Полимодальные эффекты тиотропия бромида в терапии хронической обструктивной болезни легких

Мхолинолитик длительного действия тиотропия бромид относится к лекарственным средствам первого выбора для пациентов с хронической обструктивной болезнью легких (ХОБЛ). Высокая эффективность тиотропия бромида в лечении больных ХОБЛ основана не только на блокировании парасимпатической холинергической бронхоконстрикции, но связана с его полимодальными эффектами не нейрональной природы. По результатам исследований последних лет доказана полимодальность тиотропия бромида, обусловленная его влиянием на Мрецепторопосредованные внутриклеточные сигнальные системы, участвующие в регуляции клеточномолекулярных взаимодействий, вовлеченных в процессы воспаления, пролиферации и ремоделинга легочных структур. Противовоспалительный, антипролиферативный, антиремоделирующий, противовирусный, антиоксидантный эффекты тиотропия бромида в сочетании с новым усовершенствованным устройством для его доставки (Респимат) определяют его преимущества перед другими длительно действующими антихонергическими препаратами и делают терапию пациентов с ХОБЛ более эффективной и безопасной.

1. Global initiative for chronic obstructive lung disease. Global strategy for the diagnosis, management, and prevention of chronic obstructive pulmonary disease. Update 2014. www.goldcopd.com

2. Wessler I., Kirkpatrick C.J. Acetylcholine beyond neurons: the nonneuronal cholinergic system in humans. Br. J. Pharmacol. 2008; 154 (8): 1558–1571.

3. Gosens R., Zaagsma J., Meurs H., Halayko A. Muscarinic receptor signaling in the pathophysiology of asthma and COPD. Respir. Res. 2006; 7: 73.

4. Alagha K., Palot A., Sofalvi T. et al. Longacting muscarinic receptor antagonists for the treatment of chronic airway diseases. Ther. Adv. Chronic. Dis. 2014; 5 (2): 85–98.

5. Ikeda T., Anisuzzaman A.S.M., Yoshiki H. et al. Regional quantification of muscarinic acetylcholine receptors and badrenoceptors in human airways. Br. J. Pharmacol. 2012; 166: 1804–1814.

6. Bateman E.D., Rennard S., Barnes P.J. et al. Alternative mechanisms for tiotropium. Pulm. Pharmacol. Ther. 2009; 22 (6): 533–542.

7. Celli B., ZuWallack R., Wang S., Kesten S. Improvement in resting inspiratory capacity and hyperinflation with tiotropium in COPD patients with increased static lung volumes. Chest. 2003; 124 (5): 1743–1748.

8. O’Donnell D.E., Fluge T., Gerken F. et al. Effects of tiotropium on lung hyperinflation, dyspnoea and exercise tolerance in COPD. Eur. Resp. J. 2004; 23 (6): 832–840.

9. Buels K.S., Fryer A.D. Muscarinic receptor antagonists: effects on pulmonary function. Handb. Exp. Pharmacol. 2012; 208: 317–341.

10. Tashkin D.P., Celli B., Senn S. et al. A 4year trial of tiotropium in chronic obstructive pulmonary disease. N. Engl. J. Med. 2008; 359 (15): 1543–1554.

11. Celli B., Decramer M., Leimer I. et al. Cardiovascular safety of tiotropium in patients with COPD. Chest. 2010; 137 (1): 20–30.

12. Авдеев С.Н. Вопросы сердечнососудистой безопасности длительной терапии тиотропием пациентов с ХОБЛ. Consilium Medicum. 2012; 14 (3): 34–39. / Avdeev S.N. Issued of cardiovascular safety of longterm therapy with tiotropium in COPD patients. Consilium Medicum. 2012; 14 (3): 34–39 (in Russian).

13. Barnes P.J. Cellular and molecular mechanisms of chronic obstructive pulmonary disease. Clin. Chest Med. 2014; 35 (1): 71–86.

14. Wise R.A., Anzueto A., Cotton D. et al. Tiotropium Respimat inhaler and the risk of death in COPD. N. Engl. J. Med. 2013; 369 (16): 1491–501.

15. Karakiulakis G., Roth M. Muscarinic receptors and their antagonists in COPD: antiinflammatory and antiremodeling effects. Mediators Inflamm. 2012; 2012: 409580.

16. Pieper M.P. The nonneuronal cholinergic system as novel drug target in the airways. Life Sci. 2012; 91 (21–22): 1113–1118.

17. Meurs H., Dekkers B.G., Maarsingh H. et al. Muscarinic receptors on airway mesenchymal cells: novel findings for an ancient target. Pulm. Pharmacol. Ther. 2013; 26 (1): 145–155.

18. Koarai A., Traves S.L., Fenwick P.S. et al. Expression of muscarinic receptors by human macrophages. Eur. Respir. J. 2012; 39 (3): 698–704.

19. Moffatt J.D., Cocks T.M., Page C.P. Role of the epithelium and acetylcholine in mediating the contraction to 5hydrox ytryptamine in the mouse isolated trachea. Br. J. Pharmacol. 2004; 141 (7): 1159–1166.

20. Kistemaker L.E., Oenema T.A., Meurs H., Gosens R. Regulation of airway inflammation and remodeling by muscarinic receptors: perspectives on anticholinergic therapy in asthma and COPD. Life Sci. 2012; 91 (21–22): 1126–1133.

21. Xu Z.P., Devillier P., Xu G.N. et al. TNFαinduced CXCL8 production by A549 cells: involvement of the nonneuronal cholinergic system. Pharmacol. Res. 2013; 68 (1): 16–23.

22. Profita M., Giorgi R.D., Sala A. et al. Muscarinic receptors, leukotriene B4 production and neutrophilic inflammation in COPD patients. Allergy. 2005; 60: 1361–1369.

23. Елшин Н.Д., Чухловин А.Б., Кузубова Н.А., Титова О.Н. Определение экспрессии генов CHRM3 и ADRB2 в лейкоцитах крови в процессе комплексного лечения хронической обструктивной болезни легких. / Мультидисциплинарные аспекты молекулярной медицины. СПб: Издательство Санкт'Петербургского государственного экономического университета; 2015: 71–72. / Elshin N.D., Chukhlovin A.B., Kuzubova N.A., Titova O.N. CHRM3 and ADRB2 gene expression in blood leukocytes during treatment of chronic obstructive pulmonary disease. / Multidisciplinary aspects of molecular medicine. SaintPetersburg: Izdatel'stvo Sankt'Peterburgskogo gosudarstvennogo ekonomicheskogo universiteta; 2015: 71–72 (in Russian).

24. Zhang L., Cheng Z., Liu W., Wu K. Expression of interleukin (IL)10, IL17A and IL22 in serum and sputum of stable chronic obstructive pulmonary disease patients. COPD. 2013; 10 (4): 459–465.

25. Profita M., Albano G.D., Riccobono L. et al. Increased levels of Th17 cells are associated with nonneuronal acetyl choline in COPD patients. Immunobiology. 2014; 219 (5):392–401.

26. Xu Z.P., Song Y., Yang K. et al. M3 mAChRmediated IL8 expression through PKC/NFκB signaling pathways. Inflamm. Res. 2014; 63 (6): 463–473.

27. Kolahian S., Shahbazfar A.A., TayefiNasrabadi H. et al. Tiotropium effects on airway inflammatory events in the catas an animal model for acute cigarette smokeinduced lung inflammation. Exp. Lung Res. 2014; 40 (6): 272–287.

28. Bühling F., Lieder N., Kühlmann U.C. et al. Tiotropium suppresses acetylcholineinduced release of chemotactic mediators in vitro. Respir. Med. 2007; 101 (11): 2386–2394.

29. Vacca G., Randerath W.J., Gillissen A. Inhibition of granulocyte migration by tiotropium bromide. Respir. Res. 2011; 12 (1): 24–29.

30. Santus P., Buccellati C., Centanni S. et al. Bronchodilators modulate inflammation in chronic obstructive pulmonary disease subjects. Pharmacol. Res. 2012; 66 (4): 343–348.

31. Yamaya M., Nishimura H., Hatachi Y. et al. Inhibitory effects of tiotropium on rhinovirus infection in human air way epithelial cells. Eur. Respir. J. 2012; 40 (1): 122–132.

32. van Koppen C.J., Kaiser B. Regulation of muscarinic acetylcholine receptor signaling. Pharmacol. Ther. 2003; 98 (2): 197–220.

33. Oenema T.A., Kolahian S., Nanninga J.E. et al. Proinflammatory mechanisms of muscarinic receptor stimulation in airway smooth muscle. Respir. Res. 2010; 11: article 130.

34. Suzaki I., Asano K., Shikama Y. et al. Suppression of IL8 production from airway cells by tiotropium bromide in vitro. Int. J. Chron. Obstruct. Pulm. Dis. 2011; 6: 439–448.

35. Profita M., Bonanno A., Montalbano A.M. et al. Cigarette smoke extract activates human bronchial epithelial cells affecting nonneuronal cholinergic system signalling in vitro. Life Sci. 2011; 89 (1–2): 36–43.

36. Profita M., Albano G.D., Montalbano A.M. et al. Acetylcholine leads to signal transducer and activator of transcription 1 (STAT1) mediated oxidative / nitrosative stress in human bronchial epithelial cell line. Biochim. Biophys. Acta. 2013; 1832 (12): 1949–1958.

37. Holownia A., Mroz R.M., Wielgat P. et al. Altered histone deacetylase activity and iNOS expression in cells isolated from induced sputum of COPD patients treated with tiotropium. Adv. Exp. Med. Biol. 2013; 788: 1–6.

38. Holownia A., Mroz R.M., Skopinski T. et al. Tiotropium increases PPAR? and decreases CREB in cells isolated from induced sputum of COPD patients. Adv. Exp. Med. Biol. 2013; 756: 9–14.

39. Kistemarker L.E., Gosens R. Acetylcholine beyond bronchoconstriction: roles in inflammation and remodeling. Trends Pharmacol. Sci. 2015; 36 (3): 164–171.

40. Pera T., Zuidhof A., Valadas J. et al. Tiotropium inhibits pulmonary inflammation and remodelling in a guinea pigmodel of COPD. Eur. Respir. J. 2011; 38 (4): 789–796.

41. Arai N., Kondo M., Izumo T. et al. Inhibition of neutrophil elastaseinduced goblet cell metaplasia by tiotropium in mice. Eur. Respir. J. 2010; 35 (5): 1164–1171.

42. Gosens R., Bos I.S., Zaagsma J., Meurs H. Protective effects of tiotropium bromide in the progression of airway smooth muscle remodeling. Am. J. Respir. Crit. Care Med. 2005; 171 (10): 1096–1102.

43. Asano K., Shikama Y., Shoji N. et al. Tiotropium bromide inhibits TGFβinduced MMP production from lung fibroblasts by interfering with Smad and MAPK pathways in vitro. Int. J. Chron. Obsrtruct. Pulm. Dis. 2010; 5: 277–286.

44. Кузубова Н.А., Федин А.Н., Лебедева Е.С., Платонова И.С. Влияние различных вариантов терапии на сокращение бронхов крыс с моделированной обструктивной болезнью легких. Российский физиологический журнал им. И.М.Сеченова. 2014; 100 (9): 1049–1058. / Kuzubova N.A., Fedin A.N., Lebedeva E.S., Platonova I.S. Effects of different treatments on bronchial constriction in rat models of obstructive lung disease. Rossiyskiy fiziologicheskiy zhurnal im. I.M.Sechenova. 2014; 100 (9): 1049– 1058 (in Russian).

45. Birrell M.A., Bonvini S.J., Dubuis E. et al. Tiotropium modulates transient receptor potential V1 (TRPV1) in air way sensory nerves: A beneficial offtarget effect? J. Allergy Clin. Immunol. 2014; 133 (3): 679–687.e9.

46. Laube B.L., Janssens H.M., de Jongh F.H. et al. What the pulmonary specialist should know about the new inhalation therapies. Eur. Respir. J. 2011; 37 (6): 1308–1331.

47. Malmberg L.P., Rytilä P., Happonen P., Haahtela T. Inspiratory flows through dry powder inhaler in chronic obstructive pulmonary disease: age and gender rather than severity matters. Int. J. Chron. Obstruct. Pulm. Dis. 2010; 5: 257–262.

48. Архипов В.В., Абросимов А.Г., Архипова Д.Е. Спирива Респимат – новое направление в лечении ХОБЛ. Русский медицинский журнал. 2013; 7: 379–383. / Arkhipov V.V., Abrosimov A.G., Arkhipova D.E. Spiriva Respimat is a novel approach to therapy of COPD. Russkiy meditsinskiy zhurnal. 2013; 7: 379–383 (in Russian).

49. Barczok M., Perleberg C., Kardos P., Hodder R. Presented at VIII Deutsches Aerosol Therapie Seminar, Marburg, Germany, November 2003. http://experts.respimat.com/presentation_kit/patient_preference.html

50. van Noord J.A., Cornelissen P.J., Aumann J.L. et al. The efficacy of tiotropium administered via Respimat Soft Mist Inhaler or HandiHaler in COPD patients. Respir. Med. 2009; 103 (1): 22–29.