlying the effect of volatile anesthetics are poorly understood.

Coronary Vasoregulation

Volatile anesthetics modulate several determinants of myocardial oxygen supply and demand. They also directly modulate the myocyte’s response to ischemia.

The effect of isoflurane on coronary vessels was controversial and dominated much of the relevant literature in the 1980s and early 1990s. Several reports indicated that it caused direct coronary arteriolar vasodilatation in vessels with diameters of 100 µm or less and that isoflurane could cause coronary steal in patients with steal-prone coronary anatomy. Several studies in which potential confounding variables were controlled found that isoflurane did not cause coronary steal. Studies of sevoflurane and desflurane showed similar results that were consistent with a mild direct coronary vasodilator effect of these agents.

Systemic Vascular Effects

All volatile anesthetics decrease systemic blood pressure (BP) in a dose-dependent manner. With halothane and enflurane, the decrease in systemic BP primarily results from decreases in stroke volume (SV) and cardiac output (CO), whereas isoflurane, sevoflurane, and desflurane decrease overall systemic vascular resistance (SVR) while maintaining CO.

Baroreceptor Reflex

All volatile agents attenuate the baroreceptor reflex. Baroreceptor reflex inhibition by halothane and enflurane is more potent than that observed with isoflurane, desflurane, or sevoflurane, each of which has a similar effect. Each component of the baroreceptor reflex arc (eg, afferent nerve activity, central processing, efferent nerve activity) is inhibited by volatile agents.

Reversible Myocardial Ischemia

Prolonged ischemia results in irreversible myocardial damage and necrosis ( Box 7.2 ). Depending on the duration and sequence of ischemic insults, shorter durations of myocardial ischemia can lead to preconditioning or myocardial stunning ( Fig. 7.1 ). Stunning, first described in 1975, occurs after brief ischemia and is characterized by myocardial dysfunction in the setting of normal restored blood flow and by an absence of myocardial necrosis. Ischemic preconditioning (IPC) was first described in 1986 and is characterized by an attenuation of infarct size after sustained ischemia if the period of sustained ischemia is preceded by a period of brief ischemia ( Fig. 7.2 ). This effect is independent of collateral flow. Short periods of ischemia followed by reperfusion can lead to stunning or preconditioning with a reduction in infarct size.

Box 7.2

Volatile Agents and Myocardial Ischemia

• 
  

  Volatile anesthetic agents can attenuate the effects of myocardial ischemia (ie, acute coronary syndromes).

  
  
• 
  

  Nonacute manifestations of myocardial ischemia include hibernating myocardium, stunning, and preconditioning.

  
  
• 
  

  Halothane and isoflurane facilitate the recovery of stunned myocardium.

  
  
• 
  

  Preconditioning, an important adaptive and protective mechanism in biologic tissues, can be provoked by protean nonlethal stresses, including ischemia.

  
  
• 
  

  Volatile anesthetic agents can mimic preconditioning (ie, anesthetic preconditioning), which can have important clinical implications and provide insight into the cellular mechanisms of action of these volatile agents.

Effects of ischemia and reperfusion on the heart based on studies using an anesthetized canine model of proximal coronary artery occlusion. Periods of ischemia of less than 20 minutes followed by reperfusion are not associated with development of necrosis (ie, reversible injury). Brief ischemia and reperfusion results in stunning and preconditioning. If the duration of coronary occlusion is extended beyond 20 minutes, necrosis develops from the subendocardium to subepicardium over time. Reperfusion before 3 hours of ischemia salvages ischemic but viable tissue. Salvaged tissue may demonstrate stunning. Reperfusion beyond 3 to 6 hours in this model does not reduce myocardial infarct size. Late reperfusion may still have a beneficial effect on reducing or preventing myocardial infarct expansion and left ventricular (LV) remodeling.

(From Kloner RA, Jennings RB. Consequences of brief ischemia: stunning, preconditioning, and their clinical implications, part I. Circulation . 2001;104:2981.)

Infarct size and collateral blood flow in a 40-minute study. Infarct size as a percentage of the anatomic area at risk in the control (purple) and preconditioned (green) hearts (left) . Infarct size in control animals averaged 29.4% of the area at risk. Infarct size in preconditioned hearts averaged only 7.3% of the area at risk (preconditioned vs control, P < .001). Transmural mean collateral blood flow (right) was not significantly different in the two groups. The protective effect of preconditioning was independent of the two major baseline predictors of infarct size: area at risk and collateral blood flow. Bars represent the group mean ± standard error of the mean.

(From Warltier DC, al-Wathiqui MH, Kampine JP, et al. Recovery of contractile function of stunned myocardium in chronically instrumented dogs is enhanced by halothane or isoflurane. Anesthesiology . 1988;69:552.)

Anesthetic Preconditioning

Volatile agents can elicit delayed (ie, late) and classic (ie, early) preconditioning. APC is dose dependent, exhibits synergy with ischemia in affording protection, and perhaps not surprisingly in view of the differential uptake and distribution of volatile agents, requires different time intervals between exposure and the maintenance of a subsequent benefit that is agent dependent.

Volatile agents that exhibit APC activate mitochondrial K ⁺ _ATP channels, and specific mitochondrial K ⁺ _ATP channel antagonists block this effect. The precise contributions of sarcolemmal versus mitochondrial K ⁺ _ATP channel activation to APC remain to be elucidated ( Fig. 7.3 ).

Multiple endogenous signaling pathways mediate volatile anesthetic-induced myocardial activation of an end-effector that promotes resistance against ischemic injury. Mitochondrial K ⁺ _ATP channels have been implicated as the end-effector in this protective scheme, but sarcolemmal K ⁺ _ATP channels may also be involved. A trigger initiates a cascade of signal transduction events, resulting in protection. Volatile anesthetics signal through adenosine and opioid receptors, modulate G proteins (G), stimulate protein kinase C (PKC) and other intracellular kinases, or directly stimulate mitochondria to generate reactive oxygen species (ROS) that ultimately enhance K ⁺ _ATP channel activity. Volatile anesthetics may also directly facilitate K ⁺ _ATP channel opening. Dotted arrows delineate the intracellular targets that may be regulated by volatile anesthetics; solid arrows represent potential signaling cascades.

(From Tanaka K, Ludwig LM, Kersten JR, et al. Mechanisms of cardioprotection by volatile anesthetics. Anesthesiology . 2004;100:707.)

Myocardial Function

The influence of volatile anesthetics on contractile function has been investigated extensively in several animal species and in humans using various in vitro and in vivo models. It is widely agreed that volatile agents cause dose-dependent depression of contractile function ( Box 7.1 ). Different volatile agents are not identical in this regard, and the preponderance of information indicates that halothane and enflurane exert equal but more potent myocardial depression than isoflurane, desflurane, or sevoflurane, in part because of reflex sympathetic activation with the latter agents. In the setting of preexisting myocardial depression, volatile agents have a greater effect than in normal myocardium. At the cellular level, volatile anesthetics exert their negative inotropic effects mainly by modulating sarcolemmal L-type Ca ²⁺ channels, the sarcoplasmic reticulum (SR), and contractile proteins. However, the mechanisms by which anesthetic agents modify ion channels are not completely understood.

Box 7.1

Volatile Anesthetic Agents

• 
  

  All volatile anesthetic agents cause dose-dependent decreases in systemic blood pressure, which for halothane and enflurane predominantly result from attenuation of myocardial contractile function; and which for isoflurane, desflurane, and sevoflurane predominantly result from decreases in systemic vascular resistance.

  
  
• 
  

  Volatile agents obtund all components of the baroreceptor reflex arc.

  
  
• 
  

  The effects of volatile agents on myocardial diastolic function are not well characterized and await the application of emerging technologies that have the sensitivity to quantitate indices of diastolic function.

  
  
• 
  

  Volatile anesthetics lower the arrhythmogenic threshold to catecholamines. However, the underlying molecular mechanisms are not well understood.

  
  
• 
  

  When confounding variables are controlled (eg, systemic blood pressure), isoflurane does not cause coronary steal by a direct effect on coronary vasculature.

  
  
• 
  

  The effects of volatile agents on systemic regional vascular beds and on the pulmonary vasculature are complex and depend on many variables, including the specific anesthetic, precise vascular bed, and vessel size, and whether endothelial-dependent or endothelial-independent mechanisms are being investigated.

Cardiac Electrophysiology

Volatile anesthetics reduce the arrhythmogenic threshold for epinephrine. For volatile agents, the order of sensitization is halothane > enflurane > sevoflurane > isoflurane = desflurane. The molecular mechanisms underlying the effect of volatile anesthetics are poorly understood.

Coronary Vasoregulation

Volatile anesthetics modulate several determinants of myocardial oxygen supply and demand. They also directly modulate the myocyte’s response to ischemia.

The effect of isoflurane on coronary vessels was controversial and dominated much of the relevant literature in the 1980s and early 1990s. Several reports indicated that it caused direct coronary arteriolar vasodilatation in vessels with diameters of 100 µm or less and that isoflurane could cause coronary steal in patients with steal-prone coronary anatomy. Several studies in which potential confounding variables were controlled found that isoflurane did not cause coronary steal. Studies of sevoflurane and desflurane showed similar results that were consistent with a mild direct coronary vasodilator effect of these agents.

Systemic Vascular Effects

All volatile anesthetics decrease systemic blood pressure (BP) in a dose-dependent manner. With halothane and enflurane, the decrease in systemic BP primarily results from decreases in stroke volume (SV) and cardiac output (CO), whereas isoflurane, sevoflurane, and desflurane decrease overall systemic vascular resistance (SVR) while maintaining CO.

Baroreceptor Reflex

All volatile agents attenuate the baroreceptor reflex. Baroreceptor reflex inhibition by halothane and enflurane is more potent than that observed with isoflurane, desflurane, or sevoflurane, each of which has a similar effect. Each component of the baroreceptor reflex arc (eg, afferent nerve activity, central processing, efferent nerve activity) is inhibited by volatile agents.

Reversible Myocardial Ischemia

Prolonged ischemia results in irreversible myocardial damage and necrosis ( Box 7.2 ). Depending on the duration and sequence of ischemic insults, shorter durations of myocardial ischemia can lead to preconditioning or myocardial stunning ( Fig. 7.1 ). Stunning, first described in 1975, occurs after brief ischemia and is characterized by myocardial dysfunction in the setting of normal restored blood flow and by an absence of myocardial necrosis. Ischemic preconditioning (IPC) was first described in 1986 and is characterized by an attenuation of infarct size after sustained ischemia if the period of sustained ischemia is preceded by a period of brief ischemia ( Fig. 7.2 ). This effect is independent of collateral flow. Short periods of ischemia followed by reperfusion can lead to stunning or preconditioning with a reduction in infarct size.

Box 7.2

Volatile Agents and Myocardial Ischemia

• 
  

  Volatile anesthetic agents can attenuate the effects of myocardial ischemia (ie, acute coronary syndromes).

  
  
• 
  

  Nonacute manifestations of myocardial ischemia include hibernating myocardium, stunning, and preconditioning.

  
  
• 
  

  Halothane and isoflurane facilitate the recovery of stunned myocardium.

  
  
• 
  

  Preconditioning, an important adaptive and protective mechanism in biologic tissues, can be provoked by protean nonlethal stresses, including ischemia.

  
  
• 
  

  Volatile anesthetic agents can mimic preconditioning (ie, anesthetic preconditioning), which can have important clinical implications and provide insight into the cellular mechanisms of action of these volatile agents.

Effects of ischemia and reperfusion on the heart based on studies using an anesthetized canine model of proximal coronary artery occlusion. Periods of ischemia of less than 20 minutes followed by reperfusion are not associated with development of necrosis (ie, reversible injury). Brief ischemia and reperfusion results in stunning and preconditioning. If the duration of coronary occlusion is extended beyond 20 minutes, necrosis develops from the subendocardium to subepicardium over time. Reperfusion before 3 hours of ischemia salvages ischemic but viable tissue. Salvaged tissue may demonstrate stunning. Reperfusion beyond 3 to 6 hours in this model does not reduce myocardial infarct size. Late reperfusion may still have a beneficial effect on reducing or preventing myocardial infarct expansion and left ventricular (LV) remodeling.

(From Kloner RA, Jennings RB. Consequences of brief ischemia: stunning, preconditioning, and their clinical implications, part I. Circulation . 2001;104:2981.)

Infarct size and collateral blood flow in a 40-minute study. Infarct size as a percentage of the anatomic area at risk in the control (purple) and preconditioned (green) hearts (left) . Infarct size in control animals averaged 29.4% of the area at risk. Infarct size in preconditioned hearts averaged only 7.3% of the area at risk (preconditioned vs control, P < .001). Transmural mean collateral blood flow (right) was not significantly different in the two groups. The protective effect of preconditioning was independent of the two major baseline predictors of infarct size: area at risk and collateral blood flow. Bars represent the group mean ± standard error of the mean.

(From Warltier DC, al-Wathiqui MH, Kampine JP, et al. Recovery of contractile function of stunned myocardium in chronically instrumented dogs is enhanced by halothane or isoflurane. Anesthesiology . 1988;69:552.)

Anesthetic Preconditioning

Volatile agents can elicit delayed (ie, late) and classic (ie, early) preconditioning. APC is dose dependent, exhibits synergy with ischemia in affording protection, and perhaps not surprisingly in view of the differential uptake and distribution of volatile agents, requires different time intervals between exposure and the maintenance of a subsequent benefit that is agent dependent.

Volatile agents that exhibit APC activate mitochondrial K ⁺ _ATP channels, and specific mitochondrial K ⁺ _ATP channel antagonists block this effect. The precise contributions of sarcolemmal versus mitochondrial K ⁺ _ATP channel activation to APC remain to be elucidated ( Fig. 7.3 ).

Multiple endogenous signaling pathways mediate volatile anesthetic-induced myocardial activation of an end-effector that promotes resistance against ischemic injury. Mitochondrial K ⁺ _ATP channels have been implicated as the end-effector in this protective scheme, but sarcolemmal K ⁺ _ATP channels may also be involved. A trigger initiates a cascade of signal transduction events, resulting in protection. Volatile anesthetics signal through adenosine and opioid receptors, modulate G proteins (G), stimulate protein kinase C (PKC) and other intracellular kinases, or directly stimulate mitochondria to generate reactive oxygen species (ROS) that ultimately enhance K ⁺ _ATP channel activity. Volatile anesthetics may also directly facilitate K ⁺ _ATP channel opening. Dotted arrows delineate the intracellular targets that may be regulated by volatile anesthetics; solid arrows represent potential signaling cascades.

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