key: cord-0003182-vclnb0eh
authors: de Almeida, Carlos Podalirio Borges; Ziegelmann, Patrícia Klarmann; Couban, Rachel; Wang, Li; Busse, Jason Walter; Silva, Denise Rossato
title: Predictors of In-Hospital Mortality among Patients with Pulmonary Tuberculosis: A Systematic Review and Meta-analysis
date: 2018-05-08
journal: Sci Rep
DOI: 10.1038/s41598-018-25409-5
sha: 6f7b203d2f9e6349477e89e472ab1144b978fe60
doc_id: 3182
cord_uid: vclnb0eh

Background: There is uncertainty regarding which factors are associated with in-hospital mortality among patients with pulmonary TB (PTB). The aim of this systematic review and meta-analysis is to identify predictors of in-hospital mortality among patients with PTB. Methods: We searched MEDLINE, EMBASE, and Global Health, for cohort and case-control studies that reported risk factors for in-hospital mortality in PTB. We pooled all factors that were assessed for an association, and presented relative associations as pooled odds ratios (ORs). Results: We identified 2,969 records, of which we retrieved 51 in full text; 11 cohort studies that evaluated 5,468 patients proved eligible. Moderate quality evidence suggested an association with co-morbid malignancy and in-hospital mortality (OR 1.85; 95% CI 1.01–3.40). Low quality evidence showed no association with positive sputum smear (OR 0.99; 95% CI 0.40–2.48), or male sex (OR 1.09, 95% CI 0.84–1.41), and very low quality evidence showed no association with diabetes mellitus (OR 1.31, 95% IC 0.38–4.46), and previous TB infection (OR 2.66, 95% CI 0.48–14.87). Conclusion: Co-morbid malignancy was associated with increased risk of in-hospital death among pulmonary TB patients. There is insufficient evidence to confirm positive sputum smear, male sex, diabetes mellitus, and previous TB infection as predictors of in-hospital mortality in TB patients.

mortality and worse outcomes compared with women 19, 20 . Previous TB with multiple treatments has also been associated with in-hospital mortality [21] [22] [23] . Furthermore, patients with malignant tumors are immunocompromised and can have unusual clinical presentations, both related to delayed diagnosis and high mortality [24] [25] [26] .

In TB program monitoring, TB deaths are crucial indicators of the impact of TB control measures [10] [11] [12] [13] [14] , especially in areas with high HIV and TB prevalence. Data on TB deaths should provide us with a better understanding of the factors associated with these deaths and help guide interventions to reduce mortality; however, there is uncertainty regarding which factors are associated with in-hospital mortality among patients with pulmonary TB 10 .

We therefore conducted a systematic review and meta-analysis to establish predictors of in-hospital mortality among patients with pulmonary TB.

Search strategy. We used a multimodal search strategy focused on 3 bibliographical databases (MEDLINE, EMBASE and Global Health). An experienced librarian (RC) used medical subject headings, adding terms and keywords from a preliminary search to develop the database search strategies. In each database, the librarian used an iterative process to refine the search strategy through testing several search terms and incorporating new search terms as new relevant citations were identified. There were no language restrictions. The search included the following databases from inception to November 2015: MEDLINE, EMBASE and Global Health. The search consisted of three concepts combined using the AND operator 1 : tuberculosis 2 , hospitalization and 3 mortality (Appendix 1). The protocol of this study was published elsewhere 27 .

Study selection. Eligibility criteria. Eligible trials met the following criteria 1 : cohort or case-control design 2 ; explored risk factors for in-hospital mortality among patients with pulmonary TB in an adjusted analysis.

Assessment of study eligibility. Two reviewers (CPBA and DRS) trained in health research methodology screened, independently and in duplicate, the titles and abstracts of all citations identified in our search. The same reviewers screened all full text articles for eligibility; disagreements were resolved by consensus, with consultation of a third investigator (JWB) when resolution could not be achieved. We measured agreement between reviewers with the kappa statistic to assess the reliability of full-text review using the guidelines proposed by Landis and Koch 28 : <0.20 as slight agreement, 0.21-0.40 as fair agreement, 0.41-0.60 as moderate agreement, 0.61-0.80 as substantial agreement and >0.80 as almost perfect agreement.

Assessment of study quality. Two reviewers (CPBA and DRS) assessed risk of bias for each eligible study, independently and in duplicate, using the Newcastle-Ottawa quality assessment scale (NOS) for Cohort Studies 29 . The scale consists of nine items that cover three dimensions 1 : patient selection (4 items) 2 ; comparability of cohorts on the basis of the design or analysis (2 items); and 3 assessment of outcome (3 items). A point is awarded for each item that is satisfied by the study. The total score therefore ranges from zero to nine, with higher scores indicating higher quality. A total score ≥7 represents high quality.

Data Extraction and Analysis. Two reviewers (CPBA and DRS) extracted data from each eligible study, including demographic information (e.g. sex, age, race), methodology, and all reported predictors.

We performed meta-analysis for all predictors that were reported by more than one study. We used odds ratios (ORs) with associated 95% CI to measure the association of binary predictors and in-hospital mortality. We used random effects models for all meta-analyses. If a study reported more than 1 regression model, we used data from the most fully adjusted model presented. We also presented the results from the predictors explored by the studies but that were not eligible for meta-analysis.

We evaluated heterogeneity for all pooled estimates through visual inspection of forest plots, because statistical tests of heterogeneity can be misleading when sample sizes are large and CIs are therefore narrow 30 . We used the software R.

Publication bias. For meta-analyses with at least 10 studies, we assessed publication bias by visual assessment of asymmetry of the funnel plot and performed the Begg rank correlation test 31 .

Quality of evidence. We used the Grading of Recommendations Assessment, Development and Evaluation (GRADE) approach to summarize the quality of evidence for all meta-analyses 32 . We categorized the confidence in estimates (quality of evidence) as high, moderate, low or very low, on the basis of risk of bias 33 , imprecision 34 , indirectness, inconsistency 35 and publication bias 36 . We used GRADE evidence profiles to provide a succinct, easily digestible presentation of the quality of evidence and magnitude of associations 32 . In case of doubt or missing details about the studies, authors were contacted for clarification.

Ethics and Dissemination. This study is based on published data, and therefore ethical approval was not a requirement. This systematic review and meta-analysis is expected to serve as a basis for evidence to reduce in-hospital mortality in TB patients, and as a guide for future research based on identified knowledge gaps. It is anticipated that findings from this review will be useful for informing policy, practice and research priorities, improving the management of in-hospital TB patients. We also plan to update the review in the future to monitor changes and guide health services and policy solutions. 

Search Results and Study Characteristics. We identified 2,969 unique records, of which we retrieved 51

English and 3 non-English language articles in full text; 11 cohort studies, published between 2003 and 2013, that evaluated 5,468 patients proved eligible. Figure 1 shows the study selection flow diagram. There was substantial agreement (κ = 0.64) at the titles and abstract screening stage and perfect agreement (κ = 1.00) between reviewers at the full-text review stage.

All 11 eligible studies 1,4,15,37-44 were single-center and there was one non-English (Chinese) study included in our analysis. Two studies 38, 42 were conducted in Japan, two 40, 41 in Taiwan, three 15, 39, 43 in Korea, one 37 in Germany, one 4 in Israel, one 1 in Iran and one 44 in China. One study 39 used TB-related mortality as defined by the World Health Organization (the number of TB patients who died during treatment, irrespective of cause) 45 , two 38, 42 used all-cause mortality, and eight 1, 4, 15, 37, 40, 41, 43, 44 used TB-related mortality as judged by the investigators. The majority (9 of 11) 1,4,15,37,39-41,43,44 acquired data from medical records, with eight retrospective cohorts 1,4,37-42 and one prospective cohort study 15 (Table 1) .

Overall, the quality, evaluated by the NOS checklist for the outcome "mortality", was high (Table 2) . We did not have a sufficient number of studies in our meta-analyses to assess publication bias.

A total of 11 studies, involving a total of 2343 patients, reported the association of 60 factors with in-hospital mortality 1, 4, 15, [37] [38] [39] [40] [41] [42] . On the basis of our criteria, we conducted meta-analyses for 5 predictors of in-hospital mortality 1 : acid-fast bacilli (AFB) smear positive 2 , diabetes mellitus 3 , malignancy 4 , history of previous TB, and 5 . 2; Table 3 ). Table 4 presents the associations with in-hospital mortality for the factors that were not amenable to meta-analysis.

We found moderate quality evidence that co-morbid malignancy was associated with increased in-hospital mortality among TB patients. Low quality evidence showed that sex and AFB smear positive were not associated with in-hospital mortality, and very low quality evidence showed no association with previous TB infection and diabetes mellitus.

Our review has a number of strengths. Our search, which had no language restrictions, was designed and implemented by a research librarian, and literature screening and data extraction were performed independently and in duplicate by two reviewers using pretested, standardized extraction forms. The main limitation of our review was the small numbers of events that contributed to our meta-analyses, resulting in wide estimates of precision for our pooled measures of association.

Other studies 24-26 also found that malignancy increases the risk of death in TB patients. Patients with malignant tumors are immunocompromised due to the local or systemic effects of the disease itself, as well as to the treatment regimens, which can impair the immune system and make these patients particularly susceptible to developing TB 46 . In addition, TB can have an unusual clinical presentation, making diagnosis more difficult in these patients, contributing to delay in diagnosis and high mortality rates 47, 48 .

While not significantly associated with mortality in our review, previous TB has been reported to be associated with in-hospital mortality in many studies 1,21-23 . Patients who undergo multiple treatment regimens for TB can develop resistance to drugs with the subsequent emergence of MDR-TB and XDR-TB, conditions highly associated with greater risk of death 21 . Further, in settings other than hospitals, studies 49, 50 have demonstrated that smear positive patients have a better prognosis regarding mortality than smear negative patients. Indeed, indicators of atypical manifestations, such as smear-negative sputum, were associated with delayed diagnosis and Recently, a retrospective cohort study from Brazil 6 reported a high mortality rate during hospitalization (16.1%), and negative sputum smear microscopy was an in-hospital mortality predictor in the population studied. However, patients with pulmonary and extrapulmonary TB were included in this study. We did not find a significant association between male sex and in-hospital mortality among pulmonary TB patients. Worldwide TB notification data show that far more men than women have TB 7 . Some studies showed that mortality rates are higher in females during their reproductive years, but after that they are higher in men 19, 20 .

Diabetes was also not associated with mortality in pulmonary TB patients in this study. Only one study 1 included in this meta-analysis showed that diabetes was a predictor of mortality in TB patients, possibly because they included a larger number of diabetes patients (18% of the enrolled individuals). Some studies 1,16-18 have found that diabetes increases risk of early mortality during TB treatment. This effect may be explained by impaired TB treatment response 16 . In conclusion, the presence of malignancy was significantly associated with in-hospital death in pulmonary TB patients. Other predictors were not associated with in-hospital mortality in TB patients, probably due to the small number of events. Further research should explore promising predictors of in-hospital mortality in large prospective studies. Table 4 . Unpooled predictors for in-hospital mortality among TB patients.

Factors associated with mortality in tuberculosis patients

Prognostic factors in tuberculosis related mortalities in hospitalized patients

Mortality of patients hospitalized for active tuberculosis in Israel

High mortality in adults hospitalized for active tuberculosis in a low HIV prevalence setting

Factors associated with mortality in hospitalized patients with newly diagnosed tuberculosis

Geneva: World Health Organization. Available at: www.who

Tuberculosis in hospitalized patients: clinical characteristics of patients receiving treatment within the first 24 h after admission

Time delays in diagnosis of pulmonary tuberculosis: a systematic review of literature

Hospitalizations for tuberculosis in the United States in 2000: predictors of in-hospital mortality

Quality of life in tuberculosis: patient and provider perspectives

The impact of comorbidity on mortality following in-hospital diagnosis of tuberculosis

Experience with a medical-psychosocial inpatient unit

Delay in diagnosis among hospitalized patients with active tuberculosis-predictors and outcomes

The impact of nutritional deficit on mortality of in-patients with pulmonary tuberculosis

Diabetes is a strong predictor of mortality during tuberculosis treatment: a prospective cohort study among tuberculosis patients from Mwanza, Tanzania

Impact of diabetes and smoking on mortality in tuberculosis

Diabetes mellitus is associated with increased mortality during tuberculosis treatment: a prospective cohort study among tuberculosis patients in South-Eastern Amahra Region

A review of sex differences in the epidemiology of tuberculosis

Social and cultural dimensions of gender and tuberculosis

Mortality among MDR-TB cases: comparison with drug-susceptible tuberculosis and associated factors

Differences between Risk Factors Associated with Tuberculosis Treatment Abandonment and Mortality

Independent predictors of tuberculosis mortality in a high HIV prevalence setting: a retrospective cohort study

Initial presentations predict mortality in pulmonary tuberculosis patients-a prospective observational study

Tuberculosis mortality: patient characteristics and causes

Excess mortality due to tuberculosis and factors associated to death in and annual cohort of patients diagnosed of tuberculosis

Predictors of in-hospital mortality among patients with pulmonary tuberculosis: a protocol of systematic review and meta-analysis of observational studies

The measurement of observer agreement for categorical data

The Newcastle-Ottawa Scale (NOS) for assessing the quality of non-randomised studies in meta-analyses. Ottawa Hospital Research Institute

Undue reliance on I(2) in assessing heterogeneity may mislead

Operating characteristics of a rank correlation test for publication bias

Grading quality of evidence and strength of recommendations

GRADE guidelines: 4. Rating the quality of evidence-study limitations (risk of bias)

GRADE guidelines 6. Rating the quality of evidence-imprecision

GRADE guidelines: 7. Rating the quality of evidence-inconsistency

GRADE guidelines: 5. Rating the quality of evidence-publication bias

Characteristics and outcome of patients with active pulmonary tuberculosis requiring intensive care

Development and validation of a tuberculosis prognostic score for smear-positive in-patients in Japan

Risk factors related with mortality in patient with pulmonary tuberculosis

Patient mortality of active pulmonary tuberculosis requiring mechanical ventilation

Predictive factors for mortality among non-HIV-infected patients with pulmonary tuberculosis and respiratory failure

Hypoalbuminemia and lymphocytopenia are predictive risk factors for in-hospital mortality in patients with tuberculosis

Prognostic factors in pulmonary tuberculosis requiring mechanical ventilation for acute respiratory failure

Global Tuberculosis Programme. A framework for effective tuberculosis control

The risk of tuberculosis in patients with cancer

Solid-organ malignancy as a risk factor for tuberculosis

Risk factors for and attributable mortality from tuberculosis in patients with hematologic malignances

The Directly Observed Therapy Short-Course (DOTS) strategy in Samara Oblast, Russian Federation

Risk factors for death during tuberculosis treatment in Orel, Russia

Deaths from pulmonary tuberculosis in a low-incidence country

All authors made substantial contributions to conception and design. C.P.B.A. designed the study, collected data, and wrote the manuscript. R.C. designed the search strategy. L.W. designed the study and collected data. P.Z. analyzed data and wrote the paper. J.B. designed the study and wrote the paper. D.R.S. designed the study, collected data, and wrote the paper. All authors provided final approval of the version to be published.

Supplementary information accompanies this paper at https://doi.org/10.1038/s41598-018-25409-5.

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