- Research article
- Open Access
- Open Peer Review
Detection of Mycobacterium tuberculosis in pediatric stool samples using TruTip technology
BMC Infectious Diseasesvolume 19, Article number: 563 (2019)
Rapid and accurate diagnosis of childhood tuberculosis (TB) is challenging because children are often unable to produce the sputum sample required for conventional tests. Stool is an alternative sample type that is easy to collect from children, and studies investigating the use of stool for molecular detection of Mycobacterium tuberculosis (Mtb) have led to promising results. Our objective was to evaluate stool as an alternative specimen to sputum for Mtb detection in children. We did so using the TruTip workstation (Akonni Biosystems), a novel automated lysis and extraction platform.
We tested stool samples from 259 children aged 0–14 years old, in Lima, Peru who presented with TB symptoms. Following extraction with TruTip, we detected the presence of Mtb DNA by IS6110 real-time PCR. We calculated assay sensitivity in two groups: (1) children with culture confirmed TB (N = 22); and (2) children with clinically-diagnosed unconfirmed TB (N = 84). We calculated specificity among children in whom TB was ruled out (N = 153). Among children who were diagnosed with TB, we examined factors associated with a positive stool test.
Assay sensitivity was 59% (95% confidence interval [CI]: 39–80%) and 1.2% (95% CI: 0.0–6.5%) in children with culture-confirmed and clinically-diagnosed unconfirmed TB, respectively, and specificity was 97% (95% CI: 93–99%). The assay detected Mtb in stool of 7/7 children with smear-positive TB (100% sensitivity; 95% CI: 59–100%), and in 6/15 of children with smear-negative, culture-confirmed TB (40% sensitivity; 95% CI: 16–68%). Older age, smear positivity, culture positivity, ability to produce sputum and cavitary disease were associated with a positive stool result.
Testing of stool samples with the TruTip workstation and IS6110 amplification yielded sensitivity and specificity estimates comparable to other tests such as Xpert. Future work should include detection of resistance using the TruTip closed amplification system and assay optimization to improve sensitivity in children with low bacillary loads.
The World Health Organization estimates that one million new pediatric tuberculosis (TB) cases and 194,000 childhood TB deaths occurred in 2017 . Rapid case detection and treatment initiation is critical to minimizing TB morbidity and mortality in children but is hampered by the absence of a rapid, accurate diagnostic tool for this group. Bacteriologic confirmation of Mycobacterium tuberculosis (Mtb) in children is often difficult to achieve because they are frequently unable to expectorate sputum for bacteriologic testing and often have paucibacillary disease that cannot be detected using sputum smear microscopy, culture, and/or molecular testing [e.g. Xpert (Cepheid, Sunnyvale CA, USA)]. Sputum induction and gastric aspiration can be used to obtain respiratory specimens from children unable to expectorate sputum; however, gastric aspiration is invasive and neither procedure is widely implemented in resource-constrained settings. Due to these diagnostic challenges, bacteriologic confirmation of TB is obtained in only a small minority of children diagnosed with TB [2,3,4].
Stool can be easily obtained from most children and Mtb can be detected in stool using Xpert [5,6,7,8,9,10] or other laboratory-developed PCR assays [11,12,13]. In the case of Xpert, the process is automated, but detection of drug resistance is currently limited to rifampin-associated resistance mutations in rpoB. Non-integrated methods for DNA isolation and amplification using extraction kits and in-house tests are often laborious, multistep procedures. An ideal test would be an automated point-of-care workstation with integrated capacity for both Mtb and expanded drug resistance testing-criteria listed in the target product profile for novel TB diagnostics in low resource settings . The TruTip workstation is an automated platform including lysis and homogenization with TruTip nucleic acid extraction and purification (Akonni Biosystems, Frederick, MD, USA) [15,16,17]. TruTip has been used for nucleic acid isolation from a variety of pathogens and sample types and has demonstrated efficient Mtb DNA recovery from raw sputum [15, 18]. The platform can be connected to a closed amplicon system for amplification and microarray-based detection of Mtb as well as a number of drug resistance-associated mutations [17, 19,20,21]. The aim of the present study was to estimate sensitivity and specificity of Mtb detection in stool from children with symptoms compatible with intrathoracic TB in Lima, Peru, using this novel technology with IS6110 real-time PCR.
Study participants’ guardians provided written informed consent to participate, and children eight years of age and older provided written assent. Consent for publication was not applicable. All study procedures were approved by the Ethics Committee of Peru’s National Institute of Health and the Office of Human Research Administration at Harvard Medical School.
Between May 2015 and February 2018, we recruited children to participate in a pediatric TB diagnostics study. Eligible children were less than 15 years of age, had a history of contact with an adult with TB within the previous two years, and presented to a participating public sector health center in Lima, Peru with symptoms compatible with TB (i.e., persistent cough for more than two weeks; unexplained weight loss; unexplained fever for more than one week; and/or unexplained fatigue or lethargy) . For this analysis, we included the subset of children with culture-confirmed TB or clinically-diagnosed unconfirmed TB who had at least one stool sample available. For each case, we selected up to two children in whom TB had been ruled out (i.e, controls), matching on age and sample collection date when possible.
Study procedures and sample collection
Children were evaluated for TB per Peruvian National Tuberculosis Strategy guidelines . In brief, children provided up to two gastric aspirate (GA) and/or sputum samples (expectorated or induced) for smear and culture, and Ministry of Health pediatric pulmonologists considered these results as well as medical history, physical examination, chest X-ray findings and tuberculin skin testing (TST) results to diagnose or rule out TB. GA samples were neutralized to a pH of 6.8–7.2 upon collection. We requested two stool samples from all children for research purposes. From children who were diagnosed with TB, we aimed to collect these samples prior to TB treatment initiation. Stool collection took place at home or the health center. For children in diapers, plastic wrap was inserted on the inside of the diaper and a urine collection bag was adhered to the child. The latter served to collect a urine sample as well as to prevent mixing of urine and stool. Following collection, all samples were transported by cold-chain to the laboratory, aliquoted and stored at − 80 °C until testing. Because testing of stool did not occur in real time and because the assay was experimental, stool testing results were not shared with families or healthcare providers. HIV testing was not performed because the HIV prevalence among children in the study setting is low (< 0.1%) .
Sample processing and testing was performed in the BSL-3 and BSL-2 facilities at the Socios En Salud Sucursal Laboratory in Lima. We centrifuged and decontaminated sputum and GA samples in 2% NaOH/0.25% n-acetyl-L-cysteine (NALC). GA and sputum samples were analyzed by Ziehl-Neelsen staining/smear microscopy and liquid culture (BACTEC MGIT 960, BD Franklin Lakes, USA).
For lysis and DNA extraction procedures using the TruTip workstation we followed methods similar to those previously described for sputum samples . This TruTip protocol performed best in a head-to-head comparison to five other technologies for bacterial nucleic acid extraction from stool . In brief, 500 mg of thawed stool was homogenized in TE buffer in a magnetically-induced vortexing (MagVor) element, and after a 20 min heating step at 56 °C, the samples were transferred to the TruTip workstation for DNA extraction . Mtb DNA was amplified in duplicate by real-time PCR using a Roche 480 Lightcycler (Basel, Switzerland) with primers targeting the insertion element IS6110 . We considered a sample positive for Mtb DNA if, for both PCR replicates, the cycle threshold (Ct) value was < 37 and the change in fluorescence was > six units. We repeated the PCR step in duplicate for discordant replicates and considered the sample to be indeterminate for Mtb DNA if the two replicates remained discrepant after a second PCR run. Laboratory staff were blinded to participants’ clinical status.
Data were analyzed using SAS (Version 9.4. SAS Institute Inc., Cary, NC, USA). A child was classified as having confirmed TB if s/he had a positive culture result from sputum or GA and having clinically-diagnosed unconfirmed TB if a physician made a TB diagnosis in the absence of a positive culture result. We calculated sensitivity and specificity and 95% confidence intervals (CI) both at the child-level (including all samples from each child) and at the sample-level. Sensitivity of Mtb detection from stool was calculated separately for children with confirmed TB and clinically-diagnosed unconfirmed TB. Specificity was estimated among those in whom TB had been ruled out. In per-sample analyses we adjusted confidence intervals for clustering from multiple samples per child. Among all children with a TB diagnosis, we used chi-square tests to examine the associations between a positive stool test and the following variables: age, sex, smear and culture results, ability to spontaneously expectorate sputum, and cavitation on chest x-ray. Numerical precision for all percentages, p-values and 95% CIs are presented based on the evidence-based recommendations proposed by Cole .
From 628 children enrolled in the study, we selected 259 children based on stool sample availability (22 children with culture confirmed TB, 84 children with clinically-diagnosed unconfirmed TB, and 153 children in whom TB had been ruled out (Fig. 1)). These children had a median age of 5.1 years and 48% were female. Nearly all children (255/259; 98%) had at least one respiratory sample collected. Of the four with no respiratory sample, three were diagnosed with TB based on clinical criteria and TB was ruled out in one. Children between the ages of 11 and 14 years old were more likely than younger children to have a culture-confirmed diagnosis, and seven children had a smear-positive sputum sample, with AFB results of ‘+’ (one child) ‘++’ (two children), or ‘+++’ (four children). All seven children with smear-positive sputum belonged to the older age group (Table 1). A minority of children (41%) were able to spontaneously expectorate a sputum sample for culture. In contrast, the majority (59%, 13/22) of children with confirmed TB, and all children with smear-positive disease, were diagnosed based on analyses of expectorated sputum (Table 1).
From the 259 children, we collected a total of 484 stool samples. Most children had two stool samples; however 34 children (13%) had only one sample available. Seventeen samples from children diagnosed with TB were collected after TB treatment initiation (median time from treatment initiation to collection: three days; range [1–11 days]). Eight samples were collected 72 h or more after treatment start. Four of these eight samples were from children with smear-positive sputum. This occurred because children with a positive sputum smear result were eligible to initiate TB treatment immediately, and did not need to await culture results. This resulted in a narrow window between enrollment and treatment initiation during which pre-treatment samples could be collected.
Per sample analyses
The assay detected Mtb in 25/484 samples. Only one sample, from a child in the control group, had an indeterminate result, which we excluded from further analyses. Among 13 stool samples from seven children with smear positive sputum, 100% (95% confidence interval [CI]: 59–100%) were positive by the stool assay (Table 2). Sensitivity was lower in the smear-negative culture-confirmed group (23%; 95% CI: 5.6–41%, Table 2). We detected Mtb in 4/282 (1.4%) samples from control children, resulting in a specificity of 99% (95% CI: 97–99.8%).
Per child analyses
In child-level analyses, sensitivity of the stool assay conducted in each child’s first sample was 55% (95% CI: 33–75%). When we included the results of both samples, we identified one additional confirmed TB case, which increased sensitivity to 59% (95% CI: 39–80%) (Table 3). While the majority of children with a positive stool sample also had a spontaneous sputum sample that was culture positive (11/14, 79%), we detected Mtb in the stool of two children in whom TB was confirmed based on gastric aspirate and one child with clinically-diagnosed unconfirmed TB (this child had one expectorated and one induced sputum sample, both of which tested negative for Mtb). All three children were under five years of age.
Factors associated with stool test positivity among TB cases
Features of adult-like TB (i.e., a positive smear result, a positive culture result, the ability to spontaneously expectorate sputum and cavitary TB), were associated with detection in stool and more common in the 11–14 year age group (Table 4). There was no association between stool positivity and sex.
We found that our test was 100% sensitive for Mtb detection in stool among children with smear-positive confirmed TB and 40% sensitive in children with smear-negative confirmed TB. Importantly, we detected Mtb in stool of three children below the age of five who were not able to expectorate sputum (two of whom were diagnosed based on GA samples and one who was culture negative by sputum, but clinically-diagnosed).
Our study of 259 children included 106 (40%) TB cases, of whom 22 (21%) had culture-confirmed TB, reflecting the poor sensitivity of culture for pediatric TB. These numbers are similar to the number of culture-confirmed children in other studies [6, 10, 28,29,30,31,32,33]. The sensitivity (59%) and specificity (97%) of this stool assay relative to liquid culture of respiratory samples was comparable to previous studies using Xpert for stool testing in children . Sensitivity of Xpert stool testing among children was estimated 67% (95% CI: 52–79) in a recent systematic review. The authors highlighted the heterogeneity in design between studies as contributor to the wide variability in sensitivity, which ranged from 32 to 85%, but did not stratify for smear results .
Unfortunately, we detected TB in only 1.2% of children with culture negative, clinically-diagnosed TB. Other studies have reported similarly low sensitivities in children with clinically-diagnosed unconfirmed TB, ranging from 0 to 3% [6, 28, 29, 35]. Considerations for improving sensitivity include incorporating an initial homogenization step prior to aliquotting, testing of multiple sample aliquots, incorporating inhibitor-removal compounds, and altering the sample volume. Our stool test protocol required a relatively small input volume (500 mg), which may minimize the impact of PCR inhibitors in stool that can impede the detection of Mtb. In fact, several studies show reduced sensitivity with larger sample volumes. For example, Banada et al. reported higher sensitivity and fewer invalid test results when stool input volume was decreased from 1200 to 600 mg . Recently, DiNardo et al. obtained 67% sensitivity with an in-house developed method using only 50 mg, demonstrating that even smaller volumes can be sufficient to reach high sensitivity. Our assay had a limit of detection of at least 80 CFU/ml for sputum ; future work will include optimization steps described above and determination of the limit of detection for the stool application.
In line with previous reports [8, 36] we found strong associations between a positive stool test and features of more adult-like TB (i.e., cavitary disease; positive sputum culture; positive sputum smear; the ability to produce sputum), which were most common in the oldest age group. This emphasizes the impact of age and smear status on the outcomes of stool testing and has critical implications for the reporting of pediatric TB diagnostic studies because stool assay sensitivities may vary widely based on the percentage of children in the cohort with adult-like TB and/or high bacterial burden. Because children with adult-like TB are often able to produce a sputum sample for testing, a stool assay will only begin to fill the pediatric TB diagnostic gap if it is sensitive among children who cannot already spontaneously expectorate sputum. To facilitate an understanding of stool assay performance and its utility across settings, we recommend stratifying stool sensitivity results by some measure of disease severity, ideally smear status, and reporting the added yield among children unable to spontaneously expectorate sputum.
Akonni TruTip is not yet commercially produced; we expect the per-assay cost in combination with PCR detection to be competitive with existing TB diagnostic assays, such as Xpert. The TruTip workstation had a number of attractive attributes for Mtb DNA extraction from stool. Extraction procedures required limited pipetting steps compared to commercially available kits. Additional future advantages include that the extracted DNA eluate can be isolated for other purposes, such as sequencing. Most importantly, the TruTip workstation can be integrated with a microarray-based detection of Mtb as well as a number of drug resistance-associated mutations [17, 19, 20], which is a focus of future studies.
A limitation of our study was that we lacked follow-up data on the clinical evolution of children, a key criterion for classifying pediatric cases of clinically-diagnosed, unconfirmed TB. To the extent that unconfirmed clinical TB was overdiagnosed, sensitivity will be underestimated in this group. Similarly, missed TB diagnoses among children in whom TB was ruled out could lead to an underestimate of assay specificity. The influence of these potential biases appears limited given the very low sensitivity among children with clinically-diagnosed unconfirmed clinical TB and a high overall specificity. A second limitation of our study is the absence of children living with HIV. Studies have shown that sensitivity of stool assays may be higher in children living with HIV [6, 7], in particular with severe immunosuppression , therefore, our results may not be generalizable to children living with HIV.
In conclusion, the results of our study show that we can detect Mtb in pediatric stool samples. We used the TruTip workstation in combination with realtime IS6110 PCR for detection, and its performance is comparable to other platforms. Future work should include detection of resistance in stool samples using the TruTip closed amplification system and assay optimization to improve sensitivity in children with low bacillary loads.
Availability of data and materials
Reported data are available on request to the corresponding author.
Acid fast bacilli
Drug sensitivity testing
Polymerase Chain Reaction
Tuberculin skin test
World Health Organization
World Health Organization. Global Tuberculosis Report. 2018.
Starke JR. Pediatric tuberculosis: time for a new approach. Tuberculosis. 2003;83(1–3):208–12.
Newton S, Brent A, Anderson S, Whittaker E, Kampmann B. Paediatric Tuberculosis. Lancet Infect Dis. 2008;8(8):498–510.
DiNardo AR, Detjen A, Ustero P, Ngo K, Bacha J, Mandalakas AM. Culture is an imperfect and heterogeneous reference standard in pediatric tuberculosis. Tuberculosis. 2016;101:S105–8.
Banada PP, Naidoo U, Deshpande S, Karim F, Flynn JL, O’Malley M, et al. A novel sample processing method for rapid detection of tuberculosis in the stool of pediatric patients using the Xpert MTB/RIF assay. PLoS One. 2016;11(3):1–13.
Nicol MP, Spiers K, Workman L, Isaacs W, Munro J, Black F, et al. Xpert MTB/RIF testing of stool samples for the diagnosis of pulmonary tuberculosis in children. Clin Infect Dis. 2013;57(3):e18–21.
Chipinduro M, Mateveke K, Makamure B, Ferrand RA, Gomo E. Stool Xpert MTB / RIF test for the diagnosis of childhood pulmonary tuberculosis at primary clinics in Zimbabwe. Int J Tuberc Lung Dis. 2017;21(2):161–6.
Walters E, Scott L, Nabeta P, Demers A-M, Reubenson G, Bosch C, et al. Molecular detection of mycobacterium tuberculosis from stools in young children by use of a novel centrifugation-free processing method. J Clin Microbiol. 2018;56(9):e00781–18.
Walters E, Gie RP, Hesseling AC, Friedrich SO, Diacon AH, Gie RP. Rapid diagnosis of pediatric intrathoracic tuberculosis from stool samples using the xpert MTB/RIF assay: a pilot study. Pediatr Infect Dis J. 2012;31(12):1316.
Hasan Z, Shakoor S, Arif F, Mehnaz A, Akber A, Haider M, et al. Evaluation of Xpert MTB/RIF testing for rapid diagnosis of childhood pulmonary tuberculosis in children by Xpert MTB/RIF testing of stool samples in a low resource setting. BMC Res Notes. 2017;10(1):473.
Wolf H, Mendez M, Gilman RH, Sheen P, Soto G, Velarde AK, et al. Diagnosis of pediatric pulmonary tuberculosis by stool PCR. Am J Trop Med Hyg. 2008;79(6):893–8.
DiNardo AR, Kay AW, Maphalala G, Harris NM, Fung C, Mtetwa G, et al. Diagnostic and treatment monitoring potential of a stool-based quantitative polymerase chain reaction assay for pulmonary tuberculosis. Am J Trop Med Hyg. 2018;99(2):310–6.
Oberhelman RA, Soto-Castellares G, Caviedes L, Castillo ME, Kissinger P, Moore DA, et al. Improved recovery of mycobacterium tuberculosis from children using the microscopic observation drug susceptibility method. Pediatrics. 2006;118(1):e100–6.
Denkinger CM, Dolinger D, Schito M, Wells W, Cobelens F, Pai M, et al. Target product profile of a molecular drug-susceptibility test for use in microscopy centers. J Infect Dis. 2015;211(Suppl 2):S39–49.
Chandler DP, Griesemer SB, Cooney CG, Holmberg R, Thakore N, Mokhiber B, et al. Rapid , simple influenza RNA extraction from nasopharyngeal samples. J Virol Methods. 2012;183(1):8–13.
Thakore N, Garber S, Bueno A, Qu P, Norville R, Villanueva M, et al. A bench-top automated workstation for nucleic acid isolation from clinical sample types. J Microbiol Methods. 2018;148(January):174–80.
Linger Y, Kukhtin A, Golova J, Perov A, Lambarqui A, Bryant L, et al. Simplified microarray system for simultaneously detecting rifampin,isoniazid, ethambutol, and streptomycin resistance markers in mycobacterium tuberculosis. J Clin Microbiol. 2014;52(6):2100–7.
Thakore N, Norville R, Franke M, Calderon R, Lecca L, Villanueva M, et al. Automated TruTip nucleic acid extraction and purification from raw sputum. PLoS One. 2018;13(7):e0199869.
Chandler D, Bryant L, Griesemer S, Gu R, Knickerbocker C, Kukhtin A, et al. Integrated amplification microarrays for infectious disease diagnostics. Microarrays. 2012;1(3):107–24.
Linger Y, Knickerbocker C, Sipes D, Golova J, Franke M, Calderon R, et al. Genotyping multi-drug resistant M. tuberculosis from primary sputum and decontaminated sediment with an integrated microfluidic amplification microarray. J Clin Microbiol. 2018;56(3):e01652–17.
Kukhtin AC, Sebastian T, Golova J, Perov A, Knickerbocker C, Linger Y, et al. Lab-on-a-film disposable for genotyping multidrug-resistant mycobacterium tuberculosis from sputum extracts. Lab Chip. 2019; Available from. https://doi.org/10.1039/C8LC01404C.
Cuevas LE, Browning R, Bossuyt P, Casenghi M, Cotton MF, Cruz AT, et al. Evaluation of tuberculosis diagnostics in children: 2. Methodological issues for conducting and reporting research evaluations of tuberculosis diagnostics for intrathoracic tuberculosis in children. Consensus from an expert panel. J Infect Dis. 2012;205(SUPPL. 2):209–15.
MINSA. Norma técnica de la salud para el control de la Tuberculosis. Peru: Ministerio de Salud; 2013.
UNAIDS. UNAIDS Data 2017. 2017.
Beall SG, Cantera J, Diaz MH, Winchell JM, Lillis L, White H, et al. Performance and workflow assessment of six nucleic acid extraction technologies for use in resource limited settings. PLoS One. 2019;14(4):e0215753.
Savelkoul PHM, Catsburg A, Mulder S, Oostendorp L, Schirm J, Wilke H, et al. Detection of mycobacterium tuberculosis complex with real time PCR : comparison of different primer-probe sets based on the IS6110 element. J Microbiol Methods. 2006;66:177–80.
Cole TJ. Too many digits: the presentation of numerical data. Arch Dis Child. 2015;100(7):608–9.
Walters E, van der Zalm MM, Palmer M, Bosch C, Demers A-M, Draper H, et al. Xpert MTB/RIF on stool is useful for the rapid diagnosis of tuberculosis in young children with severe pulmonary disease. Pediatr Infect Dis J. 2017;36(9):837–43.
Orikiriza P, Nansumba M, Nyehangane D, Bastard M, Mugisha IT, Nansera D, et al. Xpert MTB/RIF diagnosis of childhood tuberculosis from sputum and stool samples in a high TB-HIV-prevalent setting. Eur J Clin Microbiol Infect Dis. 2018;37(8):1465–73.
Lacourse SM, Pavlinac PB, Cranmer LM, Njuguna IN, Mugo C, Gatimu J, et al. Stool Xpert MTB/RIF and urine lipoarabinomannan for the diagnosis of tuberculosis in hospitalized HIV-infected children. Aids. 2018;32(1):69–78.
Moussa HS, Bayoumi FS, Mohamed AMA. Gene Xpert for direct detection of mycobacterium tuberculosis in stool specimens from children with presumptive pulmonary tuberculosis. Ann Clin Lab Sci. 2016;46(2):198–203.
Marcy O, Ung V, Goyet S, Borand L, Msellati P, Tejiokem M, et al. Performance of Xpert MTB/RIF and alternative specimen collection methods for the diagnosis of tuberculosis in HIV-infected children. Clin Infect Dis. 2016;62(9):1161–8.
Oberhelman RA, Soto-Castellares G, Gilman RH, Caviedes L, Castillo ME, Kolevic L, et al. Diagnostic approaches for paediatric tuberculosis by use of different specimen types, culture methods, and PCR: a prospective case-control study. Lancet Infect Dis. 2010;10(9):612–20.
MacLean E, Sulis G, Denkinger CM, Johnston JC, Pai M, Khan FA. Diagnostic accuracy of stool Xpert MTB/RIF for the detection of pulmonary tuberculosis in children: a systematic review and meta-analysis. J Clin Microbiol. 2019;57(6):e02057–18.
Memon SS, Sinha S, Sharma S, Kabra S, Lodha R, Soneja M. Diagnostic accuracy of xpert MTB/RIF assay in stool samples in intrathoracic childhood tuberculosis. J Tuberc Ther. 2018;3(2):115.
Walters E, Demers A-M, van der Zalm MM, Whitelaw A, Palmer M, Bosch C, et al. Stool culture for the diagnosis of pulmonary tuberculosis in children. J Clin Microbiol. 2017;55(12):00801–17.
We are grateful for all children and guardians who participated in this study, and for the participating health centers of the Ministry of Health of Peru. We thank Dr. Rafael Alejandro Ortiz Sousa, Dr. Javier Nicolaz Jugo Rebaza, Dr. Ildauro Aguirre Sosa, Dra. Silvanna De la Gala De los Santos, Dr. Hernán Del Castillo Barrientos, Cynthia Pinedo Chuquizuta, Helen Marín Samanez and Gissela Valderrama Yalán for their participation and Zibiao Zhang for data management support. We thank Socios En Salud for contribution and dedication to health equity and all the health care workers who contributed to this study and treat patients.
This work was supported by the National Institutes of Health (NIH) under the Center of Excellence in Translational Research (CETR) grant U19 AI109755.
Ethics approval and consent to participate
Study participant guardians’ provided written informed consent, and children eight years of age and older provided written assent. All study procedures were approved by the Ethics Committee of Peru’s National Institute of Health and the Office of Human Research Administration at the Harvard Medical School.
Consent for publication
Our manuscript does not contain individual person’s data. Consent for publication was not applicable.
RH is an employee Akonni Biosystems inc. The company was not involved in study design. MFF and NRP were paid consultants on a National Institutes of Health Small Business Innovation Research program award granted to Akonni Biosystems inc (SBIR #HHSN272201700063C).
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