395. Beyond the Boards: Channelopathies with Dr. Michael Ackerman

Dr. Amit Goyal, along with episode chair Dr. Dinu Balanescu (Mayo Clinic, Rochester), and FIT leads Dr. Sonu Abraham (University of Kentucky) and Dr. Natasha Vedage (MGH), dive into the fascinating topic of channelopathies with Dr. Michael Ackerman, a genetic cardiologist and professor of medicine, pediatrics, and pharmacology at Mayo Clinic, Rochester, Minnesota. Using a case-based approach, they review the nuances of diagnosis and treatment of channelopathies, including Brugada syndrome, catecholaminergic polymorphic ventricular tachycardia (CPVT), and long QT syndrome. Dr. Sonu Abraham drafted show notes. Audio engineering for this episode was expertly handled by CardioNerds intern, Christiana Dangas. The CardioNerds Beyond the Boards Series was inspired by the Mayo Clinic Cardiovascular Board Review Course and designed in collaboration with the course directors Dr. Amy Pollak, Dr. Jeffrey Geske, and Dr. Michael Cullen. CardioNerds Beyond the Boards SeriesCardioNerds Episode PageCardioNerds AcademyCardionerds Healy Honor Roll CardioNerds Journal ClubSubscribe to The Heartbeat Newsletter!Check out CardioNerds SWAG!Become a CardioNerds Patron! Pearls and Quotes - Channelopathies One cannot equate the presence of type 1 Brugada ECG pattern to the diagnosis of Brugada syndrome. Clinical history, family history, and/or genetic testing results are required to make a definitive diagnosis. The loss-of-function variants in the SCN5A gene, which encodes for the α-subunit of the NaV1.5 sodium channel, is the only Brugada susceptibility gene with sufficient evidence supporting pathogenicity. Exertional syncope is an “alarm” symptom that demands a comprehensive evaluation with 4 diagnostic tests: ECG, echocardiography, exercise treadmill test, and Holter monitor. Think of catecholaminergic polymorphic ventricular tachycardia (CPVT) in a patient with exertional syncope and normal EKG! ICD therapy is never prescribed as monotherapy in patients with CPVT. Medical therapy with a combination of nadolol plus flecainide is the current standard of care. Long QT syndrome is one of the few clinical scenarios where genetic testing clearly guides management, particularly with respect to variability in beta-blocker responsiveness. Notes - Channelopathies 1. What are the diagnostic criteria for Brugada syndrome (BrS)? Three repolarization patterns are associated with Brugada syndrome in the right precordial leads (V1-V2): Type 1: Prominent coved ST-segment elevation displaying J-point amplitude or ST-segment elevation ≥2 mm, followed by a negative T wave. Type 2/3: Saddleback ST-segment configuration with variable levels of ST-segment elevation. It is important to note that only a type 1 pattern is diagnostic for Brugada syndrome, whereas patients with type 2/3 patterns may benefit from further testing. The Shanghai score acknowledges that relying solely on induced type 1 ECG changes has limitations. Therefore, one cannot equate the presence of a type 1 Brugada ECG pattern alone to the diagnosis of Brugada syndrome. The score suggests incorporating additional information—such as clinical history, family history, and/or genetic testing results—to achieve a definitive diagnosis. 2. What is the significance of genetic testing in Brugada syndrome? There are 23 alleged Brugada syndrome susceptibility genes published with varying levels of evidence. However, only one gene mutation, the loss-of-function variants in the SCN5A gene encoding for the α-subunit of the NaV1.5 sodium channel, is considered to have sufficient evidence. The overall yield of BrS genetic testing is 20%. The presence of PR prolongation (>200 ms) along with type I EKG pattern increases the yield to 40%. On the contrary, in the presence of a normal PR interval, the likelihood of SCN5A positivity drops to 460 ms. 10. What are the three primary mutations implicated in Long QT syndrome? LQT1 (30-40% of cases) Mutation: loss of function in potassium channel gene KCNQ1 ECG: broad-based T wave Trigger: activity, adrenaline, exercise BB responsiveness: +++ (nadolol or propranolol) LQT2 (second most common) Mutation: loss of function in potassium channel gene KCNH2 ECG: notched T wave Trigger: auditory (alarm clock), post-partum BB responsiveness: ++ LQT3 Mutation: gain of function or leakiness of sodium channel SCN5A (note: BrS is due to loss of function in the same gene) ECG: normal T wave after prolonged isoelectric ST segment Trigger: none, but typically happens during rest BB responsiveness: + (propranolol); may consider combination therapy with mexiletine or mexiletine monotherapy. References - Channelopathies Charles Antzelevitch, Gan-Xin Yan, Michael J. Ackerman, Arthur A.M. Wilde et al. J-Wave syndromes expert consensus conference report: Emerging concepts and gaps in knowledge, EP Europace, Volume 19, Issue 4, April 2017, Pages 665–694 Krahn AD, Behr ER, Hamilton R, Probst V, Laksman Z, Han HC. Brugada Syndrome. JACC Clin Electrophysiol. 2022 Mar;8(3):386-405. PMID: 35331438. Chockalingam, P, Crotti, L, Girardengo, G. et al. Not All Beta-Blockers Are Equal in the Management of Long QT Syndrome Types 1 and 2: Higher Recurrence of Events Under Metoprolol. JACC. 2012 Nov, 60 (20) 2092–2099 Priori SG, Wilde AA, Tracy C et al. HRS/EHRA/APHRS expert consensus statement on the diagnosis and management of patients with inherited primary arrhythmia syndromes: document endorsed by HRS, EHRA, and APHRS in May 2013 and by ACCF, AHA, PACES, and AEPC in June 2013. Heart Rhythm. 2013 Dec;10(12):1932-63. PMID: 24011539. Viskin S, Rosovski U, Zeltser D et al. Inaccurate electrocardiographic interpretation of long QT: the majority of physicians cannot recognize a long QT when they see one. Heart Rhythm. 2005 Jun;2(6):569-74. PMID: 15922261. Horner JM, Ackerman MJ. Ventricular ectopy during treadmill exercise stress testing in the evaluation of long QT syndrome. Heart Rhythm. 2008 Dec;5(12):1690. PMID: 19084807; PMCID: PMC3281579.