Long QT syndrome

Long QT syndrome
Schematic representation of normal ECG trace (sinus rhythm) with waves, segments, and intervals labeled. The QT interval is marked by blue stripe at bottom.
Classification and external resources
Specialty Cardiology
ICD-10 I45.8
ICD-9-CM 426.82
DiseasesDB 11104
eMedicine med/1983
MeSH D008133

Long QT syndrome (LQTS) is a rare congenital and inherited or acquired heart condition in which delayed repolarization of the heart following a heartbeat increases the risk of episodes of torsades de pointes (TdP, a form of irregular heartbeat that originates from the ventricles). These episodes may lead to fainting and sudden death due to ventricular fibrillation. Episodes may be provoked by various stimuli, depending on the subtype of the condition.[1]

The condition is named for the appearance of the electrocardiogram (ECG/EKG) on which a prolongation of the QT interval occurs. Normally, the QT interval duration is between 350 and 440 milliseconds.[2] In some individuals, the QT prolongation occurs after the administration of certain medications, which may be dangerous.[1] In addition to medications, long QT syndrome can be acquired from too low blood potassium or low blood magnesium, as in anorexia nervosa.

Signs and symptoms

Many people with long QT syndrome have no signs or symptoms.[3]

Some people may experience the following symptoms:

Risk factors

Risk factors for long QT syndrome include the following:[4]

Anorexia nervosa has been associated with sudden death, possibly due to QT prolongation. It can lead a person to have dangerous electrolyte imbalances, leading to acquired long QT syndrome and can in turn result in sudden cardiac death. This can develop over a prolonged period of time, and the risk is further heightened when feeding resumes after a period of abstaining from consumption. Care must be taken under such circumstances to avoid complications of refeeding syndrome.[5]

Pathophysiology

All forms of LQTS involve an abnormal repolarization of the heart, which causes differences in the refractory period of the heart muscle cells (myocytes). After-depolarizations (which occur more commonly in LQTS) can be propagated to neighboring cells due to the differences in the refractory periods, leading to re-entrant ventricular arrhythmias.

The so-called early after-depolarizations (EADs) seen in LQTS are believed to be due to reopening of L-type calcium channels during the plateau phase of the cardiac action potential. Since adrenergic stimulation can increase the activity of these channels, this is an explanation for why the risk of sudden death in individuals with LQTS is increased during increased adrenergic states (i.e., exercise, excitement), especially since repolarization is impaired. Normally during adrenergic states, repolarizing currents also are enhanced to shorten the action potential. In the absence of this shortening and the presence of increased L-type calcium current, EADs may arise.

The so-called delayed after-depolarizations are thought to be due to an increased Ca2+ filling of the sarcoplasmic reticulum. This overload may cause spontaneous Ca2+ release during repolarization, causing the released Ca2+ to exit the cell through the 3Na+/Ca2+-exchanger, which results in a net depolarizing current.

Genetics

LQTS can arise from mutation of one of several genes.[6] These mutations tend to prolong the duration of the ventricular action potential (APD), thus lengthening the QT interval. LQTS can be inherited in an autosomal dominant or a much less common autosomal recessive fashion.[7] The autosomal recessive forms of LQTS tend to have a more severe phenotype, with two variants having associated with other congenital heart disease, autism, immune deficiency and complex syndactyly (LQT8) or congenital neural deafness (LQT1). A number of specific gene loci have been identified to be associated with LQTS. Genetic testing for LQTS is clinically available and may help to direct appropriate therapies . The most common causes of LQTS are mutations in the genes KCNQ1 (LQT1), KCNH2 (LQT2), and SCN5A (LQT3);[2] the following is a list of all known genes associated with LQTS:

Type OMIM Mutation Notes
LQT1 192500 alpha subunit of the slow delayed rectifier potassium channel (KvLQT1 or KCNQ1)[2] The current through the heteromeric channel (KvLQT1 + minK) is known as IKs. These mutations often cause LQT by reducing the amount of repolarizing current, which is required to terminate the action potential, leading to an increase in the action potential duration. These mutations tend to be the most common yet least severe.
LQT2 152427 Alpha subunit of the rapid delayed rectifier potassium channel (hERG + MiRP1)[2] Current through this channel is known as IKr. This phenotype is also probably caused by a reduction in repolarizing current.
LQT3 603830 alpha subunit of the sodium channel (SCN5A) Current through this channel is commonly referred to as INa. Depolarizing current through the channel late in the action potential is thought to prolong APD. The late current is due to the failure of the channel to remain inactivated. As a consequence, it can enter a bursting mode, during which significant current enters abruptly when it should not. These mutations are more lethal but less common.
LQT4 600919 anchor protein Ankyrin B LQT4 is very rare. Ankyrin B anchors the ion channels in the cell.
LQT5 176261 beta subunit MinK (or KCNE1), which coassembles with KvLQT1 -
LQT6 603796 beta subunit MiRP1 (or KCNE2), which coassembles with hERG -
LQT7 170390 potassium channel KCNJ2 (or Kir2.1) The current through this channel and KCNJ12 (Kir2.2) is called IK1. LQT7 leads to Andersen-Tawil syndrome.
LQT8 601005 alpha subunit of the calcium channel Cav1.2 encoded by the gene CACNA1c. Leads to Timothy's syndrome.
LQT9 611818 Caveolin 3
LQT10 611819 SCN4B
LQT11 611820 AKAP9
LQT12 601017 SNTA1
LQT13 600734 GIRK4
LQT14 616247 CALM1
LQT15 616249 CALM2
LQT1

LQT1 is the most common type of long QT syndrome,[2] making up about 30 to 35% of all cases. The LQT1 gene is KCNQ1, which has been isolated to chromosome 11p15.5. KCNQ1 codes for the voltage-gated potassium channel KvLQT1 that is highly expressed in the heart. The product of the KCNQ1 gene is thought to produce an alpha subunit that interacts with other proteins (in particular, the minK beta subunit) to create the IKs ion channel, which is responsible for the delayed potassium rectifier current of the cardiac action potential.

Mutations to KCNQ1 can be inherited in an autosomal dominant or an autosomal recessive pattern in the same family. In the autosomal recessive mutation of this gene, homozygous mutations lead to severe prolongation of the QT interval (due to near-complete loss of the IKs ion channel), and are associated with increased risk of ventricular arrhythmias and congenital deafness. This variant of LQT1 is known as the Jervell and Lange-Nielsen syndrome.[8] Furthermore, LQT1 patients also have an endocrine phenotype. During a glucose load, LQT1 patients respond with an exaggerated insulin secretion followed by a temporary insulin resistance. When the resistance diminishes, LQT1 patients are at risk for hypoglycaemia.[9]

Most individuals with LQT1 show paradoxical prolongation of the QT interval with infusion of epinephrine. This can also unmark latent carriers of the LQT1 gene. Many missense mutations of the LQT1 gene have been identified. These are often associated with a high frequency of syncopes, but less sudden death than LQT2.

LQT2

The LQT2 type is the second-most common gene location in long QT syndrome, making up about 25 to 30% of all cases. This form of long QT syndrome most likely involves mutations of the 'human ether-a-go-go related gene' (hERG) on chromosome 7. The hERG gene (also known as KCNH2) is part of the rapid component of the potassium rectifying current (IKr). (The IKr current is mainly responsible for the termination of the cardiac action potential, and therefore the length of the QT interval.) The normally functioning hERG gene allows protection against early after depolarizations.[10]

Most drugs that cause long QT syndrome do so by blocking the IKr current via the hERG gene. These include erythromycin, terfenadine, and ketoconazole. The hERG channel is very sensitive to unintended drug binding due to two aromatic amino acids, the tyrosine at position 652 and the phenylalanine at position 656. These amino acid residues are poised so a drug binding to them blocks the channel from conducting current. Other potassium channels do not have these residues in these positions, so are, therefore, not as prone to blockage.

LQT3

The LQT3 type of long QT syndrome involves mutation of the gene that encodes the alpha subunit of the Na+ ion channel. This gene is located on chromosome 3p21-24, and is known as SCN5A (also hH1 and NaV1.5). The mutations involved in LQT3 slow the inactivation of the Na+ channel, resulting in prolongation of the Na+ influx during depolarization. However, the mutant sodium channels inactivate more quickly, and may open repetitively during the action potential.

A large number of mutations have been characterized as leading to or predisposing to LQT3. Calcium has been suggested as a regulator of SCN5A protein, and the effects of calcium on SCN5A may begin to explain the mechanism by which some these mutations cause LQT3. Furthermore, mutations in SCN5A can cause Brugada syndrome, cardiac conduction disease, and dilated cardiomyopathy. In rare situations, some affected individuals can have combinations of these diseases.

LQT5

LQT5 is an autosomal-recessive, relatively uncommon form of LQTS. It involves mutations in the gene KCNE1, which encodes for the potassium channel beta subunit MinK. In its rare homozygous forms, it can lead to Jervell and Lange-Nielsen syndrome.

LQT6

LQT6 is an autosomal-dominant, relatively uncommon form of LQTS. It involves mutations in the gene KCNE2, which encodes for the potassium channel beta subunit MiRP1, constituting part of the IKr repolarizing K+ current.

LQT7

Andersen-Tawil syndrome is an autosomal-dominant form of LQTS associated with skeletal deformities. It involves mutation in the gene KCNJ2, which encodes for the potassium channel protein Kir 2.1. The syndrome is characterized by LQTS with ventricular arrhythmias, periodic paralysis, and skeletal developmental abnormalities such as clinodactyly, low-set ears, and micrognathia. The manifestations are highly variable.[11]

LQT8

Timothy's syndrome is due to mutations in the calcium channel Cav1.2 encoded by the gene CACNA1c. Since the calcium channel Cav1.2 is abundant in many tissues, patients with Timothy's syndrome have many clinical manifestations, including other congenital heart disease, autism, immune deficiency and complex syndactyly.[12]

LQT9

This newly discovered variant is caused by mutations in the membrane structural protein, caveolin-3. Caveolins form specific membrane domains called caveolae in which, among others, the NaV1.5 voltage-gated sodium channel sits. Similar to LQT3, these particular mutations increase so-called 'late' sodium current, which impairs cellular repolarization.

LQT10

This novel susceptibility gene for LQT is SCN4B encoding the protein NaVβ4, an auxiliary subunit to the pore-forming NaV1.5 (gene: SCN5A) subunit of the voltage-gated sodium channel of the heart. The mutation leads to a positive shift in inactivation of the sodium current, thus increasing sodium current. Only one mutation in one patient has so far been found.

LQT13

GIRK4 is involved in the parasympathetic modulation of the heart. Clinically, the patients are characterized by only modest QT prolongation, but an increased propensity for atrial arrhythmias.[13]

LQT14

LQT14 is caused by heterozygous mutations in the CALM1 (Calmodulin 1) gene (114180) on chromosome 14q32.

LQT15

LQT15 is caused by heterozygous mutations in the CALM2 (Calmodulin 2) gene (114182) on chromosome 2p21.

Jervell and Lange-Nielsen syndrome

Jervell and Lange-Nielsen syndrome (JLNS) is an autosomal-recessive form of LQTS with associated congenital deafness. It is caused specifically by mutation of the KCNE1 and KCNQ1 genes.

In untreated individuals with JLNS, about 50% die by the age of 15 years due to ventricular arrhythmias.

Romano-Ward syndrome

Romano-Ward syndrome is an autosomal-dominant form of LQTS not associated with deafness. The diagnosis is clinical and is now less commonly used in centres where genetic testing is available, in favour of the LQT number scheme given above.

Pharmacology

Drug-induced QT prolongation is usually a result of treatment by antiarrhythmic drugs such as amiodarone and sotalol or a number of other drugs that have been reported to cause this problem (e.g., cisapride). Some antipsychotic drugs, such as haloperidol and ziprasidone, have a prolonged QT interval as a rare side effect. Genetic mutations may make one more susceptible to drug-induced LQT. The antidepressant citalopram is also associated with an increased risk of long QT syndrome.

Diagnosis

The diagnosis of LQTS is not easy since 2.5% of the healthy population has prolonged QT interval, and 1015% of LQTS patients have a normal QT interval.[14] A commonly used criterion to diagnose LQTS is the LQTS "diagnostic score",[15] calculated by assigning different points to various criteria (listed below). With four or more points, the probability is high for LQTS; with one point or less, the probability is low.[2] A score of two or three points indicates intermediate probability.[2]

Treatment

Those diagnosed with LQTS are usually advised to avoid drugs that would prolong the QT interval further or lower the threshold for TDP.[16] In addition to this, two intervention options are known for individuals with LQTS: arrhythmia prevention and arrhythmia termination.

Arrhythmia prevention

Arrhythmia suppression involves the use of medications or surgical procedures that attack the underlying cause of the arrhythmias associated with LQTS. Since the cause of arrhythmias in LQTS is EADs, and they are increased in states of adrenergic stimulation, steps can be taken to blunt adrenergic stimulation in these individuals. These include administration of beta receptor blocking agents, which decreases the risk of stress-induced arrhythmias. Beta blockers are an effective treatment for LQTS caused by LQT1 and LQT2.[2]

Genotype and QT interval duration are independent predictors of recurrence of life-threatening events during beta-blocker therapy. To be specific, the presence of QTc >500 ms and LQT2 and LQT3 genotype are associated with the highest incidence of recurrence. In these patients, primary prevention with use of implantable cardioverter-defibrillators can be considered.[2]

Arrhythmia termination

Arrhythmia termination involves stopping a life-threatening arrhythmia once it has already occurred. One effective form of arrhythmia termination in individuals with LQTS is placement of an implantable cardioverter-defibrillator (ICD). Also, external defibrillation can be used to restore sinus rhythm. ICDs are commonly used in patients with fainting episodes despite beta blocker therapy, and in patients having experienced a cardiac arrest.

With better knowledge of the genetics underlying LQTS, more precise treatments hopefully will become available.[17]

Prognosis

The risk for untreated LQTS patients having events (syncopes or cardiac arrest) can be predicted from their genotype (LQT1-8), gender, and corrected QT interval.[18]

A 1992 study reported that mortality for symptomatic, untreated patients was 20% within the first year and 50% within the first 10 years after the initial syncope.[19]

Epidemiology

Inherited LQTS is estimated to affect between one in 2,500 and 7,000 people.[2]

History

The first documented case of LQTS was described in Leipzig by Meissner in 1856, when a deaf girl died after her teacher yelled at her. When the parents were notified of her death, they reported that her older brother, who also was deaf, died after a terrible fright.[20] This was several decades before the ECG was invented, but is likely the first described case of Jervell and Lange-Nielsen syndrome. In 1957, the first case documented by ECG was described by Anton Jervell and Fred Lange-Nielsen, working in Tønsberg, Norway.[21] Italian pediatrician Cesarino Romano, in 1963,[22] and Irish pediatrician Owen Conor Ward, in 1964,[23] separately described the more common variant of LQTS with normal hearing, later called Romano-Ward syndrome. The establishment of the International Long-QT Syndrome Registry in 1979 allowed numerous pedigrees to be evaluated in a comprehensive manner. This helped in detecting many of the numerous genes involved.[24]

See also

[25]

References

  1. 1 2 Morita H, Wu J, Zipes DP; Wu; Zipes (August 2008). "The QT syndromes: long and short". Lancet. 372 (9640): 750–63. PMID 18761222. doi:10.1016/S0140-6736(08)61307-0.
  2. 1 2 3 4 5 6 7 8 9 10 11 12 Levine E, Rosero SZ, Budzikowski AS, Moss AJ, Zareba W, Daubert JP; Rosero; Budzikowski; Moss; Zareba; Daubert (August 2008). "Congenital long QT syndrome: considerations for primary care physicians". Cleve Clin J Med. 75 (8): 591–600. PMID 18756841.
  3. "Long QT syndrome - Symptoms".
  4. Thomson, Clare; Wright, Paul (2014-10-15). "Long QT syndrome". The Pharmaceutical Journal. 293 (7833). Retrieved 18 October 2014.
  5. Jáuregui-Lobera, Ignacio; Jáuregui-Garrido (February 2012). "Sudden death in eating disorders". Vascular Health and Risk Management. 8: 91–8. PMC 3292410Freely accessible. PMID 22393299. doi:10.2147/VHRM.S28652.
  6. Hedley PL; Jorgensen P; Schlamowitz S; Wangari, Romilda; et al. (2009). "The genetic basis of long QT and short QT syndromes: a mutation update". Human Mutation. 30 (11): 1486–511. PMID 19862833. doi:10.1002/humu.21106.
  7. Goldman 2011, pp. 185
  8. Arrhythmia/Electrophysiology The Jervell and Lange-Nielsen Syndrome Natural History, Molecular Basis, and Clinical Outcome Peter J. Schwartz, MD; Carla Spazzolini, DVM; Lia Crotti, MD; Jørn Bathen, MD; Jan P. Amlie, MD; Katherine Timothy, RN; Maria Shkolnikova, MD; Charles I. Berul, MD; Maria Bitner-Glindzicz, MD; Lauri Toivonen, MD; Minoru Horie, MD; Eric Schulze-Bahr, MD; Isabelle Denjoy, MD; https://circ.ahajournals.org/content/113/6/783.abstract. Circulation. 2006; 113: 783-790 doi: 10.1161/CIRCULATIONAHA.105.592899
  9. Torekov SS, Iepsen E, Christiansen M, et al. (2014). "KCNQ1 Long QT syndrome patients have hyperinsulinemia and symptomatic hypoglycemia.". Diabetes. 63 (4): 1315–25. PMID 24357532. doi:10.2337/db13-1454.
  10. Shinnawi R, Gepstein L; Gepstein (September 2014). "iPS Cell Modeling of Inherited Cardiac Arrhythmias". Curr Treat Options Cardiovasc Med. 16 (9): 331. PMID 25080030. doi:10.1007/s11936-014-0331-4.
  11. Tristani-Firouzi M, Jensen JL, Donaldson MR, et al. (2002). "Functional and clinical characterization of KCNJ2 mutations associated with LQT7 (Andersen syndrome)". J. Clin. Invest. 110 (3): 381–8. PMC 151085Freely accessible. PMID 12163457. doi:10.1172/JCI15183. |first10= missing |last10= in Authors list (help); |first11= missing |last11= in Authors list (help)
  12. Shah, Dipak P.; Baez-Escudero, Jose L.; Weisberg, Ian L.; Beshai, John F.; Burke, Martin C. (2012). "Ranolazine Safely Decreases Ventricular and Atrial Fibrillation in Timothy Syndrome (LQT8)". Pacing and Clinical Electrophysiology. 35 (3): e62–e64. ISSN 0147-8389. doi:10.1111/j.1540-8159.2010.02913.x.
  13. Wang F, Liu J, Hong L, et al. (2013). "The phenotype characteristics of type 13 long QT syndrome with mutation in KCNJ5 (Kir3.4-G387R).". Heart Rhythm. 10 (10): 1500–6. PMID 23872692. doi:10.1016/j.hrthm.2013.07.022.
  14. Moric-Janiszewska E, Markiewicz-Łoskot G, Loskot M, Weglarz L, Hollek A, Szydlowski L; Markiewicz-Łoskot; Łoskot; Weglarz; Hollek; Szydłowski (2007). "Challenges of diagnosis of long-QT syndrome in children". Pacing Clin Electrophysiol. 30 (9): 11681170. PMID 17725765. doi:10.1111/j.1540-8159.2007.00832.x.
  15. Schwartz PJ, Moss AJ, Vincent GM, Crampton RS; Moss; Vincent; Crampton (1993). "Diagnostic criteria for the long QT syndrome. An update". Circulation. 88 (2): 782–4. PMID 8339437. doi:10.1161/01.CIR.88.2.782.
  16. "QT Drug List by Risk Groups". Arizona Center for Education and Research on Therapeutics. Retrieved 2010-07-04.
  17. Compton SJ, Lux RL, Ramsey MR, et al. (1996). "Genetically defined therapy of inherited long-QT syndrome. Correction of abnormal repolarization by potassium". Circulation. 94 (5): 1018–22. PMID 8790040. doi:10.1161/01.CIR.94.5.1018.
  18. Ellinor PT, Milan DJ, MacRae CA; Milan; MacRae (2003). "Risk stratification in the long-QT syndrome". N. Engl. J. Med. 349 (9): 908–9. PMID 12944579. doi:10.1056/NEJM200308283490916.
  19. Schwartz, P. J.; Moss, A. J.; Vincent, G. M.; Crampton, R. S. (1993-08-01). "Diagnostic criteria for the long QT syndrome. An update.". Circulation. 88 (2): 782–784. ISSN 0009-7322. PMID 8339437. doi:10.1161/01.CIR.88.2.782.
  20. Tranebjaerg L, Bathen J, Tyson J, et al. (1999). "Jervell and Lange-Nielsen syndrome: a Norwegian perspective". American Journal of Medical Genetics. 89 (3): 137–46. PMID 10704188. doi:10.1002/(SICI)1096-8628(19990924)89:3<137::AID-AJMG4>3.0.CO;2-C.
  21. Jervell A, Lange-Nielsen F; Lange-Nielsen (July 1957). "Congenital deaf-mutism, functional heart disease with prolongation of the Q-T interval and sudden death". Am. Heart J. 54 (1): 59–68. PMID 13435203. doi:10.1016/0002-8703(57)90079-0.
  22. Romano C, Gemme G, Pongiglione R; Gemme; Pongiglione (September 1963). "Rare cardiac arrythmias of the pediatric age. II. Syncopal attacks due to paroxysmal ventricular fibrillation". Clin Pediatr (Bologna) (in Italian). 45: 656–83. PMID 14158288.
  23. Ward OC (April 1964). "A new familial cardiac syndrome in children". J Ir Med Assoc. 54: 103–6. PMID 14136838.
  24. Moss AJ; Schwartz PJ (2005). "25th Anniversary of the International Long-QT Syndrome Registry". Circulation. 111 (9): 1199–1201. PMID 15753228. doi:10.1161/01.CIR.0000157069.91834.DA.
  25. "Avs forward Konowalchuk retires after heart tests". ESPN. Associated Press. Sep 29, 2006. Retrieved 14 April 2017.

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