ABSTRACT
The authors report in detail the case of a 27-year-old man who experienced sudden cardiac death 2 days after coprescription of the neuroleptic pimozide and the macrolide antibiotic clarithromycin after the documentation of a prolonged QT interval. To determine the prevalence of this interaction, the authors referred to the Spontaneous Reporting System of the Food and Drug Administration and identified one similar case in which clarithromycin was coprescribed with pimozide and sudden cardiac death occurred shortly thereafter. In addition, the search identified 39 cases of cardiac arrhythmia associated with pimozide, 11 with pimozide alone, and 6 with clarithromycin alone, 1 of which had a positive rechallenge. The mechanism of the interaction between clarithromycin and pimozide seems to involve the inhibition of the hepatic metabolism of pimozide by the macrolide. The authors demonstrated that clarithromycin is able to inhibit the metabolism of pimozide in human liver microsomal preparations (K(i) = 7.65 +/- 1.18 microM) and that pimozide, but not clarithromycin or its primary metabolite, is able to prolong the electrocardiac QT interval in a dose-dependent manner in the isolated perfused rabbit heart. The increase was 9.6 +/- 1.1% in male hearts (N = 5) and 13.4 +/- 1.2% in female hearts (N = 4) (p < 0.05).
Subject(s)
Anti-Bacterial Agents/adverse effects , Antipsychotic Agents/adverse effects , Clarithromycin/adverse effects , Pimozide/adverse effects , Tourette Syndrome/complications , Adolescent , Adult , Aged , Aged, 80 and over , Animals , Antipsychotic Agents/pharmacokinetics , Area Under Curve , Biotransformation , Child , Child, Preschool , Cytochrome P-450 CYP2D6/genetics , Death, Sudden, Cardiac/etiology , Drug Interactions , Electrocardiography/drug effects , Electrophysiology , Female , Genotype , Humans , Male , Microsomes, Liver/drug effects , Microsomes, Liver/enzymology , Middle Aged , Pimozide/pharmacokinetics , Rabbits , Tourette Syndrome/geneticsABSTRACT
PURPOSE: To determine who might qualify for allogeneic bone marrow transplantation (BMT), we reviewed the medical records of all 143 patients with sickle cell anemia under the age of 16 years who were registered at our center. PATIENTS AND METHODS: A total of 135 records were complete and were used to estimate donor availability and disease severity. The mean number of siblings per patient was two, but this number decreased to 0.73 if half-siblings and siblings who had sickle cell anemia were excluded. Probability calculations indicated that a human leukocyte antigen (HLA)-matched sibling donor would be available for only 18% of patients with sickle cell disease. RESULTS: With regard to clinical severity, if only stroke and chronic debilitating pain are considered criteria for bone marrow transplantation, only 16% of sickle cell patients would qualify, but with use of the broader criteria of the National Collaborative Study, 38% of patients would qualify. However, not all parents will consent to have bone marrow transplantation for their child, and only a minority of patients (18%) will have an HLA-matched sibling donor. Thus, as few as 1-2% of the total population of children with sickle cell anemia will ultimately qualify for marrow transplantation. Increasing the number who can undergo transplantation will require increasing the size of the donor pool. CONCLUSIONS: Search for other therapies not based on marrow transplantation should continue. For the majority of patients with sickle cell disease, these nontransplant treatments offer the best chance for enabling patients to achieve greater longevity and a better quality of life.
