ISSN : 1301-5680
e-ISSN : 2149-8156
Turkish Journal of Thoracic and Cardiovascular Surgery     
Brugada syndrome and anesthesia
İbrahim Öztürk1, Selen Öztürk2
1Anesteziyoloji ve Reanimasyon, Dışkapı Yıldırım Beyazıt Training and Research Hospital, Ankara, Turkey
2Department of Cardiovascular Surgery, Dışkapı Yıldırım Beyazıt Training and Research Hospital, Ankara, Turkey
DOI : 10.5606/tgkdc.dergisi.2013.8100

Abstract

Brugada syndrome is a genetic disease leading to sudden cardiac death, which is characterized by a spontaneous or induced ST-segment elevation with right bundle branch block in V1-3 leads in electrocardiography in those without any structural heart disease. As there is a limited number of experiences on anesthetizing patients with Brugada syndrome, no consensus report for clinical practice has been available yet. In this systematic review, we discussed the anesthesia techniques, and the effects and safety of anesthesia applied in this rarely seen heart disease.

Advances in the fields of both surgery and anesthesia have increased the possibility of encountering patients who have rare diseases, in addition to common diseases such as diabetes mellitus, hypertension chronic obstructive pulmonary disease, and hyper/ hypothyroidism in clinical practice. Hence, knowing the pathophysiological and clinical features of uncommon diseases and establishing how prescribed medications affect the progression of these diseases is important. Accomplishing this would make it possible to prevent probable adverse outcomes like mortality. Brugada syndrome (BS), a rare disease that can lead to sudden cardiac death, has special significance in the practice of anesthesia.

Brugada syndrome, which was firstly defined by Pedro and Josep Brugada[1] in 1992, is a disease that has typical electrocardiographic findings. However, it can cause polymorphic ventricular tachycardia and fibrillation along with secondary sudden cardiac death without structural heart disease.[2] In fact, BS is responsible for 4-12% of sudden cardiac deaths.[3] F urthermore, i t i s a ssociated w ith e thnic and geographical difference as well,[4] with estimates indicating that that there are higher numbers of cases in Southeastern Asia than Europe (1-5/10,000 vs. 12/10,000, respectively).[2] In addition, BS is seen more frequently in men[5] a nd h as a c hannelopathy which causes arrhythmia as a result of electrical dysfunction.[4] Arrhythmias a ssociated with BS are mostly often found in patients between the ages of 40 and 45[5] and emerge generally during sleep, rest, or after heavy meals.[2]

Specific electrocardiographic changes also occur with BS. Three types of repolarization patterns have been defined,[6] but the J wave amplitude is ≥2 mm in all of them. Types 2 and 3 contain ST-T configuration located in the saddleback. Type 1 has the coved-type configuration. In addition, types 2 and 3 occur when the ST-segment elevation is ≥1 mm, but in type 1, it gradually descends. The T wave is negative in the type 1 repoloarization pattern, but it is positive in type 3, and can be positive or biphasic in type 2.[6] Even if all three changes are seen, only the type 1 electrocardiogram (ECG) pattern is diagnostic for BS.[7] T o m eet t he criteria for a major diagnosis, patients must have more than one right pericardial derivation along with having ≥2 mm type 1 ST-segment elevation. Patients with the following any of the following conditions that can lead to similar ECG changes can be ruled out as having BS: arrhythmogenic right ventricular dysplasia/cardiomyopathy, acute myocardial ischemia or infarction, acute myocarditis, acute pulmonary thromboemboli, cocaine intoxication, a dissecting aortic aneurysm, Duchenne muscular dystrophy (DMD), early repolarization syndrome, Friedreich’s ataxia, a heterocyclic antidepressant overdose, hypercalcemia, hyperkalemia, long QT syndrome (LQTS), right ventricular ischemia or infarction, right or left bundle branch block, left ventricular hypertrophy, thiamine deficiency, and various central and autonomic nervous system abnormalities) that can lead to similar ECG changes.[6] A d iagnosis i s t hen made with the patient based on patients having one of the following minor criteria: documented ventricular fibrillation, (self-terminating) polymorphic ventricular tachycardia, the induction of ventricular arrhythmias with programmed arrhythmias, electrical stimulation, a family history of sudden death before the age of 45, the presence of a coved-type repolarization pattern on the ECG in family members, syncope, and nocturnal agonal respiration. In addition, type 1 ST-segment elevations are also present (elevation ≥2 mm in more than one right precordial lead), either occurring spontaneously or after sodium-blocker exposure.[5]

Electrocardiogram results are sometimes normal in patients with BS; however, diagnostic changes may appear in some cases, for example fever, alcohol, mental stress, and class 1 anti-arrhythmic drug administration.[8,9] Therefore, the antiarrhythmics ajmaline,[10] flecainide,[11] procainamide,[12] pilsicainid[13] are applied in diagnostic tests. Autosomal recessive BS has a heterogeneous genetic basis and is associated with mutation in 10 genes (SCN5A, GPD1-L, CACNA1c, CACNB2, SCN1B, KCNE3, SCN3B, MOG1, KCNE5, KCND3). Loss of function has been seen in all of these except for KCNE3, KCNE5, and KCND3. Among patients with BS, the SCN5A gene association is seen the most (11%-18%).[2]

In BS, mortality can occur with even a single cardiac event. Hence, life-threatening arrhythmias and complications can be prevented by making an early diagnosis.[14] For patients who are diagnosed with BS, drugs which trigger type 1 ECG and/or ventricular arrhythmias should be discontinued, and they should forego items such as fever, alcohol, and mental stress which promote attacks.

There are two choices for the treatment of BS patients: an implantable cardioverter defibrillator (ICD) or pharmacological agents; however, the ICD is the only method that has been proven to prevent sudden cardiac deaths.[2] On the other hand, isoproterenol,[15] quinidine,[16] dysopyramide,[17] orciprenaline,[18] tedisamil,[19] cilostazol,[20] and dimethyl lithospermate B[21] a re a mong t he p harmacological a gents w hich have been beneficial in the hindrance of an electrical storm.

Postema et al.[22] researched BS-related drugs and divided them into four groups: (i) drugs which should be avoided (ajmaline, flecainide, pilsicainide, procainamide, propafenone, amitriptyline, clomipramine, desipramine, lithium, bupivacaine, and propofol), (ii) drugs which a re recommended to be avoided (amiodarone, lidocaine, verapamil, diltiazem, and imipramine), (iii) potential anti-arrhythmic drugs (isoproterenol, isoprenaline, and quinidine), and (iv) diagnostic drugs (ajmaline, flecainide, pilsicainide, and procainamide).

The perioperative period affects all of the organ systems. Neuroendocrine and hemodynamic changes due to factors associated with both surgery and anesthesia (drugs, intubation, position, regional blocks) can directly affect the cardiovascular system. Therefore, in this systematic research, we aimed to examine the anesthetic methods used for BS and determine how these affected patients with this disease.

Methods

In order to investigate the anesthesia techniques, two authors analyzed the effects and safety of anesthetics used in patients with BS via an electronic literature review conducted on November 1, 2012 which covered the years between 1992 and 2012. No other literature review was performed. The following research terms and word combinations were entered into the Pubmed, Ovid, Science Direct databases: brugada syndrome and anesthesia, general anesthesia, spinal anesthesia, epidural anesthesia, propofol, thiopental, ethomidate, midazolam, ketamine, desflurane, sevoflurane, isoflurane, nitrous oxide, morphine, fentanyl, remifentanil, sufentanil, alfentanil, tramadol, meperidin, sugammadex, neostigmine, atropine, thiamylal, vecuronium, rocuronium, and succinylcholine. We began the research from 1992 when BS was first identified. We limited the investigation to English (full texts and abstracts), and the detailed data (age, gender, number of patients, procedures employed, anesthesia techniques, anesthetics, and complications) found in the articles, including the abstracts. However, case reports that focused on propofol infusion syndrome (PRIS) were not included because of controversy concerning the use of propofol. We discovered a larger number of studies which stated that the combination of propofol and intravenous anesthesia do not create PRIS,[23] but this information was based mostly on case reports.[24,25] In addition, in these case reports, instead of interpreting the effects of propofol on patients who were definitely diagnosed with BS, they focused on the fact that propofol can cause BS-like ECG changes.

Our methodology was organized according to the Preferred Reporting Items for Systematic Reviews and Meta-Analyses (PRISMA) statement which provides recommendations for systematic compilation.[26] Statistical analysis was carried out with the SPSS Windows version 16.0 software program (SPSS Inc. Chicago, IL, USA), and the data was presented as mean ± standard deviation or as a proportion.

Results

The literature review produced 140 pertinent articles. After duplicates were removed, 58 articles were analyzed, and 25 of these met the criteria for inclusion (Table 1). All of the reports were composed of either a case report or a series of case reports, and a total of 43 cases were evaluated in the 25 articles. After statistical analysis, it was observed that most of the patients were male (39 males and 4 females), and the average age was 41.9±20.9 (Table 2).

Table 1: Summary of patients with Brugada syndrome

Table 1: Continued

Table 2: Analysis of demographical and perioperative data

The following procedures were employed: ICD (n=11, 25.6%), general surgery (n=8, 18.6%), neurosurgery (n=4, 9.3%), thoracic surgery (n=4, 9.3%), and other procedures (n=16, 37.2%). In addition, general anesthesia was used with 32 of the patients (74.4%), general/regional anesthesia was utilized for six (14%), regional anesthesia alone was used for three (7%) and sedation was needed for two others (4.7%) (Table 2).

The following intravenous anesthetics were used: propofol (n=25, 58.1%), midazolam (n=13, 30.2%), diazepam (n=10, 23.3%), thiopental (n=5, 11.6%), ketamine (n=2, 4.7%), thiamylal (n=2, 4.7%), and ethomidate (n=1, 2.3%). Furthermore, the following inhalational anesthetics were utilized: sevoflurane (n=22, 53.7%), nitrous oxide (N2O) (n=14, 32.6%), isoflurane (n=6, 14%), desflurane (n=2, 4.7%), and enflurane (n=1, 2.3%). In addition, 31 patients used fentanyl (75.1%), two required (4.7%), two needed remifentanil (4.7%), and one patient was given morphine (2.3%). Neuromuscular blocker agents (NMBAs) were also employed in the following manner: 16 were prescribed vecuronium (37.2%), five used rocuronium (11.6%), another five utilized cisatracurium (11.6%), three were given succinylcholine (7%), and two used atracurium (4.7%). Local anesthetics were also distributed, with eight being prescribed bupivacaine (18.6%), five needing lidocaine (11.6%), and one receiving ropivacaine (2.3%). Finally, the anticholinesterases neostigmine (n=9, 20.9%) and sugammadex (n=2, 4.7%) were also prescribed along with the anticholinergic drugs glycopyrrolate (n=6, 14%) and atropine (n=2, 4.7%). Propofol was the most frequently used intravenous anesthetic (58.1%), and sevoflurane was the most commonly prescribed inhalation agent (53.7%). In addition fentanyl was the opioid used most often (75.1%), and vecuronium was the NMBA that was prescribed the most (37.2%) (Table 3).

Table 3: Analysis of anesthetic drugs

However, in 28 (65.1%) of the cases, no complications were observed. However, when a complication was present, the most frequent was bradycardia in three patients (7%) followed by hypertension in three others (7%). Additionally, there was one case of mortality (2.3%) (Table 2).

Discussion

It is seen that various anesthetic techniques (general or regional anesthesia and sedation) along with anesthetic drugs (intravenous and inhalation anesthetics, opioids, etc.) were employed in the BS cases in this study. The intravenous anesthetic propofol was used for both the induction[27-38] and maintenance of anesthesia[29,37-40] while midazolam was utilized for both premedication[31,34,37,38,41] and induction.[27,29,33] Only the one case in which ketamine and diazepam were used died,[42] and this was due to sedation with high-dose ketamine, which led to cardiac arrest.[43] Propofol is different from other intravenous anesthetics because it leads to PRIS in which occur BS-like ECG changes.[24,25] In addition, we discovered a case involving thiopental that had a clinically similar picture to the propofol case which, interestingly, occurred at about the same time.[44] On the other hand, Schmidt et al.[23] concluded in a study comprised of 6,161 patients that there was no link between propofol and total intravenous anesthesia regarding PRIS. In our opinion, this study demonstrated that a causal relationship linking mortality to propofol and PRIS could be established more clearly through prospective trials.

Our research also indicated that the inhalation anesthetics isoflurane,[27,45,46] desflurane,[27,34] sevoflur ane,[27-29,31-33,35,41,43,47-49] and N2O[27,29,31,43,45,48] were safely used; however, the patient who received enflurane died.[42] The opioids fentanyl,[28,31-35,37,38,41-43,45-48,50] sufentanil,[40] morphine,[42] and remifentanil[28,32] were frequently prescribed as adjuvants to general anesthesia. Two patients were also given opioids via an epidural.[33,40] However, there have been no reports of adverse effects associated with this type of medication. Furthermore, although there have not been reported any experience of anesthesia with tramadol in patients with BS, it has been seen that tramadol has led to BS-like ECG changes.[51] All opioids except high-dose morphine, caused reversible suppression of sodium channels, but as long the patients took the prescribed dosage, they were safe.[52]

Local anesthetics like bupivacaine,[33,40,45,46,50,53] lidocaine,[27,29,32] and ropivacaine[35] are also prescribed for BS patients. Of these, lidocaine is generally given in low doses and is safe when used as an adjuvant in induction. However, the study by Vernooy et al.[40] clearly established a correlation between bupivacaine given via an epidural and impairment of the clinical picture.

Our patients also received the NMBAs vecuronium,[27,29,34,35,43,45,46,54] rocuronium,[30-33,36] cisatracurium,[28,47] succinylcholine,[27,38,45] and atracurium[37,38,48] but succinylcholine is not normally used because of its adverse effects.[29] As an anticholinesterase agent, neostigmine is also avoided because it can lead to ST-segment elevation in BS patients.[54] Nevertheless, neostigmine[27,31,37,44,45] was the most frequently chosen agent in our cases to reverse the effects of NMBAs. Hayashida et al.[54] applied as much as half of a normal dose of neostigmine with atropine for the purpose of ST-segment depression due to the effect of atropine. However, concerns about neostigmine have led some authors to prefer sugammadex, which was used safely in two of the reported cases.[30,36] Additionally, we found that atropine was selected for use in only one case[54] and that glycopyrrolate[27,31,45,48] was more commonly applied as an anticholinergic agent.

In BS, sudden cardiac death develops secondary to polymorphic ventricular tachycardia and fibrillation. For this reason, it is necessary to take into account the possible arrhythmogenic effects of anesthetic agents. Volatile anesthetics like isoflurane, sevoflurane, and desflurane do not predispose patients to ventricular arrhythmias, and they do not sensitize the heart to the arrhythmogenic effects of epinephrine, with the exception of halothane.[55] At the same time, volatile anesthetics reduce, in a dose-dependent fashion, the arterial baroreflex modulation of the heart rate and blood pressure.[55] Moreover, propofol is especially known for causing rare cardiac events, including severe bradycardia, sinus arrest, heart block, and asystole.[56] In contrast, intravenous anesthetics cause a decrease in blood pressure and an increase in the heart rate, with ketamine being the only drug in this category that causes elevated blood pressure.[56] The recommended induction dose of ketamine is 0.5-1.0 mg.kg-1 intravenously or 2-4 mg.kg-1 intramuscularly.[56] Therefore, in the case report by Canbay et al.,[43] the dose of ketamine with midazolam was too high for sedation, resulting in cardiac arrest of patient.

Although bradycardia and hypertension were seen frequently in the patients with BS, anesthesia application was generally carried out without complications. In fact, there was only one case in which this might have played in role in the mortality of a patient,[42] but major surgery most likely also contributed. Although propofol was used safely in most of the cases, it was noteworthy that some patients developed complications due to this drug.

A website (http://www.brugadadrugs.org) has recommended that propofol and bupivacaine not be used as anesthetics for BS patients and that lidocaine, ketamine, and tramadole should preferably be avoided.[57] Barajas-Martínez et al.[58] stated that lidocaine creates a BS-like ECG pattern. However, no proof has been offered that shows a connection between adverse outcomes and the anesthetic application of lidocaine in BS. In addition, there were two case reports that mentioned the BS-like ECG changes that occurred with ketamine[59] and tramadol,[52] but these were related to overdose not anesthesia.

In most cases of BS, general anesthesia is preferred. Vernooy et al.[40] have tried no other local anesthetic except for bupivacaine. Therefore, it is difficult to determine whether bupivacaine or the anesthetic technique they have used was responsible for the worsening clinical conditions in the patients in their study. General anesthesia was also used for the patient who died;[42] however, it is important to reiterate that the patient also underwent major surgery. In one patient for whom an ICD had been inserted, the first application of anesthesia resulted in cardiac arrest, but general anesthesia was performed without any further complications.[43] In that case, the cardiac arrest was associated with the larger dose of ketamine (5 mg.kg-1) and not the anesthetic technique.

Our research had two significant limitations. Not only did we evaluate only English sources, but we also excluded cases involving PRIS. Being unable to access full texts or at least abstracts of Asian case reports that met our criteria of inclusion[60-63] meant we had to ignore articles in countries where the incidence of BS is the highest. Moreover, although BS-like ECG changes occur in PRIS cases and these changes are regarded as an early indicator of death, no gene analysis was carried out for these patients.[64] Therefore, no clear connection between PRIS and BS could be established.

In conclusion, patients with family members who have experienced sudden death must be carefully evaluated for BS in the preoperative period. Prior to any surgical procedures, the patients must be monitored and a defibrillator must be made available in the operating room. However, after the necessary research has been done and the probable risk classification[65] has been determined for those who are thought to have BS, anesthetic agents can be carefully applied by taking into account their pharmacological features and potential adverse effects.

Declaration of conflicting interests
The authors declared no conflicts of interest with respect to the authorship and/or publication of this article.

Funding
The authors received no financial support for the research and/or authorship of this article.

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Keywords : Anesthesia; anesthetic drug; Brugada syndrome
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