Thrombocyte aggregation activity in the conditions of intensive light deprivation
https://doi.org/10.15372/SSMJ20200303
Abstract
The aim of the research was to study the effect of photoperiodism disturbances on platelet aggregation activity. Material and methods. The experiment was conducted in two stages in 5 groups of male rats: the control group and four experimental groups. At the first stage, the animals were exposed to 24 h/day continuous light (24L:0D) for 10 and 21 days. In the second stage, animals after 10 and 21 days of round-the-clock lighting were returned to natural lighting for a period of 21 days to study the reversibility of changes. Animals were withdrawn from the experiment by intramuscular injection based on body weight of drugs for anesthesia (telazol, xylanite). Blood sampling was performed by puncture of the right heart. The functional activity of platelets was determined no later than 3 hours after the collection of blood. Results and discussion. The results of the experiment indicate a direct effect of light desynchronosis on the increase in platelet aggregation ability, while it was noted that the degree of increase in aggregation activity and reversibility of changes directly depend on the duration of round-the-clock lighting. So, a 10-day stay of animals in conditions of abnormal lighting leads to an increase in aggregation indices, which remain at a high level even when animals return to normal conditions. In animals that were under round-the-clock illumination for 21 days, a more pronounced increase in platelet aggregation values relative to animals on day 10 was noted. In this regard, it can be argued that circadian rhythm disturbances provoke the development of microvasculature disorders.
Supporting agencies: Authors thank the administration of the Saratov State Medical University n.a. VI Razumovsky for providing the basis for research.
About the Authors
V. F. Kirichuk
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Vyacheslav F. Kirichuk, doctor of medical sciences, professor
410012, Saratov, Bolshaya Kazachia str., 112
V. M. Romanova
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Vera M. Romanova
410012, Saratov, Bolshaya Kazachia str., 112
O. V. Zlobina
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Olga V. Zlobina, candidate of medical sciences, professor
410012, Saratov, Bolshaya Kazachia str., 112
I. O. Bugaeva
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Irina O. Bugaeva, doctor of medical sciences, professor
410012, Saratov, Bolshaya Kazachia str., 112
A. Yu. Karetnikova
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Alena Yu. Karetnikova
410012, Saratov, Bolshaya Kazachia str., 112
E. S. Terekhina
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Elena S. Terekhina
410012, Saratov, Bolshaya Kazachia str., 112
N. V. Shlyapnikov
Saratov State Medical University n.a. V.I. Razumovsky
Russian Federation
Russian Federation
Nikita V. Shlyapnikov
410012, Saratov, Bolshaya Kazachia str., 112
References
1. Ежов С.Н., Ящук А.В., Кравцов С.В. Влияние десинхронизирующих эффектов трансмеридианных перелетов на циркадианный ритм терморегуляции. Физ. культура, спорт – наука и практика. 2018; (2): 80–87. @@ Ezhov S.N., Yashchuk A.V., Kravtsov S.V. The effect of the desynchronizing effects of transmeridian hops on the circadian rhythm of thermoregulation. Fizicheskaya kul’tura, sport – nauka i praktika = Physical Culture, Sport – Science and Practice. 2018; (2): 80–87. [In Russian].
2. Лихтенштейн Л.З., Томилова С.В. Анализ медицинских аспектов эффективности проведения профосмотров работающих вахтовым методом на Севере Тюменской области. Тюмен. мед. журн. 2015; 17 (2): 34–37. @@ Likhtenshtein L.Z., Tomilova S.V. Analysis of medical aspects of the effectiveness of professional examinations working on a rotational basis in the North of the Tyumen region. Tyumenskiy meditsinskiy zhurnal = Tyumen Medical Journal. 2015; 17 (2): 34–37. [In Russian].
3. Иванов А.Н. Реакция тромбоцитов на электромагнитное излучение частотой молекулярного спектра излучения и поглощения оксида азота. Тромбоз, гемостаз и реология. 2006; (3): 51–57. @@ Ivanov A.N. Platelets reaction on electromagnetic radiation at frequency waves of nitric oxide. Tromboz, gemostaz i reologiya = Thrombosis, Hemostasis and Rheology. 2006; (3): 51–57. [In Russian].
4. Костенко Е.В., Маневич Т.М., Разумов Н.А. Десинхроноз как один из важнейших факторов возникновения и развития цереброваскулярных заболеваний. Лечеб. дело. 2013; 17 (2): 104–116. @@ Kostenko E.V., Manevich T.M., Razumov N.A. Desynchronosis as one of the most important factors in the occurrence and development of cerebrovascular diseases. Lechebnoye delo = Med. Care. 2013; 17 (2): 104–116. [In Russian].
5. Киричук В.Ф., Злобина О.В., Иванов А.Н., Антонова В.М. Функциональная активность тромбоцитов в условиях нарушенного фотопериода. Рос. физиол. журн. 2019; 105 (9): 1171–1178. doi: 10.1134/S0869813919090073 @@ Kirichuk V.F., Zlobina O.V., Ivanov A.N., Antonova V.M. Functional activity of platelets in a disturbed photoperiod. Rossiyskiy fiziologicheskiy zhurnal imeni Ivana Mikhaylovicha Sechenova = Russian Journal of Physiology. 2019; 105 (9): 1171–1178. doi: 10.1134/S0869813919090073. [In Russian].
6. Снежицкий В.А., Побиванцева Н.Ф. Циркадианные ритмы в кардиологической практике. Журн. Гродненск. гос. мед. ун-та. 2013; (1): 9–13. @@ Snezhitskii V.A., Pobivantseva N.F. Circadian rhythms in cardiology practice. Zhurnal Grodnenskogo gosudarstvennogo meditsinskogo universiteta = Journal of the Grodno State Medical University. 2013; (1): 9–13. [In Russian].
7. Фатеева Н.М., Арефьева А.В., Глухих Т.А. Состояние гемодинамики человека в условиях производственной деятельности на Крайнем Севере. Здоровье и образование в XXI в. 2016; 18 (1): 237–239. @@ Fateeva N.M., Aref’eva A.V., Glukhikh T.A. The state of human hemodynamics in conditions of production activity in the Far North. Zdorov’ye i obrazovaniye v XXI veke = Health and Education in the 21st Century. 2016; 18 (1): 237–239. [In Russian].
8. Бондарчук Ю.А., Алексеева О.В., Шахматов И.И., Лебедева Ю.Б., Медведева Е.Ю. Состояние системы гемостаза крыс с разным уровнем двигательной активности после витального стресса. Тромбоз, гемостаз и реология. 2019; 3 (79): 72–80. doi: 10.25555/THR.2019.3.0893 @@ Bondarchuk Yu.A., Alekseeva O.V., Shakhmatov I.I., Lebedeva Yu.B., Medvedeva E.Yu. The state of the hemostatic system of rats with different levels of motor activity after vital stress. Tromboz, gemostaz i reologiya = Thrombosis, Hemostasis and Rheology. 2019; 3 (79): 72–80. [In Russian]. doi: 10.25555/THR.2019.3.0893
9. Журкин К.И., Злобина О.В., Иванов А.Н., Бугаева И.О. Изменения микроциркуляции и гемокоагуляции при экспериментальном световом десинхронозе. Тромбоз, гемостаз и реология. 2016; 3 (67): 164–166. @@ Zhurkin K.I., Zlobina O.V., Ivanov A.N., Bugaeva I.O. Changes in microcirculation and blood coagulation during experimental light desynchronosis. Tromboz, gemostaz i reologiya = Thrombosis, Hemostasis and Rheology. 2016; 3 (67): 164–166. [In Russian].
10. Nordoy A., Odegaard A. E. The influence of citrate and heparin on the adhesiveness of rat platelets and human platelets measured in vitro. Scand. J. Clin. Lab. Invest. Suppl. 1963; 15 (4): 399–404. doi:10.3109/00365516309079762
11. Габбасов З.А., Попов Е.Г., Гаврилов И.Ю., Позин Е.Я., Маркосян Р.А. Новый высокочувствительный метод анализа агрегации тромбоцитов. Лаб. дело. 1989; (10): 15–18. @@ Gabbasov Z.A., Popov E.G., Gavrilov I.Yu., Pozin E.Ya., Markosyan R.A. A new highly sensitive platelet aggregation assay. Laboratornoe delo = Laboratory Business. 1989; (10): 15–18. [In Russian].
12. Нестерова М.В. Мелатонин – адаптоген с мультимодальными возможностями. Мед. совет. 2015; (18): 50–53. @@ Nesterova M.V. Melatonin – adaptogen with multimodal capabilities. Meditsinskiy sovet = Medical Council. 2015; (18): 50–53. [In Russian].
13. Арушанян Э.Б. Влияние мелатонина на тромбоцитарный гемостаз и его циркадную организацию. Экспер. и клин. фармакология. 2013; 76 (5): 32–36. doi: 10.30906/0869-2092-2013-76-5-32-36 @@ Arushanyan E.B. The effect of melatonin on platelet hemostasis and its circadian organization. Eksperimental’naya i klinicheskaya farmakologiya = Experimental and Clinical Pharmacology. 2013; 76 (5): 32–36. [In Russian]. doi: 10.30906/0869-2092-2013-76-5-32-36
14. Лазарева Е.Н., Галимзянов Х.М., Самотруева М.А. Влияние мелаксена на функциональную активность тромбоцитов в условиях экспериментальной гипо- и гиперагрегации. Биомедицина. 2015; (2): 55–61. @@ Lazareva E.N., Galimzyanov Kh.M., Samotrueva M.A. Influence of melaxen on the functional activity of platelets under experimental hypo and hyperaggregation. Biomeditsina = Biomedicine. 2015; (2): 55–61. [In Russian].
15. Лысенко А.С., Редькин Ю.В., Голевцова З.Ш. Мелатонин как элемент патогенетически обоснованной фармакокоррекции постравматических нарушений гемостаза. Омск. науч. вестн. 2003; (2): 164–166. @@ Lysenko A.S., Red’kin Yu.V., Golevtsova Z.Sh. Melatonin as an element of pathogenetically based pharmacocorrection of post-traumatic hemostasis disorders. Omskiy nauchnyy vestnik = Omsk Scientific Journal. 2003; (2): 164–166. [In Russian].
16. Рожкова Е.А., Турова Е.А., Рассулова М.А., Гозулов А.С., Сейфулла Р.Д. Механизмы развития лимитирующих физическую работоспособность нарушений гемодинамики в звене микроциркуляции. Вест. спорт. науки. 2013; (2): 25–30. @@ Rozhkova E.A., Turova E.A., Rassulova M.A., Gozulov A.S., Sejfulla R.D. Mechanisms of development of hemodynamic disorders limiting physical performance in the microcirculation link. Vestnik sportivnoy nauki = Sports Science Bulletin. 2013; (2): 25–30. [In Russian].
17. Муляр А.Г., Гасанов М.Т., Ющук Е.Н., Дунаева О.В., Авфукова Ю.С. Рецепторная регуляция активности тромбоцитов. Экспер. и клин. фармакология. 2004; 67 (1): 61–68. @@ Mulyar A.G., Gasanov M.T., Yushchuk E.N., Dunaeva O.V., Avfukova Yu.S. Receptor regulation ofplatelet activity. Eksperimental’naya i klinicheskaya farmakologiya = Experimental and Clinical Pharmacology. 2004; 67 (1): 61–68. [In Russian].
Review
For citations:
Kirichuk V.F., Romanova V.M., Zlobina O.V., Bugaeva I.O., Karetnikova A.Yu., Terekhina E.S., Shlyapnikov N.V. Thrombocyte aggregation activity in the conditions of intensive light deprivation. Сибирский научный медицинский журнал. 2020;40(3):21-27. (In Russ.) https://doi.org/10.15372/SSMJ20200303
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