The Challenge of Tuberculosis in the 21st Century page 105

12 Kendall EA, Shrestha S, Dowdy DW. The epidemiological importance of subclinical tuberculosis. A critical reappraisal. Am J Respir Crit Care Med 2021 203: 168–174. 13 Uplekar M, Weil D, Lonnroth K, et al. WHO’s new End TB Strategy. Lancet 2015 385: 1799–1801. 14 Ortiz-Brizuela E, Menzies D. Tuberculosis active case-finding: looking for cases in all the right places? Lancet Public Health 2021 6: e261–e262. 15 Graham SM, Cuevas LE, Jean-Philippe P, et al. Clinical case definitions for classification of intrathoracic tuberculosis in children: an update. Clinical Infectious Diseases 2015 61: Suppl. 3, S179–S187. 16 WHO. WHO Consolidated Guidelines on Tuberculosis: Module 5: Management of Tuberculosis in Children and Adolescents. Geneva, WHO, 2022. 17 Frija G, Blažić I, Frush DP, et al. How to improve access to medical imaging in low- and middle-income countries? EClinicalMedicine 2021 38: 101034. 18 Pedrazzoli D, Lalli M, Boccia D, et al. Can tuberculosis patients in resource-constrained settings afford chest radiography? Eur Respir J 2017 49: 1601877. 19 Pande T, Pai M, Khan FA, et al. Use of chest radiography in the 22 highest tuberculosis burden countries. Eur Respir J 2015 46: 1816–1819. 20 Yadav H, Shah D, Sayed S, et al. Availability of essential diagnostics in ten low-income and middle-income countries: results from national health facility surveys. Lancet Glob Health 2021 9: e1553–e1560. 21 Hanson C, Osberg M, Brown J, et al. Finding the missing patients with tuberculosis: lessons learned from patient-pathway analyses in 5 countries. J Infect Dis 2017 216: Suppl. 7, S686–S695. 22 Fleming KA, Horton S, Wilson ML, et al. The Lancet Commission on diagnostics: transforming access to diagnostics. Lancet 2021 398: 1997–2050. 23 WHO. WHO Consolidated Guidelines on Tuberculosis: Module 1: Prevention – Tuberculosis Preventive Treatment. Geneva, WHO, 2020. 24 Ou X, Chen X, Xu X, et al. Recent development in X-ray imaging technology: future and challenges. Research (Wash D C) 2021 2021: 9892152. 25 Bansal GJ. Digital radiography. A comparison with modern conventional imaging. Postgrad Med J 2006 82: 425–428. 26 Hewitt PJ. Occupational health problems in processing of X-ray photographic films. Ann Occup Hyg 1993 37: 287–295. 27 Takashima Y, Suganuma N, Sakurazawa H, et al. A flat-panel detector digital radiography and a storage phosphor computed radiography: screening for pneumoconioses. J Occup Health 2007 49: 39–45. 28 Jha Y, Kik S, Ruhwald M. Digital Chest Radiography and Computer-Aided Detection (CAD) Solutions for Tuberculosis Diagnostics, Technology Landscape Analysis. Geneva, Foundation for Innovative New Diagnostics (FIND), 2021. 29 WHO. Portable Digital Radiography System: Technical Specifications. Geneva, WHO, 2021. 30 Centers for Disease Control and Prevention (CDC). ALARA – As Low As Reasonably Achievable. www.cdc.gov/ nceh/radiation/alara.html#:∼:text=ALARA/%20stands%20for%20%E2%80%9Cas%20low,time%2C%20distance% 2C%20and%20shielding Date last accessed: 29 June 2023. Date last updated: 17 May 2022. 31 Ministerio de Salud. Minsa lanza Plan de detección de casos de TB por radiografía de tórax y pruebas moleculares para Lima Metropolitana. www.gob.pe/institucion/minsa/noticias/594787-minsa-lanza-plan-de- deteccion-de-casos-de-tb-por-radiografia-de-torax-y-pruebas-moleculares-para-lima-metropolitana Date last accessed: 29 June 2023. Date last updated: 24 March 2022. 32 Vo LNQ, Codlin A, Ngo TD, et al. Early evaluation of an ultra-portable X-ray system for tuberculosis active case finding. Trop Med Infect Dis 2021 6: 163. 33 Stop TB Partnership. Ultra-portable Digital X-ray Systems: the Introducing New Tools Project (iNTP). www. stoptb.org/introducing-new-tools-project/ultra-portable-digital-x-ray-systems Date last accessed: 29 June 2023. 34 Stop TB Partnership. September 2022: Diagnostics, Medical Devices &Other Health Products Catalog: Global Drug Facility (GDF). Geneva, Stop TB Partnership, 2022. 35 Stop TB Partnership. Screening and Triage for TB using Computer-Aided Detection (CAD) Technology and Ultra-portable X-ray Systems: a Practical Guide. Geneva, Stop TB Partnership, 2021. 36 Qin ZZ, Naheyan T, Ruhwald M, et al. A new resource on artificial intelligence powered computer automated detection software products for tuberculosis programmes and implementers. Tuberculosis 2021 127: 102049. 37 Your Europe. CE Marking. https://europa.eu/youreurope/business/product-requirements/labels-markings/ce-marking/ index_en.htm Date last accessed: 29 June 2023. Date last updated: 8 May 2022. 38 Stop TB Partnership/FIND. AI Products for TB. www.ai4hlth.org/ Date last accessed: 29 June 2023. 39 Meskó B, Görög M. A short guide for medical professionals in the era of artificial intelligence. NPJ Digital Medicine 2020 3: 126. 40 Qin ZZ, Ahmed S, Sarker MS, et al. Tuberculosis detection from chest X-rays for triaging in a high tuberculosis- burden setting: an evaluation of five artificial intelligence algorithms. Lancet Digit Health 2021 3: e543–e554. 41 WHO. Determining the Local Calibration of Computer-assisted Detection (CAD) Thresholds and Other Parameters: a Toolkit to Support the Effective Use of CAD for TB Screening. Geneva, WHO, 2021. https://doi.org/10.1183/2312508X.10024322 87 IMAGING AND DIAGNOSIS |J. BIGIO ET AL.

Previous Page Next Page

The Challenge of Tuberculosis in the 21st Century Page 105 (105 of 312)

The Challenge of Tuberculosis in the 21st Century resources

Help