The meta-analysis for ideal cytokines to distinguish the latent and active TB infection

Tuberculosis (TB) is still an urgent public health threat and a leading cause of death in spite of worldwide application of vaccination. It has been estimated that approximately a fourth of the world’s population is infected with Mycobacterium tuberculosis (Mtb) [1]. The majority of infected individuals are able to control the infection and remain asymptomatic, establishing a state of latent TB infection (LTBI). But approximately 5 to 10% LTBI patients develop into active TB due to reactivation and resuscitation of dormant bacilli indicating that persons with LTBI are the largest reservoir of infectious source after activation [2]. Thus, the development of rapid and accurate new diagnostic methods that can detect Mtb infection, especially distinguish between active TB and LTBI, is essential for intensifying the fight against TB and implementing the End TB Strategy [3, 4].

Diagnosis of TB status is challenging due to its diverse clinical forms and outcomes [2, 5]. Current active TB diagnosis relies on microbiologic detection of the pathogen, radiological imaging or clinical manifestations. Measurement of host immune responses, like the tuberculin skin test (TST) that is the intracutaneous injection of purified protein derivative (PPD) into the forearm, and interferon-gamma (IFN-γ) release assays (IGRAs) including the QuantiFERON®-TB Gold In-Tube (QFT) assay and T-SPOT.TB test, remains the common diagnosis for TB infection [6]. However, the TST bears limited specificity due to fail in identifying non-tuberculous mycobacteria (NTM) as well as Bacille Calmette-Guérin (BCG) vaccination [7, 8]. Although the T-cell-based IGRAs have higher specificity than the traditional TST, they remain relatively insensitive and considerable indetermining results especially in immunocompromised individuals and young children [9, 10]. Another significant limitation of both TST and IGRAs is unable to distinguish between active TB and LTBI, and this greatly hampers the early treatment and control of TB [11]. Consequently, an immunodiagnostic test to discriminate the infection statues is urgent required and would be a major advance for clinical care.

Mounting data showed that the numerous cytokines and chemokines played an important role in cellular immune responses to Mtb infection [12‐14]. Only measuring IFN-γ response by IGRAs may leave out other key molecules in Mtb infection diagnosis [15]. Additional biomarkers have been investigated to improve clinical diagnosis of TB and assessment of disease status. Several studies proved that interleukin (IL)-2, IFN-γ-inducible protein of 10 kDa (IP-10), IL-5 and IL-10 had promising diagnostic performance for TB infection (including both active TB and LTBI) [16‐19]. Importantly, some cytokines were shown potential diagnostic value in distinguishing of patients with active disease and LTBI, such as macrophage inflammatory protein (MIP)-1β [18], or tumor necrosis factor (TNF-α), IL-12 p40 and IL-17 [20]. It also suggested that combination of biomarker could be more sensitive than single markers for differentiating between the various stages of TB infection [17, 19, 21]. Although several markers have been suggested for diagnosing TB infection as well as differentiate between active TB and LTBI, each marker showed heterogeneity in specificity and sensitivity in different studies. To verify the diagnostic values of each biomarker in TB infection is critical for the economical selection of proper item for clinical practice, especially to provide better diagnosis performance in implying the combination of biomarkers.

In the light of these limitations, we present a systematic review and meta-analysis of the literature according to evidence-based highest-standard criteria on the accuracy of different biomarkers for differentiating active TB and LTBI, to determine their diagnostic performance and operational characteristics.

The systematic review was conducted following the guidelines of the Preferred Reporting Items for Systematic Reviews and Meta-Analyses statement (PRISMA) [22] checklist.

After database searching and selection criterial, our systematic review and meta-analysis enrolled 14 studies examining the ability of cytokine production to distinguish between active TB and LTBI [16, 28‐40]. Specifically, 8 studies with 11 independent data detected IL-2 levels [29, 31‐34, 38‐40], 8 studies for IP-10 representing 10 independent data [28, 30, 35‐40], 6 studies for IFN-γ representing 8 independent data [28, 29, 33, 38‐40], 3 studies for IL-13 representing 4 independent data [28, 29, 38]. The detection of IL-5, IL-10 and TNF-α were available from 3 independent studies. Other cytokines were excluded for our meta-analysis because relevant data resource was less than 3. The study search and selection flow chart was shown in Fig. 1.

There is a great need for profiling biomarkers, even biomarker panels, in addition to IFN-γto improve TB diagnosis to facilitate quick and correct treatment implementation. However, there are few studies to work on it. We identified the diagnostic performance of each cytokine with the hope that our study will pave a road to certain which variables as critically essential for TB diagnosis in several settings elsewhere. In current meta-analysis, IL-2 had the highest diagnostic accuracy with total 90% AUC. And IP-10, IL-5, IL-13 and IFN-γ showed an acceptable diagnostic accuracy. Our systematic analysis data added the confidence to distinguish active TB and LTBI through fully assessment of the host immune response and combined biomarkers provided enhanced diagnostic capacity in clinical practice. To our knowledge, this is the first systematic review and meta-analysis for assessment of immune molecules’ diagnostic accuracy in the distinction of active TB and LTBI.

It is well known that Th1-type immune response and relevant cytokines play a critical protective role in the host defense against Mtb infection, especially IFN-γ, IL-2 and TNF-α [39, 41, 42]. However, IFN-γdetection is not ideal in our data with sensitivity of 0.67, and specificity of 0.75. In contrast, IL-2 levels had greater sensitivity, but with comparable lower specificity in the discrimination of active TB and LTBI (Fig. 3a). With their diagnosis strength, we believed that IL-2 + IFNγ combination may be an idea strategy due to the compensation of each other. Several studies have supported that IL-2/IFN-γ ratio has the potential to be a useful value to distinguish between active TB and LTBI [17, 31, 43]. The diagnostic value of the IL-2/IFN-γ ratio was based on the dynamics of functional T-cell signatures that antigen clearance are typically associated with IL-2-dominant T-cell responses, while high antigen loads are associated with IFN-γ-dominant T-cell responses [44]. The diagnostic value of the IFN-γ and IL-2 in discrimination of active TB and LTBI need further investigation. We proposed that a panel with additional molecules might be optimal besides the combination of IFN-γ and IL-2.

In our meta-analysis, other biomarkers were also evaluated for their sensitivity and specificity in distinguishing between active TB and LTBI. IL-10 can suppress T-cell proliferation and IFN-γproduction, which maybe initiate the activation of LTBI. Decreased IL-10 expression was found to release the suppression to Th1 immunity in active TB patients [39]. Further, in chronic mycobacterial infections, a higher proportion of IL-10⁺ CD4⁺ T cell subsets are found [39, 45]. In our analysis, IL-2 and IL-10 pattern was suggested to discriminate active TB and LTBI [39]. However, IL-10 detection was only found in 3 studies, with low sensitivity and specificity. The potential of IL-10 alone or in combination with other biomarkers for discriminating active TB and LTBI needs to be further evaluated. IP-10 is a chemokine that promotes Th1-type CD4⁺ T cells responses and IFN-γ upregulation, attracts monocytes and activated lymphocytes to inflammatory foci. Current studies reported that IP-10 contributes to the necrosis of tuberculous granulomas by recruiting the immune cells and inhibiting angiogenesis [46‐48]. A number of studies have previously highlighted the diagnostic potential of IP-10 in distinguishing between active TB and LTBI [28, 35, 36]. Our data showed IP-10 identified active TB and LTBI with sensitivity of 77 and 73% specificity, indicating IP-10 has potential in differential diagnosis between TB diseases.

Previous studies have mentioned that the combination panel of fractalkine, IFN-γ, IL-4, IL-10 and TNF-α could distinguish active TB and LTBI [38, 49]. Another study found that the combination of TNF-α, IL-2 and IP-10 had the strongest diagnostic potential to differentiate active TB and LTBI [40]. These results all indicated that multiple cytokine pattern may improve the ability to detect various TB disease stages. More prospective studies are still necessary to identify the ideal combination.

Among our candidate cytokines, a few studies have been conducted on IL-5 and IL-13 detection. Based on the results obtained from our analysis, we reported that the sensitivity of two cytokines were 64 and 75%, and the specificity were 75 and 71%, respectively, in discriminating active TB and LTBI. Thus, these cytokines may also be a good candidate for differential diagnosis of active TB and LTBI.

The I² test for the pooled sensitivity and specificity indicated that there is heterogeneity during the data analysis in our study. Stratified (subgroup) analysis for IL-2, IP-10 and IFN-γ based on cytokine detection assay, population with different TB incidence, stimulator with Mtb antigens. Surprisingly, we found that the accuracy of cytokine detection assays varied in different cytokine measurement. ELISA is good for IL-2 and IFN-γ detection, while IP-10 preferred Luminex detection with higher sensitivity and specificity. In contrast, both RT-PCR and ELISPOT did not reach the expectation regarding to the diagnostic performance in certain cytokines (Table 3). The results indicated that detection method is critical for different biomarkers in their diagnostic capacity.

Our results displayed the diagnostic value of certain cytokine varied at different area with different TB incidence. IP-10 and IFN-γ detection were less sensitive for distinguishing between active TB and LTBI in areas with high incidence of tuberculosis than low ones, even IFN-γdetection showed higher specificity. However, the distinguishing sensitivity of IL-2, IP-10 and IFN-γwere better in the low prevalence area of TB. Therefore, proper selection of cytokines or panels according to areas with different incidence of tuberculosis is necessary in help to improve the ability to distinguish between active TB and LTBI.

The Mtb-antigens were used as stimulators for cytokine detection. In our subgroup analysis, our data supported that AlaDH antigen is better compared to other Mtb-specific antigens and PPD, especially in IL-2 production. AlaDH antigen had different modified conformation in latent and active TB [50]. Since this antigen is missing in M. bovis and in BCG, it is highly specific to Mtb. Thus Mtb AlaDH might be a better candidate as a stimulator in cytokine production to discriminate between active TB and LTBI. Of course, our subgroup analysis did not fully cover the variability found in cytokine assay results across studies. Other factors, such as background TB disease, technician skill and experience or ethnic background could account for the heterogeneity.

Several limitations should be considered when interpreting the results. First, our literature search was limited to published studies that had probably missed some of the conference literature. Second, subgroup analysis of IL-5, IL-13, IL-10 and TNF-α was restricted by limited original data. The third limitation was stemmed from the study design of each original study. The non-prospective study designs may impair the quality of a study for diagnostic test accuracy.