RESEARCH ARTICLE

Predictors for MTB Culture-Positivity among
HIV-Infected Smear-Negative Presumptive
Tuberculosis Patients in Uganda: Application
of New Tuberculosis Diagnostic Technology
Lydia Nakiyingi1,2*, Bareng A. S. Nonyane3, Willy Ssengooba4, Bruce J. Kirenga2,
Damalie Nakanjako1,2, Gloria Lubega1, Pauline Byakika-Kibwika1,2, Moses L. Joloba4,
Jerry J. Ellner6, Susan E. Dorman5, Harriet Mayanja-Kizza2, Yukari C. Manabe1,5

1 Infectious Diseases Institute, Makerere University College of Health Sciences, Kampala, Uganda,
2 Department of Medicine, School of Medicine, Makerere University College of Heath Sciences, Kampala,
Uganda, 3 Department of International Health, Johns Hopkins Bloomberg School of Public Health,
Baltimore, Maryland, United States of America, 4 Department of Medical Microbiology, Makerere University
College of Heath Sciences, Kampala, Uganda, 5 Division of Infectious Diseases, Department of Medicine,
Johns Hopkins University School of Medicine, Baltimore, Maryland, United States of America, 6 Boston
Medical Center, Boston University School of Medicine, Boston, MA, United States of America

* lydikiyingi@yahoo.com

Abstract

Background

The existing World Health Organization diagnostic algorithms for smear-negative TB per-

form poorly in HIV-infected individuals. New TB diagnostics such as urine TB lipoarabino-

mannan (LAM) could improve the accuracy and reduce delays in TB diagnosis in HIV-

infected smear-negative presumptive TB. We sought to determine predictors for MTB cul-

ture-positivity among these patients.

Methods

This study was nested into a prospective evaluation of HIV-infected outpatients and inpa-

tients clinically suspected to have TB who were screened by smear-microscopy on two spot

sputum samples. Data on socio-demographics, clinical symptoms, antiretroviral therapy,

CXR, CD4 count, mycobacterial sputum and blood cultures and TB-LAM were collected.

Logistic regression and conditional inference tree analysis were used to determine the most

predictive indicators for MTB culture-positivity.

Results

Of the 418 smear-negative participants [female, 64%; median age (IQR) 32 (28-39) years,

median CD4 106 (IQR 22 - 298) cells/mm3], 96/418 (23%) were sputum and/ or blood cul-

ture-positive forMycobacterium tuberculosis (MTB) complex. Abnormal CXR (aOR 3.68,

95% CI 1.76- 7.71, p=0.001) and positive urine TB-LAM (aOR 6.21, 95% CI 3.14-12.27, p<

0.001) were significantly associated with MTB culture-positivity. Previous TB treatment

PLOS ONE | DOI:10.1371/journal.pone.0133756 July 29, 2015 1 / 13

OPEN ACCESS

Citation: Nakiyingi L, Nonyane BAS, Ssengooba W,
Kirenga BJ, Nakanjako D, Lubega G, et al. (2015)
Predictors for MTB Culture-Positivity among HIV-
Infected Smear-Negative Presumptive Tuberculosis
Patients in Uganda: Application of New Tuberculosis
Diagnostic Technology. PLoS ONE 10(7): e0133756.
doi:10.1371/journal.pone.0133756

Editor: Yoshihiko Hoshino, National Institute of
Infectious Diseases, JAPAN

Received: February 11, 2015

Accepted: June 30, 2015

Published: July 29, 2015

Copyright: © 2015 Nakiyingi et al. This is an open
access article distributed under the terms of the
Creative Commons Attribution License, which permits
unrestricted use, distribution, and reproduction in any
medium, provided the original author and source are
credited.

Data Availability Statement: Third party data
underlying the findings in this study is part of the
Tuberculosis Clinical Diagnostic Research
Consortium (TB CDRC) study data that is available
for public access through https://www.tbcdrc.org.
Request forms that include a TB CDRC Data
Proposal Application Form and the TB CDRC Data
Sharing Agreement form can be freely obtained on
the link: https://www.tbcdrc.org. In order to obtain TB
CDRC study data, the interested researcher sends
filled data request forms to the following address:

http://crossmark.crossref.org/dialog/?doi=10.1371/journal.pone.0133756&domain=pdf
http://creativecommons.org/licenses/by/4.0/
https://www.tbcdrc.org
https://www.tbcdrc.org


(aOR 0.41, 95% CI 0.17-0.99, p=0.049) reduced the likelihood of a positive MTB culture. A

conditional inference tree analysis showed that positive urine TB-LAM and abnormal CXR

were the most predictive indicators of MTB culture-positivity. A combination of urine TB-

LAM test and CXR had sensitivity and specificity of 50% and 86.1% respectively overall,

and 70.8% and 84.1% respectively among those with CD4<100 cells/mm3.

Conclusions

A positive urine TB-LAM test and an abnormal CXR significantly predict MTB culture-posi-

tivity among smear-negative HIV-infected presumptive TB patients while previous TB treat-

ment reduces the likelihood of a positive MTB culture. Validation studies to assess the

performance of diagnostic algorithms that include urine TB-LAM in the diagnosis of smear-

negative TB in HIV-infected individuals are warranted.

Introduction
Tuberculosis (TB) is a major cause of death among HIV-infected patients [1–3]. Early diagno-
sis of TB is essential for prompt initiation of therapy to reduce TB-associated morbidity and
mortality as well as transmission. Despite the current wave of rapid molecular TB diagnostics,
sputum smear microscopy continues to be the most available and used TB diagnostic in many
SSA countries [4, 5]. Several studies in sub-Saharan Africa (SSA) have found an increased prev-
alence of sputum smear-negative TB in HIV-infected patients [6] which is associated with high
morbidity and mortality [7–10] as a consequence of delayed or missed diagnosis. This has
emphasized the need for more rapid, sensitive and affordable TB diagnostic tools. There are
few inexpensive and easy to use alternatives to sputum smear microscopy in resource limited
settings (RLS) [11–14].Mycobacterium tuberculosis (MTB) culture, which is the gold standard
for diagnosis, is not widely available due to technical and biosafety requirements [12, 13], while
the use of molecular tests such as Xpert MTB/Rif test is limited by cost [15–17]. The WHO rec-
ommended diagnostic algorithms for smear-negative pulmonary TB (PTB) [18] are limited by
the poor diagnostic performance particularly in HIV-infected individuals [11, 19–22] and the
long duration required to establish a diagnosis (11 to 34 days) [23, 24], which poses risks of dis-
ease progression, transmission and loss to follow-up. Several validation studies have found
poor performance of the existing algorithms for smear-negative TB diagnosis especially in HIV
[19–22]. For instance, the sensitivity and specificity of the diagnostic algorithm for smear-neg-
ative PTB were 38.1% and 74.5% respectively in a Tanzania study [22] and 55% and 72.9%
respectively in Kenya [21]. In addition, several reports indicate that the guidelines are not
always followed by clinicians [11, 25]; with majority empirically initiating TB treatment. In
Botswana [25] for instance, laboratory delays and inability by patients to produce sputum were
cited as reasons for not following the guidelines. In our recent study [26], empirical TB treat-
ment initiation resulted in over-treatment of HIV-infected patients. Strategies to improve the
diagnosis of smear-negative TB in HIV-infected individuals, particularly those that would
reduce laboratory delays or provide alternatives to sputum production in HIV are warranted.

The lateral flow urine determine TB lipoarabinomannan (LAM) antigen test (herein referred
to as urine TB-LAM test) is a new point of care antigen test which provides results within less
than an hour of sample collection and has been shown to perform best among HIV-infected
patients with advanced immune-suppression [27–29]. In addition, the TB-LAM test utilizes

MTB Culture-Positivity among HIV-Infected Smear-Negative Patients

PLOS ONE | DOI:10.1371/journal.pone.0133756 July 29, 2015 2 / 13

David Hom, Administrative, Data & Operations
Center, TB Clinical Diagnostics Research
Consortium, Boston University Medical Center, 771
Albany Street, Boston, Tel: 617-414-45277, Fax: 617-
414-2875, Email: David.Hom@bmc.org.

Funding: LN is a PhD candidate funded by Medical
Education for Equitable Services to All Ugandans
(MESAU), a Medical Education Partnership Initiative
(MEPI) grant number 5R24TW008886 from the Office
of Global AIDS Coordinator and the U. S. Department
of Health and Human Services, Health Resources
and Services Administration and National Institutes of
Health. The study project was funded with federal
funds from the Division of Microbiology and Infectious
Diseases, National Institute of Allergy and Infectious
Diseases, National Institutes of Health, Department of
Health and Human Services, under contract
#HHSN2722000900050C, “TB Clinical Diagnostics
Research Consortium.” Additional support to YCM
was by the Johns Hopkins University Center for AIDS
Research (Grant Number 1P30AI094189 from the
National Institute of Allergy and Infectious Diseases).
The funders had no role in study design, data
collection and analysis, decision to publish, or
preparation of the manuscript.

Competing Interests: The authors have declared
that no competing interests exist.



urine which is readily available and easy to collect in HIV-infected individuals. Urine TB-LAM
test has the potential to improve accuracy and to reduce delays associated with the current
smear-negative TB diagnostic algorithms but has not been evaluated as a possible predictor for
MTB culture-positivity among smear-negative HIV-infected presumptive TB patients.

We previously showed that in HIV-infected adults with CD4�100, the urine TB-LAM tests
detected over half of culture-positive TB patients without need for equipment or reagents. Our
report considered HIV-infected adults with TB symptoms and/or signs irrespective of their
sputum-smear status [27]. In this study, we sought to determine the factors that could predict
MTB culture-positivity among smear-negative HIV-infected presumptive TB patients by
applying the urine TB-LAM test as a new point of care technology in TB diagnosis. The aim is
to develop strategies to improve the diagnosis of smear-negative TB in HIV-infected patients
and to reduce related diagnostic delays through possible application of the new technology in
the development of smear-negative TB diagnostic criteria in HIV-infected individuals.

Methods

Study design and setting
We performed secondary analysis of data collected from participants enrolled in a TB diagnos-
tic accuracy study of the lateral flow TB-LAM test for the diagnosis of TB among HIV-infected
presumptive TB patients [27]. Participants for this study were recruited from the outpatient
adult Infectious Diseases Institute (IDI) Clinic [30] and the inpatient wards of the Mulago
National Referral Hospital, Kampala Uganda between January and November 2011.

Patient recruitment and study population
Patient recruitment has been described in detail previously [27]. In summary, HIV-infected
patients aged�18 years and clinically suspected to have active TB were recruited. A patient was
suspected to have active TB (presumptive TB) if he/she reported having at least one of the follow-
ing symptoms: cough, fever, drenching night sweats or weight loss [3]. Patients were excluded if
they had taken anti-TB medication for more than two days within 60 days prior to enrolment.

At enrolment, participants were interviewed to obtain socio-demographic and medical infor-
mation before study-specific specimens were collected. They provided two spot sputum samples
for direct fluorescence microscopy (FM) and Ziehl-Neelson (ZN) microscopy; mycobacterial
growth indicator tube (MGIT) and Lowenstein-Jensen (LJ) sputum cultures. Sputum induction
using 7% nebulized hypertonic saline was performed for participants who were unable to sponta-
neously expectorate sputum. Blood was collected from each participant for mycobacterial blood
cultures and to determine the CD4 cell count. Urine was collected for TB-LAM testing using a
lateral flow assay (TB-LAMAlere, Waltham, MA, USA). Chest X-ray was obtained for male par-
ticipants and non-pregnant women. Participants were classified as sputum smear-negative if they
were smear-negative on both ZN and FMmicroscopy and these were considered for this analysis.
MTB culture-positives were MTB positive on any of the sputum or blood mycobacterial cultures.

Laboratory procedures
Details of the laboratory procedures for the TB tests including smear microscopy, sputum and
blood TB culture as well as urine TB-LAM test have been described [27]. In summary, for
urine TB-LAM test, 60 μl of urine was pipetted onto the sample pad. According to the manu-
facturer’s instructions, the strip was read 25 minutes later by two different technicians indepen-
dently who compared the test strips with the reference card provided by the manufacturer and
graded the result from 1+ to 5+. A result was considered positive if the band was graded as 2

MTB Culture-Positivity among HIV-Infected Smear-Negative Patients

PLOS ONE | DOI:10.1371/journal.pone.0133756 July 29, 2015 3 / 13



+ or above. CD4 cell counts were performed at the College of American Pathologists (CAP)-
certified laboratory at the IDI [30].

All study TB laboratory results except for urine LAM which was an investigational test were
made available to the attending clinicians. Discharged participants were contacted by telephone
to deliver results and those whose TB tests were positive were requested to return for treatment.
Participants whose TB results were positive but could not be contacted by phone were visited
at their homes. MTB positive patients by smear and/or culture were immediately initiated on
TB treatment by the attending clinician according to Uganda Ministry of Health TB and Lep-
rosy program guidelines [31].

Statistical analysis
Statistical analyses were performed using STATA (Stata Corp. STATA 12.0, college station,
Texas 77845 USA.) and R version 3.1.1 (the R Foundation for Statistical Computing 2014).

The primary outcome was MTB culture status (on blood and/or sputum TB cultures) of
sputum smear-negative HIV-infected presumptive TB participants, classified as positive or
negative. Continuous variables were summarized using medians and inter-quartile ranges
(IQR) while categorical variables were summarized using frequencies, percentages and propor-
tions. Using Wilcoxon rank sum test for continuous variables and either chi-square test or
Fisher’s Exact test for categorical variables as appropriate, we compared the characteristics of
the study population by the strata of the primary outcome.

To identify predictors of MTB culture positivity among sputum smear-negative HIV-
infected presumptive TB patients, bivariate and multivariate logistic regression models were
built and results presented as unadjusted and adjusted odds ratio (OR) with 95% confidence
intervals (95% CI). The modeling process involved selecting all factors from bivariate analysis
that had a p-value of� 0.2 and those of known clinical significance for inclusion in the initial
multivariate logistic regression model. Using a systematic backward approach, non-significant
variables were removed from the model until no further variables were eligible for removal to
arrive at the final model. ART treatment and CD4 cell count were retained in the model at all
levels due to their clinical significance. A p-value of< 0.05 in the final model was considered
statistically significant. In order to determine the relative predictive power of the variables con-
sidered in the multivariable model, we fitted a conditional inference tree model [32, 33]. The
model included only the smear-negative participants with complete records. This model was
fitted using the ‘party’ package in R.

Ethical considerations
The study was approved by the Scientific Review Board of the Infectious Diseases Institute
(IDI), the Institutional Review Board (IRB) of the Joint Clinical Research Centre, Kampala,
Uganda and the Uganda National Council for Science and Technology. All participants pro-
vided written informed consent before participation in the study. All consent forms were
approved by the above mentioned ethics committees and IRBs.

Results

Baseline characteristics
Of the 501 HIV-infected presumptive TB patients who provided sputum samples for micros-
copy, 418 (83.4%) were sputum smear- negative and eligible for this analysis (Fig 1). Of the 418
sputum smear-negative participants, 69% (288/418) were inpatients, 64% (267/418) were female;
median age was 32 (IQR 28–39) years and median CD4 was 106 (IQR 22–298) cells/mm3.

MTB Culture-Positivity among HIV-Infected Smear-Negative Patients

PLOS ONE | DOI:10.1371/journal.pone.0133756 July 29, 2015 4 / 13



Of the 418 sputum smear-negative participants, 96/418 (23%) were positive for MTB com-
plex on blood and/or sputum TB cultures; of which, 55/96 (57.3% were MTB culture positive
on sputum alone, 35/96 (36.5%) were positive on both sputum and blood cultures while 6/96
(6.3%) were positive on blood culture alone. The median CD4 cell count was significantly
lower in the MTB culture-positive compared to the culture-negative participants [60 (IQR 14–
152) versus 127 (IQR 26–329) cells/mm3, p = 0.001 respectively]. Majority of the MTB culture-
positives were inpatients (80%). A comparison of clinical and laboratory characteristics
between MTB culture-positive and negative participants is shown in Table 1.

Predictors of MTB culture-positive, smear-negative TB
Results of bivariate analysis are presented in Table 2. On multivariate logistic regression analy-
sis (Table 2), presence of an abnormal CXR (aOR 3.68, 95% CI 1.76–7.71, p = 0.001) and a pos-
itive urine TB-LAM test (aOR 6.21, 95% CI 3.14–12.27, p< 0.001) were significantly associated
with MTB culture-positivity among smear-negative HIV-infected presumptive TB patients.
On the other hand, previous TB treatment (aOR 0.41, 95% CI 0.17–0.99, p = 0.049) reduced
the likelihood of a positive TB culture. The conditional inference tree model to determine the
ranking of the factors showed that the urine TB-LAM was the most predictive of MTB culture
positivity, followed by a CXR in this cohort of patients based on Bonferroni-adjusted p-values
(p<0.001 for urine TB-LAM and p = 0.004 for CXR). A plot of the fitted conditional inference
tree (Fig 2). From the model, of the 52 participants that were declared positive by the urine
TB-LAM test, 31(59.6%) were true MTB culture positives. Of the 329 participants that had
been declared negative by urine TB-LAM test, the CXR found an additional 12 true MTB cul-
ture positives.

Fig 1. Participant flow diagram and MTB culture results distribution.

doi:10.1371/journal.pone.0133756.g001

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Accuracy of urine TB-LAM in the diagnosis of smear-negative–culture
positive TB in HIV
The accuracy values (Tables 3 and 4) for urine TB-LAM test were calculated using MTB culture
performed on blood and/or sputum specimens as the reference standard. The urine TB-LAM
test had a sensitivity and specificity of 37.5% and 93.1% respectively among all smear-negative
participants and 55.2% and 89.5% respectively among participants with CD4<100 cells/mm3.
A combination of urine TB-LAM test and CXR had sensitivity and specificity of 50% and
86.1% respectively overall, and 70.8% and 84.1% respectively among those with CD4<100
cells/mm3 (Table 3). The performance indices among the inpatient and the outpatient partici-
pants are shown in Table 4.

Discussion
Diagnosis of smear-negative TB in HIV-infected individuals is difficult and is often associated
with delays. New TB diagnostics techniques such as the urine TB-LAM antigen test have a
potential to improve accuracy and to reduce delays in smear-negative TB diagnosis in HIV.
We aimed to identify factors that could predict MTB culture-positivity among sputum smear-
negative HIV-infected presumptive TB patients in a high prevalence TB/HIV setting and also

Table 1. Clinical and socio-demographic characteristics of smear-negative HIV- infected presumptive TB patients.

Characteristics Total n = 418 Culture-negative n = 322 Culture-positive n = 96 P value

Gender: Female 267 (63.9) 215 (66.8) 52 (54.2) 0.024

Age (years): Median (IQR) 32 (28–39) 32 (28–39) 32 (28–38) 0.116

Inpatients 288 (68.9) 211 (65.5) 77 (80.2) 0.006

* CD4 count, cells/μl (N = 413)

Median CD4 (IQR) 106 (22–298) 127 (26–329) 60 (14–152) 0.001

<50 158 (38.3) 114 (35.7) 44 (46.8) 0.002

50–99 43 (10.4) 29 (9.1) 14 (14.9) 0.003

100–199 70 (17.0) 51 (16.0) 19 (20.2) 0.008

200–350 61 (14.8) 52 (16.3) 9 (9.6) 0.378

>350 81 (19.6) 73 (22.9) 8 (8.5) reference

Treatment history

Previous TB 76 (18.2) 68 (21.1) 8 (8.3) 0.004

Not on ART treatment 261 (62.4) 193 (59.9) 68 (70.8) 0.053

Cotrimoxazole prophylaxis 390 (93.3) 302 (93.8) 88 (91.7) 0.465

Symptoms

**Cough duration in weeks (IQR) 4 [2–8) 4 [2–6) 4 [2–8) 0.204

*Drenching night sweats (N = 407) 303 (74.5) 224 (71.1) 79 (85.9) 0.004

*Anorexia (n = 404) 303 (75.0) 224 (71.3) 79 (87.8) 0.001

Fever 379 (90.7) 292 (90.7) 87 (90.6) 0.986

Weight (kg): Median (IQR) 50 (45–55) 50(44–56) 51(45–55) 0.944

Investigations

*Abnormal CXR (N = 381) 43 (11.3) 22 (7.5) 21 (24.4) 0.000

*Positive urine TB-LAM (N = 417) 58(13.9) 22(6.9) 36(37.5) 0.000

* means the number of variables is less than the total N = 418. These were missing data due to unrecorded data and unperformed study tests. CXR was

considered abnormal if the study clinician reported the CXR as highly suggestive of TB.

**means period for which the patient has had the current cough at the time of enrolment.

Abbreviations: TB, tuberculosis; ART, antiretroviral therapy; CXR, chest X-ray; LAM, lipoarabinomannan; IQR, inter-quartile range

doi:10.1371/journal.pone.0133756.t001

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assessed the accuracy of urine TB-LAM test in smear-negative TB diagnosis. In our cohort, the
prevalence of culture-positive TB was high at 23% of the smear-negative HIV-infected pre-
sumptive TB patients. The predictors for MTB culture-positivity among smear-negative HIV-
infected patients were; positive urine TB-LAM and an abnormal CXR read as highly suggestive
of TB by a clinician. Previous TB treatment reduced the likelihood of finding a positive MTB
culture. Positive urine TB-LAM test followed by CXR were the most predictive combination
and would reduce the total number of CXRs that would have to be performed. CXR facilities
are not readily available in many lower level health facilities in RLS and where available, they
may not be affordable and maintenance is costly.

Similar to earlier reports from other sub-Saharan African studies [6, 34, 35], we found a
high prevalence of MTB culture-positive smear-negative TB among HIV-infected presumptive
TB patients and these MTB culture positive participants had immunologically advanced HIV
disease as shown by the low median CD4 cell counts obtained. HIV-infected patients with
advanced immunosuppression often have paucibacillary TB which reduces the sensitivity of
sputum smear microscopy, requiring TB diagnostic tests with higher sensitivity such as TB cul-
ture. Our study found that abnormal CXR was independently associated with a positive MTB
culture in smear-negative HIV-infected presumptive TB patients. This finding corroborates
with several earlier studies [20, 24, 36–39] that report CXR and other clinical symptoms as
important predictors for TB in sputum smear-negative presumptive TB patients. On the other
hand, several other studies [21, 22, 40, 41] have reported poor diagnostic performances of clini-
cal and radiological characteristics in smear-negative TB diagnosis. The variation in perfor-
mance could be due to the differences in the study settings and/or populations. Studies
performed among largely HIV-infected populations have reported poorer performances [21,
22, 40, 41] when compared with studies that included very few or no HIV-infected patients
[42, 43].

A positive urine TB-LAM test was another independent predictor for MTB culture-positiv-
ity among HIV-infected smear-negative participants in our study, with higher accuracy values
seen among participants with CD4<100 cells/mm3. Our findings are in agreement with earlier
reports that urine TB-LAM performs much better among HIV-infected individuals with

Table 2. Logistic regression analysis for predictors of MTB culture-positive TB in sputum smear-negative HIV-infected presumptive TB**.

Characteristics crude OR (95%CI) P-value Adjusted OR (95%CI) P-value

Female gender 0.59(0.37–0.94) 0.025 - -

Age per 5 year increase 0.91 (0.79–1.05) 0.194 - -

Hospitalization 2.13 (1.23–3.70) 0.007 - -

CD4(cells/μl); per 50 cells increase 0.87 (0.80–0.93) 0.000 0.93 (0.86–1.01) 0.070

Previous TB treatment 0.34 (0.16–0.73) 0.006 0.41 (0.17–0.99) 0.049

Not on ART treatment 1.62 (0.99–2.66) 0.054 1.39 (0.76–2.53) 0.284

Cotrimoxazole prophylaxis .73 (0.31–1.71 0.467 - -

Cough duration (weeks) 1.02 (0.99–1.06) 0.207 - -

Weight (per kg increase) 1.00 (0.98–1.02) 0.944 - -

Abnormal CXR 4.01 (2.08–7.73 0.000 3.68 (1.76–7.71) 0.001

Positive urine TB-LAM 8.15 (4.48–14.84 0.000 6.21 (3.14–12.27) 0.000

** N = 381 with complete records.

The model adjusted for CD4 cell count, previous TB treatment, antiretroviral therapy, CXR findings, ART therapy and urine TB-LAM test

Abbreviations: TB, tuberculosis; ART, antiretroviral therapy; CXR, chest X-ray; LAM, lipoarabinomannan; IQR, inter-quartile range; OR, odds ratio; CI,

confidence intervals.

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advanced HIV disease [27–29]. This could be explained in part by the fact that HIV-infected
presumptive TB patients who have negative sputum smears could have other forms of TB
including extra pulmonary and/or disseminated TB that is diagnosed by the urine TB-LAM
test. However, the sensitivity of urine TB-LAM increases at the expense of the specificity in
patients with CD4<100 cell count. This could be due to other comorbidities mimicking TB
that could occur among patients with advanced HIV disease or that sputum and blood

Fig 2. A plot of a conditional inference tree showing the most predictive indictors for MTB culture-positivity. The model was fitted on the 381
participants with complete records.

doi:10.1371/journal.pone.0133756.g002

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mycobacterial cultures are an incomplete gold standard. A significant association was found
between previous TB treatment and MTB culture positivity on logistic regression, with previ-
ous TB being associated with reduced likelihood of MTB culture positivity. This highlights the
clinical issue of patients who have previously suffered from TB presenting with respiratory
symptoms (probably due to post-TB complications) who are often misdiagnosed as presump-
tive TB.

Our findings suggest that a combination of urine TB-LAM test followed by a CXR signifi-
cantly improves the accuracy of TB diagnosis in smear-negative HIV-infected patients, espe-
cially when CD4 counts are< 100cells/mm3. Almost two thirds of MTB culture-positive smear
negative HIV-infected patients with CD4< 100cells/mm3 in our study were diagnosed by a
combination of urine TB-LAM and CXR with a high negative predictive value. Use of this pro-
posed algorithm would reduce on the inaccuracy associated with empirical TB treatment initia-
tion as often used in smear-negative HIV-infected individuals [26]. Information on whether
TB treatment initiation in HIV- infected patients with the proposed algorithm would improve
patients’ outcome or not would be important to guide its clinical application. Therefore, our
data provide rationale for future research on assessment of the impact of TB treatment initia-
tion among HIV-infected patients with positive urine TB-LAM and abnormal CXR on
patients’ outcome.

Further, the application of the urine TB-LAM based algorithm suggested from our findings
would be limited to low-income settings where the highly accurate but costly molecular assays
are not readily available for use in TB diagnosis. In an earlier report [44], urine TB-LAM and
sputum Xpert MTB/Rif testing were complementary to each other and therefore, the algo-
rithms may be useful in settings where use of Xpert MTB/Rif test is limited by cost and unavail-
ability. In addition, the urine TB-LAM test does not identify multiple drug resistant (MDR) TB
strains, thus its use may be limited to settings where the prevalence of MDR is low, as is the
case in our study setting [45].

Table 3. Performance of the urine TB-LAM test in the diagnosis of smear-negative TB stratified by
CD4 cell count.

Overall accuracy
(95% CI)

Accuracy among patients with
CD4<100 (95% CI

Urine TB-LAM test N = 417 N = 201

Sensitivity 37.5 (27.8–48.0) 55.2 (41.5–68.3)

Specificity 93.1 (89.8–95.7) 89.5 (83.3–94.0)

PPV 62.1 (48.4–74.5) 68.1 (52.9–80.9)

NPV 83.3 (79.0–87.0) 83.1 (76.2–88.7)

LR (positive) 5.47 (3.39–8.83) 5.26 (3.09–8.95)

LR (negative) 0.67 (0.57–0.79) 0.50 (0.37–0.67)

Combination of Urine TB-LAM test
and CXR

N = 381 N = 174

Sensitivity 50.0 (39.0–61.0) 70.8 (55.9–83.0)

Specificity 86.1 (81.6–89.8) 84.1 (76.6–90.0)

PPV 51.2 (40.0–62.3) 63.0 (48.7–75.7)

NPV 85.5 (81.0–89.3) 88.3 (81.2–93.5)

LR (positive) 3.60 (2.52–5.13) 4.46 (2.87–6.94)

LR (Negative) 0.58 (0.47–0.72) 0.35 (0.22–0.54)

Abbreviations: TB, tuberculosis; LAM, lipoarabinomannan; CXR, Chest X-ray; PPV, positive predictive

value; NPV, negative predictive value; LR, likelihood ratio

doi:10.1371/journal.pone.0133756.t003

MTB Culture-Positivity among HIV-Infected Smear-Negative Patients

PLOS ONE | DOI:10.1371/journal.pone.0133756 July 29, 2015 9 / 13



Our study had some limitations. First, the mycobacterial blood and sputum cultures may
have failed to detect some participants with TB and some culture-negative patients could have
been misclassified as not TB. This may have underestimated the association between the pre-
dicting factors and TB disease in this population as well as the accuracy of the suggested algo-
rithm. Secondly, we did not follow-up the MTB culture-negative participants to obtain
information on empirical TB treatment.

Despite these limitations, our study has important strengths. In order to accurately classify
participants as having TB or not, we performed both solid and liquid MTB cultures in addition
to TB blood cultures, making the findings more reliable and accurate. The classification of par-
ticipants as smear-negative presumptive TB was based on both ZN and FMmicroscopy, also
making our study population definition and findings more accurate and reliable. Further, we
report findings from a population that includes both outpatients and inpatients making our
findings generalizable and relevant to most HIV/TB prevalent settings.

In conclusion, smear-negative culture-positive TB is common in this setting. Positive urine
TB-LAM test and abnormal CXR significantly predict MTB culture-positive TB among smear-
negative HIV-infected presumptive TB patients while previous TB treatment reduces the likeli-
hood of a positive MTB culture. Positive urine TB-LAM test followed by CXR are the two most
predictive factors for MTB culture positivity. Urine TB-LAM test may be applied in the devel-
opment of diagnostic algorithms for smear-negative TB in HIV. We recommend validation
studies to assess the performance of diagnostic algorithms that include urine TB-LAM test in
the diagnosis of smear-negative TB in HIV-infected individuals.

Acknowledgments
The authors would like to thank the research team at the IDI, particularly John Mark Bwanika,
Allen Mukhwana, Allan Buzibye, Olive Mbabazi and Francis Kakooza and the

Table 4. Performance of the urine TB-LAM test in the diagnosis of smear-negative TB among inpatients and outpatients stratified by CD4 cell
count.

Overall accuracy(95% CI) Accuracy among patients with CD4<100
(95% CI)

Inpatients outpatients Inpatients Outpatients

Urine TB-LAM N = 287 N = 130 N = 169 N = 32

Sensitivity 39.0 (28.0–50.8) 31.6 (12.6–56.6) 54.2 (39.2–68.6) 60.0 (26.2–87.8)

Specificity 90.0 (85.1–93.7) 99.1 (95.1–100.0) 87.6 (80.4–92.9) 100.0 (84.6–100.0)

PPV 58.8 (44.2–72.4) 85.7 (42.1–99.6) 63.4 (46.9–77.9) 100.0 (54.1–100.0)

NPV 80.1 (74.4–85.0) 89.4 (82.6–94.3) 82.8 (75.1–88.9) 84.6 (65.1–95.6)

LR (positive) 3.90 (2.38–6.38) 35.05 (4.47–275.1) 4.37 (2.55–7.50) N/A

LR (negative) 0.68 (0.56–0.82) 0.69 (0.51–0.94) 0.52 (0.38–0.72) 0.40 (0.19–0.85)

Combination of Urine TB-LAM and CXR N = 256 N = 125 N = 144 N = 30

Sensitivity 52.9 (40.4–65.2) 38.9 (17.3–64.3) 71.8 (55.1–85.0) 66.7 (29.9–92.5)

Specificity 84.0 (78.0–89.0) 89.7 (82.3–94.8) 81.0 (72.1–88.0) 100.0 (83.9–100.0)

PPV 54.5 (41.8–66.9) 38.9 (17.3–64.3) 58.3 (43.2–72.4) 100.0 (54.1–100.0)

NPV 83.2 (77.1–88.2) 89.7 (82.3–94.8) 88.5 (80.4–94.1) 87.5 (67.6–97.3)

LR (positive) 3.32 (2.23–4.94) 3.78 (1.69–8.46) 3.77 (2.43–5.86) N/A

LR (Negative) 0.56 (0.43–0.73) 0.68 (0.47–0.99) 0.35 (0.21–0.58) 0.33 (0.13–0.84)

Abbreviations: TB, tuberculosis; LAM, lipoarabinomannan; CXR, Chest X-ray; PPV, positive predictive value; NPV, negative predictive value; LR,

likelihood ratio

doi:10.1371/journal.pone.0133756.t004

MTB Culture-Positivity among HIV-Infected Smear-Negative Patients

PLOS ONE | DOI:10.1371/journal.pone.0133756 July 29, 2015 10 / 13



Mycobacteriology (BSL-3) Laboratory of Makerere University for their important contribu-
tions to the implementation of this study. The authors gratefully acknowledge the study partici-
pants for their willingness to participate in the study.

Author Contributions
Conceived and designed the experiments: LN GL DNMLJ HMK SED YCM. Performed the
experiments: LN GLWS YCM. Analyzed the data: LN BNWS PBK BK HMK YCM. Contrib-
uted reagents/materials/analysis tools: LN YCM JJE SED. Wrote the paper: LN BNWS BK DN
GL PBKMLJ JJE SED HMK YCM.

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