Pharmacokinetics of Antituberculosis Drugs in HIV-Positive and HIV-Negative Adults in Malawi

ABSTRACT Limited data address the impact of HIV coinfection on the pharmacokinetics (PK) of antituberculosis drugs in sub-Saharan Africa. A total of 47 Malawian adults underwent rich pharmacokinetic sampling at 0, 0.5, 1, 2, 3, 4, 6, 8, and 24 h postdose. Of the subjects, 51% were male, their mean age was 34 years, and 65% were HIV-positive with a mean CD4 count of 268 cells/μl. Antituberculosis drugs were administered as fixed-dose combinations (150 mg rifampin, 75 mg isoniazid, 400 mg pyrazinamide, and 275 mg ethambutol) according to recommended weight bands. Plasma drug concentrations were determined by high-performance liquid chromatography (rifampin and pyrazinamide) or liquid chromatography-mass spectrometry (isoniazid and ethambutol). Data were analyzed by noncompartmental methods and analysis of variance of log-transformed summary parameters. The pharmacokinetic parameters were as follows (median [interquartile range]): for rifampin, maximum concentration of drug in plasma (Cmax) of 4.129 μg/ml (2.474 to 5.596 μg/ml), area under the curve from 0 to 24 h (AUC0–∞) of 21.32 μg/ml · h (13.57 to 28.60 μg/ml · h), and half-life of 2.45 h (1.86 to 3.08 h); for isoniazid, Cmax of 3.97 μg/ml (2.979 to 4.544 μg/ml), AUC0–24 of 22.5 (14.75 to 34.59 μg/ml · h), and half-life of 3.93 h (3.18 to 4.73 h); for pyrazinamide, Cmax of 34.21 μg/ml (30.00 to 41.60 μg/ml), AUC0–24 of 386.6 μg/ml · h (320.0 to 463.7 μg/ml · h), and half-life of 6.821 h (5.71 to 8.042 h); and for ethambutol, Cmax of 2.278 μg/ml (1.694 to 3.098 μg/ml), AUC0–24 of 20.41 μg/ml · h (16.18 to 26.27 μg/ml · h), and half-life of 7.507 (6.517 to 8.696 h). The isoniazid PK data analysis suggested that around two-thirds of the participants were slow acetylators. Dose, weight, and weight-adjusted dose were not significant predictors of PK exposure, probably due to weight-banded dosing. In this first pharmacokinetic study of antituberculosis drugs in Malawian adults, measures of pharmacokinetic exposure were comparable with those of other studies for all first-line drugs except for rifampin, for which the Cmax and AUC0–24 values were notably lower. Contrary to some earlier observations, HIV status did not significantly affect the AUC of any of the drugs. Increasing the dose of rifampin might be beneficial in African adults, irrespective of HIV status. Current co-trimoxazole prophylaxis was associated with an increase in the half-life of isoniazid of 41% (P = 0.022). Possible competitive interactions between isoniazid and sulfamethoxazole mediated by the N-acetyltransferase pathway should therefore be explored further.

[1]  R. Mlotha,et al.  Pharmacokinetics of anti-TB drugs in Malawian children: reconsidering the role of ethambutol , 2015, The Journal of antimicrobial chemotherapy.

[2]  R. Altman,et al.  PharmGKB summary: very important pharmacogene information for N-acetyltransferase 2. , 2014, Pharmacogenetics and genomics.

[3]  H. McIlleron,et al.  Serum drug concentrations predictive of pulmonary tuberculosis outcomes. , 2013, The Journal of infectious diseases.

[4]  R. Donders,et al.  Isoniazid, Rifampin, and Pyrazinamide Plasma Concentrations in Relation to Treatment Response in Indonesian Pulmonary Tuberculosis Patients , 2013, Antimicrobial Agents and Chemotherapy.

[5]  G. Kibiki,et al.  Pharmacokinetics of First-Line Tuberculosis Drugs in Tanzanian Patients , 2013, Antimicrobial Agents and Chemotherapy.

[6]  A. Benedetti,et al.  An updated systematic review and meta-analysis on the treatment of active tuberculosis in patients with HIV infection. , 2012, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[7]  P. Denti,et al.  Reduced Antituberculosis Drug Concentrations in HIV-Infected Patients Who Are Men or Have Low Weight: Implications for International Dosing Guidelines , 2012, Antimicrobial Agents and Chemotherapy.

[8]  A. Matteelli,et al.  Systemic exposure to rifampicin in patients with tuberculosis and advanced HIV disease during highly active antiretroviral therapy in Burkina Faso. , 2012, The Journal of antimicrobial chemotherapy.

[9]  H. McIlleron,et al.  Variability in the population pharmacokinetics of isoniazid in South African tuberculosis patients. , 2011, British journal of clinical pharmacology.

[10]  S. Swaminathan,et al.  Pharmacokinetics of Anti-tuberculosis Drugs in Children , 2011, Indian journal of pediatrics.

[11]  G. Kahlmeter,et al.  Evaluation of wild-type MIC distributions as a tool for determination of clinical breakpoints for Mycobacterium tuberculosis. , 2009, The Journal of antimicrobial chemotherapy.

[12]  P. Hopewell,et al.  Isoniazid, rifampin, ethambutol, and pyrazinamide pharmacokinetics and treatment outcomes among a predominantly HIV-infected cohort of adults with tuberculosis from Botswana. , 2009, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[13]  Y. Bossé,et al.  Influence of leukotriene gene polymorphisms on chronic rhinosinusitis , 2008, BMC Medical Genetics.

[14]  A. Langaney,et al.  Worldwide distribution of NAT2 diversity: Implications for NAT2 evolutionary history , 2008, BMC Genetics.

[15]  P. V. Helden,et al.  The influence of dose and N-acetyltransferase-2 (NAT2) genotype and phenotype on the pharmacokinetics and pharmacodynamics of isoniazid , 2007, European Journal of Clinical Pharmacology.

[16]  H. McIlleron,et al.  Determinants of Rifampin, Isoniazid, Pyrazinamide, and Ethambutol Pharmacokinetics in a Cohort of Tuberculosis Patients , 2006, Antimicrobial Agents and Chemotherapy.

[17]  S. Swaminathan,et al.  Decreased Bioavailability of Rifampin and Other Antituberculosis Drugs in Patients with Advanced Human Immunodeficiency Virus Disease , 2004, Antimicrobial Agents and Chemotherapy.

[18]  E. Kantharaj,et al.  Pharmacokinetics-Pharmacodynamics of Rifampin in an Aerosol Infection Model of Tuberculosis , 2003, Antimicrobial Agents and Chemotherapy.

[19]  C. Dye,et al.  Effects of human immunodeficiency virus infection on recurrence of tuberculosis after rifampin-based treatment: an analytical review. , 2003, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[20]  M. Kimerling,et al.  Low serum antimycobacterial drug levels in non-HIV-infected tuberculosis patients. , 1998, Chest.

[21]  R. Jelliffe,et al.  Population pharmacokinetic modeling of isoniazid, rifampin, and pyrazinamide , 1997, Antimicrobial agents and chemotherapy.

[22]  A. Rachlis,et al.  Reduced Plasma Concentrations of Antituberculosis Drugs in Patients with HIV Infection , 1997, Annals of Internal Medicine.

[23]  R. Long,et al.  Pharmacokinetics of antimycobacterial drugs in patients with tuberculosis, AIDS, and diarrhea. , 1997, Clinical infectious diseases : an official publication of the Infectious Diseases Society of America.

[24]  W. Burman,et al.  Low Antituberculosis Drug Concentrations in Patients with AIDS , 1996, The Annals of pharmacotherapy.

[25]  S. Kaaya,et al.  Arylamine N-acetyltransferase (NAT2) genotypes in Africans: the identification of a new allele with nucleotide changes 481C>T and 590G>A. , 2003, Pharmacogenetics.