Mapping the Distribution of Detected Cases in the Region with a Low Tuberculosis Incidence Rate

Introduction: A decrease in the incidence of tuberculosis (TB) in the regions of the Russian Federation is accompanied by spatial heterogeneity in the distribution of detected TB cases in their municipal districts, which requires optimization of planning annual periodic health examinations aimed at early detection of TB in the population.

Objective: To establish spatial distribution of detected tuberculosis cases in the municipal districts of the Kaluga Region.

Materials and methods: We used data from Rosstat report forms Nos. 8 and 30 for 2019–2023, QGIS 3.36.1, and Statistica software to map the spatial distribution of detected TB cases. The correlation coefficient (r) and the Fisher’s exact test were used for the analysis. The differences were regarded as statistically significant at p < 0.05.

Results: We identified the Northern and the Southern Clusters comprising 459 detected TB cases in the Kaluga Region, the former including 75 % of the patients. The density of TB cases in the Northern Cluster per square kilometer was 4 times higher than in the Southern Cluster. Tuberculosis case detection rates in the Northern Cluster were 71.7 %, 78.8 %, and 79 % in the years 2021, 2022, and 2023, respectively, which indicated a higher risk of TB spread among the population living in this territory.

Conclusion: The cluster analysis of spatial distribution of newly detected TB cases across municipal districts of the constituent entities of the Russian Federation allows timely measures to be taken to optimize scheduling of annual tuberculosis screening among the population.

1. Morozko NP, Alekseeva AA. Research and analysis of TB incidence in the Russian Federation. Meridian. 2022;(1(63)):27–29. (In Russ.)

2. Balashova LA, Shalaev AG, Zhmakin IA, Kolyadinskaya AV. Preventive work and the incidence of tuberculosis in the population of the Tver region for the period from 2014 to 2019. Tverskoy Meditsinskiy Zhurnal. 2021;(5):67–74. (In Russ.)

3. Tsvetkov AI, Cherniaev IA, Nozhkina NV, Drobot AG. Tuberculosis trends in the Sverdlovsk Region. Zdorov'e Naseleniya i Sreda Obitaniya. 2023;31(10):18–27. (In Russ.) doi: 10.35627/2219-5238/2023-31-10-18-27

4. Golubova TN, Makhkamova ZR, Tkachenko IYu. Territorial differentiation of the tuberculosis morbidity and mortality trend in the Republic of Crimea. Byulleten' Fiziologii i Patologii Dykhaniya. 2017;(66):22–28. (In Russ.) doi: 10.12737/article_5a1f7019efb6c1.83634772

5. Geltser BI, Shakhgeldyan KI, Krivelevich EB, Medvedev VI, Ermolitskaya MZ. Certain approaches to efficiency evaluation of the regional TB services. Tuberkulez i Bolezni Legkikh. 2017;95(12):28–34. (In Russ.) doi: 10.21292/2075-1230-2017-95-12-28-34

6. Markelov YuM, Schegoleva LV. Evaluation of clinical and economic efficiency and impact of mass fluorography screening on tuberculosis epidemiological rates in four federal districts of the Russian Federation with different levels of population coverage with mass fluorography screening. Tuberkulez i Bolezni Legkikh. 2023;101(1):8-16. (In Russ.) doi: 10.58838/2075-12302023-101-1-8-16

7. Zubova NА. Effectiveness of mass preventive examinations in subjects of the Russian Federation with low morbidity rates of tuberculosis. Sotsial'nye Aspekty Zdorov'ya Naseleniya. 2016;(4(50)):8. (In Russ.)

8. Romanyukha AA, Karkach AS, Borisov SE, Belilovsky EM, Sannikova TE, Krivorotko OI. Small-scale stable clusters of elevated tuberculosis incidence in Moscow, 2000–2015: Discovery and spatiotemporal analysis. Int J Infect Dis. 2020;91:156-161. doi: 10.1016/j.ijid.2019.11.015

9. Tsybikova EB, Zubova NA. Efficiency evaluation of regular mass screening aimed at tuberculosis detection. Tuberkulez i Bolezni Legkikh. 2016;94(4):13-19. (In Russ.) doi: 10.21292/2075-1230-2016-94-4-13-19

10. Efimov EI, Nikitin PN, Ershov VI, Rabikova TF. Development and usage of geoinformational technologies in the sphere of antiepidemic practice. Aims, tasks, methods, results. Meditsinskiy Al'manakh. 2009;(2(7)):43-47. (In Russ.)

11. Henry NJ, Zawedde-Muyanja S, Majwala RK, et al. Mapping TB incidence across districts in Uganda to inform health program activities. IJTLD Open. 2024;1(5):223-229. doi: 10.5588/ijtldopen.23.0624

12. Territorial body of the Federal State Statistics Service (Kalugastat). Accessed November 21, 2024. https:// rosstat.gov.ru/dbscripts/munst/munst29/DBInet.cgi

13. Lapshina IS, Tsybikova EB, Kotlovskiy MYu. Groups at high risk of developing respiratory tuberculosis among adult population of Kaluga Oblast. Tuberkulez i Bolezni Legkikh. 2022;100(11):20-28. (In Russ.) doi: 10.21292/2075-1230-2022-100-11-20-28

14. Gupta RK, Lule SA, Krutikov M, et al. Screening for tuberculosis among high-risk groups attending London emergency departments: A prospective observational study. Eur Respir J. 2021;57(6):2003831. doi: 10.1183/13993003.03831-2020

15. Rastoder E, Shaker SB, Naqibullah M, et al. Chest x-ray findings in tuberculosis patients identified by passive and active case finding: A retrospective study. J Clin Tuberc Other Mycobact Dis. 2019;14:26-30. doi: 10.1016/j.jctube.2019.01.003

16. Bogorodskaya EM, Slogotskaya LV, Tuktarova LM, Oganezova GS, Musatkina NV, Litvinova NV. Screening for tuberculosis infection in risk groups in the adult population of Moscow. Tuberkulez i Bolezni Legkikh. 2023;101(4):13-21. (In Russ.) doi: 10.58838/2075-1230-2023-101-4-13-21

17. Yazdani-Charati J, Siamian H, Kazemnejad A, Mohammad V. Spatial clustering of tuberculosis incidence in the North of Iran. Glob J Health Sci. 2014;6(6):288-294. doi: 10.5539/gjhs.v6n6p288

18. Parreira PL, Fonseca AU, Soares F, Conte MB, Rabahi MF. Chest X-ray evaluation using machine learning to support the early diagnosis of pulmonary TB. Int J Tuberc Lung Dis. 2024;28(4):171-175. doi: 10.5588/ijtld.23.0230

19. Chakaya J, Petersen E, Nantanda R, et al. The WHO Global Tuberculosis 2021 Report – not so good news and turning the tide back to End TB. Int J Infect Dis. 2022;124(Suppl 1): S26–S29. doi: 10.1016/j.ijid.2022.03.011

20. Savelyev VN, Kasimova VR, Okhotnikova EA, Islamova AA, Noskova AS. Conducting preventive examinations and health examinations to reduce the incidence of tuberculosis. Aktual'nye Issledovaniya. 2022;(49-1(128)):77–80. (In Russ.)

21. Harries AD, Nair D, Thekkur P, et al. TB preventive therapy: Uptake and time to initiation during implementation of ‘7–1–7’. IJTLD Open. 2024;1(4):189-191. doi: 10.5588/ijtldopen.24.0101