digoxin and Long-QT-Syndrome

The objective of this review is to characterize the mechanisms, risk factors, and offending pharmacotherapeutic agents that may cause drug-induced arrhythmias in critically ill patients. PubMed, other databases, and citation review were used to identify relevant published literature. The authors independently selected studies based on relevance to the topic. Numerous drugs have the potential to cause drug-induced arrhythmias. Drugs commonly administered to critically ill patients are capable of precipitating arrhythmias and include antiarrhythmics, antianginals, antiemetics, gastrointestinal stimulants, antibacterials, narcotics, antipsychotics, inotropes, digoxin, anesthetic agents, bronchodilators, and drugs that cause electrolyte imbalances and bradyarrhythmias. Drug-induced arrhythmias are insidious but prevalent. Critically ill patients frequently experience drug-induced arrhythmias; however, enhanced appreciation for this adverse event has the potential to improve prevention, treatment, patient safety, and outcomes in this patient population.

Topics: Anesthetics, Inhalation; Anti-Arrhythmia Agents; Arrhythmias, Cardiac; Bradycardia; Bronchodilator Agents; Cardiotonic Agents; Critical Care; Digoxin; Drug-Related Side Effects and Adverse Reactions; Humans; Long QT Syndrome; Risk Factors; Torsades de Pointes; Water-Electrolyte Balance

Individuals vary widely in their responses to therapy with most drugs. Indeed, responses to antiarrhythmic drugs are so highly variable that study of the underlying mechanisms has elucidated important lessons for understanding variable responses to drug therapy in general. Variability in drug response may reflect variability in the relationship between a drug dose and the concentrations of the drug and metabolite(s) at relevant target sites; this is termed pharmacokinetic variability. Another mechanism is that individuals vary in their response to identical exposures to a drug (pharmacodynamic variability). In this case, there may be variability in the target molecule(s) with which a drug interacts or, more generally, in the broad biological context in which the drug-target interaction occurs. Variants (polymorphisms and mutations) in the genes that encode proteins that are important for pharmacokinetics or for pharmacodynamics have now been described as important contributors to variable drug actions, including proarrhythmia, and these are described in this review. However, the translation of pharmacogenetics into clinical practice has been slow. To this end, the creation of large, well-characterised DNA databases and appropriate control groups, as well as large prospective trials to evaluate the impact of genetic variation on drug therapy, may hasten the impact of pharmacogenetics and pharmacogenomics in terms of delivering personalised drug therapy and to avoid therapeutic failure and serious side effects.

Topics: Anti-Arrhythmia Agents; Arrhythmias, Cardiac; Arylamine N-Acetyltransferase; ATP Binding Cassette Transporter, Subfamily B, Member 1; Cytochrome P-450 CYP2D6; Digoxin; Humans; Long QT Syndrome; Personal Health Services; Pharmacogenetics; Polymorphism, Genetic; Potassium Channels; Propafenone; Risk Factors; Sodium Channel Blockers; Sodium Channels; Torsades de Pointes

Digoxin is characterized by a small therapeutic window and a QT-interval shortening effect. Moreover, it has been shown that the genetic variants of the nitric oxide synthase-1 adaptor protein (NOS1AP) gene are associated with QT-interval prolongation. We investigated whether the rs10494366 variant of the NOS1AP gene decreases the QT-interval shortening effect of digoxin in patients using this drug. We included 10,057 individuals from the prospective population-based cohort of the Rotterdam Study during a median of 12.2 (interquartile range (IQR) 6.7-18.1) years of follow-up. At study entry, the mean age was 64 years and almost 59% of participants were women. A total of 23,179 ECGs were longitudinally recorded, of which 334 ECGs were from 249 individuals on digoxin therapy. The linear mixed model analysis was used to estimate the effect of the rs10494366 variant on the association between digoxin use and QT-interval duration, adjusted for age, sex, RR interval, diabetes, heart failure, and history of myocardial infarction. In non-users of digoxin, the GG genotype was associated with a significant 6.5 ms [95% confidence interval (CI) 5.5; 7.5] longer QT-interval duration than the TT variant. In current digoxin users, however, the GG variant was associated with a significantly -23.9 [95%CI -29.5; -18.5] ms shorter mean QT-interval duration than in those with the TT variant with -15.9 [95%CI -18.7; -13.1]. This reduction was strongest in the high digoxin dose category [≥0.250 mg/day] with the GG genotype group, with -40.8 [95%CI -52.5; -29.2] ms changes compared to non-users. Our study suggests that the minor homozygous GG genotype group of the NOS1AP gene rs10494366 variant is associated with a paradoxical increase of the QT-interval shortening effect of digoxin in a population of European ancestry.

Topics: Adaptor Proteins, Signal Transducing; Aged; Aged, 80 and over; Cardiotonic Agents; Digoxin; Electrocardiography; Female; Follow-Up Studies; Genetic Variation; Genotype; Humans; Linear Models; Long QT Syndrome; Longitudinal Studies; Male; Middle Aged; Prospective Studies; Treatment Outcome

Membrane trafficking in concert with the peripheral quality control machinery plays a critical role in preserving plasma membrane (PM) protein homeostasis. Unfortunately, the peripheral quality control may also dispose of partially or transiently unfolded polypeptides and thereby contribute to the loss-of-expression phenotype of conformational diseases. Defective functional PM expression of the human ether-a-go-go-related gene (hERG) K(+) channel leads to the prolongation of the ventricular action potential that causes long QT syndrome 2 (LQT2), with increased propensity for arrhythmia and sudden cardiac arrest. LQT2 syndrome is attributed to channel biosynthetic processing defects due to mutation, drug-induced misfolding, or direct channel blockade. Here we provide evidence that a peripheral quality control mechanism can contribute to development of the LQT2 syndrome. We show that PM hERG structural and metabolic stability is compromised by the reduction of extracellular or intracellular K(+) concentration. Cardiac glycoside-induced intracellular K(+) depletion conformationally impairs the complex-glycosylated channel, which provokes chaperone- and C-terminal Hsp70-interacting protein-dependent polyubiquitination, accelerated internalization, and endosomal sorting complex required for transport-dependent lysosomal degradation. A similar mechanism contributes to the down-regulation of PM hERG harboring LQT2 missense mutations, with incomplete secretion defect. These results suggest that PM quality control plays a determining role in the loss-of-expression phenotype of hERG in certain hereditary and acquired LTQ2 syndromes.

Topics: Adaptor Proteins, Signal Transducing; Cardiac Glycosides; Cardiotonic Agents; Cation Transport Proteins; Cell Line, Tumor; Cell Membrane; Digoxin; Down-Regulation; Endosomal Sorting Complexes Required for Transport; Enzyme Inhibitors; Ether-A-Go-Go Potassium Channels; Heart; HEK293 Cells; HeLa Cells; Humans; Long QT Syndrome; Ouabain; Patch-Clamp Techniques; Potassium; Protein Folding; Protein Transport; RNA Interference; RNA, Small Interfering; Ubiquitination

Topics: Adolescent; Bone Marrow Transplantation; Digoxin; Drug Therapy, Combination; Electrocardiography, Ambulatory; Heart Arrest; Humans; Immunosuppressive Agents; Long QT Syndrome; Male; Tachycardia, Sinus; Tacrolimus

Topics: Adolescent; Arrhythmias, Cardiac; Digoxin; Humans; Long QT Syndrome; Male; Sinoatrial Block

Quinidine therapy is one of the most common causes of the acquired long QT syndrome and torsade de pointes. In reviewing clinical data in 24 patients with the quinidine-associated long QT syndrome, 20 of whom had torsade de pointes, we have delineated several heretofore unreported or underemphasized features. (1) This adverse drug reaction occurred either in patients who were being treated for frequent nonsustained ventricular arrhythmias or for atrial fibrillation or flutter. (2) In patients being treated for atrial fibrillation, torsade de pointes occurred only after conversion to sinus rhythm. (3) Although most patients developed the syndrome within days of starting quinidine, four had torsade de pointes during long-term quinidine therapy, usually in association with hypokalemia. (4) Because of the large experience with this entity at our institution, we have been able to estimate the risk as at least 1.5% per year. (5) Twenty of the 24 patients had at least one major, easily identifiable, associated risk factor including serum potassium below 3.5 mEq/L (four); serum potassium between 3.5 and 3.9 mEq/L (nine); high-grade atrioventricular block (four); and marked underlying, (unrecognized) QT prolongation (two). Plasma quinidine concentrations were low, being at or below the lower limit of the therapeutic range in half of patients. The ECG features typically included absence of marked QRS widening, marked QT prolongation (by definition), and a stereotypic series of cycle length changes just prior to the onset of torsade de pointes. Torsade de pointes started after the T wave of a markedly prolonged QT interval that followed a cycle that had been markedly prolonged (usually by a post ectopic pause).(ABSTRACT TRUNCATED AT 250 WORDS)

Topics: Adolescent; Adult; Aged; Arrhythmias, Cardiac; Digoxin; Electrocardiography; Female; Heart Ventricles; Humans; Long QT Syndrome; Male; Middle Aged; Potassium; Quinidine; Tachycardia