Toxicity of Local Anesthetics

Toxicity of Local Anesthetics


Steven Dewaele, and Alan C. Santos


Introduction


Systemic toxicity of local anesthetics can occur after administration of an excessive dose, with rapid absorption, or because of an accidental intravenous injection. The management of local anesthetic toxicity can be challenging, and in the case of cardiac toxicity, prolonged resuscitation efforts may be necessary.1,2 Therefore, understanding the circumstances that can lead to systemic toxicity of local anesthetics and being prepared for treatment is essential to optimize the patient outcome.


Systemic toxicity is typically manifested as central nervous system (CNS) toxicity (tinnitus, disorientation, and ultimately, seizures) or cardiovascular toxicity (hypotension, dysrhythmias, and cardiac arrest).3 The dose capable of causing CNS symptoms is typically lower than the dose and concentration result in cardiovascular toxicity. This is because the CNS is more susceptible to local anesthetic toxicity than the cardiovascular system. However, bupivacaine toxicity may not adhere to this sequence, and cardiac toxicity may precede the neurologic symptoms.4 Although less common, cardiovascular toxicity is more serious and more difficult to treat than CNS toxicity.


Other reported, but much less common, adverse effects of certain local anesthetics include allergic reactions,5 methemoglobinemia,6 and bronchospasm.7 Direct neural8 and local tissue toxicity9 have been reported also; however, discussion about these topics is beyond the scope of this chapter.


Signs and Symptoms of Systemic Local Anesthetic Toxicity


The earliest signs of systemic toxicity are usually caused by blockade of inhibitory pathways in the cerebral cortex.10 This allows for disinhibition of facilitator neurons resulting in excitatory cell preponderance and unopposed (generally enhanced) excitatory nerve activity. As a result, initial subjective symptoms of CNS toxicity include signs of excitation, such as lightheadedness and dizziness, difficulty focusing, tinnitus, confusion, and circumoral numbnesss.11,12 Likewise, the objective signs of local anesthetic toxicity are excitatory, for example, shivering, myoclonia, tremors, and sudden muscular contractions.13 As the local anesthetic level rises, tonic-clonic convulsions occur. Symptoms of CNS excitation typically are followed by signs of CNS depression: Seizure activity ceases rapidly and ultimately is succeeded by respiratory depression and respiratory arrest. In the concomitant presence of other CNS depressant drugs (e.g., premedication), CNS depression can develop without the preceding excitatory phase.


The CNS toxicity is directly correlated with local anesthetic potency.14–17 However, there is an inverse relationship between the toxicity of local anesthetics and the rate at which the agents are injected: Increasing speed of injection will decrease the blood-level threshold for symptoms to appear.


All local anesthetics can induce cardiac dysrhythmias,18,19 and all, except cocaine, are myocardium depressants.20–25 Local anesthetic–induced arrhythmias can manifest as conduction delays (from prolonged PR interval to complete heart block, sinus arrest, and asystole) to ventricular dysrhythmias (from simple ventricular ectopy to torsades de pointes and fibrillation). The negative inotropic action of local anesthetics is exerted in a dose-dependent fashion and consists of depressed myocardial contractility and a decrease in cardiac output. Dysrhythmias due to local anesthetic overdose may be recalcitrant to traditional therapies; the reduced myocardial contractility and low output state further complicate the treatment.


The sequence of cardiovascular events is ordinarily as follows: Low blood levels of local anesthetic usually generate a small increase in cardiac output, blood pressure, and heart rate, which is most likely due to a boost in sympathetic activity and direct vasoconstriction. As the blood level of local anesthetic rises, hypotension ensues as a result of peripheral vasodilation due to relaxation of the vascular smooth muscles. Further rise of local anesthetic blood levels leads to severe hypotension, resulting from the combination of reduced peripheral vascular resistance, reduced cardiac output, and/or malignant arrhythmias. Eventually, extreme hemodynamic instability may lead to cardiac arrest.


Acid–base status plays an important role in the setting of local anesthetic toxicity.26 Acidosis and hypercarbia amplify the CNS effects of local anesthetic overdose and exacerbate cardiotoxicity. Hypercarbia enhances cerebral blood flow; consequently, more local anesthetic is made accessible to the cerebral circulation. Diffusion of carbon dioxide across the nerve membrane can cause intracellular acidosis, and as such, it is promoting the conversion of the local anesthetic into the cationic, or active, form. Because it is impossible for the cationic form to travel across the nerve membrane, ionic trapping occurs, worsening the CNS toxicity of the local anesthetic. Hypercarbia and/or acidosis also reduce the binding of local anesthetics by plasma proteins,27 and as a result, the fraction of free drug readily available for diffusion expands.


Prevention


Prevention of toxicity is key to safer practice, and it starts with making sure that the work environment is optimized for performing regional anesthesia.28 The logistics for treating an emergency, including equipment for airway management and treating cardiac arrest, must be readily available and functioning.


A judicious selection of the type, dose, and concentration of the local anesthetic, and the regional anesthesia technique, is important. As a rule, the optimal dose and concentration is the lowest one that achieves the aimed for effect. The effects of pretreatment with a benzodiazepine is often debated but almost routinely used in our practice. Benzodiazepines lower the probability of seizures29–32 but can mask early signs of toxicity.33 A sedated patient is theoretically less able to keep the physician updated on the subjective symptoms of light toxicity, and severe toxicity can establish itself without a recognizable toxic prodrome. This concern remains only theoretical; many symptoms of limited, mild CNS toxicity can be prevented by routine premedication with benzodiazepines in addition to making the PNB procedure more pleasant to patients.


Therefore, the presence of premedication or general anesthesia is not perceived to increase the risk of local anesthetic toxicity. Considerable research has been invested into the subject of the ideal test for detecting intravenous injection and to what constitutes the ideal test dose. Epinephrine (5–15 μg) is still widely in use as a marker of intravascular injection. End points with an acceptable sensitivity are defined by an increase in heart rate >10 bpm, increase in systolic blood pressure by >15 mm Hg,34 or a 25% decrease in lead II T-wave amplitude.35 However, elderly patients are less responsive to beta stimulation36 as are those on beta-blocking agents. Low cardiac output can prolong drug circulation and delay the clinical effect of the beta mimetic, and therefore, the sensitivity of the test. Accordingly, the interpretation of the test result is not always as straightforward as one would wish. The significant proportion of false negative test results warrants a reevaluation of the routine use of this test as a sole determinant to detect inadvertent intravenous injection.


Regardless of whether epinephrine is used as a marker of an intravascular injection, it is of utmost importance to use slow, incremental injections of local anesthetic, with frequent aspirations (every 3–5 mL) between injections while monitoring the patient for signs of toxicity.37 A slow rate of injection of divided doses at distinct intervals can decrease the possibility of summating intravascular injections. With a rapid injection the seizures may occur at higher blood level because there is no time for distribution of the drug as compared to a slow infusion where the seizure occurs at a lower drug level because of the distribution. It is prudent to decrease the local anesthetic dosage in elderly or debilitated patients and in any patient with diminished cardiac output. However, there are no firm recommendations on the degree of dose reduction.


Treatment


Early recognition of the toxicity and early discontinuation of the administration is of crucial importance.38 The administration of local anesthetics should be stopped immediately. The airway should be maintained at all times, and supplemental oxygen is provided while ensuring that the monitoring equipment is functional and properly applied. Neurologic parameters and cardiovascular status should be assessed until the patient is completely asymptomatic and stable.39


Administration of a benzodiazepine to offset or ameliorate excitatory neurological symptoms or a potential tonic-clonic seizure is indicated.40 Early treatment of convulsions is particularly meaningful because convulsions can result in metabolic acidosis, thus aggravating the toxicity. Seizures should be controlled at all times. Based on the recent data in animal studies,41–43 as well as mounting case reports,44–53 starting an infusion of lipid emulsion (intralipid), especially in those cases where symptoms of cardiac toxicity are present, should be contemplated early.54 Importantly, there is a mounting consensus that infusion of intralipids may be initiated early, to also prevent, rather then treat cardiac arrest. If available, arrangements for transfer to an operating room where cardiopulmonary bypass can be instituted should also be contemplated in situations where the response to early treatment is not favorable.55–58


Malignant arrhythmias and asystole are managed using standard cardiopulmonary resuscitation protocols,59,60 acknowledging that a prolonged effort may be needed to increase the chance of resuscitation. The rationale of this approach is to maintain the circulation until the local anesthetic is redistributed or metabolized below the level associated with cardiovascular toxicity, at which time spontaneous circulation should resume. Because the contractile depression is a core factor underlying severe cardiotoxicity, it would be intuitive to believe that the use of sympathomimetics should be helpful. Nonetheless, epinephrine can induce dysrhythmia or it can exacerbate the ongoing arrhythmia associated with local anesthetic overdose.61,62 Consequently, in the setting of local anesthetic toxicity, vasopressin may be more appropriate to maintain the blood pressure, support coronary perfusion, and facilitate local anesthetic metabolism.63

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Jan 8, 2017 | Posted by in ANESTHESIA | Comments Off on Toxicity of Local Anesthetics

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