Claudio Scarparo

Clinical validation of Xpert MTB/RIF for the diagnosis of extrapulmonary tuberculosis

Extrapulmonary tuberculosis (EPTB) accounts for more than 20% of tuberculosis (TB) cases. Xpert MTB/RIF (Xpert) (Cepheid, Sunnyvale, CA, USA) is a fully automated amplification system, for which excellent results in the diagnosis of pulmonary TB in highly endemic countries have been recently reported. We aimed to assess the performance of the Xpert system in diagnosing EPTB in a low incidence setting. We investigated with Xpert a large number of consecutive extrapulmonary clinical specimens (1,476, corresponding to 1,068 patients) including both paediatric (494) and adult samples. We found, in comparison with a reference standard consisting of combination of culture and clinical diagnosis of TB, an overall sensitivity and specificity of 81.3% and 99.8% for Xpert, while the sensitivity of microscopy was 48%. For biopsies, urines, pus and cerebrospinal fluids the sensitivity exceeded 85%, while it was slightly under 80% for gastric aspirates. It was, in contrast, lower than 50% for cavitary fluids. High sensitivity and specificity (86.9% and 99.7%, respectively) were also obtained for paediatric specimens. Although the role of culture remains central in the microbiological diagnosis of EPTB, the sensitivity of Xpert in rapidly diagnosing the disease makes it a much better choice compared to smear microscopy. The ability to rule out the disease still remains suboptimal.

Meta-Analysis of BACTEC MGIT 960 and BACTEC 460 TB, with or without Solid Media, for Detection of Mycobacteria

ABSTRACT In a meta-analysis of 10 studies, the BACTEC 960/MGIT and BACTEC 460 systems showed a sensitivity and specificity in detecting mycobacteria (1,381 strains from 14,745 clinical specimens) of 81.5 and 99.6% and 85.8 and 99.9%, respectively. Combined with solid media, the sensitivity of the two systems increased to 87.7 and 89.7%, respectively.

Relevance of Commercial Amplification Methods for Direct Detection of Mycobacterium tuberculosis Complex in Clinical Samples

Mycobacteria are a group of acid-fast, aerobic, slow-growing organisms whose genus includes more than 90 different species. The causative agents of tuberculosis (TB), which is currently considered a global emergency, with more than 2 million people dying every year and 8 million new cases, belong to the Mycobacterium tuberculosis complex (MTB). Moreover, although of lesser public health importance, many other species referred to as nontuberculous mycobacteria (NTM) have also been associated with human disease with increasing frequency worldwide (65). As MTB is highly infectious for humans, it is of paramount importance that TB be diagnosed as early as possible to stop the spread of the disease. Active TB is currently diagnosed by conventional laboratory procedures including specimen digestion and decontamination, microscopic examination for the presence of acid-fast bacilli (AFB), isolation by culture on solid and/or liquid media, and identification and drug susceptibility testing of the recovered isolate. Because of the slow growth of mycobacteria, the above-reported laboratory procedures may require turnaround times of 3 to 4 weeks or longer. During the last decade, several molecular methods have been developed for direct detection and identification of MTB in clinical specimens. These methods, being able to potentially reduce the diagnostic time from weeks to days, have been acquiring greater and greater relevance in the field of laboratory TB diagnosis. The basic principle of any molecular diagnostic test is the detection of a specific nucleic acid sequence by hybridization to a complementary sequence, a probe, followed by detection of the hybrid. However, the sensitivity of nucleic acid probe tests that do not involve amplification is much lower than that of amplified ones. Any portion of nucleic acid can be copied by using the specific polymerase, provided that some sequence data are known for the setup of appropriate primers. In general, amplification of target nucleic acid sequences is composed of three parts: denaturation, primer annealing, and primer extension. Discovery of PCRs in 1986 made this process reiterative, leading to an exponential increase in the production of the amplified target. Soon after, alternative amplification techniques were developed and patented by companies, which used different enzymes and strategies, but they are all based on reiterative reactions. Many different amplification targets including both DNA or RNA fragments have been proposed. The target most frequently amplified in MTB is the IS6110 (31) repetitive element, of which 10 to 16 copies are present in most clinical isolates. Numerous techniques for nucleic acid extraction have been proposed, as have different types of controls for monitoring the efficacy of nucleic acid extraction and amplification procedures. Currently, the U.S. Food and Drug Administration (FDA) requires that culture (still considered the “gold standard” for TB diagnosis) must be done in conjunction with the performance of each amplification-based test. In this paper, we review and discuss the currently available commercial methods which are capable of detecting MTB directly from clinical samples.

Extrapulmonary infections associated with nontuberculous mycobacteria in immunocompetent persons.

Incidence data are lacking, and diagnosis remains difficult.

Performance Assessment of New Multiplex Probe Assay for Identification of Mycobacteria

ABSTRACT A new DNA probe assay (INNO LiPA Mycobacteria; Innogenetics, Ghent, Belgium) for the simultaneous identification, by means of reverse hybridization and line-probe technology, of Mycobacterium tuberculosis complex, Mycobacterium kansasii,Mycobacterium xenopi, Mycobacterium gordonae, the species of the Mycobacterium avium complex (MAC),Mycobacterium scrofulaceum, and Mycobacterium chelonae was evaluated on a panel of 238 strains including, besides representatives of all the taxa identifiable by the system, a number of other mycobacteria, some of which are known to be problematic with the only other commercial DNA probe system (AccuProbe; Gen-Probe, San Diego, Calif.), and two nocardiae. The new kit, which includes a control probe reacting with the whole genus Mycobacterium, correctly identified 99.6% of the strains tested; the one discrepancy, which remained unresolved, concerned an isolate identified as MAC intermediate by INNO LiPA Mycobacteria and as Mycobacterium intracellulare by AccuProbe. In five cases, because of an imperfect checking of hybridization temperature, a very slight, nonspecific, line was visible which was no longer evident when the test was repeated. Two strains whose DNA failed amplification at the first attempt were regularly identified when the test was repeated. Interestingly, the novel kit dodged all the pitfalls presented by the strains giving anomalous reactions with AccuProbe. A unique feature of INNO LiPA Mycobacteria is its ability to recognize different subgroups within the species M. kansasii and M. chelonae, while the declared overlapping reactivity of probe 4 with some M. kansasii and Mycobacterium gastri organisms and of probe 9 with MAC, Mycobacterium haemophilum, andMycobacterium malmoense, may furnish a useful aid for their identification. The turnaround time of the method is approximately 6 h, including a preliminary PCR amplification.

Evaluation of the Fully Automated BACTEC MGIT 960 System for Testing Susceptibility of Mycobacterium tuberculosis to Pyrazinamide, Streptomycin, Isoniazid, Rifampin, and Ethambutol and Comparison with the Radiometric BACTEC 460TB Method

ABSTRACT The performance of the fully automated BACTEC MGIT 960 (M960) system for the testing of Mycobacterium tuberculosis susceptibility to streptomycin (SM), isoniazid (INH), rifampin (RMP), ethambutol (EMB), and pyrazinamide (PZA) was evaluated with 100 clinical isolates and compared to that of the radiometric BACTEC 460TB (B460) system. The agar proportion method and the B460 system were used as reference methods to resolve the discordant results for SM, INH, RMP, and EMB (a combination known as SIRE) and PZA, respectively. The overall agreements were 96.3% for SIRE and 92% for PZA. For SIRE, a total of 26 discrepancies were found and were resolved in favor of the M960 system in 8 cases and in favor of the B460 system in 18 cases. The M960 system produced 8 very major errors (VME) and 10 major errors (ME), while the B460 system showed 4 VME and 4 ME. No statistically significant differences were found. Both systems exhibited excellent performance, but a higher number of VME was observed with the M960 system at the critical concentrations of EMB and SM. For PZA, a total of eight discrepancies were observed and were resolved in favor of the M960 system in one case and in favor of the B460 system in seven cases; no statistically significant differences were found. The M960 system showed four VME and three ME. The mean times to report overall PZA results and resistant results were 8.2 and 9.8 days, respectively, for the M960 system and 7.4 and 8.1 days, respectively, for the B460 system. Statistically significant differences were found. The mean times to report SIRE results were 8.3 days for the M960 system and 8.2 days for the B460 system. No statistically significant differences were found. Twelve strains tested for SIRE susceptibility and seven strains tested for PZA susceptibility had been reprocessed because of contamination. In conclusion, the M960 system can represent a valid alternative to the B460 for M. tuberculosis susceptibility testing; however, the frequent contamination of the tests needs to be improved.

Pulmonary infections associated with non-tuberculous mycobacteria in immunocompetent patients

A decline in the prevalence of tuberculosis in the developed world over the past several years has been accompanied by an increase in the rate of mycobacterial disease caused by non-tuberculous mycobacteria. However, it is still unclear whether there is a real increase in prevalence or whether non-tuberculous mycobacterial disease is being recognised more frequently by clinicians in a variety of clinical settings, thus enhancing the competence of microbiologists to detect the more unusual and fastidious mycobacteria. The introduction of liquid media for isolation of mycobacteria coupled with more accurate methods for identification have allowed several new species associated with human disease to be recognised. Despite this progress, several issues related to non-tuberculous mycobacterial infections need to be addressed, including the timely and reliable identification of isolates, standardisation and clinical evaluation of susceptibility testing, and capability to distinguish disease-causing isolates from contaminant or saprophytic species. Treatment regimens for non-tuberculous mycobacterial disease are still largely undefined and outcome remains disappointing despite substantial upgrading in laboratory diagnosis and the availability of new antimicrobials. Treatment success is impaired by the long duration of regimens, side-effects, and drug interactions, which prevent patients from full compliance. We discuss the epidemiological features, clinical syndromes, and developments in the investigation, prevention, and treatment of pulmonary non-tuberculous mycobacterial infections.

Current Perspectives on Drug Susceptibility Testing of Mycobacterium tuberculosis Complex: the Automated Nonradiometric Systems

Until the beginning of the 1990s, it was quite common to learn that many patients with tuberculosis (TB) were treated for several months with a standard regimen including isoniazid (INH) and rifampin (RMP) without the physician knowing whether the causative organism was susceptible to these drugs. The main reason for such an attitude was that the probability of a Mycobacterium tuberculosis complex (MTC) initial isolate being resistant was negligible. Unfortunately, the situation has strikingly changed now. Not only does TB continue to represent one of the most relevant infectious diseases in the world, responsible for 8 million new cases and 2 to 3 million casualties occurring annually, but in low-prevalence countries, the rates of initial-drug- and multidrug-resistant (MDR) TB (e.g., resistant to both INH and RMP) (13) have been climbing, causing a worrying rise in morbidity and mortality. An additional factor is human immunodeficiency virus, which has significantly increased the incidence of TB, particularly in sub-Saharan Africa but also elsewhere. While the long-term solution is likely to come from the development of a better vaccine, for the near future, reliance on chemotherapy will have to be continued. This matter has refocused attention on the importance of MTC drug susceptibility testing (DST) and on the laboratorys key role in providing clinicians with timely, reliable, and comprehensive information (2). Currently, a number of automated, nonradiometric detection systems (NRS) that can also perform MTC susceptibility testing are commercially available to clinical laboratories (30). Not all the methods presented herewith have been cleared by the Food and Drug Administration. However, we performed a systematic review and meta-analysis to evaluate the performance of these systems in comparison with the radiometric BACTEC 460 TB (B460) system, currently regarded as a reference able to combine timely and reliable results (27, 36).

Burden of Unidentifiable Mycobacteria in a Reference Laboratory

ABSTRACT Modern identification techniques at the genomic level have greatly improved the taxonomic knowledge of mycobacteria. In adjunct to nucleic acid sequences, mycobacterial identification has been endorsed by investigation of the lipidic patterns of unique mycolic acids in such organisms. In the present investigation, the routine use of high-performance liquid chromatography (HPLC) of mycolic acids, followed by the sequencing of the 16S rRNA, allowed us to select 72 mycobacterial strains, out of 1,035 screened, that do not belong to any of the officially recognized mycobacterial species. Most strains (i.e., 47) were isolated from humans, 13 were from the environment, 3 were from animals, and 9 were from unknown sources. The majority of human isolates were grown from the respiratory tract and were therefore most likely not clinically significant. Some, however, were isolated from sterile sites (blood, pleural biopsy, central venous catheter, or pus). Many isolates, including several clusters of two or more strains, mostly slow growers and scotochromogenic, presented unique genetic and lipidic features. We hope the data reported here, including the results of major conventional identification tests, the HPLC profiles of strains isolated several times, and the whole sequences of the 16S rRNA hypervariable regions of all 72 mycobacteria, may encourage reporting of new cases. The taxonomy of the genusMycobacterium is, in our opinion, still far from being fully elucidated, and the reporting of unusual strains provides the best background for the recognition of new species. Our report also shows the usefulness of the integration of novel technology to routine diagnosis, especially in cases involving slow-growing microorganisms such as mycobacteria.

Performance Assessment of Two Commercial Amplification Assays for Direct Detection of Mycobacterium tuberculosis Complex from Respiratory and Extrapulmonary Specimens

ABSTRACT The new BDProbeTec ET Mycobacterium tuberculosis Complex Direct Detection Assay (DTB) was compared with the enhanced M. tuberculosis Amplified Direct Test (AMTDII). The system is an automated walkaway system characterized by simultaneous DNA amplification (strand displacement amplification) and real-time fluorometric detection. It also contains an internal amplification control (IAC) designed to identify inhibition from the processed samples. The AMTDII assay amplifies rRNA by transcription-mediated amplification; it uses hybridization with a chemoluminescent probe as a detection system and is entirely manual. A total of 515 N-acetyl-l-cysteine-sodium hydroxide-decontaminated respiratory (n = 331) and extrapulmonary (n = 184) sediments (from 402 patients) were tested in parallel by both assays. The results were compared with those of acid-fast staining and culture (solid plus liquid media), setting the combination of culture and clinical diagnosis as the “gold standard.” Culture results from the tested specimens were as follows: 121 Mycobacterium tuberculosis complex (MTB) (98 smear-positive), 46 nontuberculous mycobacteria (38 smear-positive), and 338 culture-negative results. After resolution of the discrepant results, the percent sensitivity, percent specificity, and positive and negative likelihood ratios for AMTDII were 88%, 99.2%, 110, and 0.11 for respiratory specimens and 74.3%, 100%, 740, and 0.26 for extrapulmonary specimens, respectively. The corresponding values for DTB were 94.5%, 99.6%, 235, and 0.05 for respiratory specimens and 92.3%, 100%, 920, and 0.07 for extrapulmonary specimens, respectively. The cumulative difference for all tuberculosis-positive extrapulmonary specimens was significant (P = 0.03). The overall inhibition rate for DTB was 5% (26 specimens). We conclude that both amplification assays proved to be rapid and specific for the detection of MTB in clinical samples and particularly feasible for a routine laboratory work flow. DTB combines a labor-intensive specimen preparation procedure with a completely automated amplification and detection. Finally, differences between AMTDII and DTB sensitivities were associated with the presence of inhibitory samples that the former assay, lacking IAC, could not detect.