IMMUNE MECHANISMS UNDERLYING OCCUPATIONAL BRONCHOPULMONARY DISEASES DUE TO DUST.

The review summarizes contemporary literature data on mechanisms of immune respose to development of occupational lung diseases due to dust. Experimental data are compared to results of clinical examinations of workers engaged into main occupations of coal extracting industry. The authors demonstrate universal pathogenetic immune mechanisms underlying formation of lung diseases due to dust, and specific reactions associated with duration of antigen intake by the body.

1. Andrienko L.A., Peskov S.A., Smirnova E.L. State of cellular and humoral immunity in occupational dust exposure. J of Siberian Medical Sciences. 2014; 1: 36–42 (in Russian).

2. Babanov S.A., Budash D.S. Immune system state and diagnosis in lung diseases due to dust. In: Topical problems of pulmonology in working populations — innovations and prospects: Materials of Russian scientific and practical conference. Novosibirsk, 2017: 7–14 (in Russian).

3. Panev N.I. Immune inflammatory mechanisms and endothelial dysfuction in atherosclerosis development in miners with lung diseases due to dust. Med. immunologiya. 2017; 19: 416 (in Russian).

4. Shpagina L.A., Poteryaeva E.L., Kotova O.S., Shpagin I.S., Smirnova E.L. Topical problems of pulmonology in contemporary occupational therapy clinic. Med. truda i prom. ekol. 2015; 9: 11–4 (in Russian).

5. Boeva S.S. Features of certain immunity links disorders in pneumoconiosis and their correction in experiments. Vestnik neotlozhnoj i vosstanovitelnoj med. 2009; 10; 4: 469–71 (in Russian).

6. Gazizov O.M. Immunologic parameters in miners with upper respiratory tract diseases. In: V.V. Zaharenkov, ed. Topical problems of occupational medicine: Materials of XL Inter-regional scientific and practical conference with international participation. Novokuzneck. 2005: 47–9 (in Russian)

7. Zhestkov A.V. Immune diagnosis of lung diseases due to dust. Immunopatologiya, allergologiya, infektologiya. 2000; 1: 63–7 (in Russian).

8. Pavlovskaya N.A., Rushkevich O.P. Biomarkers for early diagnosis of miners’ exposure to coal dust consequences. Med. truda i prom. ekol. 2012; 9: 36–42 (in Russian).

9. Zaharenkov V.V., Kazickaya A.S., Mihajlova N.N., Romanenko D.V., Zhdanova N.N., Zhukova A.G. Influence of occupational hazards on immune state. Med. truda i prom. ekol. 2017; 12: 19–23 (in Russian).

10. Kosarev V.V., Zhestkov A.V., Babanov S.A., Kosov A.I. Clinical and functional features of occupational pulmonary diseases caused by exposure to low-fibrogenic occupational aerosols. Pulmonologiya 2008; 4: 56–61 (in Russian)

11. Panev N.I., Zaharenkov V.V., Ambrosova M.O., Korotenko O.Yu., Erdeeva S.V., Surzhikova G.S. On relationships between immune reactivity, cytokine state and ventilation disorders in patients with respiratory diseases due to dust. Materials of III Russian congress of occupational therapists. Novosibirsk; 2008: 416–7 (in Russian)

12. Piktushanskaya T.E. Features of formation and course of pneumoconiosis in miners of East Donbass nowadays. Med. truda i prom. ekol., 2014; 2: 10–14 (in Russian).

13. Izmerov N.F., Dueva L.A., Milishnikova V.V. Immunologic aspects of contemporary types of pneumoconiosis. Med. truda i prom. ekol. 2000; 6: 1–6 (in Russian).

14. Perić I., Arar D., Barisić I., Goić-Barisić I., Pavlov N., Tocilj J. Dynamics of the lung function in asbestos pleural disease. Arh. Hig. Rada Toksikol. 2007; 58 (4): 407–12.

15. Haitov P.M. Physiology of immune system. Rossijskij fiziologicheskij zhurnal im. Sechenova. 2000; 86(3): 252–67 (in Russian).

16. Kazickaya A.S., Ulanova E.V., Fomenko D.V. Experimental search of biochemical markers for early diagnosis of occupational diseases. Vestnik Kuzbasskoj gosudarstvennoj pedagogicheskoj akademii. 2013; 1 (26): 50–5 (in Russian).

17. Dahlgren C., Karlsson A. Respiratory burst in human neutrophils. J. Immunol. Methods. 1999; 232 (1–2): 3–14.

18. Martin T.R., Frevert C.W. Innate immunity in the lungs. Proceedings of the American Thoracic Society. 2005; 2 (5): 403–11.

19. Velichkovskij B.T. Pathogenesis and classification of pneumoconioses. Med. truda i prom. ekol. 2003; 7: 8–13 (in Russian).

20. Marchand-Adam S., Guillon F., Brauner M., Valeyre D. Chronic beryllium disease: a model of interaction between environmental exposure and genetic predisposition. Pathogenesis and clinical features (Part 2). Rev. Mal. Respir. 2005; 22: 271–87.

21. Kazickaya A.S., Zhukova A.G., Bugaeva M.S., Zhdanova N.N. Relationship of lipid profile and immune state in dynamics of long exposure to coal stock dust (experimental studies). Medicina v Kuzbasse. 2017; 4: 12–8 (in Russian)

22. Arcangeli G., Cupelli V., Giuliano G. Effects of silica on human lung fibroblast in culture. Sci. Total Environ. 2001; 270 (1–3): 135–9.

23. Gulumian M., Borm P.J., Vallyathan V., Castranova V., Donaldson K., Nelson G., et al. Mechanistically identified suitable biomarkers of exposure, effect, and susceptibility for silicosis and coal-worker’s pneumoconiosis: a comprehensive review. J. Toxicol. Environ. Health B. Crit. Rev. 2006; 9 (5): 357–95.

24. Fomenko D.V., Gorohova L.G., Panev N.I., Kazickaya A.S., Bondarev O.I. Clinical experimental studies of metabolic response to chronic exposure to coal stock dust. Med. truda i prom. ekol. 2011; 2: 15–21 (in Russian).

25. Averyanov A.V. Role of neutrophil elastase in pathogenesis of chronic obstructive lung disease. Citokiny i vospalenie. 2007; 6(4): 3–8 (in Russian).

26. Pinegin B.V., Karsonova M.I. Macrophages: properties and functions. Immunologiya. 2009; 30(4): 241–49 (in Russian).

27. Fomina B.C., Kuzmina L.P. Evaluation of matrix metalloproteinases (PRO-MMP–1, MMP–2,8) and their inhibitor (TIMP–1) contents in patients with occupational pulmonary diseases. Med. truda i prom. ekol. 2010; 7: 29–33 (in Russian).

28. Hou Z., Ye Q. Immunomodulatory effects of regulatory T cells in the lung fibrosis. Zhonghua Lao Dong Wei Sheng Zhi Ye Bing Za Zhi. 2015; 33 (3): 237–40.

29. Poteryaeva O.N. Matrix metalloproteinases: structure, regulation, role in development of pathologic states (review of literature). J of Siberian Medical Sciences. 2010; 5: 7–17 (in Russian).

30. Foronjy R.F., Okada Y., Cole R., D’Armiento J. Progressive adult-onset emphysema in transgenic mice expressing human MMP–1 in the lung. Am. J. Physiol. Lung Cell Mol. Physiol. 2003; 284; 5: 727–37.

31. Visse R., Nagase H. Matrix metalloproteinases and tissue inhibitors of metalloproteinases: structure, function, and biochemistry. Circulation Res. 2003; 92 (8): 827–39.

32. Shojhet Ya.N., Korenovskij Yu.V., Motin Yu.G., Lepilov A.V., Lel N.V. Role of matrix metalloproteinases in inflammatory diseases of lungs. Problemy klinicheskoj mediciny. 2008; 3 (15): 99–101 (in Russian).

33. Gipson T.S., Bless N.M., Shanley T.P., Crouch L.D., Bleavins M.R., Younkin E.M. et al. Regulatory effects of endogenous protease inhibitors in acute lung inflammatory injury. J. Immunol. 1999; 162 (6): 3653–62.

34. Kogan E.A., Tyung F.V., Demura S.A. Mechanism of lung tissue remodelling in progressive idiopathic pulmonary fibrosis. Arhiv patologii. 2010; 72(4): 30–6 (in Russian).

35. Churg A., Wright J.L. Proteases and emphysema. Curr. Opin. Pulm. Med. 2005; 11 (2): 153–9.

36. Ushatikova O.N., Kuzmina L.P., Gorblyanskij Yu.Yu. Contribution of occupational factors into development of atherogenic dyslipoproteinemias in coal miners. Med. truda i prom. ekol. 2006; 12: 11–7 (in Russian).

37. Fubini B., Hubbard A. Reactive oxygen species (ROS) and reactive nitrogen species (RNS) generation by silica in inflammation and fibrosis. Free Radic. Biol. Med. 2003; 34 (12): 1507–16.