Tinne Gils1, Lutgarde Lynen2, Bouke C de Jong3, Armand Van Deun4, Tom Decroo5. 1. Unit of HIV and Coinfections, Department of Clinical Sciences, Institute of Tropical Medicine, Antwerp, Belgium. Electronic address: tgils@itg.be. 2. Unit of HIV and Coinfections, Department of Clinical Sciences, Institute of Tropical Medicine, Antwerp, Belgium. 3. Unit of Mycobacteriology, Department of Biomedical Sciences, Institute of Tropical Medicine, Antwerp, Belgium. 4. Independent consultant, Leuven, Belgium. 5. Unit of HIV and Coinfections, Department of Clinical Sciences, Institute of Tropical Medicine, Antwerp, Belgium; Research Foundation Flanders, Brussels, Belgium.
Abstract
BACKGROUND: Outcomes of treatment of tuberculosis patients with regimens including pretomanid have not yet been systematically reviewed. OBJECTIVES: To appraise existing evidence on efficacy and safety of pretomanid in tuberculosis. DATA SOURCES: Pubmed, clinicaltrials.gov. and Cochrane library. STUDY ELIGIBILITY CRITERIA: Quantitative studies presenting original data on clinical efficacy or safety of pretomanid. PARTICIPANTS: Patients with tuberculosis. INTERVENTIONS: Treatment with pretomanid or pretomanid-containing regimens in minimum one study group. METHODS: Two authors independently extracted data and assessed risk of bias. Data on efficacy (early bactericidal activity, bactericidal activity, end-of-treatment outcomes and acquired resistance) and safety were summarized in tables. Mean differences in efficacy outcomes between regimens across studies were calculated. RESULTS: Eight studies were included; four randomized controlled trials on 2-week early bactericidal activity in rifampicin-susceptible tuberculosis, three trials with randomized rifampicin-susceptible tuberculosis arms and a single rifampicin-resistant tuberculosis arm (two on 8-week bactericidal activity, one on end-of-treatment outcomes), one single-arm trial with end-of-treatment outcomes in highly resistant tuberculosis. Activity of pretomanid-moxifloxacin-pyrazinamide was superior to standard treatment on daily change in colony-forming units at days 0-2, 0-56 and 7-56 and time to culture conversion in rifampicin-susceptible tuberculosis (hazard ratio: 1.7; 95% CI 1.1-2.7), but not at end of treatment in one study. This study was stopped due to serious hepatotoxic adverse events, including three deaths, in 4% (95% CI 2-8) patients on pretomanid-moxifloxacin-pyrazinamide and none in controls. In patients with uncomplicated rifampicin-resistant tuberculosis on pretomanid-moxifloxacin-pyrazinamide treatment, 91% (95% CI 59-100) had favourable end-of-treatment outcomes. In patients with highly resistant tuberculosis, 90% (95% CI 83-95) on pretomanid-bedaquiline-linezolid had favourable outcomes six months after treatment, but linezolid-related toxicity was frequent. No acquired resistance to pretomanid was reported. CONCLUSIONS: Evidence suggests an important role for pretomanid in rifampicin-resistant and highly resistant tuberculosis. Trials comparing pretomanid to existing core and companion drugs are needed to further define that role.
BACKGROUND: Outcomes of treatment of tuberculosis patients with regimens including pretomanid have not yet been systematically reviewed. OBJECTIVES: To appraise existing evidence on efficacy and safety of pretomanid in tuberculosis. DATA SOURCES: Pubmed, clinicaltrials.gov. and Cochrane library. STUDY ELIGIBILITY CRITERIA: Quantitative studies presenting original data on clinical efficacy or safety of pretomanid. PARTICIPANTS: Patients with tuberculosis. INTERVENTIONS: Treatment with pretomanid or pretomanid-containing regimens in minimum one study group. METHODS: Two authors independently extracted data and assessed risk of bias. Data on efficacy (early bactericidal activity, bactericidal activity, end-of-treatment outcomes and acquired resistance) and safety were summarized in tables. Mean differences in efficacy outcomes between regimens across studies were calculated. RESULTS: Eight studies were included; four randomized controlled trials on 2-week early bactericidal activity in rifampicin-susceptible tuberculosis, three trials with randomized rifampicin-susceptible tuberculosis arms and a single rifampicin-resistant tuberculosis arm (two on 8-week bactericidal activity, one on end-of-treatment outcomes), one single-arm trial with end-of-treatment outcomes in highly resistant tuberculosis. Activity of pretomanid-moxifloxacin-pyrazinamide was superior to standard treatment on daily change in colony-forming units at days 0-2, 0-56 and 7-56 and time to culture conversion in rifampicin-susceptible tuberculosis (hazard ratio: 1.7; 95% CI 1.1-2.7), but not at end of treatment in one study. This study was stopped due to serious hepatotoxic adverse events, including three deaths, in 4% (95% CI 2-8) patients on pretomanid-moxifloxacin-pyrazinamide and none in controls. In patients with uncomplicated rifampicin-resistant tuberculosis on pretomanid-moxifloxacin-pyrazinamide treatment, 91% (95% CI 59-100) had favourable end-of-treatment outcomes. In patients with highly resistant tuberculosis, 90% (95% CI 83-95) on pretomanid-bedaquiline-linezolid had favourable outcomes six months after treatment, but linezolid-related toxicity was frequent. No acquired resistance to pretomanid was reported. CONCLUSIONS: Evidence suggests an important role for pretomanid in rifampicin-resistant and highly resistant tuberculosis. Trials comparing pretomanid to existing core and companion drugs are needed to further define that role.
Authors: Juan Espinosa-Pereiro; Adrian Sánchez-Montalvá; Maria Luisa Aznar; Maria Espiau Journal: Medicina (Kaunas) Date: 2022-01-26 Impact factor: 2.430
Authors: Sara Occhineri; Tommaso Matucci; Laura Rindi; Giusy Tiseo; Marco Falcone; Niccolò Riccardi; Giorgio Besozzi Journal: Curr Res Pharmacol Drug Discov Date: 2022-09-09