Top

Published in:

01-02-2021 | Tuberculosis | Chest

Deep learning–based automated detection algorithm for active pulmonary tuberculosis on chest radiographs: diagnostic performance in systematic screening of asymptomatic individuals

Authors: Jong Hyuk Lee, Sunggyun Park, Eui Jin Hwang, Jin Mo Goo, Woo Young Lee, Sangho Lee, Hyungjin Kim, Jason R. Andrews, Chang Min Park

Published in: European Radiology | Issue 2/2021

Abstract

Objectives

Performance of deep learning–based automated detection (DLAD) algorithms in systematic screening for active pulmonary tuberculosis is unknown. We aimed to validate DLAD algorithm for detection of active pulmonary tuberculosis and any radiologically identifiable relevant abnormality on chest radiographs (CRs) in this setting.

Methods

We performed out-of-sample testing of a pre-trained DLAD algorithm, using CRs from 19.686 asymptomatic individuals (ages, 21.3 ± 1.9 years) as part of systematic screening for tuberculosis between January 2013 and July 2018. Area under the receiver operating characteristic curves (AUC) for diagnosis of tuberculosis and any relevant abnormalities were measured. Accuracy measures including sensitivities, specificities, positive predictive values (PPVs), and negative predictive values (NPVs) were calculated at pre-defined operating thresholds (high sensitivity threshold, 0.16; high specificity threshold, 0.46).

Results

All five CRs from four individuals with active pulmonary tuberculosis were correctly classified as having abnormal findings by DLAD with specificities of 0.959 and 0.997, PPVs of 0.006 and 0.068, and NPVs of both 1.000 at high sensitivity and high specificity thresholds, respectively. With high specificity thresholds, DLAD showed comparable diagnostic measures with the pooled radiologists (p values > 0.05). For the radiologically identifiable relevant abnormality (n = 28), DLAD showed an AUC value of 0.967 (95% confidence interval, 0.938–0.996) with sensitivities of 0.821 and 0.679, specificities of 0.960 and 0.997, PPVs of 0.028 and 0.257, and NPVs of both 0.999 at high sensitivity and high specificity thresholds, respectively.

Conclusions

In systematic screening for tuberculosis in a low-prevalence setting, DLAD algorithm demonstrated excellent diagnostic performance, comparable with the radiologists in the detection of active pulmonary tuberculosis.

Key Points

• Deep learning–based automated detection algorithm detected all chest radiographs with active pulmonary tuberculosis with high specificities and negative predictive values in systematic screening.

• Deep learning–based automated detection algorithm had comparable diagnostic measures with the radiologists for detection of active pulmonary tuberculosis on chest radiographs.

• For the detection of radiologically identifiable relevant abnormalities on chest radiographs, deep learning–based automated detection algorithm showed excellent diagnostic performance in systematic screening.

World Health Organization (2019) Global tuberculosis repot 2019. World Health Organization, Geneva. Available via https://www.who.int/tb/publications/global_report/en/. Accessed 12 Feb 2020

World Health Organization (2016) Chest radiography in tuberculosis detection: summary of current WHO recommendations and guidance on programmatic approaches. World Health Organization, Geneva Available via https://www.who.int/tb/publications/chest-radiography/en/. Accessed 12 Feb 2020

World Health Organization (2013) Systematic screening for active tuberculosis: principles and recommendations. World Health Organization, Geneva Available via https://www.who.int/tb/tbscreening/en/. Accessed 12 Feb 2020

World Health Organization (2011) Early detection of tuberculosis: an overview of approaches, guidelines and tools. World Health Organization, Geneva Available via https://apps.who.int/iris/handle/10665/70824. Accessed 12 Feb 2020

World Health Organization (2015) The global plan to stop TB, 2016-2020. World Health Organization, Geneva. Available via http://www.stoptb.org/global/plan/plan2/. Accessed 12 Feb 2020

World Health Organization (2010) Public-private mix for TB care and control. World Health Organization, Geneva Available via https://www.who.int/tb/publications/tb-publicprivate-toolkit/en/. Accessed 12 Feb 2020

Yoon C, Dowdy DW, Esmail H, MacPherson P, Schumacher SG (2019) Screening for tuberculosis: time to move beyond symptoms. Lancet Respir Med 7:202–204CrossRef

Dara M, Solovic I, Sotgiu G et al (2016) Tuberculosis care among refugees arriving in Europe: a ERS/WHO Europe Region survey of current practices. Eur Respir J 48:808–817CrossRef

Melendez J, Sánchez CI, Philipsen RH et al (2016) An automated tuberculosis screening strategy combining X-ray-based computer-aided detection and clinical information. Sci Rep 6:25265CrossRef

10.

Pande T, Cohen C, Pai M, Ahmad Khan F (2016) Computer-aided detection of pulmonary tuberculosis on digital chest radiographs: a systematic review. Int J Tuberc Lung Dis 20:1226–1230CrossRef

11.

Hogeweg L, Mol C, de Jong PA, Dawson R, Ayles H, van Ginneken B (2010) Fusion of local and global detection systems to detect tuberculosis in chest radiographs. Med Image Comput Comput Assist Interv 13:650–657PubMed

12.

Rahman MT, Codlin AJ, Rahman MM et al (2017) An evaluation of automated chest radiography reading software for tuberculosis screening among public-and private-sector patients. Eur Respir J 49:1602159CrossRef

13.

Jaeger S, Karargyris A, Candemir S et al (2014) Automatic tuberculosis screening using chest radiographs. IEEE Trans Med Imaging 33:233–245CrossRef

14.

Nam JG, Park S, Hwang EJ et al (2018) Development and validation of deep learning–based automatic detection algorithm for malignant pulmonary nodules on chest radiographs. Radiology 290:218–228CrossRef

15.

Hwang EJ, Park S, Jin K-N et al (2019) Development and validation of a deep learning-based automatic detection algorithm for active pulmonary tuberculosis on chest radiographs. Clin Infect Dis 69:739–747CrossRef

16.

Hwang EJ, Park S, Jin K-N et al (2019) Development and validation of a deep learning-based automated detection algorithm for major thoracic diseases on chest radiographs. JAMA Netw Open 2:3191095CrossRef

17.

Qin ZZ, Sander MS, Rai B et al (2019) Using artificial intelligence to read chest radiographs for tuberculosis detection: a multi-site evaluation of the diagnostic accuracy of three deep learning systems. Sci Rep 9:15000CrossRef

18.

Go U, Park M, Kim U-N et al (2018) Tuberculosis prevention and care in Korea: evolution of policy and practice. J Clin Tuberc Other Mycobact Dis 11:28–36CrossRef

19.

(2000) Diagnostic Standards and Classification of Tuberculosis in Adults and Children. This official statement of the American Thoracic Society and the Centers for Disease Control and Prevention was adopted by the ATS Board of Directors, July 1999. This statement was endorsed by the Council of the Infectious Disease Society of America, September 1999. Am J Respir Crit Care Med 161:1376–1395

20.

Skoura E, Zumla A, Bomanji J (2015) Imaging in tuberculosis. Int J Infect Dis 32:87–93CrossRef

21.

Geng E, Kreiswirth B, Burzynski J, Schluger NW (2005) Clinical and radiographic correlates of primary and reactivation tuberculosis: a molecular epidemiology study. JAMA 293:2740–2745CrossRef

22.

Moskowitz CS, Pepe MS (2006) Comparing the predictive values of diagnostic tests: sample size and analysis for paired study designs. Clin Trials 3:272–279CrossRef

23.

Lakhani P, Sundaram B (2017) Deep learning at chest radiography: automated classification of pulmonary tuberculosis by using convolutional neural networks. Radiology 284:574–582CrossRef

24.

Philipsen R, Sánchez C, Maduskar P et al (2015) Automated chest-radiography as a triage for Xpert testing in resource-constrained settings: a prospective study of diagnostic accuracy and costs. Sci Rep 5:12215CrossRef

25.

Ting DSW, Tan T-E, Lim C (2019) Development and validation of a deep learning system for detection of active pulmonary tuberculosis on chest radiographs: clinical and technical considerations. Clin Infect Dis 69:748–750CrossRef

26.

Park SH (2019) Diagnostic case-control versus diagnostic cohort studies for clinical validation of artificial intelligence algorithm performance. Radiology 290:272–372CrossRef

27.

Ting DS, Yi PH, Hui F (2018) Clinical applicability of deep learning system in detecting tuberculosis with chest radiography. Radiology 286:729–731CrossRef

28.

Park SH, Han K (2018) Methodologic guide for evaluating clinical performance and effect of artificial intelligence technology for medical diagnosis and prediction. Radiology 286:800–809CrossRef

29.

Rutjes AW, Reitsma JB, Vandenbroucke JP, Glas AS, Bossuyt PM (2005) Case–control and two-gate designs in diagnostic accuracy studies. Clin Chem 126:1777–1782

30.

LoBue PA, Moser KS (2004) Screening of immigrants and refugees for pulmonary tuberculosis in San Diego County, California. Chest 126:1777–1782CrossRef

31.

Wang PD, Lin RS (2000) Tuberculosis transmission in the family. J Infect 41:249–251CrossRef

32.

Ross J, Reid K, Jamieson A (1977) Pulmonary tuberculosis in the common hostel population. Update 7:167–174

33.

Den Boon S, Verver S, Lombard C et al (2008) Comparison of symptoms and treatment outcomes between actively and passively detected tuberculosis cases: the additional value of active case finding. Epidemiol Infect 136:1342–1349CrossRef

34.

Eang MT, Satha P, Yadav RP et al (2012) Early detection of tuberculosis through community-based active case finding in Cambodia. BMC Public Health 12:469CrossRef

35.

Santha T, Renu G, Frieden T et al (2003) Are community surveys to detect tuberculosis in high prevalence areas useful? Results of a comparative study from Tiruvallur District, South India. Int J Tuberc Lung Dis 7:258–265PubMed

36.

Parikh R, Mathai A, Parikh S, Sekhar GC, Thomas R (2008) Understanding and using sensitivity, specificity and predictive values. Indian J Ophthalmol 56:45–50CrossRef

Title: Deep learning–based automated detection algorithm for active pulmonary tuberculosis on chest radiographs: diagnostic performance in systematic screening of asymptomatic individuals
Authors: Jong Hyuk Lee
Sunggyun Park
Eui Jin Hwang
Jin Mo Goo
Woo Young Lee
Sangho Lee
Hyungjin Kim
Jason R. Andrews
Chang Min Park
Publication date: 01-02-2021
Publisher: Springer Berlin Heidelberg
Keywords: Tuberculosis
Tuberculosis
Published in: European Radiology / Issue 2/2021
Print ISSN: 0938-7994
Electronic ISSN: 1432-1084
DOI: https://doi.org/10.1007/s00330-020-07219-4

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Deep learning–based automated detection algorithm for active pulmonary tuberculosis on chest radiographs: diagnostic performance in systematic screening of asymptomatic individuals

Abstract

Objectives

Methods

Results

Conclusions

Key Points

Keynote webinar | Spotlight on medication adherence

Springer Medicine

Abstract

Objectives

Methods

Results

Conclusions

Key Points

Please log in to get access to this content

Other articles of this Issue 2/2021

Multiparametric functional MRI and 18F-FDG-PET for survival prediction in patients with head and neck squamous cell carcinoma treated with (chemo)radiation

Positive predictive value for malignancy of uncertain malignant potential (B3) breast lesions diagnosed on vacuum-assisted biopsy (VAB): is surgical excision still recommended?

Application of Liver Imaging Reporting and Data System version 2018 ancillary features to upgrade from LR-4 to LR-5 on gadoxetic acid–enhanced MRI

Radiomics in predicting treatment response in non-small-cell lung cancer: current status, challenges and future perspectives

Involvement of radiologists in oncologic multidisciplinary team meetings: an international survey by the European Society of Oncologic Imaging

Diffusion kurtosis imaging in evaluating gliomas: different region of interest selection methods on time efficiency, measurement repeatability, and diagnostic ability