Abstract
Tuberculosis (TB) is a major cause of morbidity and mortality in children, and early diagnosis and treatment are crucial to reduce long-term morbidity and mortality. In this study, we explore whether urine nuclear magnetic resonance (NMR)-based metabolomics could be used to identify differences in the metabolic response of children with different diagnostic certainty of TB. We included 62 children with signs and symptoms of TB and 55 apparently healthy children. Six of the children with presumptive TB had bacteriologically confirmed TB, 52 children with unconfirmed TB, and 4 children with unlikely TB. Urine metabolic fingerprints were identified using high- and low-field proton NMR platforms and assessed with pattern recognition techniques such as principal components analysis and partial least squares discriminant analysis. We observed differences in the metabolic fingerprint of children with bacteriologically confirmed and unconfirmed TB compared to children with unlikely TB (p = 0.041 and p = 0.013, respectively). Moreover, children with unconfirmed TB with X-rays compatible with TB showed differences in the metabolic fingerprint compared to children with non-pathological X-rays (p = 0.009). Differences in the metabolic fingerprint in children with different diagnostic certainty of TB could contribute to a more accurate characterisation of TB in the paediatric population. The use of metabolomics could be useful to improve the prediction of TB progression and diagnosis in children.
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Introduction
One-quarter of the world’s population is infected with Mycobacterium tuberculosis, and 10 million people fell ill with tuberculosis (TB) in 20191. TB is also a major cause of morbidity and mortality in children, with an estimated one million dying from TB each year1. Under-detection of childhood TB is common in low- and middle-income countries2 as its clinical presentation overlaps with other respiratory infections, children have low sputum bacillary loads and are often unable to produce sputum, making its diagnosis difficult3,4.
Metabolomics, or the systematic study of a unique chemical fingerprint present in a cellular system or biofluid, increasingly allows discrimination between samples with different physiological or pathological states5. These fingerprints can be measured in biological samples, such as urine, serum or plasma, using non-invasive methods such as nuclear magnetic resonance (NMR) spectroscopy6, and have been used to monitor metabolic changes over time induced by pathogens7. Furthermore, the application of metabolomics to low-field (LF) NMR spectrometry has facilitated the development of smaller platforms suitable for primary and secondary medical centres laboratories8,9. In recent years, metabolomics has facilitated gaining insights into TB pathogenesis10, disease progression, and evaluation of treatment responses11.
A few studies have focused on the discovery of urine-based biomarkers for TB diagnosis. Urine is a non-invasive sample that requires minimal preparation12 and would be an easily obtained clinical sample for diagnosis, especially for individuals unable to produce sputum, such as children. In this study, we aimed to describe a urine proton (1H) NMR-based metabolic fingerprint for the diagnosis of TB in children.
Results
One hundred and seventeen children were included, of which 62 had presumptive TB and 55 were apparently healthy (controls). Sixty-eight (58.1%) were male, and their mean (SD) age was 7 (3.6) years (Table 1). There were no sex or age differences between children with presumptive TB and controls. Eighty-one (69.2%) participants had received the Bacillus Calmette et Guérin (BCG) vaccine and had a BCG scar (Table 1). Among the 62 children with presumptive TB, 6 had bacteriologically confirmed TB, 52 unconfirmed TB (bacteriologically negative) and four were considered to be unlikely to have TB (unlikely TB), as described in Table 2. Eighteen (29%) of the 62 children with presumptive TB had X-rays compatible with intrathoracic TB, nine (14.5%) had X-rays and clinical findings of extra-thoracic TB, and four (6.5%) had both intra- and extra-thoracic TB. Thirty-one (50%) children’s X-rays were considered inconclusive. Fifty-seven (91.9%) children had positive tuberculin skin test (TST, 54, 88.5%) and/or QuantiFERON-TB Gold In-Tube test (QFT-GIT, 39, 70.9%), with 63.2% (36/57) agreement between the tests. Fifty-three (85.5%) had documented exposure to an index case of TB. Seven (11.3%) of the 62 children had five clinical criteria of TB, while 21 (33.9%) had four, 28 (45.2%) had three, and six (9.7%) had two clinical criteria.
Thirty-one (43.6%) of the 55 controls were male, and their mean (SD) age was 6.5 (2.9) years, as shown in Table 1.
Performance of the TB metabolic fingerprinting
The metabolic fingerprint of the urine samples (n = 117) were measured using both high-field (HF) and LF 1H NMR spectroscopy, as detailed in Fig. 1. Representative spectra obtained with the HF and LF 1H NMRs are shown in Supplementary Fig. 1.
An unsupervised principal component analysis (PCA)13 was applied to the HF 1H NMR urine spectra of the six bacteriologically confirmed, 52 unconfirmed and four unlikely TB, and the 55 controls not showing clustering patterns between samples. Two children’s samples (one bacteriologically confirmed TB and one control) were considered outliers in the PCA score plot and were excluded14 (Supplementary Fig. 2). A supervised partial least squares discriminant analysis (PLS-DA) was applied to identify a discriminatory metabolic pattern between presumptive TB and control groups to the remaining 115 urine samples. We observed groupings along the scores of the first component of the PLS-DA (PLS-DA component 1) (Fig. 2). The robustness parameters of the HF PLS-DA model were tested by Leave-One-Out Cross-Validation (LOOCV) using the PLS-DA component 1 showing a performance accuracy to discriminate between presumptive TB and controls of 0.68, with R2 and Q2 values of 0.61 and 0.13, respectively; and an Area Under the Curve of Receiver Operating Characteristic (AUC-ROC) of 0.65. The Variable Importance in Projection (VIP) scores for the PLS-DA component 1 identified the main spectral regions of the metabolic fingerprint to differentiate between children with presumptive TB and controls (Supplementary Table 1). There was a trend in the PLS-DA component 1 scores with the certainty of TB diagnosis (Fig. 2). Thus, children with bacteriologically confirmed (n = 5) and unconfirmed TB (n = 52) had higher median PLS-DA component 1 scores (883.3 ± 751.1 and 913.3 ± 716.6) than children with unlikely TB (n = 4; − 385.2 ± 417.3) (p = 0.026 and p = 0.005, respectively; Fig. 3a). The PLS-DA component 1 scores also varied with the number of clinical criteria for TB. Children with five (n = 7), four (n = 21), and three (n = 27) clinical criteria had significantly higher median PLS-DA component 1 scores (1262.4 ± 649.8, 1062.7 ± 839.3, and 736.3 ± 644.6, respectively) than children with two (n = 6) criteria (− 100.5 ± 582.7) (p = 0.014, p = 0.007, and p = 0.021, respectively; Fig. 3b). Children with unconfirmed TB with X-rays compatible with TB (n = 24) had higher PLS-DA component 1 scores than unconfirmed cases with normal X-rays (n = 28) (1080.8 ± 736.3 and 796.2 ± 634.4) (p = 0.043).
If children who had already started treatment (for less than 15 days) are excluded from the analysis (4 confirmed TB, 19 unconfirmed TB and 1 unlikely TB), children with bacteriologically confirmed TB or unconfirmed TB still had significantly higher median PLS-DA component 1 scores (1333.4 ± 636.5 and 480.3 ± 508.5, respectively) than children with unlikely TB (− 437.9 ± 125.1) (p = 0.005 and p = 0.010, respectively; Fig. 4).
The PCA applied to the 117 LF 1H NMR acquired urine fingerprints detected eight outliers (two bacteriologically confirmed TB, 4 unconfirmed TB and two controls), which were excluded from the PLS-DA (Supplementary Fig. 3). A PLS-DA was applied to the remaining 109 urine fingerprints to identify a discriminatory metabolomic pattern between presumptive TB and control groups. We observed groupings between presumptive TB and control groups along the scores of the first component of the PLS-DA (PLS-DA component 1) (Fig. 5). PLS-DA component 1 scores were higher in children with presumptive TB than controls. The robustness parameters of the LF PLS-DA model were tested by LOOCV using the PLS-DA component 1 (performance accuracy to discriminate between presumptive TB and controls = 0.70, R2 = 0.76, Q2 = 0.08, and AUC-ROC = 0.65). Supplementary Table 1 shows the VIP for PLS-DA component 1 responsible for differentiating between children with presumptive TB and controls. Children with bacteriologically confirmed TB (n = 5) had higher median PLS-DA component 1 scores (825.2 ± 1236.52) than children with unlikely TB (n = 3; − 316.5 ± 1464.3) (p = 0.040 Fig. 6a). The PLS-DA component 1 scores also varied with the number of clinical criteria for TB. Children with five (n = 6) clinical criteria had significantly higher median PLS-DA component 1 scores (1426.1 ± 1088.1) than children with two (n = 5) criteria (− 46.3 ± 1229.8) (p = 0.009; Fig. 6b). The median PLS-DA component 1 scores among children with unconfirmed TB with compatible TB X-rays (n = 23) and normal X-rays (n = 28) were similar (1518.7 ± 1136.3 and 1920.1 ± 1419.3) (p = 0.643).
Discussion
Early diagnosis and treatment are crucial to stop the epidemic of childhood TB2. The search for biomarkers in non-invasive biological samples as alternatives to sputum is needed to improve the diagnostic sensitivity of TB in this population1,15. We report here a urine NMR-based metabolic fingerprint associated with bacteriologically and clinically diagnosed TB in children16.
Recently, the detection of TB from Xpert MTB/RIF (Cepheid, Sunnyvale, CA, USA) in urine has been evaluated in children17; however, the results have not achieved the accuracy desired to improve TB diagnosis in this population. Other emerging alternative diagnostic include Fujifilm SILVAMP TB (FujiLAM, Fujifilm, Tokyo, Japan), a new assay generation for detecting lipoarabinomannan (LAM) in urine18,19. In studies evaluating FujiLAM in children, the sensitivity and specificity reported were 50% and 92%, respectively, in a South African cohort, and 64.9% and 83.8%, respectively, in a multicentre evaluation in Africa 20,21. Despite its low sensitivity, its high specificity could help confirm the disease in children with a high probability of TB (e.g. children living in high-TB burden areas and those with HIV or malnutrition).
Biofluid metabolomics provides a snapshot of all the mechanisms that act during the disease, thus facilitating understanding the interaction between host and pathogen during infection and TB disease progression22,23. Previously, metabolomic profiles have been described in serum24,25,26,27,28,29 and plasma24,25,30,31 by NMR spectroscopy and mass spectrometry for the prediction and detection of TB. In children, two studies have reported different metabolomic profiles for TB detection in plasma32 and serum33 analysed by 1H NMR spectroscopy. However, neither of these studies reported whether the metabolic profile could discriminate between children with different diagnostic certainty of TB32. We have previously identified an NMR‑based metabolomic profile in urine to diagnose TB in adults34 and here we extend their potential application to the diagnosis of TB in a paediatric population and we have demonstrated differences in the urinary metabolic fingerprint of children with different certainty in the TB diagnosis.
TB in children is characterized by a continuum of conditions correlated with bacterial load, host immune responses, clinical manifestation, and the detection of M. tuberculosis3. Inflammatory host biomarkers in plasma have potential to discriminate latent TB infection from overt TB in children, and to identify the onset of TB disease 35,36,37. During latent infection, the host is able to contain the infection, the bacteria has restricted metabolic activity and there are no clinical manifestations. However, with progression to active TB, the infection overcomes the host immune system, the bacilli replicate, and the increased metabolomic activity of the mycobacteria modifies the tissues physiopathology, with changes in the host metabolome. The metabolic fingerprinting analysed by HF 1H NMR spectroscopy showed metabolic differences between children with presumptive TB with two or fewer clinical criteria and three or more clinical criteria. Moreover, children with high diagnostic certainty of TB showed metabolic fingerprints similar to that of children with bacteriologically confirmed TB. This metabolic response could be attributed to the physiological stimuli that occurs during disease progression23,38.
The paucibacillary nature of TB in children, combined with the limitation of current microbiological methods, results on a high dependence on chest X-rays for diagnosis39. In this study, children with unconfirmed TB and abnormal X-rays had differences in their metabolic fingerprint compared with those with normal X-rays. The differences in the metabolic fingerprint are consistent with studies interpreting the occurrence of radiological features from the pathway of incipient TB infection to subclinical and symptomatic TB40,41.
One limitation of this study is the low confirmation rate of TB (8% and 7% in HF and LF NMR metabolic fingerprint approach, respectively). This low rate, together with the inherent resonance overlap phenomenon in LF spectrometers (60 Hz)8,9 might have hindered the pattern recognition process in the LF metabolic fingerprinting approach, losing its discriminatory power between the study sub-groups with presumptive TB. The compact and portable size and the successful performance of this approach, demonstrated in previous studies8,9,34, makes LF benchtop NMR-based metabolic fingerprinting a promising diagnostic tool. However, further analysis with a larger group of children with confirmed TB is needed to evaluate the full potential of this approach in children as the small final number of bacteriologically confirmed TB cases (9.7%) in our study, prevented the development of a TB-specific discriminatory model.
In summary, this study identified an association between the urine NMR-based metabolic fingerprint and the clinical case definitions used for the classification of TB in children, and observed differences in the metabolic response of children with different diagnostic certainty of TB. This finding could contribute to the identification and classification of childhood TB, which would improve the characterization of the clinical spectrum of the disease and the search for new diagnostic and prognostic biomarkers of TB in children.
Methods
This was a prospective case series of children aged 0 to 14 years old with presumptive TB attending the St. Damien Paediatric Hospital, Port-au-Prince, Haiti, in 2015 and 2016, and healthy children attending a local primary school in the same neighbourhood.
Clinical and demographic information obtained at the time of enrolment included age, sex, weight, medical history and clinical presentation (history and exposure of TB, presence of cough, fever for ≥ 2 weeks, unexplained weight loss, and asthenia/fatigue, TB treatment, HIV status, and comorbidities), vaccines received (including BCG), and current and previous medications. Children with known immunodeficiencies, those receiving immunosuppressive treatment, or those starting TB treatment more than 15 days ago were excluded. The Mantoux TST (Sanofi Pasteur, Canada) and the QFN-GIT (Qiagen, Germany) assays were performed and interpreted according to the manufacturer’s instructions.
All children with presumptive TB had a chest X-ray and induced or aspirated nasopharyngeal/nasogastric sputum collected on three consecutive days. Sputum was examined using fluorescent smear microscopy (auramine stain). Children with positive smear microscopy or abnormal X-rays were tested with Xpert MTB/RIF. Children with lymph node adenopathy underwent biopsies, and specimens underwent histological examination from a pathologist.
Children with presumptive TB were classified, following the updated clinical case definitions for classification of intrathoracic TB in children into confirmed, unconfirmed, and unlikely TB16. Children were classified as: confirmed TB, if bacteriological confirmation was attained by Xpert MTB/RIF; unconfirmed TB, if there was not bacteriological confirmation, but evidence of M. tuberculosis infection (i.e., TST or QFT-GIT positive) and at least one clinical criteria of the clinical case definition (i.e., X-ray consistent with TB, symptoms and signs suggestive of TB, close TB exposure, or positive response on TB treatment), or two clinical criteria, if TST and QFT-GIT results were negative. Children were considered unlikely TB if the child had only evidence of M. tuberculosis infection or presented only one clinical criterion compatible with TB. School children were enrolled as controls if they had negative TST and QFT-GIT and no signs or symptoms of TB.
Urine collection
Midstream urine samples were collected from all participants in sterile plastic containers following standardized procedures12. In children who attended the hospital, urine samples were collected within the first week of the TB diagnosis. Two millilitres of urine were aliquoted in cryovials with screw caps that were frozen at − 20 °C until the 1H NMR analysis. According to a protocol established in a previous study34, 400 µl of urine were mixed with either 200 µl of the standard deuterated buffer for HF 1H NMR measurements or 250 µl for LF 1H NMR measurements. The standard deuterated buffer was a 0.2 M phosphate buffer solution dissolved in 99.9% deuterated water to adjust the internal pH to 7.4, containing 0.09% sodium azide and 0.3 mM trimethylsilyl propanoic acid (TMSP). Six hundred µl of buffered urine was transferred into 5 mm diameter NMR tubes (CortecNet, Les Ulis, France) for 1H NMR spectra acquisition.
Acquisition of NMR spectra
All 1H NMR urine spectra were measured following the procedures previously described9,42 using two different instruments operating at HF and LF, respectively: (1) a Bruker Avance 700 MHz spectrometer at a 1H frequency of 700 MHz (CNIO, Madrid, Spain) and (2) a Magritek Spinsolve 60 Ultra benchtop NMR spectrometer at a 1H frequency of 60 MHz (Magritek GmbH, Aachen, Germany). Briefly, HF 1H NMR spectra were measured using a pulse sequence based on the first increment of the nuclear Overhauser effect spectroscopy (NOESY) with pre-saturation to effect suppression of the water signal (δ = ~ 4.80 ppm). The spectra were acquired using the following parameters: 32,000 data points over a spectral width of 8,333.33 Hz and 256 scans resulting in acquisition times of 13 min per sample. LF 1H NMR spectra were measured using a one-dimensional presaturation (1D PRESAT) sequence to allow for efficient saturation of the water signal (δ = ~ 4.95 ppm). The spectra were acquired using the following parameters: 64 scans, an acquisition time of 6.4 s, and shimming of the sample after each new one to maintain a line width below 0.55 Hz. Data were zero-filled before Fourier transformation, and free induction decays (FIDs) were multiplied by exponential line broadening of 0.3 Hz.
Processing spectral data
Spectral data were processed using the MestReNova program (v.14; Mestrelab Research, Santiago de Compostela, Spain). According to the established protocols described in previous studies34,42, metabolite signals of the spectra were shift-aligned using TMSP as a reference signal standard (δ = 0.00 ppm), and the chemical shift regions of the raw HF 1H NMR spectra from 6.50 to 4.22 ppm were excluded from the analysis to remove the random effects of variation in urea and water resonance suppression34,42. Then, the chemical shift region around 0.00 ppm containing the internal reference (TMSP) was excluded, and baseline correction was performed using the ‘Withakker Smoother’ algorithm34,42. Binning (also known as bucketing) was applied to 1H NMR spectra and data-reduced to equal length integral segments (bins) of 0.04 ppm to compensate variations in resonance positions. All bins were normalized by the total sum of the spectral regions (each bin was divided by the sum of all the 1H NMR signals) 34,42. Thus, the concentration of each metabolite was normalized by the urine total metabolite content to compare these concentrations (in arbitrary units) between samples34,42. Before multivariate statistical analysis, spectral data were Pareto scaled43, where the square root of the standard deviation is used as the scaling factor.
Multivariate analysis of spectral data
Processed 1H NMR data were analysed in a multivariate manner using the Metabonomic package of R software (rel.3.3.1)44,45 and MetaboAnalyst v.5.046. The analysis included all urine spectra acquired using the HF and LF 1H NMR equipment. Graphs were plotted using SPSS statistical software for windows (SPSS version 26; SPSS Inc, Chicago, IL, USA).
Unsupervised data were analysed by applying the PCA to reduce the dimensionality of NMR-processed data and to observe clustering patterns according to their elemental composition13,14. In addition, PCA score plots were used to highlight statistical outliers based on Mahalanobis distance. Mahalanobis distance was calculated from the data point to the centroid of all samples in PC1, PC2, and PC3 three-dimensional space. A single case was considered a statistical outlier if it was placed out of the tolerance ellipse of 97.5%47.
Supervised PLS-DA13 was applied to the metabolic fingerprint of children with presumptive TB and controls to detect a discriminatory metabolic pattern between groups. Thus, all spectral regions grouped in bins of 0.04 ppm were transformed into a new set of orthogonal components obtained by maximising the covariance between spectral data and the class membership (presumptive TB and controls).
The robustness of the HF and LF PLS-DA models using the PLS-DA component 1 was validated using the LOOCV procedure (performance accuracy, R2, Q2, AUC-ROC). The VIP scores for PLS-DA were calculated to identify the spectral regions of the metabolic fingerprint most important for differentiating between children with presumptive TB and controls. Statistical significance was determined using Student’s t-test.
Since PLS-DA scores were trained to maximise the covariance between spectral data and class membership (presumptive TB vs controls), we hypothesised that the same PLS-DA scores should be sensitive also to differences within the group of children with presumptive TB (sub-categorised into bacteriologically confirmed TB, unconfirmed TB, and unlikely TB). Thus, the resulting PLS-DA component 1 (first latent variable) scores were used to evaluate metabolic differences between children with presumptive TB classified according to the standardized case definitions for TB and with the number of clinical criteria of TB.
Statistical analysis
Clinical and demographic characteristics were described using descriptive statistics. Categorical variables were described using frequencies and percentages, while continuous data were described using means and standard deviations (SD). Variables normally distributed were compared using parametric tests, including analysis of variance, and Student’ T-tests, and with non-parametric tests for comparisons of proportions. Comparison of PLS-DA scores among the children with presumptive TB groups and clinical criteria score groups were performed using the Kruskal–Wallis test with Dunn’s post hoc comparisons. Differences were considered statistically significant when a p-value was < 0.05. Analyses were performed using the SPSS 26 software package (SPSS, Chicago, USA).
Ethical statement
The study protocol was approved by the ethical review board of the Ethics Committee of the University of Barcelona and the Haiti National Ethics Committee (reference number IRB00003099). Written informed consent was obtained from the children’s parents or legal guardians before enrolment. Sample collection and all experiments were performed in accordance with relevant guidelines and regulations.
References
World Health Organization. Global Tuberculosis Report 2019. https://www.who.int/tb/publications/global_report/en/ (2019).
International Union Against Tuberculosis and Lung Disease. Silent Epidemic: A Call to Action Against Child Tuberculosis. The Union. https://childtb.theunion.org/wp-content/uploads/2018/08/Silent-Epidemic.pdf (2018).
Roya-Pabon, C. L. & Perez-Velez, C. M. Tuberculosis exposure, infection and disease in children: A systematic diagnostic approach. Pneumonia 8, 1–18 (2016).
World Health Organization. Roadmap Towards Ending TB in Children and Adolescents. (World Health Organization, 2018). Licence: CC BY-NC-SA 3.0 IGO. http://www.who.int/tb/publications/2018/tb-childhoodroadmap/en/ (2018).
Ellis, D. I., Dunn, W. B., Griffin, J. L., Allwood, J. W. & Goodacre, R. Metabolic fingerprinting as a diagnostic tool. Pharmacogenomics 8, 1243–1266 (2007).
Paris, D., Maniscalco, M. & Motta, A. Nuclear magnetic resonance-based metabolomics in respiratory medicine. Eur. Respir. J. 52, 1–5 (2018).
Izquierdo-García, J. L., Nin, N., Cardinal-Fernandez, P., Ruiz-Cabello, J. & Lorente, J. Á. Metabolomic profile of acute respiratory distress syndrome of different etiologies. Intensive Care Med. 45, 1318–1320 (2019).
Leenders, J. et al. Benchtop low-frequency 60 MHz NMR analysis of urine: A comparative metabolomics investigation. Metabolites 10, 1–13 (2020).
Percival, B. C. et al. Low-field, benchtop NMR spectroscopy as a potential tool for point-of-care diagnostics of metabolic conditions: Validation, protocols and computational models. High-Throughput 8, 1–33 (2019).
Mirsaeidi, M., Banoei, M. M., Winston, B. W. & Schraufnagel, D. E. Metabolomics: Applications and promise in mycobacterial disease. Ann. Am. Thorac. Soc. 12, 1278–1287 (2015).
Haas, C. T., Roe, J. K., Pollara, G., Mehta, M. & Noursadeghi, M. Diagnostic ‘omics’ for active tuberculosis. BMC Med. 14, 1–19 (2016).
Emwas, A. H. et al. Recommendations and standardization of biomarker quantification using NMR-based metabolomics with particular focus on urinary analysis. J. Proteome Res. 15, 360–373 (2016).
Lindon, J. C., Holmes, E. & Nicholson, J. K. Pattern recognition methods and applications in biomedical magnetic resonance. Prog. Nucl. Magn. Reson. Spectrosc. 39, 1–40 (2001).
Filzmoser, P. & Hron, K. Outlier detection for compositional data using robust methods. Math. Geosci. 40, 233–248 (2008).
Goletti, D., Lee, M. R., Wang, J. Y., Walter, N. & Ottenhoff, T. H. M. Update on tuberculosis biomarkers: From correlates of risk, to correlates of active disease and of cure from disease. Respirology 23, 455–466 (2018).
Graham, S. M. et al. Clinical case definitions for classification of intrathoracic tuberculosis in children: An update. Clin. Infect. Dis. 61, S179–S187 (2015).
Lopez, A. L. et al. Urine Xpert MTB/RIF for the diagnosis of childhood tuberculosis. Int. J. Infect. Dis. 79, 44–46 (2019).
Broger, T. et al. Novel lipoarabinomannan point-of-care tuberculosis test for people with HIV: a diagnostic accuracy study. Lancet Infect. Dis. 19, 852–861 (2019).
Sigal, G. B. et al. A novel sensitive immunoassay targeting the 5-methylthio-D- xylofuranose–lipoarabinomannan epitope meets the WHO’s performance target for tuberculosis diagnosis. J. Clin. Microbiol. 56, 1–17 (2018).
Nicol, M. P. et al. Accuracy of a novel urine test, Fujifilm SILVAMP tuberculosis lipoarabinomannan, for the diagnosis of pulmonary tuberculosis in children. Clin. Infect. Dis. 1–9. https://doi.org/10.1093/cid/ciaa1052 (2020).
Nkereuwem, E. et al. Comparing accuracy of lipoarabinomannan urine tests for diagnosis of pulmonary tuberculosis in children from four African countries: A cross-sectional study. Lancet Infect. Dis. 3099, 1–9 (2020).
Kosmides, A. K., Kamisoglu, K., Calvano, S. E., Corbett, S. A. & Androulakis, I. P. Metabolomic fingerprinting: Challenges and opportunities. Crit. Rev. Biomed. Eng. 41, 205–221 (2013).
Nicholson, J. K. & Lindon, J. C. Metabonomics. 455, 1054–1056 (2008).
Duffy, F. J. et al. Immunometabolic signatures predict risk of progression to active tuberculosis and disease outcome. Front. Immunol. 10, 1–16 (2019).
Weiner, J. et al. Metabolite changes in blood predict the onset of tuberculosis. Nat. Commun. 9, 1–12 (2018).
Weiner, J. et al. Biomarkers of inflammation, immunosuppression and stress with active disease are revealed by metabolomic profiling of tuberculosis patients. PLoS ONE 7, 1–7 (2012).
Cho, Y. et al. Identification of serum biomarkers for active pulmonary tuberculosis using a targeted metabolomics approach. Sci. Rep. 10, 1–11 (2020).
Zhou, A. et al. Application of 1H NMR spectroscopy-based metabolomics to sera of tuberculosis patients. J. Proteome Res. 12, 4642–4649 (2013).
Feng, S. et al. Analysis of serum metabolic profile by ultra-performance liquid chromatography-mass spectrometry for biomarkers discovery: Application in a pilot study to discriminate patients with tuberculosis. Chin. Med. J. (Engl) 128, 159–168 (2015).
Zhou, A. et al. Metabolomics specificity of tuberculosis plasma revealed by 1H NMR spectroscopy. Tuberculosis 95, 294–302 (2015).
Frediani, J. K. et al. Plasma metabolomics in human pulmonary tuberculosis disease: A pilot study. PLoS ONE 9, 1–9 (2014).
Sun, L. et al. Utility of novel plasma metabolic markers in the diagnosis of pediatric tuberculosis: A classification and regression tree analysis approach. J. Proteome Res. 15, 3118–3125 (2016).
Maechler, M. et al. Basic robust statistics. In CRAN. http://robustbase.r-forge.r-project.org/.
Izquierdo-Garcia, J. L. et al. Discovery and validation of an NMR-based metabolomic profile in urine as TB biomarker. Sci. Rep. 10, 1–13 (2020).
Pérez-Porcuna, T. M. et al. Mycobacterium tuberculosis infection in young children: Analyzing the performance of the diagnostic tests. PLoS ONE 9, 1–9 (2014).
Latorre, I. et al. Study of CD27 and CCR4 markers on specific CD4+ T-cells as immune tools for active and latent tuberculosis management. Front. Immunol. 10, 1–11 (2019).
Comella-del-Barrio, P. et al. A model based on the combination of IFN-γ, IP-10, ferritin and 25-hydroxyvitamin D for discriminating latent from active tuberculosis in children. Front. Microbiol. 10, 1–15 (2019).
Yong, Y. K. et al. Immune biomarkers for diagnosis and treatment monitoring of tuberculosis: Current developments and future prospects. Front. Microbiol. 10, 1–18 (2019).
Marais, B. J. et al. A proposed radiological classification of childhood intra-thoracic tuberculosis. Pediatr. Radiol. 34, 886–894 (2004).
Drain, P. K. et al. Incipient and subclinical tuberculosis: A clinical review of early stages and progression of infection. Clin. Microbiol. Rev. 31, 1–24 (2018).
Concepcion, N. D. P. et al. Standardized radiographic interpretation of thoracic tuberculosis in children. Pediatr. Radiol. 47, 1237–1248 (2017).
Izquierdo-Garcia, J. L. et al. Identification of novel metabolomic biomarkers in an experimental model of septic acute kidney injury. Am. J. Physiol. Renal Physiol. 316, F54–F62 (2019).
Nemeth, M. A. Multi- and megavariate data analysis. Technometrics 45, 362–362 (2003).
Izquierdo-García, J. L. et al. A novel R-package graphic user interface for the analysis of metabonomic profiles. BMC Bioinform. 10, 1–10 (2009).
R Core Team. R: A Language and Environment for Statistical Computing. (R Foundation for Statistical Computing, 2011).
Chong, J., Wishart, D. S. & Xia, J. Using MetaboAnalyst 4.0 for comprehensive and integrative metabolomics data analysis. Curr. Protoc. Bioinform. 68, e86 (2019).
Shah, N. K. & Gemperline, P. J. Program for calculating mahalanobis distances using principal component analysis. TrAC-Trends Anal. Chem. 8, 357–361 (1989).
Acknowledgements
The authors would like to thank Dr Margareth Narcisse, Mr Movil Junior Wilfrid, Mr Louis Yves and Ms Achil Nancy, and the laboratory technicians from the Paediatric Hospital Saint Damien of the Nos Petits Frères et Sœurs Foundation, Port-au-Prince for their collaboration and valuable assistance and care during recruitment and sampling. We also thank Federico Casanova (Magritek GmbH, Aachen, Germany) for providing the Spinsolve 60 Ultra Spectrometer to acquire the LF urine spectra and for technical support. Finally, we thank Dr Beatriz Sallés Mingels and Dr Lydia Canales Aliaga from the radiology service of the Primary Care Centre of Manso, and Dr Jaume Ollé Goig from the ACTMON Association for his support to the TB unit of the Saint Damien Hospital, for his indirect but positive influence on this project. This research was supported by grants from: (i) the Isolana Foundation; (ii) the Maria Francesca Roviralta Foundation (iii) the Spanish Ministry of Economy, Industry, and Competitiveness (MEIC-AEI) (SAF2017-84494-C2-1-R); (vi) the Instituto de Salud Carlos III (PI13/01546, PI16/01912, and DTS18/0092), integrated in the Plan Nacional de I+D+I, and cofounded by the ISCIII Subdirección General de Evaluación and the European Reginal Development Fund (ERDF); (v) the Spanish Ministry of Science and Innovation (PID2019-10656RJ-I00); (vi) the Sociedad Española de Neumología y Cirugía Torácica (project 052/2011; SEPAR; Barcelona, Spain); (vii) the Fundación para la Innovación y la Prospectiva en Salud en España (FIPSE: 02730-16 and 3307-17); (viii) the Comunidad de Madrid (B2017/BMD3875); (ix) the Gobierno Vasco, Dpto. Industria, Innovación, Comercio y Turismo, under the ELKARTEK programme (No. KK-2019/bmG19); and (x) the European Respiratory Society—ERS Short-Term Research Fellowship (October 2018) for C. Prat-Aymerich STRTF201810-00467; and (xi) the European Union’s Horizon 2020 Research and Innovation Programme, under the Marie Skłodowska-Curie grant agreement no. 823854 (INNOVA4TB). JRC received grants from the BBVA Foundation (Ayudas a Equipos de Investigación Científica de Biomedicina 2018) and from La Caixa Foundation (Health Research Call 2020 / HR20-00075). CIC biomaGUNE is supported by the Maria de Maeztu Units of Excellence Programme from the Spanish State Research Agency (Grant No. MDM-2017-0720). The funders were not involved at any stage from study design to submission of the manuscript for publication.
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Study design and supervision: P.C.B, T.M.P.P, J.G., J.L.I.G., L.E.C., J.R.C., and J.D. Recruitment of study subjects: T.M.P.P., J.D., M.J.C.D., J.G., and P.C.B. Acquisition of data: P.C.B., J.L.I.G., R.C.O., C.M.S., and B.M.M. Analysis and interpretation of data: P.C.B., J.L.I.G., R.A., C.P.A., L.E.C., J.R.C., and J.D. Drafting the article: P.C.B., J.L.I.G., J.R.C., L.E.C., and J.D. Revising the manuscript critically for important intellectual content and final approval of the version to be published: all authors.
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José Luis Izquierdo-Garcia, Patricia Comella-del-Barrio, Cristina Prat-Aymerich, and José Domínguez are registered as inventors on a patent filed by the Institut d’Investigació Germans Trias i Pujol and CIBERES, disclosing the use of NMR-based urine metabolomic profile for TB diagnosis. Jacqueline Gautier, Mariette Jean Coute Doresca, Ramón Campos-Olivas, Clara M. Santiveri, Beatriz Muriel-Moreno, Rosa Abellana, Tomas M. Pérez-Porcuna, Luis E. Cuevas, and Jesús Ruiz-Cabello declare no competing interests.
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Comella-del-Barrio, P., Izquierdo-Garcia, J.L., Gautier, J. et al. Urine NMR-based TB metabolic fingerprinting for the diagnosis of TB in children. Sci Rep 11, 12006 (2021). https://doi.org/10.1038/s41598-021-91545-0
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DOI: https://doi.org/10.1038/s41598-021-91545-0
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