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FAST tuberculosis transmission control strategy speeds the start of tuberculosis treatment at a general hospital in Lima, Peru

Published online by Cambridge University Press:  06 October 2021

Dylan B. Tierney Open the ORCID record for Dylan B. Tierney [Opens in a new window] ,
Eli Orvis ,
Ruvandhi R. Nathavitharana ,
Shelley Hurwitz ,
Karen Tintaya ,
Dante Vargas ,
Patricia Segura ,
Silvana de la Gala ,
Leonid Lecca  and
Carole D. Mitnick
...Show all authors
Dylan B. Tierney*
Affiliation:
Brigham and Women’s Hospital, Boston, Massachusetts, United States Harvard Medical School, Boston, Massachusetts, United States
Eli Orvis
Affiliation:
Analysis Group, Boston, Massachusetts, United States
Ruvandhi R. Nathavitharana
Affiliation:
Harvard Medical School, Boston, Massachusetts, United States Beth Israel Deaconess Medical Center, Boston, Massachusetts, United States
Shelley Hurwitz
Affiliation:
Brigham and Women’s Hospital, Boston, Massachusetts, United States Harvard Medical School, Boston, Massachusetts, United States
Karen Tintaya
Affiliation:
Socios En Salud Sucursal Peru, Lima, Peru
Dante Vargas
Affiliation:
Hospital Nacional Hipolito Unanue, Lima, Peru
Patricia Segura
Affiliation:
Hospital Nacional Hipolito Unanue, Lima, Peru
Silvana de la Gala
Affiliation:
Socios En Salud Sucursal Peru, Lima, Peru
Leonid Lecca
Affiliation:
Socios En Salud Sucursal Peru, Lima, Peru
Carole D. Mitnick
Affiliation:
Brigham and Women’s Hospital, Boston, Massachusetts, United States Department of Global Health and Social Medicine, Harvard Medical School, Boston, Massachusetts, United States
Edward A. Nardell
Affiliation:
Brigham and Women’s Hospital, Boston, Massachusetts, United States Harvard Medical School, Boston, Massachusetts, United States
*
Author for correspondence: Dylan Tierney MD, E-mail: dtierney@bwh.harvard.edu
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Abstract

Objective:

To evaluate the effect of the FAST (Find cases Actively, Separate safely, Treat effectively) strategy on time to tuberculosis diagnosis and treatment for patients at a general hospital in a tuberculosis-endemic setting.

Design:

Prospective cohort study with historical controls.

Participants:

Patients diagnosed with pulmonary tuberculosis during hospitalization at Hospital Nacional Hipolito Unanue in Lima, Peru.

Methods:

The FAST strategy was implemented from July 24, 2016, to December 31, 2019. We compared the proportion of patients with drug susceptibility testing and tuberculosis treatment during FAST to the 6-month period prior to FAST. Times to diagnosis and tuberculosis treatment were also compared using Kaplan-Meier plots and Cox regressions.

Results:

We analyzed 75 patients diagnosed with pulmonary tuberculosis through FAST. The historical cohort comprised 76 patients. More FAST patients underwent drug susceptibility testing (98.7% vs 57.8%; OR, 53.8; P < .001), which led to the diagnosis of drug-resistant tuberculosis in 18 (24.3%) of 74 of the prospective cohort and 4 (9%) of 44 of the historical cohort (OR, 3.2; P = .03). Overall, 55 FAST patients (73.3%) started tuberculosis treatment during hospitalization compared to 39 (51.3%) controls (OR, 2.44; P = .012). FAST reduced the time from hospital admission to the start of TB treatment (HR, 2.11; 95% CI, 1.39–3.21; P < .001).

Conclusions:

Using the FAST strategy improved the diagnosis of drug-resistant tuberculosis and the likelihood and speed of starting treatment among patients with pulmonary tuberculosis at a general hospital in a tuberculosis-endemic setting. In these settings, the FAST strategy should be considered to reduce tuberculosis transmission while simultaneously improving the quality of care.

Type
Original Article
Information
Infection Control & Hospital Epidemiology , Volume 43 , Issue 10 , October 2022 , pp. 1459 - 1465
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Creative Commons
Creative Common License - CCCreative Common License - BY
This is an Open Access article, distributed under the terms of the Creative Commons Attribution licence (http://creativecommons.org/licenses/by/4.0/), which permits unrestricted re-use, distribution, and reproduction in any medium, provided the original work is properly cited.
Copyright
© The Author(s), 2021. Published by Cambridge University Press on behalf of The Society for Healthcare Epidemiology of America

Tuberculosis (TB) continues to be an epidemic of major global health significance; ∼10 million people develop the disease annually. 1 Hospitals in TB-endemic settings are transmission hotspots Reference Sepkowitz2 and give rise to community outbreaks, particularly with drug-resistant (DR) strains. Reference Gelmanova, Keshavjee and Golubchikova3Reference Arandjelovic, Merker and Richter5 Cross-sectional surveys of hospitalized patients in TB-endemic settings have demonstrated a high proportion of patients with undiagnosed and/or untreated TB. Reference Bantubani, Kabera and Connolly6Reference Assefa, Belachew, Wondimagegn and Klinkenberg8 These individuals can be hospitalized for extended periods in crowded wards, where TB is passed to other patients, healthcare workers, and visitors. Reference Zenhausern, Bekker, Wates, Schaaf and Dramowski9Reference Medrano, Salinas and Sanchez11 Missed opportunities for case finding, Reference Der, Grint, Narh, Bonsu and Grant12 slow diagnostic testing, Reference Sreeramareddy, Qin, Satyanarayana, Subbaraman and Pai13,Reference Martinez, Xu and Chen14 and delayed treatment Reference Asres, Jerene and Deressa15 create conditions that allow nosocomial TB transmission to occur. Poor deployment of rapid drug-susceptibility testing (DST) aggravates the situation, precluding timely initiation of effective therapy for drug-resistant TB (DR-TB). Reference Boyd, Ford, Padgen and Cox16

Awareness is growing about the need to improve TB screening, diagnosis, and treatment to achieve TB transmission control in the hospital. Reference Scott, Van Zyl Smit and Jenkins17,Reference Bulage, Sekandi, Kigenyi and Mupere18 Modeling reveals that decreasing exposure to patients with infectious TB through improved case detection and delivery of care will reduce transmission. Reference Basu and Galvani19 The FAST (Find cases Actively, Separate safely, Treat effectively) strategy has been developed to speed the delivery of key elements of TB care to reduce hospital transmission of TB from patients with undiagnosed and/or untreated disease. Reference Barrera, Livchits and Nardell20,21

The first step of FAST is universal active TB symptom and risk-factor screening of hospitalized patients. Those with symptoms or risk factors undergo rapid diagnosis and DST using nucleic acid amplification tests followed by the expedited start of effective treatment. Whether treatment is effective and stops transmission depends in large part on the match between the regimen and the susceptibility of the infecting strains of Mycobacterium tuberculosis, making the inclusion of rapid DST a critical component of FAST. Reference Dharmadhikari, Mphahlele and Venter22 Evidence suggests that even a few days of effective treatment may render a patient noninfectious. Reference Dharmadhikari, Mphahlele and Venter22Reference Riley, Mills, O’Grady, Sultan, Wittstadt and Shivpuri24 This impact contrasts starkly with the weeks of therapy often required to effect sputum smear and culture conversion, which has historically been used to signal the end of the infectious period. Reference Shaw and Wynn-Williams25,Reference Crofton26

Interrupting hospital TB transmission through FAST hinges on the strategy’s ability to decrease the institutional exposure time to patients with untreated or inadequately treated TB. Using ‘time to’ process indicators, pilot studies performed in chest and TB hospitals have shown that FAST can shorten the time to TB diagnosis and effective treatment. Reference Barrera, Livchits and Nardell20,Reference Le, Nguyen and Tran27 In those settings, all patients have respiratory symptoms or a TB diagnosis on presentation. Here, we implemented FAST among a broader population of patients in a general hospital, and we examined its effect on time to TB diagnosis, DST, and treatment for patients with pulmonary TB in a single-center prospective cohort study with historical controls.

Methods

Setting

We implemented FAST at Hospital Nacional Hipolito Unanue (HNHU), a 700-bed general hospital in Lima, Peru, between January 1, 2016, and December 31, 2019. Peru has an annual TB incidence of 119 cases per 100,000 people, and the highest MDR-TB incidence in Latin America. 1

Prior to the study period, HNHU relied on passive case finding to detect TB among hospitalized patients. Entry into the TB care cascade was driven primarily by patient self-report of TB symptoms during clinical encounters. Patients were then evaluated for pulmonary TB with 2 sputum samples tested by smear microscopy; in some patients with positive smears, GenoType (Hain Lifescience GmbH, Nehren, Germany) was also performed. Patients with 2 negative smears but clinical concern for TB were tested with mycobacterial culture on third sputum sample. HNHU clinicians from the National TB Program bore responsibility for treatment initiation according to national guidelines.

FAST intervention

Trained FAST assistants approached and solicited information about cough and risk factors for pulmonary TB from all adult patients upon facility admission, regardless of presenting complaint. Those who screened positive were offered enrollment in the study. At least 2 sputum samples were tested for TB at HNHU. Methods used were smear microscopy, Xpert MTB/RIF (Xpert, Cepheid, Sunnyvale, CA) and/or GenoType MTBDRplus line probe assay. Mycobacterial culture and conventional DST were also performed. FAST assistants collected and transferred specimens to the HNHU laboratory and communicated diagnostic test results to clinicians. Patients who were diagnosed with TB were referred to hospital-based National TB Program staff, who were responsible for starting TB treatment as recommended by the Peru TB guidelines (as in the historical period).

The research study was conducted using a formative evaluation approach, with FAST process outputs guiding iterative changes in the intervention during the study period. Reference Stetler, Legro and Wallace28 In phase 1, from August 3, 2016, to June 19, 2017, screening questions were limited to cough for >2 weeks. Because this symptom was rarely reported, cough of any duration became the screening question in the second implementation phase (June 20, 2017, to January 1, 2018). Xpert testing was also introduced as part of the FAST protocol in this second phase. The final iteration of the FAST protocol was implemented on January 2, 2018, and continued through study end on December 31, 2019. It permitted inclusion based on any of the following criteria: cough of any duration (self-reported or observed by a healthcare provider during hospitalization), history of active TB, current active TB diagnosis and treatment, or contact of someone with active TB.

Study population

We prospectively enrolled consenting patients with a laboratory-confirmed diagnosis of pulmonary TB between August 3, 2016, and December 31, 2019 (Fig. 1a). This period was established to permit expected enrollment of a sample of healthcare workers to analyze the impact of the FAST strategy on TB infection. The comparative historical cohort included all patients with laboratory-confirmed pulmonary TB diagnosed at HNHU between January 1, 2016, and July 23, 2016, a period immediately prior to FAST implementation (Fig. 1b).  Records for patients hospitalized prior to 2016 were not available for review.

Fig. 1. (A) Flowchart for prospective FAST cohort at Hospital Nacional Hipolito Unanue in Lima, Peru. Note. TB, tuberculosis.

Fig. 1. (B) Flowchart for historical cohort at Hospital Nacional Hipolito Unanue in Lima, Peru. Note. AFB, acid-fast bacilli; TB, tuberculosis.

Data collection and outcome definitions

We collected demographic variables and results from TB diagnostic tests, dates of hospitalization and discharge, and key dates from the TB care cascade (Supplementary Material 1 online). Date of TB diagnosis was defined as the date of the first positive smear microscopy or positive Xpert result for either of the first 2 sputum samples obtained. Date of DST was defined as the date of Xpert, GenoType, or culture-based DST result, whichever was available first. TB treatment initiation date was defined as the date TB treatment was started according to the patient’s medical record. We made a distinction between treatment and ‘indicated’ treatment; the latter describes the TB treatment regimen recommended by national guidelines using DST results. In patients with drug-susceptible TB (DS-TB), indicated treatment was defined as the standard World Health Organization first-line regimen. 29 For patients with rifampin-resistant (RR) or multidrug-resistant TB (MDR-TB), indicated treatment contained at least a fluoroquinolone and an aminoglycoside or polypeptide if there was no documented resistance to these agents.

Analysis

We calculated the proportion of patients diagnosed using DST and treated (with and without an indicated regimen). We compared these proportions between historical and prospective cohorts. We also calculated the days from hospital admission to TB diagnosis and from TB diagnosis to initiation of TB treatment and indicated treatment. The sum of these periods was days from hospital admission to (indicated) TB treatment initiation. Length of stay was the period between hospital admission and hospital discharge.

The analysis excluded patients who were missing date of hospitalization, TB diagnosis, or discharge (Fig. 1a and 1b). Patients were also excluded from the analysis if the diagnosis of their current episode of TB predated hospitalization at HNHU. Patients who received empiric TB treatment prior to diagnosis (ie, TB treatment initiation date preceding the date of TB diagnosis) were excluded from the primary analyses.

Odds ratios were used to compare proportions and median time (in days) to each event in the TB care cascade for historical and prospective cohorts. Time to event was also compared with Kaplan-Meier plots and Cox regressions. Follow-up time was censored at discharge date in patients who had not experienced the event prior to discharge. Unadjusted hazard ratios (HRs) and 95% confidence intervals (CIs) were reported; values >1.0 indicate shorter time to and higher likelihood of the event for the prospective cohort. The proportion of participants who started treatment within 2 days of diagnosis, along with the 95% CI, was also reported.

The ethics boards at HNHU and Brigham and Women’s Hospital approved the study.

Results

We prospectively screened 67,569 hospitalized patients from August 3, 2016, to December 31, 2019, and identified 3,128 (4.6%) with cough or other TB risk factors who were eligible to participate in the FAST study (Fig. 1a). We consented and enrolled 1,240 individuals, 272 of whom had at least 1 positive sputum test for TB. Of those, 75 were diagnosed with laboratory-confirmed TB during hospitalization. Three patients were diagnosed in phase 1 of FAST implementation, 16 were diagnosed in phase 2, and 56 were diagnosed in phase 3. An additional 162 sputum-positive patients (60%) had a TB diagnosis that predated hospitalization. In the historical period, we identified 76 patients with TB newly diagnosed during hospitalization (Fig. 1b).

In the prospective FAST cohort, Xpert testing was performed on samples collected from 68 (90.7%) patients. Results were positive in 67 (98.5%), including 26 who had negative microscopy results (Table 1). All patients in the historical cohort had positive smear microscopy; none were tested by Xpert.

Table 1. Diagnostic Testing Utilization and Results During FAST Implementation Compared to Historical Controls

Note. TB, tuberculosis; Xpert, Xpert MTB/RIF; DST, drug-susceptibility testing; RR, rifampin resistance; MDR, multidrug resistant (resistance to isoniazid and rifampin).

a Molecular DST for the prospective cohort included Xpert MTB/RIF and/or GenoType MTBDRplus. Molecular DST for the historical cohort was performed by GenoType MTBDRplus alone.

b Includes 1 patient in the prospective cohort who had indeterminant testing for rifampicin resistance by Xpert MTB/RIF.

Compared with historical controls, more FAST patients (98.7% vs 57.8%; OR, 53.8; 95% CI, 7.1–407.74; P < .001) had DST results during hospitalization. Among those with DST, MDR-TB was detected in 18 (24.3%) of 74 of the prospective cohort and 4 (9%) of 44 of the historical cohort (OR, 3.2; 95% CI, 1.01–10.2; P = .03). In addition, 2 patients in the prospective cohort had isoniazid mono-resistance and 2 had rifampin mono-resistance.

The times from hospital admission to TB diagnosis were similar between the prospective and historical cohorts (HR, 0.88; 95% CI, 0.63–1.22; P = .46) (Table 2). The time from admission to diagnosis including DST, however, was shorter during the FAST period (HR, 23.71; 95% CI, 10.39–51.11; P < .001).

Table 2. Median Time to TB Care Cascade Event at Hospital National Hipolito Unanue a

Note. TB, tuberculosis; DST, drug susceptibility testing; IQR, interquartile ratio; HR, hazard ratio; CI, confidence interval; NR, not reached.

a NR denotes not reached (ie, 50% of participants did not reach the end point).

Under the FAST strategy, 54 patients (72%) with a new diagnosis of pulmonary TB began treatment during hospitalization compared to 39 (51.3%) in the historical cohort (OR, 2.44; 95% CI, 1.23–4.79; P = .012). Less time elapsed between TB diagnosis and initiation of TB treatment in the FAST cohort than in the historical cohort (HR, 2.54; 95% CI, 1.66–3.89; P < .001). The estimated proportion receiving TB treatment within 2 days of diagnosis was 75% (95% CI, 0.64–0.86) in the FAST cohort compared to 30% (95% CI, 0.2–0.43) in the historical cohort.

Analyzing the entire period from hospital admission to the start of TB treatment, time to event was shorter under the FAST strategy (HR, 2.11; 95% CI, 1.39–3.21; P < .001) (Fig. 2). Overall, 44 (58.7%) patients in the FAST cohort and 22 (28.9%) in the historical cohort received indicated treatment during hospitalization (OR, 3.48; 95% CI, 1.77–6.85; P < .001). The FAST cohort patients also experienced fewer days from admission to initiation of indicated treatment (HR, 2.81; 95% CI, 1.67–4.73; P = .001). Furthermore, the time to discharge was shorter in the FAST cohort than in the historical control (HR, 1.38; 95% CI, 0.99–1.91; P = .058).

Fig. 2. FAST decreases time from hospital admission to start of tuberculosis treatment.

Discussion

During FAST implementation at a general hospital in Lima, Peru, patients with pulmonary TB were more likely to start TB treatment during hospitalization and experience shorter time from admission to treatment than a cohort of historical patients hospitalized prior to FAST implementation. Our findings extend the accumulating body of evidence linking FAST to decreased time to TB treatment by demonstrating that the strategy can accelerate care outside of the specialized TB hospital. Reference Le, Nguyen and Tran27,Reference Sani, Mustapha and Jumoke30

Our study uniquely assessed how FAST could be used to enhance indicated treatment, that is, a regimen tailored to DST results and following local guidelines. This distinction is pertinent because prompt delivery of effective treatment based on DST is paramount to interrupting TB transmission. Reference Riley, Mills and Nyka23,Reference Riley, Mills, O’Grady, Sultan, Wittstadt and Shivpuri24 Rapid DST also allows scarce isolation facilities to be prioritized for patients with DR-TB. These effects are particularly important in settings like Peru, where empiric first-line TB therapy cannot be assumed to be effective in newly diagnosed patients given the high prevalence of DR-TB. 1,Reference Barrera, Livchits and Nardell20

Universal TB screening during routine care for all hospitalized patients is a key intervention in high TB–incidence settings. In 41 months at HNHU, under the FAST strategy >67,000 patients were screened for symptoms. Screening took place primarily in the emergency department, where the risk for TB transmission is high. Reference Escombe, Huaroto and Ticona31 HNHU serves a much broader population of patients than the chest or TB hospitals where FAST was previously pilot tested. Reference Nathavitharana, Daru and Barrera32 Nevertheless, the number of detected cases at HNHU corresponds to an extremely high TB prevalence: nearly 2,400 of 100,000 symptomatic individuals and >6,000 of 100,000 among those with symptoms who consented to participate. This burden of TB disease is comparable to that found in prisons and other institutional settings in which routine screening for active disease is recommended to reduce transmission and improve outcomes. 33

The FAST screening protocol at HNHU evolved over the course of the study. The final iteration queried patients about any duration of cough and/or other risk factors for TB. Emerging data, however, demonstrate that TB in asymptomatic patients may also contribute to transmission. Reference Herdman, Tovar and Wingfield34 Future research should examine the feasibility and performance characteristics of a FAST strategy that starts with a chest radiograph (irrespective of symptoms) to identify additional individuals with transmissible TB disease.

Xpert testing provided rapid and highly sensitive information about the presence of Mycobacterium tuberculosis. The increased sensitivity of Xpert testing led to the diagnosis of TB in 26 FAST patients (35%) in whom smear microscopy was negative. Xpert testing was also likely a prime factor in decreasing the overall time to TB treatment initiation, as has been demonstrated in other settings. Reference Ershova, Volchenkov and Somova35

The use of Xpert testing as part of the FAST strategy additionally led to the identification of 18 patients (24%) with RR/MDR-TB in the prospective cohort relative to only 4 (5.3%) with MDR-TB in the historical cohort. There was no reported secular increase in the prevalence of MDR-TB between these contiguous study periods. It is more likely that some patients with RR/MDR-TB were missed in the historical cohort because sensitive, rapid DST was not widely performed. In settings with a high prevalence of RR/MDR-TB, universal Xpert testing for all patients being evaluated for pulmonary TB should be the standard of care to reduce missed RR/MDR-TB diagnoses.

Relative to the historical controls, a higher percentage of patients with pulmonary TB in the FAST cohort received the indicated treatment within 2 days of diagnosis. Although GenoType was used for DST in nearly 60% of the historical cohort, it was not performed in real time; samples were batch-processed, thereby prolonging the interval to results. In contrast, under the FAST strategy, regimens were was informed by near real-time Xpert (and GenoType) results. Thus, it was possible to avoid empiric treatment and to promptly start regimens informed by results from rifampin (and isoniazid) resistance testing. The 2-day benchmark for indicated treatment should be achievable for most patients hospitalized with TB, even for those with DR-TB, given the advent of rapid molecular tests like Xpert to guide regimen composition (especially with development of cartridges that test resistance to isoniazid and fluoroquinolones, as well as rifampin). We suggest treatment initiation within 2 days as a minimum target for patients hospitalized with TB. Future efforts should try to reduce that time even further.

Shortening the time to treatment for patients with TB is critical to decreasing TB transmission by reducing the duration of infectiousness. Reference Nathavitharana, Lederer, Tierney and Nardell36 In settings with a high burden of MDR-TB, increasing the speed of effective treatment for MDR-TB can lead to decreased transmission of MDR-TB, as previously demonstrated in a FAST pilot test in Russia. Reference Miller, Livchits and Ahmad Khan37 In future research, we will assess the effect of FAST on TB transmission in hospital workers at HNHU.

Although the FAST strategy is conceptually straightforward, successful implementation depends on overcoming practical barriers to coordinated care in a complex hospital environment. The use of trained FAST assistants to facilitate the TB care cascade likely helped to overcome these barriers at HNHU. One potential mechanism may have been the expedited transfer of sputum samples to the laboratory and communication of diagnostic testing results to clinicians. Additionally, FAST assistants referred patients to HNHU physicians for consideration of therapy; if necessary, they also moved medications from the pharmacy to the ward to ensure that treatment was started as soon as possible. We expect that FAST can be adapted to local environments by training existing staff with modest additional inputs from healthcare systems. FAST implementation outside the study conditions has been demonstrated in TB hospitals in Bangladesh and Russia. Reference Nathavitharana, Daru and Barrera32,Reference Miller, Livchits and Ahmad Khan37

Our study has several limitations. First, comparing FAST patients to a historical cohort potentially introduces selection bias. Because the historical cohort comprised only patients with positive smear microscopy, we may have underestimated the impact of FAST. If patients with smear-negative TB were included in the historical control, time to TB diagnosis and treatment would likely have been longer because these relied on batched GenoType or mycobacterial culture. Second, the relatively short inclusion period for the historical cohort precluded detection of seasonal variations or other time trend effects. Third, 1,888 eligible patients (60.4%) opted not to participate. Their inclusion would have more than doubled the number of patients tested and/or treated and might have overwhelmed the system, diluting the effects of the FAST implementation. It is also possible, however, that the benefits of the FAST strategy might be more pronounced with a larger intervention sample size. Notably, if the FAST strategy became routine, it would not require consent and participation would be universal, potentially leading to benefits for more patients in the form of faster time to TB diagnosis and treatment.

In conclusion, FAST improves the likelihood and speed of DST-informed treatment for patients hospitalized with TB. This impact is important for TB transmission control because it reduces the time during which hospital transmission can occur. Reference Nathavitharana, Lederer, Tierney and Nardell36 Faster TB treatment also represents a measurable improvement in quality of care for patients, meeting an urgent need in countries with a high burden of TB. Reference Cazabon, Alsdurf and Satyanarayana38 Broader roll out of the FAST strategy in general hospitals in TB-endemic settings should be considered as part of a comprehensive TB transmission control approach that includes environmental controls and personal protective equipment, making these facilities safer for visitors, staff and patients.

Acknowledgments

Financial support

This study was supported by the National Institutes for Health (grant no. NIH R01AI112748-01A1).

Conflicts of interest

All authors report no conflicts of interest relevant to this article.

Footnotes

a

Authors of equal contribution.

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Figure 0

Fig. 1. (A) Flowchart for prospective FAST cohort at Hospital Nacional Hipolito Unanue in Lima, Peru. Note. TB, tuberculosis.

Figure 1

Fig. 1. (B) Flowchart for historical cohort at Hospital Nacional Hipolito Unanue in Lima, Peru. Note. AFB, acid-fast bacilli; TB, tuberculosis.

Figure 2

Table 1. Diagnostic Testing Utilization and Results During FAST Implementation Compared to Historical Controls

Figure 3

Table 2. Median Time to TB Care Cascade Event at Hospital National Hipolito Unanuea

Figure 4

Fig. 2. FAST decreases time from hospital admission to start of tuberculosis treatment.