Evaluation of Xpert MTB/RIF Ultra for Diagnosis of Extrapulmonary Tuberculosis: A Retrospective Analysis in a Low-Tuberculosis Prevalence Setting ()
1. Introduction
Tuberculosis (TB) remains a critical clinical and public health issue worldwide. The latest data provided by the World Health Organisation (WHO) shows that in 2019 about 10 million people developed Tuberculosis with 1.4 million deaths. At the national level, the annual incidence rate of Tuberculosis ranged from less than 5 to more than 500 new and relapsed cases per 100,000 inhabitants [1]. The countries that had a low incidence of tuberculosis (<10 cases per 100,000 population per year) in 2019 were 54 located mostly in the WHO Region of the Americas and the European Region plus a few countries in the Eastern Mediterranean and Western Pacific regions [1]. In Italy, the recorded notification rate in 2017 was 6.5 cases per 100,000 people [2] indeed considered a low TB country. In the foreign-born population since 2009, more than 50% of the Tuberculosis cases notified each year and most of the cases of multidrug-resistant Tuberculosis (MDR-TB) have been registered [2]. TB mostly affects the lungs (pulmonary TB, PTB) but can also affect many other different sites such tissues, lymph nodes and blood (extrapulmonary TB, EPTB). EPTB diagnosis remains a great challenge due to the diversity of symptoms with which EPTB may present, the low level of suspicion of clinicians and the difficulty in obtaining adequate samples for M. Tuberculosis complex (MTC) detection. The delayed diagnosis of EPTB may lead to inappropriate treatment [3] [4], indeed, patients are often started on empirical antituberculosis treatment based on composite reference standard, including clinical signs and symptoms and radiological findings [5].
In 2010 the revolutionary Polymerase chain reaction (PCR)-based test, Xpert® MTB/RIF (Xpert; Cepheid, Sunnyvale, CA) was introduced. It consists of a rapid, semi-quantitative, in vitro nested real-time PCR assay for the simultaneous detection of MTC DNA and rifampicin resistance-associated rpoB gene mutations within two hours [6]. Previous studies have shown that Xpert has a good performance in the diagnosis of PTB with smear positive sputum specimens [7]. In contrast, Xpert had a high specificity, but limited sensitivity in smear negative PTB samples and for the diagnosis of EPTB [7] [8]. To improve the performance of Xpert, an upgraded version of the assay, Xpert® MTB/RIF Ultra, has been developed by Cepheid (Ultra; Sunnyvale, USA) [5] [6]. The Ultra cartridge showed an increased sensitivity compared to the Xpert cartridge for the detection of MTC in specimens with low numbers of bacilli, especially in smear-negative, in HIV/TB co-infected, in paediatric specimens and in extra-pulmonary specimens [9]. The incorporation of two new targets IS1081 and IS6110 significantly increases the sensitivity of the Ultra assay, enabling to detect 16 colony-forming units (CFU/mL), in contrast to the 114 CFU/mL, limit of detection of Xpert® MTB/RIF. To achieve this category result, named “trace”, at least one of the probes must be positive for IS1081 or IS6110 with cycle thresholds below 37 cycles and have no more than one rpoB probe with cycle thresholds below 40 cycles [10]. Since March 2017 the WHO has recommended Ultra as a replacement for Xpert in all circumstances [11].
So far, most of the studies have compared the performance of Ultra to Xpert on pulmonary samples [12] [13] [14] or have investigated Ultra for diagnosing EPTB in TB endemic countries [5] [15] [16]. The aim of our study is to provide an evaluation of Xpert Ultra in a routine diagnostic mycobacteriology laboratory of a large metropolitan city of South Italy, Naples that is considered a low tuberculosis setting (<10 cases per 100,000 population per year) [1].
2. Material and Methods
2.1. Study Design and Sample Inclusion
This study was conducted at the Laboratory of Microbiology and Virology of “A.O dei Colli” (Naples, Italy) that is the regional referral centre for the diagnosis of Mycobacterium. We analysed retrospectively all consecutive extrapulmonary samples received between January 1, 2018 and October 31, 2020 from patients with high suspect of EPTB. Patient information, including age, sex, nationality, type of sample and microbiology results of routine TB diagnostic tests were collected from the laboratory information system. We presumed that the suspect of TB was generally high for tissues, lymph nodes and most of biological fluids samples due to the difficult of sample collection. The selection of pleural fluid samples that do not require an invasive sample collection was done in basis of medium/high clinical suspect indicated in the request forms received in the laboratory. Any case with positive culture for M. tuberculosis was considered confirmed EPTB whereas any sample with negative culture for M. tuberculosis after 42 days of incubation was confirmed negative. Samples collected from patients receiving antituberculosis therapy or previously diagnosed as having TB were excluded from the analysis. No data of HIV status was available.
2.2. Sample Processing and TB Diagnostic Analysis
The collected EPTB specimens included: biological fluids, pus and abscess, tissues, lymph nodes and aspirates from extrapulmonary sites. No less than 2 mL extrapulmonary fluids specimens were collected. Tissues were first homogenized by a tissue grinder and resuspended in 5 mL of sterile saline and then processed like other specimens. EPTB specimens with more than 5 mL were centrifuged at 3000 g for 15 min and the sediments were resuspended in 2 mL PBS buffer (pH 6.8) (Becton Dickinson, BBL MycoPrep Kit) via vortexing for 30 s. Specimens were pre-treated with N-acetyl-L-cysteine-NaOH for 20 min at room temperature, and then neutralized with PBS buffer (50 mL final volume). Cerebrospinal fluid (CSF) was centrifuged at 12,000 × g for 10 min. The pellet was resuspended in PBS and treated without prior decontamination. After centrifugation at 3000 g for 20 min, the remaining volume was processed as follows: 1) smear microscopy for acid-fast bacilli (AFB) with Ziehl-Neelsen (ZN) method, 2) Xpert® MTB/RIF Ultra assay, 3) mycobacterial culture in solid (Löwenstein-Jensen) and liquid media (BACTEC MGIT 960; Becton Dickinson, Sparks, MD, USA). For liquid culture, the sediments were inoculated into a mycobacteria growth indicator tube (MGIT) to which an enrichment supplement (OADC) and an antibiotic mixture (PANTA) were added. The MGIT tubes were placed into the Bactec MGIT 960 system (BACTEC MGIT 960, Becton Dickinson, Sparks, MD, USA), which is a fluorescence-based detection instrument. Liquid and solid cultures were continuously monitored for bacterial growth for 42 days. The rapid identification of MTB isolated from solid or liquid cultures was performed by immune chromatographic assay BIO-LINE SD Ag MPT64 TB test (Standard Diagnostics, Yongin-si, Gyeonggi-do, Republic of Korea). Drug susceptibility test (DST) to first-line drugs was done using the Bactec MGIT 960 system.
2.3. Microscopy
To detect AFB, smears from clinical samples were stained by the ZN stain and examined under the oil immersion objective lens of the microscope (×100).
2.4. Xpert MTB/RIF Ultra Assay
Sample reagent was added as per protocol's instructions in a 3:1 ratio and incubated for 15 min at room temperature. Two millilitres of the liquefied sample were transferred into the Xpert MTB/RIF Ultra cartridge and loaded into the Gene Xpert system. The semiquantitative scale for Xpert Ultra results was: trace, very low, low, medium, or high.
2.5. Statistical Analysis
Culture was used as the reference standard to calculate the sensitivity, specificity and accuracy of Xpert Ultra assay. A p value of less than 0.05 was considered statistically significant. Confidence intervals for sensitivity, specificity and accuracy are “exact” Clopper-Pearson confidence intervals.
2.6. Ethical Statement
This study was retrospective without interaction with patients and all patients’ information was de-identified prior to analysis. Therefore, institutional ethics committee approval was not required.
3. Results
A total of 845 non-respiratory specimens were received for routine diagnostics from January 2018 to October 2020. 239 pleural fluids were excluded due to a low clinical suspect of TB. Finally, a total of 606 samples (449 Italian natives, 157 foreign-born people) were analysed for this study: 456 biological fluids (75.2%), 57 tissues (9.4%), 53 pus and abscess (8.7%) and 40 lymph nodes and aspirates (6.6%) (Figure 1, Figure 2). All these samples have culture (solid and liquid), ZN microscopy and Ultra results. Among these samples, 45 were culture positive, whereas 561 remained negative. Of 45 culture-positive, only 7 were smear positive and 38 were smear negative. Of the 561 culture-negative, ZN microscopy detected negative results in all these cases. The overall sensitivity of smear examination was only 15.6% (95% CI 6.5 - 29.5) and the overall specificity was 100% (95% CI 99.3 - 100) (Figure 3). The positive predictive value (PPV) and the negative predictive value (NPV) of ZN microscopy was 100% and 93.7% (95% CI 92.9 - 94.4) respectively. The accuracy of ZN microscopy was 93.7% (95% CI 91.5 - 95.5). Of 45 culture-positive, Ultra detected positive results in 43 cases and 2 cases resulted negatives. Among the 561 culture-negative, Ultra detected negative results in 547 cases, 14 cases were detected positives. The positive results (true positive and false positive) of Ultra were categorised as follows: high (n = 3), medium (n = 9), low (n = 16), very low (n = 20) and trace (n = 9). Among the positive results of Ultra assay, only two samples detected rifampicin resistance (RIF-R), and both were in concordance with the DST results. The overall sensitivity and specificity of Ultra were 95.6% (95% CI 84.8 - 99.5) and 97.5% (95% CI 95.8 - 98.6) respectively. The positive predictive value (PPV) and the negative predictive value (NPV) of Ultra assay was 75.4% (95% CI 64.6 - 83.8) and 99.6% (95% CI 98.6 - 99.9) respectively. The sensitivity and specificity of Ultra assay did not vary significantly among different clinical samples. With
Figure 1. Distribution of extrapulmonary specimens included in the study.
Figure 2. Study design and samples inclusion flowchart (EPTB extrapulmonary tuberculosis, Ultra GeneXpert MTB/Rif Ultra).
Figure 3. Sensitivity and specificity of Xpert MTB/Rif Ultra compared to Zn (Ziehl-Neelsen) smear Microscopy (CI, confidence intervals).
respect to the different specimen types, sensitivity of Ultra assay was 93.3% (95% CI 68 - 99.8) for biological fluids, 90% (95% CI 55.5 - 99.7) for tissues, 100% (95% CI 69.1 - 100) for lymph nodes, 100% (95% CI 69.1 - 100) for pus and abscess. Specificity of Ultra assay was 98.2% (95% CI 96.5 - 99.2) for biological fluids, 95.7% (95% CI 85.5 - 99.5) for tissues, 93.3% (95% CI 77.9 - 99.1) for lymph nodes, 95.3% (95% CI 84.2 - 99.4) for pus and abscess. The study has shown an accuracy of Gene Xpert Ultra 97.4% (95% CI 95.7 - 98.5) (Figure 4, Table 1).
4. Discussion
The study focuses on the evaluation of the diagnostic performance of Ultra assay using data of suspected EPTB samples under clinical routine conditions in a low-prevalence setting. So far, only few studies have investigated the use of Ultra in a non-endemic setting [17] [18] [19]. Two of these studies have used defrosted samples and the conditions of cryopreservation could have influenced any variations of sensitivity [17] [18], instead, for our study we have used a retrospective analysis method based on criteria of sample inclusion that reflects the true population-based investigation in a low prevalence setting.
In the present study, Ultra showed an overall sensitivity of 95.6% on extrapulmonary samples when culture is used as reference standard. The observed sensitivity
Figure 4. Sensitivity and specificity of Xpert MTB/Rif Ultra for different specimens; biological fluids, tissues and biopsies, lymph nodes and aspirates, pus and abscess (CI, confidence intervals).
Table 1. Performance of Xpert MTB/RIF Ultra using culture as reference standard. 95% confidence intervals for sensitivity, specificity and accuracy were calculated using Clopper-Pearson intervals. (CI confidence interval, PPV positive predictive value, NPV negative predictive value).
of Xpert® MTB/RIF Ultra assay is in line with other published studies in which reported sensitivities ranged from 69.2% to 100% [17] [19] [20].
The highest sensitivity was obtained in samples of pus and abscess (100%), lymph nodes and aspirates (100%), following by biological fluids (93.3%) and tissues (90%). The results for tissues are in line with precedent studies where the sensitivities reported were between 87% - 95% [4] [10]. We found a higher sensitivity for lymph nodes and pus specimens in respect to other studies where the sensitivity reported was generally between 90% - 94% [10] [21] and 65% - 95% [10] [16] respectively. Our results showed a general increase of sensitivity for all types of extrapulmonary specimens, contributing to improvement in the diagnosis of Tuberculosis in paucibacillary samples. These results reflect the increasing sensibility of Ultra assay due to the incorporation of multi-copy IS1081 and IS6110 insertion enable to detect lowest bacillary load of MTB [9].
In our contest, Ultra significantly improved MTB detection in EPTB samples compared to ZN microscopy that showed a sensibility of only 15.6%. Indeed, of 45 EPTB culture-positive, only 7 were detected by ZN microscopy while 43 were detected by Ultra assay. The high sensitivity of Ultra can facilitate the diagnosis of extrapulmonary forms of Tuberculosis featured by an almost complete negativity of smear microscopy [19] and in only two hours compared to 42 days of culture.
The specificity of Ultra in our study is high (97.5%). This result is in concordance with the specificities (97% - 100%) found in other low TB prevalent settings where culture was used as reference standard [10] [19]. In low TB prevalent settings, even a small reduction in specificity could increase the rate of false positive cases. For this reason, Ultra should be performed on pre-selected samples with a high clinical suspect of TB disease [18]. In other studies, it has been reported that the increase in sensitivity with Ultra respect Xpert, specifically in patients with a history of TB [12] [22] and patients with meningitis [23] came at the expense of a decrease in specificity. Although we excluded samples collected from patients receiving anti-tuberculosis therapy or previously diagnosed as having TB, we found 14 false positive results with Ultra assay. The 14 false-positive results were categorised as low (n = 3), very low (n = 8) and trace (n = 3). No medium or high results were found. Due to the difficulty in obtaining qualified pathological specimens, not repeated tests were done on tissues, lymph nodes and pus samples. On the 14 false positive, 7 were urine samples and were repeated. Out of 7 repeat tests, 6 of them turned out as not detected. Only one urine sample confirmed the positivity of Ultra assay and it was clinically diagnosed as pyelonephritis, an inflammation of the kidney, typically due to a bacterial infection. These results, although too small, suggest a reclassification of these samples as confirmed tuberculosis negative.
The incidence of MDR-TB in our country, is low [1] [2]. Indeed, only two samples presented mutations related to RIF-R with Ultra assay, both confirmed with DST. One of them was a liquor. In this case, Ultra assay was essential to the rapid diagnosis of Tuberculous meningitis and the initial treatment of TB with 2nd line anti-tuberculosis drugs. One of the strengths of Ultra assay is to simultaneously detect MTC and RIF-R is but the inconsistency of our data does not permit to evaluate the overall performance of Ultra assay on MDR-TB EPTB samples.
This study has some limitations. We conducted a retrospective investigation based on a short observation period and with a limited number of sample sizes that can lead to uncertain the sensitivity and specificity estimates. However, we used data over a period of three years, considering the new cartridge was installed in our setting at the end of 2017. Further studies, including clinical data, are needed to better investigate the accuracy of Ultra assay.
5. Conclusion
To conclude, our results confirm Ultra assay to have a good performance in the diagnosis of EPTB in our setting. More studies are required to investigate the decrease of specificity of Ultra assay on the different types of extrapulmonary samples and the incidence and clinical consequence of false-positives results in countries with low TB incidence.