The erythrocyte сation transport in and the bronchodilating and bronchoprotective effects of inhaled furosemide in asthma

The work was aimed to investigate the erythrocyte cation transport in patients with asthma with respect to bronchial hyperreactivity on anisosmotic solutions and its correction using inhaled furosemide. Rubidium uptake by and Na+ loss from erythrocytes incubated in Rb-Mg2+ solution were determined with flame emission using Perkin-Elmer АА 306 spectrophotometer. Bronchial hyperreactivity was studied using challenge tests with inhaled distilled water and hypertonic saline solution (3.6 %). In a day after the challenge test the patients inhaled 1 % solution of furosemide (60 mg, 4 ml) followed by the repeated bronchial challenge test which was performed twice at 30-min interval. The 10 to 15 % increase in erythrocyte Na+ concentration was found. Na⁺ -K⁺ pump activity in the erythrocytes increased by 34–38 %. Na⁺-K⁺-2Cl-co-transport in erythrocytes was 60-65 % higher than in healthy donors and was significantly higher in patients with bronchial hyperreactivity compared with that of patients without bronchi hyperreactivity. Inhaled furosemide inhalation was found to improve bronchial airflow parameters such as FEV₁ and FEF₅₀. The data obtained revealed alteration of erythrocyte cation transport in asthma patients as well as bronchodilating and protective effects of inhaled furosemide.

1. Брюханов В.М., Зверев Я.Ф. Фармакология и клиническое использование экстра ренального действия диуретиков. М.: Мед. книга; Н. Новгород: Изд-во НГМА; 2000.

2. Брюханов В.М., Зверев Я.Ф. Ингаляционное применение диуретиков — новое лечение бронхообструктивного синдрома. Клин. фармакол. и тер. 2002; 11 (5): 57–64.

3. Веренинов А.А. и др. Применение пламенно-эмиссионного анализа для измерения потоков щелочных катионов через клеточную мембрану. Цитология 1982; 24 (1): 98–103.

4. Орлов С.Н., Баранова И.А., Покудин Н.И. и др. Транспорт одновалентных катионов и кальция в эритроцитах у больных бронхиальной астмой. Вестн. АМН СССР 1991; 3: 43–49.

5. Орлов С.Н., Баранова И.А., Чучалин А.Г. Внутриклеточные системы сигнализации и патологии легких. Транспорт ионов в клетках эпителия дыхательных путей. Пульмонология 1999; 1: 77–83.

6. Уразаев А.Х. Натрий-калий-хлорный котранспорт клеточной мембраны. Успехи физиол. наук 1998; 29 (2): 12–37.

7. Шклярова Б.С., Ватутин В.А., Прибылова Н.Н. и др. Опыт использования ингаляции фуросемидом в лечении больных бронхиальной астмой и хроническим бронхитом. В кн.: Человек и лекарство. М.: 1997.

8. Alton E., Kingsleigh0Smith D., Munkonge F. et al. Asthma prophylaxis agents alter the function of an airway epithelial chloride channel. Am. J. Respir. Cell. Mol. Biol. 1996; 14 (4): 380–387.

9. Boucher R.C. Human airway ion transport. Part 1. Am. J. Respir. Crit. Care Med. 1994; 150 (1): 271–281.

10. Boucher R.C. Human airway ion transport. Part 2. Am. J. Respir. Crit. Care Med. 1994; 150 (2): 581–593.

11. Nair A., Mungantiwar A., Kamal K., Safar M. Antiallergic potential of furosemide. Indian J. Exp. Biol. 1997; 35 (5): 466–469.

12. Pavord I.D., Dutt S., Carey O.Y. et al. Red blood cell sodium transport in asthma. Thorax 1990; 45 (10): 799.

13. Pendino J., Nannini L., Chapman K. et al. Effect of inhaled furosemide in acute asthma. J. Asthma 1998; 35 (1): 89–93.

14. Rusell M. John. Sodium-potassium-chloride cotransport. J. Physiol. Rev. 2000; 80 (1): 211–276.

15. Siffredi M., Mastropasqua B., Pelucchi A. et al. Effect of inhaled furosemide and cromolyn on bronchoconstriction induced by ultrasonically nebulized distilled water in asthmatic subjects. Ann. Allergy Asthma Immunol. 1997; 78: 238–243.