Browsing by Author "Dolby, Tania"

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    Bedaquiline microheteroresistance after cessation of tuberculosis treatment
    (Massachusetts Medical Society, 2019-05-30) De Vos, Margaretha; Wiggins, Kristin B.; Derendinger, Brigitta; Reuter, Anja; Dolby, Tania; Burns, Scott; Schito, Marco; Engelthaler, David M.; Metcalfe, John; Theron, Grant; Van Rie, Annelies; Posey, James; Warren, Rob; Cox, Helen
    ENGLISH ABSTRACT: Bedaquiline improves survival among persons with multidrug-resistant tuberculosis (MDR-TB).1 We report the case of a 65-year-old South African man who was negative for human immunodeficiency virus and in whom MDR-TB was diagnosed in 2013 (resistant to rifampin and isoniazid; phenotypically susceptible to a fluoroquinolone and amikacin). A baseline radiograph showed changes consistent with bilateral tuberculosis with left apex cavitation. He started standardized treatment that included moxifloxacin, pyrazinamide, kanamycin, ethionamide, isoniazid, and terizidone. After initial sputum culture conversion (at month 3) and clinical improvement, the patient again became culture-positive, and bilateral cavitation developed. After detection of phenotypic resistance to fluoroquinolones (at month 6), his treatment was revised (at month 8) to include high-dose isoniazid, ethambutol, pyrazinamide, terizidone, linezolid, paraaminosalicylic acid, and kanamycin (Figure 1 and the Supplementary Appendix, available with the full text of this letter at NEJM.org). Bedaquiline was added 22 days later and was administered for 6 months.2 The patient remained culture-positive (treatment failure), and treatment was stopped 15 months after revision of the regimen. The patient died 7 months later.
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    Diagnostic accuracy of the FluoroType MTB and MTBDR VER 2.0 assays for the centralized high-throughput detection of Mycobacterium tuberculosis complex DNA and isoniazid and rifampicin resistance
    (Elsevier Ltd, 2021-09) Dippenaar, Anzaan; Derendinger, Brigitta; Dolby, Tania; Beylis, Natalie; Van Helden, Paul D.; Theron, Grant; Warren, Robin M.; De Vos, Margaretha
    Objectives To evaluate the accuracy of two new molecular diagnostic tests for the detection of drug-resistant tuberculosis, the FluoroType MTB and MTBDR VER 2.0 assays, in combination with manual and automated DNA extraction methods. Methods Sputa from 360 Xpert Ultra Mycobacterium tuberculosis complex (MTBC)-positive patients and 250 Xpert Ultra MTBC-negative patients were tested. GenoType MTBDRplus served as reference for MTBC and drug resistance detection. Sanger sequencing was used to resolve discrepancies. Results FluoroType MTB VER 2.0 showed similar MTBC sensitivity compared with FluoroType MTBDR VER 2.0 (manual DNA extraction: 91.6% (294/321) versus 89.8% (291/324); p 0.4); automated DNA extraction: 92.1% (305/331) versus 87.7% (291/332); p 0.05)). FluoroType MTBDR VER2.0 showed comparable diagnostic accuracy to FluoroType MTBDR VER1.0 as previously reported for the detection of MTBC and rifampicin and isoniazid resistance. Conclusions The FluoroType MTB and MTBDR VER 2.0 assays together with an automated DNA extraction and PCR set-up platform may improve laboratory operational efficiency for the diagnosis of MTBC and resistance to rifampicin and isoniazid and show promise for the implementation in a centralized molecular drug susceptibility testing model.
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    Extract from used Xpert MTB/ RIF Ultra cartridges is useful for accurate second-line drug-resistant tuberculosis diagnosis with minimal rpoB-amplicon cross-contamination risk
    (Nature Research (part of Springer Nature), 2020) Venter, Rouxjeane; Minnies, Stephanie; Derendinger, Brigitta; Tshivhula, Happy; De Vos, Margaretha; Dolby, Tania; Ruiters, Ashley; Warren, Robin M.; Theron, Grant
    Xpert MTB/RIF Ultra (Ultra) detects Mycobacterium tuberculosis and rifampicin resistance. Follow-on drug susceptibility testing (DST) requires additional sputum. Extract from the diamond-shaped chamber of the cartridge (dCE) of Ultra’s predecessor, Xpert MTB/RIF (Xpert), is useful for MTBDRsl-based DST but this is unexplored with Ultra. Furthermore, whether CE from non-diamond compartments is useful, the performance of FluoroType MTBDR (FT) on  CE, and rpoB cross-contamination risk associated with the extraction procedure are unknown. We tested MTBDRsl, MTBDRplus, and FT on CEs from chambers from cartridges (Ultra, Xpert) tested on bacilli dilution series. MTBDRsl on Ultra dCE on TB-positive sputa (n = 40) was also evaluated and, separately, rpoB amplicon cross-contamination risk . MTBDRsl on Ultra dCE from dilutions ≥103 CFU/ml (CTmin <25, >“low semi-quantitation”) detected fluoroquinolone (FQ) and second-line injectable (SLID) susceptibility and resistance correctly (some SLIDs-indeterminate). At the same threshold (at which ~85% of Ultra-positives in our setting would be eligible), 35/35 (100%) FQ and 34/35 (97%) SLID results from Ultra dCE were concordant with sputa results. Tests on other chambers were unfeasible. No tubes open during 20 batched extractions had FT-detected rpoB cross-contamination. False-positive Ultra rpoB results was observed when dCE dilutions ≤10−3 were re-tested. MTBDRsl on Ultra dCE is concordant with isolate results. rpoB amplicon cross-contamination is unlikely. These data mitigate additional specimen collection for second-line DST and cross-contamination concerns.
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    Using routinely collected laboratory data to identify high rifampicin-resistant tuberculosis burden communities in the Western Cape Province, South Africa : a retrospective spatiotemporal analysis
    (Public Library of Science, 2018) McIntosh, Avery I.; Jenkins, Helen E.; White, Laura F.; Barnard, Marinus; Thomson, Dana R.; Dolby, Tania; Simpson, John; Streicher, Elizabeth M.; Kleinman, Mary B.; Ragan, Elizabeth J.; Van Helden, Paul D.; Murray, Megan B.; Warren, Robin M.; Jacobson, Karen R.
    Background: South Africa has the highest tuberculosis incidence globally (781/100,000), with an estimated 4.3% of cases being rifampicin resistant (RR). Control and elimination strategies will require detailed spatial information to understand where drug-resistant We retrospectively identified cases of microbiologically confirmed tuberculosis and RRtuberculosis from all biological samples submitted for tuberculosis testing (n = 2,219,891) to the Western Cape National Health Laboratory Services (NHLS) between January 1, 2008, and June 30, 2013. Because the NHLS database lacks unique patient identifiers, we performed a series of record-linking processes to match specimen records to individual patients. We counted an individual as having a single disease episode if their positive samples came from within two years of each other. Cases were aggregated by clinic location (n = 302) to estimate the percentage of tuberculosis cases with rifampicin resistance per clinic. We used inverse distance weighting (IDW) to produce heatmaps of the RR-tuberculosis percentage across the province. Regression was used to estimate annual changes in the RR- tuberculosis exists tuberculosis percentage by clinic, and estimated average size and direction of change was mapped. We identified 799,779 individuals who had specimens submitted from mappable clinics for testing, of whom 222,735 (27.8%) had microbiologically confirmed tuberculosis. The study population was 43% female, the median age was 36 years (IQR 27±44), and 10,255 (4.6%, 95% CI: 4.6±4.7) cases had documented rifampicin resistance. Among individuals with microbiologically confirmed tuberculosis, 8,947 (4.0%) had more than one disease episode during the study period. The percentage of tuberculosis cases with rifampicin resistance documented among these individuals was 11.4% (95% CI: 10.7±12.0). Overall, the percentage of tuberculosis cases that were RR-tuberculosis was spatially heterogeneous, ranging from 0% to 25% across the province. Our maps reveal significant yearly fluctuations in RR-tuberculosis percentages at several locations. Additionally, the directions of change over time in RR-tuberculosis percentage were not uniform. The main limitation of this study is the lack of unique patient identifiers in the NHLS database, rendering findings to be estimates reliant on the accuracy of the person-matching algorithm. Conclusions: Our maps reveal striking spatial and temporal heterogeneity in RR-tuberculosis percentages across this province. We demonstrate the potential to monitor RR-tuberculosis spatially and temporally with routinely collected laboratory data, enabling improved resource targeting and more rapid locally appropriate interventions. and why it persists in those communities. We demonstrate a method to enable drug-resistant tuberculosis monitoring by identifying high-burden communities in the Western Cape Province using routinely collected laboratory data. Methods and findings: