Assessing Risk of QTC Prolongation

Publication
Article
Psychiatric TimesPsychiatric Times Vol 21 No 6
Volume 21
Issue 6

Monitoring patients for possible QTC prolongation with psychotropic use can be difficult--even more so in children or adolescents. What screening and treatment techniques should be used for maximum therapeutic benefit with minimum cardiac risk?

Certain psychotropic medications and somatic medications can increase the risk of lethal torsade de pointes through a mechanism of blocking cardiac conduction channels (e.g., Na+, K+ and/or Ca++). The best available parameter for assessing risk of torsade de pointes is measuring the rate-corrected QT interval (QTC) on electrocardiogram (Labellarte et al., 2003a; Tisdale et al., 2001).

While it is necessary to identify whether or not a psychotropic medication can prolong QTC alone or in combination with other medications, the list of marketed medications that are known to prolong QTC is incomplete (Labellarte et al., 2003a). Available QTC safety data are a hodgepodge of post-marketing clinician case reports, animal and human myocyte conduction studies using proprietary technology, and treatment studies screening for QTC prolongation. Of the medications known to prolong QTC, some are more dangerous than others at clinical doses, in overdose or in combination with other medications.

Few of the studies reporting cardiac safety of psychotropic medications have involved children and adolescents. Three practical guidelines discuss conservative screening and monitoring of children and adolescents who require treatment with psychotropics known or suspected to cause QTC prolongation (Labellarte et al., 2003a) (Table) .

Medications That Prolong QTC

The most comprehensive and easily accessed reference source for somatic and psychotropic medications known or suspected to cause QTC prolongation is at <www.Qtdrugs.org>. This Web site is maintained by the University of Arizona Center for Education and Research on Therapeutics in Tucson, Ariz. It lists cautious medication combinations by identifying which medications could cause additive pharmacodynamic risk when combined with psychotropics that prolong QTC.

A more concise list of psychotropics that can contribute to QTC prolongation is inspired by earlier recommendations from the American Heart Association (Gutgesell et al., 1999). The list contains no surprises: older medications (e.g., tricyclic antidepressants, phenothiazines, butyrophenones and pimozide [Orap]) that have been known for decades to cause QTC prolongation/torsade de pointes. The only newer medication on the list is ziprasidone (Geodon), which has caused a mild but measurable QTC prolongation in a comparison study (~21 msec) (Harrigan et al., 2004) but has not caused cardiac events in clinical or research settings (Daniel, 2003). In contrast to the old-school medications, ziprasidone's potential impact on ion channels has not been studied.

The older medications have not compared well in QTC monitoring studies of adults. Droperidol (Inapsine) caused the highest documented QTC prolongation (~59 msec) (Lischke et al., 1994) and also has the highest relative risk of causing QTC duration >450 msec (Reilly et al., 2000). Thioridazine (Mellaril) had the next highest relative risk (Reilly et al., 2000), and also caused noteworthy QTC prolongation (~30 msec to 36 msec) compared to haloperidol's (Haldol) minimal QTC prolongation (8 msec) in the comparison study by Harrigan and colleagues (2004). The impact of haloperidol on QTC duration/torsade de pointes has debatable clinical relevance (Di Salvo and O'Gara, 1995; Hatta et al., 2001), but haloperidol merits ECG monitoring in light of emerging data that its active metabolites may have different patterns of toxicity (Kalgutkar et al., 2003).

Important Drug Interactions

The most comprehensive and easily accessed reference source for pharmacokinetic interactions is maintained at <www.drug-interactions.com> by the Indiana University Department of Medicine.

While the Web site does not focus specifically on interactions that contribute to QTC prolongation, it is easy to extrapolate a working list of important medications that could cause worrisome metabolic inhibition and potentially increased risk of QTC prolongation.

In addition, protein-binding competition can potentially cause increased serum levels of medications that prolong QTC when combined with seemingly benign medications that are highly protein-bound (e.g., aspirin, valproic acid [Depakene], herbal preparations). Unclear pharmacokinetic mechanisms also result in increased exposure to psychotropics that prolong QTC with a few identified medication combinations, e.g., pimozide plus sertraline (Zoloft) (Zoloft package insert).

Pretreatment Risk Factors

Pretreatment risk factors of QTC prolongation are rare but can be easily screened. Screening includes pertinent medical history for signs/symptoms of cardiac events, including syncope-like events and pertinent family history for cardiac events such as syncope-like events, sudden death or congenital deafness (which can be associated with an inherited variant of long QT syndrome) (Ocal et al., 1997). Pretreatment laboratory test screening, when appropriate, would test serum for hyponatremia, hypokalemia or hypermagnesemia.

ECG Screening of QTC

Briefly, the QT interval represents the period of cardiac repolarization of the ventricular action potential. If the observed QT interval is too long, it suggests that cardiac repolarization is too slow and therefore unstable (Haddad and Anderson, 2002; Khan, 2002).

The range of normal QTC values in children and adolescents has roughly a mean of 400 msec with a standard deviation of 25 msec to 30 msec. Therefore, a QTC value that exceeds two standard deviations ( >450 msec to 460 msec) is too long. A QTC >450 msec is associated with increased mortality in the elderly (Labellarte et al., 2003a; Robbins et al., 2003), and QTC >500 msec is associated with increased mortality at all ages (Labellarte et al., 2003a; Moss, 1993).

Similarly, any prolongation from baseline that exceeds two standard deviations is too much; an increase in QTC >60 msec from baseline is also associated with increased mortality (Haddad and Anderson, 2002; Labellarte et al., 2003a).

However, measuring QTC duration is a limited clinical screening tool in pediatric psychopharmacology because of variability in rate-correction formulas (Tisdale et al., 2001); variability in clinician accuracy (Labellarte et al., 2003b); variability between expert clinician readings and ECG computerized printouts (Miller et al., 2001); and normal QTC variability related to fear, postural changes or time of day. Additionally, ECG measurement may not be sensitive enough to detect QTC disturbance. Most important, documentation of baseline QTC duration within the normal range is not a guarantee that environmental factors (including drug effects) will not cause QTC prolongation.

Psychiatrists should be able to screen ECGs for changes associated with QTC prolongation before and during treatment, but are not required to be experts on ECG interpretation. In addition, the computer readout of an ECG is not reliable when confounding factors are present (i.e., tachycardia, bradycardia, unusual T-wave morphology, any arrythmia including bundle branch block or significant U-waves).

Clinical guidelines suggest consulting a cardiologist if the QTC stays prolonged after discontinuing medication, if cardiovascular symptoms are present, or if pre-existing cardiac disease or strong family history is a factor (Wilens et al., 1996). Several other QTC scenarios occurring during treatment also merit consultation: QTC duration >480 msec; QTC prolongation >60 msec over pretreatment duration, or QTC duration >450 msec after 10% to 15% increase (Labellarte et al., 2003a).

A child and adolescent psychiatrist should consult a cardiologist familiar with QTC measurement if they are uncertain about the clinical significance of QTC status before treatment or during careful monitoring of patients on medications that can prolong QTC. If the utility of medications that can prolong QTC is in question, perhaps safer alternatives should be prescribed.

Dr. Labellarte is assistant professor of child and adolescent psychiatry at Johns Hopkins Medical Center.

References

Daniel DG (2003), Tolerability of ziprasidone: an expanding perspective. J Clin Psychiatry 64(suppl 19):40-49.

Di Salvo TG, O'Gara PT (1995), Torsade de pointes caused by high-dose intravenous haloperidol in cardiac patients. Clin Cardiol 18(5):285-290.

Gutgesell H, Atkins D, Barst R et al. (1999), AHA Scientific Statement: cardiovascular monitoring of children and adolescents receiving psychotropic drugs. J Am Acad Child Adolesc Psychiatry 38(8):1047-1050.

Haddad PM, Anderson IM (2002), Antipsychotic-related QTC prolongation, torsade de pointes and sudden death. Drugs 62(11):1649-1671.

Harrigan EP, Miceli JJ, Anziano R et al. (2004), A randomized evaluation of the effects of six antipsychotic agents on QTC, in the absence and presence of metabolic inhibition. J Clin Psychopharmacol 24(1):62-69.

Hatta K, Takahashi T, Nakamura H et al. (2001), The association between intravenous haloperidol and prolonged QT interval. J Clin Psychopharmacol 21(3):257-261.

Kalgutkar AS, Taylor TJ, Venkatakrishnan K, Isin EM (2003), Assessment of the contributions of CYP3A4 and CYP3A5 in the metabolism of the antipsychotic agent haloperidol to its potentially neurotoxic pyridinium metabolite and effect of antidepressants on the bioactivation pathway. Drug Metab Dispos 31(3):243-249.

Khan IA (2002), Long QT syndrome: diagnosis and management. Am Heart J 143(1):7-14.

Labellarte MJ, Crosson JE, Riddle MA (2003a), The relevance of prolonged QTC measurement to pediatric psychopharmacology. J Am Acad Child Adolesc Psychiatry 42(6):642-650.

Labellarte MJ, Walkup JT, Riddle MA (2003b), Benign U-wave mistaken for QTC prolongation. J Am Acad Child Adolesc Psychiatry 42(6):621 [letter].

Lischke V, Behne M, Doelken P et al. (1994), Droperidol causes a dose-dependent prolongation of the QT interval. Anesth Analg 79(5):983-986.

Miller MD, Porter CJ, Ackerman MJ (2001), Diagnostic accuracy of screening electrocardiograms in long QT syndrome I. Pediatrics 108(1):8-12.

Moss AJ (1993), Measurement of the QT interval and the risk associated with QTC interval prolongation: a review. Am J Cardiol 72(6):23B-25B.

Ocal B, Imamoglu A, Atalay S, Ercan Tutar H (1997), Prevalence of idiopathic long QT syndrome in children with congenital deafness. Pediatr Cardiol 18(6):401-405.

Reilly JG, Ayis SA, Ferrier IN et al. (2000), QTC-interval abnormalities and psychotropic drug therapy in psychiatric patients. Lancet 355(9209):1048-1052 [see comments].

Robbins J, Nelson JC, Rautaharju PM, Gottdiener JS (2003), The association between the length of the QT interval and mortality in the Cardiovascular Health Study. Am J Med 115(9):689-694 [see comment].

Tisdale JE, Rasty S, Padhi ID et al. (2001), The effect of intravenous haloperidol on QT interval dispersion in critically ill patients: comparison with QT interval prolongation for assessment of risk of Torsades de Pointes. [Published erratum J Clin Pharmacol 42(5):577-579.] J Clin Pharmacol 41(12):1310-1318.

Wilens TE, Biederman J, Baldessarini RJ et al. (1996), Cardiovascular effects of therapeutic doses of tricyclic antidepressants in children and adolescents. J Am Acad Child Adolesc Psychiatry 35(11):1491-1501.

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