Compatibility of a novel filter paper-based bio-safe sputum transport kit with line probe assay for diagnosing drug-resistant tuberculosis: a single-site evaluation study.

BACKGROUND: Near-patient access to appropriate tests is a major obstacle for the efficient diagnosis of tuberculosis (TB) and associated drug resistance. METHODS: We recently developed the "TB Concentration & Transport" kit for bio-safe, ambient-temperature transportation of dried sputum on Trans-Filter, and the "TB DNA Extraction" kit for DNA extraction from Trans-Filter for determining drug resistance by DNA sequencing. In the present study, we evaluated the compatibility of Kit-extracted DNA with Hain's line probe assays (LPAs), which are endorsed by National TB programmes for the detection of drug resistance in sputum collected from presumptive multidrug-resistant TB patients (n=207). RESULTS: Trans-Filter-extracted DNA was seamlessly integrated with the LPA protocol (Kit-LPA). The sensitivity of Kit-LPA for determining drug resistance was 83.3% for rifampicin (95% CI 52-98%), 77.7% for isoniazid (95% CI 52-94%), 85.7% for fluoroquinolones (95% CI 42-100%) and 66.6% for aminoglycosides (95% CI 9-99%), with a specificity range of 93.7% (95% CI 87-97) to 99.1% (95% CI 95-100) using phenotypic drug susceptibility testing (DST) as a reference standard. A high degree of concordance was noted between results obtained from Kit-LPA and LPA (99% to 100% (κ value: 0.83-1.0)). CONCLUSIONS: This study demonstrates successful integration of our developed kits with LPA. The adoption of these kits across Designated Microscopy Centres in India can potentially overcome the existing challenge of transporting infectious sputum at controlled temperature to centralised testing laboratories and can provide rapid near-patient cost-effective "Universal DST" services to TB subjects residing in remote areas.

Evaluation of 'TBDetect' sputum microscopy kit for improved detection of Mycobacterium tuberculosis: a multi-centric validation study.

OBJECTIVES: The present study aimed to evaluate the performance of the 'TBDetect' kit-based bio-safe fluorescent microscopy filter (BioFM-Filter) microscopy in comparison with direct smear microscopy and culture for the detection of pulmonary tuberculosis (TB) in a multi-centric setting in India. METHODS: The TBDetect kit enables sputum concentration through filtration using the BioFM-Filter for improved and bio-safe smear microscopy. We evaluated the performance of the TBDetect kit in a six-site multi-centric validation study on sputum collected from 2086 presumptive TB patients. RESULTS: The combined positivity of TBDetect microscopy performed on these sputum samples was 20% (n = 417/2086) vs 16.1% of light-emitting diode fluorescence microscopy (LED-FM, n = 337/2086) and 16% of Ziehl Neelsen (ZN) smear microscopy (n = 333/2086). The increment in positivity of TBDetect over both LED-FM and ZN smears was significant (p < 0.001). The overall sensitivity of TBDetect for six sites was ~55% (202/367, 95% confidence interval (CI): 50, 60%) vs 52% (191/367, 95% CI: 47, 57%) for LED-FM (p 0.14) and 50.9% (187/367, 95% CI: 46, 56%) for ZN smear (p < 0.05), using Mycobacterium Growth Indicator Tube culture (MGIT, n = 1949, culture positive, n = 367) as the reference standard. A bio-safety evaluation at six sites confirmed efficient sputum disinfection by TBDetect; 99.95% samples (1873/1874) were sterile after 42 days of incubation. Scientists and technicians at the study sites indicated the ease of use and convenience of TBDetect microscopy during feedback. CONCLUSIONS: TBDetect added value to the smear microscopy test due to its improved performance, convenience and user safety. These findings indicate that equipment-free TBDetect technology has the potential to improve TB diagnosis in basic laboratory settings by leveraging on the existing nationwide network of designated microscopy centres and primary healthcare centres.

Preuse/Poststerilization Integrity Testing (PUPSIT): To Do or Not to Do?

In manufacture of heat labile sterile drug products, the final step involves filtration through sterilizing grade filters. It is the drug manufacturer's responsibility to check whether an integral filter has been used. One method used widely to check the integrity of a filter is the bubble point test. To confirm that the filter used is integral, the postuse integrity test is made obligatory by regulatory bodies. However, preuse/poststerilization integrity testing (PUPSIT) of filters remains debatable for the risks associated in its execution. Although PUPSIT is recommended by regulatory bodies, it poses a risk of compromising downstream sterility and involves high costs to mitigate such risks. This study highlights the impact of filter clogging on bubble point values with the consequent possibility of a nonintegral filter passing postuse integrity testing. The results clearly show an increase in postuse bubble point values, which can camouflage a possible flaw in sterilizing filters. The fluid streams 20% dextrose, 0.001% bentonite, paclitaxel, and 0.05% sodium hyaluronate were selected based not only on the commonality of their clogging propensity but also on the different nature of streams that influence the clogging of sterilizing filters. Paclitaxel is an injectable for oncotherapy, and 0.05% sodium hyaluronate is an ophthalmic. The study was conducted with 0.2 µm sterilizing filters from four different manufacturers. It was observed that some fluid streams show a significant increase in the postuse bubble point test values over the preuse bubble point values. This establishes the necessity of performing PUPSIT in certain cases based on the postfiltration shift in bubble point values. As part of the filter validation studies with specific drug products, additional testing should be carried out to establish the need for PUPSIT on a case-by-case basis.

Development and evaluation of novel bio-safe filter paper-based kits for sputum microscopy and transport to directly detect Mycobacterium tuberculosis and associated drug resistance.

India has the highest burden of Tuberculosis (TB) and multidrug-resistant TB (MDR-TB) worldwide. Innovative technology is the need of the hour to identify these cases that remain either undiagnosed or inadequately diagnosed due to the unavailability of appropriate tools at primary healthcare settings. We developed and evaluated 3 kits, namely 'TB Detect' (containing BioFM-Filter device), 'TB Concentration and Transport' (containing Trans-Filter device) and 'TB DNA Extraction' kits. These kits enable bio-safe equipment-free concentration of sputum on filters and improved fluorescence microscopy at primary healthcare centres, ambient temperature transport of dried inactivated sputum filters to central laboratories and molecular detection of drug resistance by PCR and DNA sequencing (Mol-DST). In a 2-site evaluation (n = 1190 sputum specimens) on presumptive TB patients, BioFM-Filter smear exhibited a significant increase in positivity of 7% and 4% over ZN smear and LED-FM smear (p<0.05), respectively and an increment in smear grade status (1+ or 2+ to 3+) of 16% over ZN smear and 20% over LED-FM smear. The sensitivity of Mol-DST in presumptive MDR-TB and XDR-TB cases (n = 148) was 90% for Rifampicin (95% confidence interval [CI], 78-96%), 84% for Isoniazid (95% CI, 72-92%), 83% for Fluoroquinolones (95% CI, 66-93%) and 75% for Aminoglycosides (95% CI, 35-97%), using phenotypic DST as the reference standard. Test specificity was 88-93% and concordance was ~89-92% (κ value 0.8-0.9). The patient-friendly kits described here address several of the existing challenges and are designed to provide 'Universal Access' to rapid TB diagnosis, including drug-resistant disease. Their utility was demonstrated by application to sputum at 2 sites in India. Our findings pave the way for larger studies in different point-of-care settings, including high-density urban areas and remote geographical locations.