Sport Physiology

Current Issue

By Issue

By Author

By Subject

Author Index

Keyword Index

About Journal

Aims and Scope

Editorial Board

Article Processing Charges (APC)

Indexing and Abstracting

Related Links

FAQ

Reviewers

Terms and conditions for manuscript submission

Submission Instruction

Forms

Peer Review Process

Can Diving Depth Affect Blood Hemostasis System Responses?

Document Type : Research Paper

Authors

1 Associate Professor of Sport Physiology, University of Mohaghegh Ardabili

2 Ph.D. Student of Sport Physiology, University of Tarbiat Modares

3 Ph.D. Student of Sport Physiology, University of Mohaghegh Ardabili

Abstract

The purpose of this study was to investigation of hemostasis system responses to entertainment open-sea air dive in depths of 9 and 18 meters. Twenty men diver with a mean age of 24.5 ± 3.2 years voluntarily participated in this study. In each diving session, 10 participants dive in depth of 9 meters and 10 others dive in depth of 18 meters, that their selection was randomly and they were changes together in the next session. Diving lasted for 30 minutes. Blood samples were taken immediately before and after the diving. To data analysis, t test was used. The results indicated that mean platelet count, PT and aPTT were reduced followed by diving in both depths of 9 and 18 meters (P ≥ 0.05). However, fibrinogen levels were increased after diving at both 9 m and 18 m depth and tissue plasminogen activator (tPA) activity only at 18 m depth compared to the baseline (P > 0.01). Also, after diving at the depth of 18 m, platelet count and PT were lower (P ≤ 0.05), and fibrinogen and tPA activity were higher than diving at 9 m depth (P < 0.01). It seems that open-sea air diving can disrupt hemostasis system, especially blood clotting system. In addition, diving depth and height of the decompression effect hemostatic responses.

Keywords

Main Subjects

References
  1. Bacon SL, Pelletier R, Lavoie KL. The impact of acute and chronic exercise on thrombosis in cardiovascular disease. Thromb Haemost. 2009;101:452–9.
  2. El-Sayed MS, Ali N, Ali ZE. Aggregation and activation of blood platelets in exercise and training. Sports Med. 2005;35:11–22.
  3. Sugawara J, Hayashi K, Kurachi S, Tanaka T, Yokoi T, Kurachi K, et al. Age-related effects of regular physical activity on hemostatic factors in men. J Thromb Thrombolysis. 2008;26:203–10.
  4. Peat E, Dawson M, Mckenzie A, Hillis W S. The effects of acute dynamic exercise on haemostasis in first class Scottish football referees. Brit J Sport Med. 2010;44(8):573-8.
  5. Perovic A, Dumic J. Recreational scuba diving: negative or positive effects of oxidative and cardiovascular stress. Biochem Med Metab B. 2014;24(2):235-47.
  6. Radziwon P, Olszanski R, Korsak J, siermontowski P. Factor XII–A Limitation for Divers. Pol J Envirun Stud. 2015;52(3):7-12.
  7. Tetzlaff K, Shank E S, Muth C M. Evaluation and management of decompression illness an intensivist’s perspective. Intens Care Med. 2003;29(12):2128-136.
  8. Papadopoulou V. Circulatory bubble dynamics. Physican Sportsmed. 2014;206:    239-49.
  9. Philp RB. A review of blood changes associated with compression-decompression: Relationship to decompression sickness. PubMed. 1974;1(2):117-50.
  10. Kawashima M, Tamura H, Noro Y, Takao K, Kitano M, Lehner C, et al. Pathogenesis and prevention of dysbaric osteonecrosis. Decompression Sickness in Divers. Kagashima Univ Res Center S Pac. 1995;25(6):37-46.
  11. Kawashima M, Tamura H, Nagayoshi I, Takao K, Yoshida K, Yamaqushi T, et al. Hyperbaric oxygen therapy in orthopedic conditions. UHM. 2004;31(1):155-62.
  12. Bosco G, Yang Z, Savini F, Nubile G. Environmental stress on diving-induced platelet activation. Undersea Hyperbar M. 2001;28(4):207-11.
  13. Radziwon P, Olszanski R, Tomaszewski R, lipska A, Dabrowiecki Z, orzeniewski P, et al. Decreased levels of PAI-1 and alpha 2-antiplasmin contribute to enhanced fibrinolytic activity in divers. Thromb Res. 2007;121(2):235-40.
  14. Olszanski R, Radziwon P, Galar M, Klos R, Kloczko J. Diving up to 60 m depth followed by decompression has no effect on pro-enzyme and total thrombin activatable fibrinolysis inhibitor antigen concentration. Blood coagul Fibrin. 2003;14(7):659-61.
  15. Lambrechts K, Balestra C, Theron M, Henckes A, Galinat H, Mignant F, et al. Venous gas emboli are involved in post-dive macro, but not microvascular dysfunction. Eur J Appl Physiol. 2017;117(2):335-44.
  16. Olszanski R, Radziwon P, Baj Z, Kaczmarek P, Giedrojc J, Galar M, et al. Changes in the extrinsic and intrinsic coagulation pathways in humans after decompression following saturation diving. Blood Coagul Fibrin. 2001;12(4):269-74.
  17. Baj Z, Olszanski R, Majewska E, konarski M. The effect of air and nitrox divings on platelet activation tested by flow cytometry. Aviat Space Envir Md. 2000;71(9):     925-8.
  18. Siahkouhian M, Khodadadi D, Bolboli L. Diurnal variation of haemostatic sponse to exercise in young sedentary males. Biol Sport. 2013;30(2):125-30.
  19. Dill DB, Costill DL. Calculation of percentage changes in volumes of blood, plasma, and red cells in dehydration. J Appl Phycol. 1974;37(2):247-8.
  20. Aldemir H, Kilic N. The effect of time of day and exercise on platelet functions and platelet–neutrophil aggregates in healthy male subjects. Mol Cell Bioch. 2005;280   (1-2):119-24.
  21. Peat E, Dawson M, Mckenzie A, Hillis W S. The effects of acute dynamic exercise on haemostasis in first class Scottish football referees. Brit J Sport Med. 2010;44(8):573-8.
  22. Pontier JM, Gempp E, Ignatescu M. Blood platelet-derived microparticles release and bubble formation after an open-sea air dive. Appl Physiol-Int Rev. 2012;37(5):       888-92.
  23. Boussuges A, Succo E, Juhan I, Sainty JM. Activation of coagulation in decompression illness. Aviat Space Envir Md. 1998;69(2):129-32.
  24. Goad R, Neuman T, Linaweaver P. Hematologic changes in man during decompression: Relations to overt decompression sickness and bubble scores. Aviat Space Envir Md. 1976;47(8):863-7.
  25. Kannel WB, Agostino RB, Belanger A, Sibershatz H, Tofler G. Long-term influence of fibrinogen on initial and recurrent cardiovascular events in men and women. Am J Cardiol. 1996;78(1):90-2.
  26. Cadroy Y, Pillard F, Sakariassen K, Thalamas C, Boneu B, Riviere D. Strenuous but not moderate exercise increases the thrombotic tendency in healthy sedentary male volunteers. J Appl Phycol. 2002;93(3):829-33.
  27. Lund T, Kvernmo H, Sterud B. Cellular activation in response to physical exercise: the effect of platelets and granulocytes on monocyte reactivity. Blood Coagul Fibrin.1998;9(1):63-70.
  28. Boldt L H, Fraszl W, Rocker J, Schefold J C, Steinach M,Noack T, et al. Changes in the haemostatic system after thermoneutral and hyperthermic water immersion. Eur J Appl Physiol. 2008;102(5):547-54.
  29. Hilberg T, Glaser D, Prasa D, Sturzebecher J, Gabrel HW. Pure eccentric exercise does not activate blood coagulation. Eur J Appl Physiol. 2005;94(6):718-21.
  30. Ikarugi H, Taka T, Nakajima S, Noguchi T, Watanabe S, Sasaki Y, et al. Norepinephrine, but not epinephrine, enhances platelet reactivity and coagulation after exercise in humans. J Appl Phycol. 1999;86(1):133-8.
Sport Physiology
Volume 11, Issue 41
April 2019
Pages 123-136
Files
History
  • Receive Date: 20 June 2017
  • Revise Date: 28 January 2018
  • Accept Date: 05 February 2018
Share
How to cite
Statistics