QuantiFERON-TB Gold PLUS versus QuantiFERON-TB Gold In-Tube test for diagnosing tuberculosis infection

Article information

Korean J Intern Med. 2020;35(2):383-391
Publication date (electronic) : 2019 December 26
doi : https://doi.org/10.3904/kjim.2019.002
Department of Pulmonary and Critical Care Medicine, Asan Medical Center, University of Ulsan College of Medicine, Seoul, Korea
Correspondence to Tae Sun Shim, M.D. Department of Pulmonary and Critical Care Medicine, Asan Medical Center, University of Ulsan College of Medicine, 88 Olympic-ro 43-gil, Songpa-gu, Seoul 05505, Korea Tel: +82-2-3010-3892 Fax: +82-2-3010-6968 E-mail: shimts@amc.seoul.kr
Received 2019 January 2; Revised 2019 March 6; Accepted 2019 March 11.

Abstract

Background/Aims

QuantiFERON-TB Gold PLUS (QFT-PLUS) was developed as a new version of the interferon-γ (IFN-γ) release assay that contains an extra antigen tube to elicit a CD8+ T-cell response in addition to a CD4+ T-cell response. This study aimed to evaluate the performances of QFT-PLUS versus QuantiFERON-TB Gold In-Tube (QFT-GIT) for detecting tuberculosis (TB) infection.

Methods

Between October, 2016 and May, 2018, 137 participants were prospectively recruited and subjected to QFT-GIT and QFT-PLUS testing. The concordance between tests and performance based on different immune states and/or TB infection risk were evaluated.

Results

The 137 participants were classified as follows: active TB (n = 14), TB contact (n = 14), screening before biologic therapy (n = 85) and other disease (n = 24). The positive results for either test were 100% (n = 14/14), 42.9% (n = 6/14), 15.3% (n = 13/85), and 62.5% (n = 15/24) in each four groups, respectively. The QFT-GIT and QFT-PLUS test results showed good concordance with 91.2% agreement and a Cohen’s κ of 0.807. The good concordance between two tests was also observed in 64 immunocompromised subjects (agreement of 90.6% and a Cohen’s κ of 0.711). The intra-class correlation coefficient for each antigen tube of the QFT-PLUS showed a good correlation with the IFN-γ release of the QFT-GIT (TB1 = 0.912, p < 0.001; TB2 = 0.918, p < 0.001).

Conclusions

QFT-PLUS showed highly comparable results to those of QFT-GIT for diagnosing TB infection in South Korea as well as in immunocompromised subjects.

INTRODUCTION

Tuberculosis (TB) is a major global health concern, with an estimated 10.4 million incident cases worldwide in 2016 [1]. Moreover, it has been suggested that approximately one-third of the world’s population is latently infected with Mycobacterium tuberculosis (MTb) [2]. The estimated lifetime risk of developing active TB in subjects with latent TB infection (LTBI) is 5% to 15%, and the risk is highest in the first 2 years following infection [3]. The early detection and treatment of LTBI in countries with a low or intermediate TB prevalence is an important factor for preventing the progression to active TB worldwide [4,5].

After excluding active TB on a chest X-ray (CXR), the diagnosis of LTBI is indirectly made by evaluating the immune response against MTb using a tuberculin skin test (TST) and/or interferon-γ (IFN-γ) release assays (IGRA) [6]. The QuantiFERON-TB Gold In-Tube (QFT-GIT, Qiagen, Hilden, Germany) and the T-SPOT.TB (Oxford Immunotec, Abingdon, UK) are the two main commercially available IGRA products. Although IGRA products don’t have cross-reactivity with the bacillus calmette-guerin (BCG) vaccination like TST, they have cross-reactivity with some other mycobacteria (e.g., Mycobacterium kansasii, Mycobacterium marinum, and Mycobacterium szulgai) [7]. Moreover, IGRA products have a reduced sensitivity in immunocompromised patients and children [8,9]. They are also unable to distinguish between recent and remote infections [10].

Several studies have revealed that CD8+ T-cells play an important role in the host defense against MTb by the cytotoxic pathway and the cytosolic pathway [11-15]. One study reported that active TB patients with smear-positive sputum showed higher detectable CD8+ T-cell responses than those with smear-negative sputum and LTBI patients, while pulmonary TB patients also showed higher responses than extrapulmonary TB patients [16]. Furthermore, active TB patients with intermediate/high radiologic severity or microbiological TB showed higher detectable CD8+ T-cell responses than those with low radiologic severity or clinical TB [17]. The latter two studies indicated that MTb load is positively correlated with CD8+ T-cell responses.

As previous studies provided good evidence for the role of CD8+ T cell responses in MTb infection, the QuantiFERON-TB Gold PLUS (QFT-PLUS) has been introduced as a new-generation QFT-GIT. The QFT-PLUS contains two antigen tubes, TB1 and TB2: the TB1 tube contains ESAT-6- and CFP-10-derived peptides (TB 7.7 was removed) and is designed to induce CD4+ T cells response; the TB2 contains both the same long peptides of TB1 and newly designed peptides that stimulate IFN-γ production by both CD4+ and CD8+ T cells [18]. Recent studies have reported similar accuracies of QFT-PLUS and with QFT-GIT [17,19-22], and some showed higher CD8+ T cell responses to recent Mtb exposure compared to remote exposure in contact screening [19,22].

This study aimed to evaluate the performance of the new QFT-PLUS assay in diagnosing patients with TB infection to identify whether it can replace the QFT-GIT in South Korea, where the incidence of active TB is intermediate (77 per 100,000 in 2016) and the BCG vaccination is mandatory [23].

METHODS

Study population

Between October 2016 and May 2018, 182 participants of age > 18 years were prospectively recruited for diagnosing TB infection from Asan Medical Center, a tertiary referral center in Seoul, South Korea. Most of these cases comprised suspected active TB, recent TB contact, or candidates for TB infection tests. The QFT-GIT and QFT-PLUS assays were performed for each participant. Forty-one participants were excluded owing to not wanting to participate, one owing to an insufficient blood sample for analysis, and three owing to a diagnosis of nontuberculous mycobacterial (NTM) disease showing cross-reactivity with MTb in IGRA (Mycobacterium kansasii, two cases; Mycobacterium marinum infection, one case) [7]. Therefore, 137 patients were involved in the final analysis.

A full history was taken that included age, sex, body mass index, concomitant disease, BCG scar, previous TB treatment, and immune status. CXR, QFT-GIT, and QFT-PLUS were performed for all participants at the baseline examination. CXR findings suggestive of healed TB were identified in the presence of apical fibronodular lesions, calcified lymph nodes, calcified solitary nodules, and pleural thickening [24]. Immunocompromised status was defined as a history of diabetes mellitus, chronic kidney disease, malignancy, organ transplantation, human immunodeficiency virus (HIV), and the use of immunosuppressive agents or steroids (prednisolone 15 mg/day for > 1 month) [22]. All participants were classified based on TB infection risk (active TB, recent TB contact, LTBI screening before biologic therapy, or other disease). Active TB group consisted of patients with culture-positive pulmonary TB alone who were enrolled before initiating anti-TB medication, except for one patient who was enrolled after 1 month of anti-TB treatment. Recent TB contact group consisted of patients with household contacts or other close contacts with those with infectious TB. Biologic therapy group consisted of patients with immune-mediated inflammatory diseases who were also candidates for biologic therapy such as anti-TNF agents. Other disease group consisted of participants who were finally diagnosed with disease other than TB. Our study protocol was approved by the Institutional Review Board of Asan Medical Center (IRB No.: 2017-0004). All participants provided written informed consent.

QFT-GIT and QFT-PLUS diagnostics

Peripheral blood sampling and sample processing for both QFT-GIT and QFT-PLUS were performed and interpreted according to the manufacturer’s instruction [18]. Peripheral blood was withdrawn simultaneously, directly into test tubes for use in both tests. The tubes were incubated at 37°C ± 1°C for 16 to 24 hours. All active TB patients were enrolled before initiating anti-TB treatment except for one patient who was enrolled after 1 month of anti-TB treatment. The test was recorded as positive if the antigen response (TB for QFT-GIT, TB1 and/or TB2 for QFT-plus) was ≥ 0.35 IU/mL above the negative control and ≥ 25% of the negative control. The results for both tests were recorded as negative if the antigen response minus the negative control was < 0.35 IU/mL or < 25% of the negative control with a positive control (mitogen tube) of ≥ 0.5 IU/mL. The result for both tests was recorded indeterminate if the antigen tube minus the negative control was < 0.35 IU/mL or < 25% of the negative control with a positive control of < 0.5 IU/mL or the antigen response of the negative control was > 8 IU/mL [18].

Statistical analysis

The statistical analyses were performed using the IBM SPSS version 21.0 (IBM Co., Armonk, NY, USA). Continuous variables are expressed as mean ± standard deviation (SD) or as median and interquartile range (IQR), while categorical variables are expressed as number and percentage. The chi-square or linear by linear associates test was used for comparison of categorical variables. The Wilcoxon signed rank test was used for inter-test comparison of continuous variables. The Mann-Whitney U test or Kruskall-Wallis test was also used for inter-group comparison of continuous variables.

The agreement between QFT-GIT and QFT-PLUS findings was evaluated by calculating the overall percentage of concordant results and Cohen’s κ coefficient. The agreement of IFN-γ release between the QFT-GIT and QFT-PLUS was evaluated by calculation of the intraclass correlation coefficient (ICC). Linear regression analyses were performed to assess the correlation in IFN-γ release between the tests.

The difference between TB2 and TB1 antigen responses greater than the cutoff of 0.6 IU/mL was investigated to evaluate whether IFN-γ release of CD8+ T-cells is related to recent TB exposure based on a previous journal by Metcalfe et al. [25].

RESULTS

Characteristics of study population

The demographic characteristics of the 137 participants are shown in Table 1. They had a mean ± SD age of 46.8 ± 16.3. Immune-mediated inflammatory diseases (IMIDs) were the most common comorbid condition (n = 85, 62.0%). No subjects had chronic kidney disease or HIV infection. Healed TB was seen on CXR in 11 subjects (8.0%) without evidence of active TB and 10 subjects (7.3%) with a previous history of anti-TB treatment. A total of 111 subjects had BCG scarring (81.0%), while 64 subjects were immunocompromised (46.7%). LTBI screening before biologic therapy was the most frequent TB infection risk group (n = 85, 62.0%), followed by other diseases (n = 24, 17.5%) and active TB (n = 14, 10.2%) or TB contact (n = 14, 10.2%). Other disease group consisted of nine participants with healed TB on the CXR, seven with non-specific CXR abnormality, five with NTM diseases, two with pneumonia, and one under health checkup. The positive rates in each group are shown in Fig. 1.

Baseline clinical characteristics of 137 subjects

Figure 1.

Positive rates of QuantiFERON-TB Gold In-Tube (QFT-GIT) and QuantiFERON-TB Gold Plus (QFT-PLUS) by tuberculosis (TB) infection risk group (n = 137).

Comparison of QFT-GIT and QFT-PLUS

The QFT-PLUS results were comparable to those of QFT-GIT, which resulted in an agreement of 91.2% and a Cohen’s κ of 0.807 (Table 2). QFT-GIT showed a 90.5% agreement and Cohen’s κ of 0.790 to TB1 and a 92.0% agreement and Cohen’s κ of 0.820 to TB2. There were no significant differences in agreement between the QFT-GIT and QFT-PLUS for the different immune states (p = 0.811) and no significant trend for TB infection risk (p = 0.558).

Comparison of QFT-GIT versus QFT-PLUS in 137 subjects

The median IFN-γ release of TB (5.85 IU/mL; IQR, 2.05 to 10.00) was significantly higher than that of TB1 (2.62 IU/mL; IQR, 1.06 to 7.91; p = 0.001) and TB2 (3.15 IU/mL; IQR, 1.08 to 8.30; p = 0.004) in the positive QFT-GIT and QFT-PLUS results (n = 40). There were significant differences in the median IFN-γ release of TB (0.01 IU/mL; IQR, 0 to 0.05) compared to that of TB1 (0.01 IU/mL; IQR, –0.01 to 0.03; p = 0.003) and TB2 (0.01 IU/mL; IQR, –0.01 to 0.02; p = 0.002) in the negative QFT-GIT and QFT-PLUS results (n = 85). The ICC showed good correlation between the QFT-GIT and QFT-PLUS (TB1: ICC = 0.912, p < 0.001; TB2: ICC = 0.918, p < 0.001). In addition, linear regression analyses showed good correlation between tests (TB1: r2 = 0.722; TB2: r2 = 0.734) (Fig. 2A and 2B).

Figure 2.

Linear regression plot of interferon-γ concentration in (A) tuberculosis (TB) antigen–nil vs. TB1-nil, (B) TB antigen–nil vs. TB2-nil, and (C) TB1-nil vs. TB2-nil. QFT-PLUS, QuantiFERON-TB Gold Plus.

Discordant results were found in 12 subjects (Table 3), but a statistical analysis could not be performed due to the small number of subjects. Among them, IFN-γ release was in the borderline range of 0.25 to 0.8 IU/mL in 8 QFT-GIT samples [25].

Discordant results of QFT-GIT versus QFT-PLUS (n = 12)

Comparison of QFT-GIT and QFT-PLUS in immunocompromised subjects

The QFT-PLUS results were compatible with those of QFT-GIT in the 64 immunocompromised subjects, which resulted in an agreement of 90.6% and a Cohen’s κ of 0.711 (Table 4).

Results of QFT-GIT versus QFT-PLUS in 64 immunocompromised subjects

The median IFN-γ release of TB (3.01 IU/mL; IQR, 1.80 to 10.00) did not differ significantly from that of TB1 (4.93 IU/mL; IQR, 1.15 to 10.00; p = 1.000) and TB2 (4.17 IU/mL; IQR, 1.28 to 10.00; p = 0.866) in the QFT-GIT– and QFT-PLUS–positive results (n = 10). There were significant differences in the median IFN-γ release of TB (0.01 IU/mL; IQR, 0.00 to 0.05) compared to that of TB1 (0.01 IU/mL; IQR, –0.01 to 0.02; p = 0.007) and TB2 (0 IU/mL; IQR, –0.01 to 0.02; p = 0.006) in QFT-GIT– and QFT-PLUS–negative results (n = 48). ICC showed a good correlation between QFT-GIT and QFT-PLUS (TB1: ICC = 0.947, p < 0.001; TB2: ICC = 0.951, p < 0.001).

There were six cases of discordant results. A statistical analysis could not be performed due to the small number of subjects. The IFN-γ releases of the four QFT-GIT samples were in the borderline range of 0.25 to 0.8 IU/mL [25].

Evaluation of the role of CD8+ T-cells

The contribution of CD8+ T-cells was evaluated by investigating the difference in IFN-γ release between TB2 and TB1 within the QFT-PLUS–positive group (Table 5). Nine subjects showed a TB2 minus TB1 value > 0.6 IU/mL. Among them, active TB was the most frequent (n = 5), followed by other disease (n = 3) and LTBI screening before biologic therapy (n = 1). There was no significant difference in the proportion of a TB2 minus TB1 IFN-γ release > 0.6 IU/mL among the four groups (p = 0.133). This was also seen between the high probability of recent infection group (active TB and TB contact: n = 5/19, 26.3%) and low probability of infection group (biologic therapy and other disease: n = 4/25, 16.0%) (p = 0.401). Furthermore, there was no significant difference in the median value of TB2 minus TB1 within QFT-PLUS–positive subjects among the four groups (p = 0.169) or between the two groups mentioned above (p = 0.147).

Difference in IFN-γ level between TB2 and TB1 ([TB2-TB1] > 0.6 IU/mL) based on TB infection risk in subjects with QFT-PLUS–positive results (n = 44)

Comparison of TB1 and TB2 of the QFT-PLUS assay

The TB1 and TB2 results were compatible, resulting in an agreement of 97.1% and a Cohen’s κ of 0.931.

The median IFN-γ release of TB2 (2.83 IU/mL; IQR, 0.84 to 6.93) did not differ significantly from that of TB1 (2.39 IU/mL; IQR, 0.78 to 6.64) in the 44 QFT-PLUS positive results (p = 0.422). TB2 (0.01 IU/mL; IQR, –0.01 to 0.03) did not differ significantly from TB1 (0.01 IU/mL; IQR, –0.05 to 0.03) in 93 the QFT-PLUS negative results (p = 0.665). The ICC between TB1 and TB2 was 0.991 (p < 0.001), which suggested good correlation. The linear regression analyses also showed good correlation between TB1 and TB2 (r2 = 0.965) (Fig. 2C).

There were four cases of discordant results (one of TB1-negative and TB2-positive, three of TB1-positive and TB1-negative). A statistical analysis could not be performed due to the small number of subjects.

DISCUSSION

Most previous studies comparing the performances of the QFT-PLUS and QFT-GIT tests were performed in European countries with a low TB burden and showed comparable results for diagnosing TB infection [19,21,22,26]. Our study provides further evidence that the QFT-PLUS and QFT-GIT are highly comparable based on the results of agreement, Cohen’s κ, and ICC between the tests even in a TB endemic country. The test results did not differ significantly by immune status or TB infection risk. This indicates the usefulness of QFT-PLUS compared to the QFT-GIT even in an intermediate TB burden country like Korea.

We demonstrated here that the QFT-PLUS results were highly comparable to those of the QFT-GIT in immunocompromised subjects as well. Previous studies revealed that QFT-PLUS showed higher sensitivity in HIV and TB co-infected subjects than the QFT-GIT [20,27]. In this study, the majority of subjects had been assigned to an LTBI screening before biologic therapy group and had IMIDs (n = 85/137, 62.0%). Among these patients, the majority were immunocompromised (n = 53/85, 62.4%), due to the high usage of disease-modifying anti-rheumatic drugs or steroids. Anti-tumor necrosis factor-α antagonist or other biologics are being increasingly used in such patients [28]. As a result, this might lead to an increased risk of active TB, which mostly results from the reactivation of LTBI in an intermediate TB endemic country [28,29]. Our study findings suggested that QFT-PLUS could be interchangeably used with QFT-GIT to diagnose TB infection in patients with immunocompromised status (especially those resulting from CD4+ T-cell impairments) for detection of LTBI, in addition to a recent study by Ryu et al. [30]. Our study indicated that the positive rate of QFT-GIT (n = 14/64, 21.9%) was slightly higher than that of QFT-PLUS (n = 12/64, 18.8%) in immunocompromised hosts, which could be attributed to high variability of the cut-off value of QFT-GIT of ± 0.6 IU/mL, resulting in false-positive results and conversion/reversion events [25,31]. All four QFT-GIT-positive and QFT-PLUS-negative cases showed IFN-γ level in the range of 0.38 to 0.77 IU/mL. Further studies to compare between QFT-GIT and QFT-PLUS in immunocompromised subjects including larger cohort-size and long-term clinical follow-up are needed.

A previous study showed that CD8+ T-cells were frequently detected in individuals with active TB compared to those with LTBI, which correlates to a high TB burden [16]. Furthermore, other studies showed that higher IFN-γ release in TB2 compared with TB1 was associated with recent TB infection [19,22]. The high-risk TB infection group has a greater chance of recent infection than the low-risk group. However, in our study, there was no significant difference in the proportion of TB2 antigen response (TB2-TB1 difference of > 0.6 IU/mL) between the two groups, nor was there a significant difference in the median IFN-γ release of TB2-TB1 between the groups. This finding contradicts that of a previous study of the Netherlands and Belgium [19], and could be explained as follows. First, QFT-PLUS as well as QFT-GIT, doesn’t have capability to distinguish between recent TB infection and remote TB infection. Second, while QFT-PLUS could distinguish between recent TB infection and remote TB infection, it failed to show greater TB2-antigen response in the high-risk group in our study, which may be due to the low number of study participants. Furthermore, since South Korea is a TB-prevalent country, there is possibility of unnoticed, hidden infection even in the low-risk TB infection group. Further studies are needed to reveal the role of the CD8+ T-cell-response component of QFT-PLUS test in the diagnoses of TB infection.

The positive rate of either test was higher in the other disease group (62.5%) than in the TB contact group (42.9%, p = 0.240). This is contradictory with the fact that the TB contact population usually has a higher possibility of LTBI infection than the general population. This phenomenon may be attributed to the relatively low number of participants in TB contact group, and in part, to the slightly lower median-participant age in TB contact group (53.93; IQR, 45.75 to 62.25) versus other disease group (57.0; IQR, 49.25 to 64.75), despite absence of statistically significant difference [1].

In this study, the positive IFN-γ release level was significantly higher on the QFT-GIT than the TB1 on the QFT-PLUS. This might be attributable to the presence of the peptide antigen TB 7.7 in the QFT-GIT kit, which was removed from the QFT-PLUS kit [18]. Our study also showed that TB2 induced significantly lower IFN-γ release levels compared to that of TB in the QFT-GIT and QFT-PLUS positive results, which is in contrast with the previous study [19]. We expected a higher response of TB2 than TB based on the fact that TB2 contains modified peptides that elicit a CD8+ T-cell reaction in addition to the CD4+ T-cell response [18]. This unexpected result might have been due to the low number of patients with a recent TB infection in this study group.

The current diagnostic standard of IGRA tests emphasizes the importance of dichotomous value, positive or negative, over that of absolute IFN-γ level. However, based on findings of a recent study of positive association between higher absolute IFN-γ level and TB disease occurrence, absolute IFN-γ level may be considered as additional important information that enables diagnosis of TB infection [32]; hence, in our study, comparison data of absolute IFN-γ levels were presented even though they comprised negative values with similar median and IQR values between the two groups.

The discordant IFN-γ release between the QFT-GIT and the QFT-PLUS was mostly in the borderline range (n = 8/12, 66.7%). This indicates the possibility of test variability instead of true inter-test differences [25]. Among the 12 cases of discordant results, five were QFT-GIT–positive and QFT-PLUS–negative. This might be due to the relatively low IFN-γ release of TB1 compared to the QFT-GIT or the low number of patients with a recent TB infection as mentioned above.

Our study has some limitations. First, our sample size was relatively small, especially in the high-risk TB infection groups. This might have influenced the statistical results of the true IFN-γ release difference (TB2-TB1) comparison between TB infection risk groups, thereby causing confusion in the interpretation of the role of CD8+ T-cells as a predictor for TB burden or recent TB infection. Second, we could not evaluate the sensitivity and specificity of the QFT-PLUS because there is still no gold standard test for LTBI infection. Thus, we could not evaluate the actual accuracy of the QFT-PLUS or properly assess the discordant results between the tests. Third, this study was processed in Korea, a TB-prevalent country. This might have raised the problem of including a relatively high number of recent LTBI-infected subjects even in the low-risk TB infection group than expected. Fourth, this study included a relatively broad range of immunocompromised statuses. We could have drawn more meaningful results from the QFT-PLUS if we included only large numbers of CD4+-deficient subjects since the QFT-PLUS has the additional ability of inducing the CD8+ T-cell response.

In conclusion, our study showed highly comparable results between the QFT-PLUS and QFT-GIT in Korea, even in immunocompromised subjects, which suggests that QFT-PLUS has potential for use as an alternate modality to QFT-GIT in the diagnosis of TB infection. However, this study could not provide supporting evidence for the use of the QFT-PLUS in distinguishing between recent TB infection (such as active TB or recent LTBI) and remote TB infection, which might be due to the low numbers of subjects and intermediate TB burden in Korea.

KEY MESSAGE

1. QuantiFERON-TB Gold PLUS (QFT-PLUS) showed highly comparable results to those of QuantiFERON-TB Gold In-Tube (QFT-GIT) for diagnosing tuberculosis (TB) infection in Korea, as well as in immunocompromised subjects.

2. QFT-PLUS showed no significant difference in the proportion of TB2 minus TB1-interferon-γ release of > 0.6 IU/mL between the high-risk TB infection group and the low-risk TB infection group, which might be due to low numbers of subjects and the intermediate TB burden in Korea.

Notes

No potential conflict of interest relevant to this article was reported.

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Figure 1.

Positive rates of QuantiFERON-TB Gold In-Tube (QFT-GIT) and QuantiFERON-TB Gold Plus (QFT-PLUS) by tuberculosis (TB) infection risk group (n = 137).

Figure 2.

Linear regression plot of interferon-γ concentration in (A) tuberculosis (TB) antigen–nil vs. TB1-nil, (B) TB antigen–nil vs. TB2-nil, and (C) TB1-nil vs. TB2-nil. QFT-PLUS, QuantiFERON-TB Gold Plus.

Table 1.

Baseline clinical characteristics of 137 subjects

Characteristic Value
Age, yr 46.8 ± 16.3
Sex, male 67 (48.9)
Body mass index, kg/m2 23.1 ± 3.6
Comorbid conditions
 IMIDs 85 (62.0)
 Diabetes mellitus 6 (4.4)
 Malignancy 6 (4.4)
 Organ transplant recipient 2 (1.5)
Previous history of anti-TB treatment 10 (7.3)
Positive BCG scarring 111 (81.0)
Immunocompromiseda 64 (46.7)
TB infection risk group
 Active TB 14 (10.2)
 Recent TB contact 14 (10.2)
 LTBI screening before biologic therapy 85 (62.0)
 Other diseases 24 (17.5)

Values are presented as mean ± SD or number (%).

IMID, immune-mediated inflammatory disease; TB, tuberculosis; BCG, bacillus calmette-guérin; LTBI, latent tuberculosis infection.

a

Causes of immunosuppression included diabetes mellitus, chronic kidney disease, malignancy, organ transplantation, human immunodeficiency virus, immunosuppressive medications or steroids (prednisolone 15 mg/day for > 1 month).

Table 2.

Comparison of QFT-GIT versus QFT-PLUS in 137 subjects

QFT-GIT results No. of subjects QFT-PLUS results
Positive
Negative
TB1-nil or TB2-nil TB1-nil TB2-nil
Negative 89 4 4 2 85
Positive 45 40 39 39 5
Indeterminate 3 0 0 0 3
Total 137 44 43 41 93

QFT-GIT, QuantiFERON-TB Gold In-Tube; QFT-PLUS, QuantiFERON-TB Gold Plus; TB, tuberculosis.

Table 3.

Discordant results of QFT-GIT versus QFT-PLUS (n = 12)

QFT-GIT results Immunosuppression TB infection risk Sample No. IFN-γ, IU/mL
QFT-GIT
QFT-PLUS
TB-nil TB1-nil TB2-nil
Positive Yes Biologic therapy S8 0.38 0.06 0.04
S56 0.65 0.03 0.06
S98 0.69 0.12 0.02
S117 0.77 0.21 0.22
No TB contact S68 0.37 0.01 0.04
Negative Yes TB contact S18 0.19 0.42 0.25
Biologic therapy S147 0.15 3.15 2.8
No Others S72 0.28 0.55 0.66
S141 0.34 0.63 0.34
Indeterminate No Biologic therapy S26 –0.02 0 0.01
S155 0.41 0 0.01
Others S43 0 0 0

QFT-GIT, QuantiFERON-TB Gold In-Tube; QFT-PLUS, QuantiFERON-TB Gold Plus; TB, tuberculosis; IFN-γ, interferon-γ.

Table 4.

Results of QFT-GIT versus QFT-PLUS in 64 immunocompromised subjects

QFT-GIT results No. of subjects QFT-PLUS results
Positive
Negative
TB1-nil or TB2-nil TB1-nil TB2-nil
Negative 50 2 2 1 48
Positive 14 10 10 9 4
Total 64 12 12 10 52

QFT-GIT, QuantiFERON-TB Gold In-Tube; QFT-PLUS, QuantiFERON-TB Gold Plus; TB, tuberculosis.

Table 5.

Difference in IFN-γ level between TB2 and TB1 ([TB2-TB1] > 0.6 IU/mL) based on TB infection risk in subjects with QFT-PLUS–positive results (n = 44)

TB2-TB1, IU/mL Active TB/TB contact Biologic therapy/other diseases Total
> 0.6 5 4 9
≤ 0.6 14 21 35
Total 19 25 44

IFN-γ, interferon-γ; TB, tuberculosis; QFT-PLUS, QuantiFERON-TB Gold Plus.