PROFESYONEL BADMİNTON OYUNCULARINDA DAYANIKLILIK TESTLERİNİN KAN PARAMETRELERİ ÜZERİNE ETKİSİ

Year 2025, Volume: 19 Issue: 2, 184 - 196, 31.08.2025

Ayşegül Yapıcı , Yunus Emre Bağış

https://doi.org/10.61962/bsd.1709117

Abstract

Egzersiz sırasında oluşan hemoreolojik ve mikrodolaşım parametrelerindeki değişiklikler ve bunların olası sonuçları son zamanlarda çok ilgi çekmektedir. Bu çalışmanın amacı, profesyonel erkek badminton oyuncularında Yo-Yo aralıklı toparlanma testi (YIRT1) öncesi, sonrası ve 24 saat sonrasında kan parametreleri üzerindeki değişiklikleri araştırmaktır. Bu çalışmaya 16 profesyonel erkek badminton oyuncusu gönüllü olarak katıldı. Toplam kan sayımları, eritrosit deformabilitesi ve agregasyonu, testten önce ve sonra ve testten 24 saat sonra alınan örneklerde değerlendirildi. Test sırasında toplam mesafe kaydedildi. Eritrosit deformabilitesi, 0.53, 0.95, 1.69, 3.00 ve 5.33 Pascal (Pa) altında değerlendirildi ve test sonunda anlamlı bir artış gösterdi (p<0.05). Testten sonra agregasyon indeksi artarken eritrosit birikimi anlamlı şekilde azaldı (p<0.05). Hematokrit seviyeleri, hemoglobin konsantrasyonları ve eritrosit sayıları testten hemen sonra anlamlı artışlar gösterdi (p<0.05), ancak bu değerler testten 24 saat sonra, ön test seviyelerine göre anlamlı şekilde daha düşüktü (p<0.05). Lökosit parametreleri test öncesi değerlere göre belirgin bir artış gösterdi (p<0.05). Trombosit sayıları test öncesi, test sonrası ve testten 24 saat sonra yapılan ölçümler arasında anlamlı farklılıklar gösterdi (p<0.05). Hemoreolojik değişiklikler egzersiz şiddetine paralel olarak artmakta ve egzersiz sonrasında da devam etmektedir. Oyuncuların fiziksel kapasiteleri hakkında bilgi veren YIRT1'in hemoreolojik parametreleri etkilediği bulunmuştur. Yapılacak diğer araştırmalarda farklı egzersiz prokollerinin olası etkileri için, hemoreolojik değişikliklerde hücresel faktörlerin (enzim, hormon, oksidan stres) rolleri dikkate alınarak incelenebilir.

Keywords

Badminton , Eritrosit deformabilitesi , Eritrosit agregasyonu , Tam kan sayımı

THE EFFECTS OF ENDURANCE TESTS ON BLOOD PARAMETERS IN PROFESSIONAL BADMINTON PLAYERS

Abstract

Changes in hemorheological and microcirculatory parameters that occur during exercise and their possible consequences have attracted much attention recently. The aim of this study was to investigate the changes in blood parameters before, after and 24 hours after the Yo-Yo intermittent recovery test (YIRT1) in level 1 professional male badminton players. Sixteen professional male badminton players voluntarily participated in this study. Total blood counts, erythrocyte deformability and aggregation were evaluated in samples taken prior to and following the test and 24h after the completion of the test. During the test, the total distance was recorded. Erythrocyte deformability, evaluated under shear stresses of 0.53, 0.95, 1.69, 3.00, and 5.33 Pascal (Pa), showed a significant increase at the end of the test (p<0.05). Following the test, the aggregation index rose while erythrocyte accumulation decreased significantly (p<0.05). Hematocrit levels, hemoglobin concentrations, and erythrocyte counts also demonstrated significant increases immediately after the test (p<0.05), but these values were significantly lower 24 hours post-test compared to pre-test levels (p<0.05). Leukocyte parameters exhibited a marked increase relative to pre-test values (p<0.05). Additionally, thrombocyte counts displayed significant differences between pre-test, post-test, and 24-hour post-test measurements (p<0.05). Hemorheological changes increase parallel with exercise intensity and it continues after the exercise. YIRT1, which provides information about the physical capacities of the players, was found to affect the hemorheological parameters. In further studies, the possible effects of different exercise protocols can be examined by taking into account the roles of cellular factors (enzymes, hormones, oxidant stress) in hemorheological changes.

Keywords

Badminton , Erythrocyte deformability , Erythrocyte aggregation , Total blood count

References

• 1. Brun JF., Varlet-Marie E., Connes P., Aloulou I. (2010). Hemorheological alterations related to training and overtraining. Biorheology. 47(2), 95-115. doi: 10.3233/BIR-2010-0563.
• 2. ⁠Mohandas N., Chasis JA., Shoet SB. (1993). The influence of membrane skeleton on red cell deformability, membrane material properties and shape. Seminars in Hematology. 20, 225-242.
• 3. Brun JF., Varlet-Marie E., Myzia J., Raynaud de Mauverger E., Pretorius E. (2021). Metabolic influences modulating erythrocyte deformability and eryptosis. Metabolites. 12(1), 4. doi: 10.3390/metabo12010004.
• 4. ⁠Gattner H., Adamiak J., Piotrowska A., Czerwińska-Ledwig O., Mętel S., Kępińska-Szyszkowska M., Pilch W. (2023). Effect of whole-body vibration training on hemorheological blood indices in young, healthy women. International Journal of Environmental Research and Public Health. 20(4), 3232. doi: 10.3390/ijerph20043232.
• 5. Tong SF., Nasrawi F., Fanari MP., Agosti R. (1995). Hemorheology during exercise: Is there a microcirculatory relationship? Biorheology. 32, 400.
• 6. Chien S. (1997). Red cell deformability and its relevance to blood flow. Annual Review of Physiology. 49, 177-192.
• 7. ⁠Nageswari K., Banerjee R., Gupte RV., Puniyani RR. (2000). Effects of exercise on rheological and microcirculatory parameters. Clinical Hemorheology and Microcirculation. 23(2-4), 243-247.
• 8. Convertino VA. (1991). Blood volume: Its adaptation to endurance training. Medicine & Science in Sports & Exercise. 23, 1338-1348.
• 9. Brun JF., Khaled S., Ranaud E., Bouix D., Micallef JP., Orsetti A. (1998). The triphasic effects of exercise on blood rheology: Which relevance to physiology and pathophysiology? Clinical Hemorheology and Microcirculation. 19, 89-104.
• 10. Varlet-Marie E., Gaudard A., Monnier JF., Micallef JP., Mercier J., Bressolle F., Brun JF. (2003). Reduction of red blood cell disaggregability during submaximal exercise: Relationship with fibrinogen levels. Clinical Hemorheology and Microcirculation. 28(3), 139-149.
• 11. El-Sayed MS., Ali N., El-Sayed AZ. (2005). Haemorheology in exercise and training. Sports Medicine. 35(8), 649-670. doi: 10.2165/00007256-200535080-00001.
• 12. Yang RF., Zhao CJ., Wu YP., Wu X. (1995). Deformability of erythrocytes after exercise. Biorheology. 32, 250.
• 13. ⁠Brun JF. (2002). Exercise hemorheology as three acts play with metabolic actors: Is it of clinical relevance? Clinical Hemorheology and Microcirculation. 26(3), 155-174.
• 14. El-Sayed MS. (1998). Effects of exercise and training on blood rheology. Sports Medicine. 26(5), 281-292. doi: 10.2165/00007256-199826050-00001.
• 15. Hughes MG. (1995). Physiological demands of training in elite badminton players. In: Reilly T., Hughes M., Lees A. (Eds.), Science and Racket Sports. London: E and FN Spon, 38-43.
• 16. Faccini P., Dal Monte A. (1996). Physiologic demands of badminton match play. American Journal of Sports Medicine. 24, 64-66.
• 17. ⁠Aloui G., Souhail H., Hayes LD., Bouhafs EG., Chelly MS., Schwesig R. (2021). The effects of loaded plyometrics and short sprints in U19 male soccer players in Tunisia. Applied Sciences. 11, 1-14. doi: 10.3390/app11010001.
• 18. ⁠McLellan CP., Lovell DI., Gass GC. (2011). The role of rate of force development on vertical jump performance. Journal of Strength and Conditioning Research. 25(2), 379-385. doi: 10.1519/JSC.0b013e3181bf3c9b.
• 19. ⁠Alizadeh R., Hovanloo F., Safania AM. (2010). The relationship between aerobic power and repeated sprint ability in young soccer players with different levels of VO2 max. Journal of Physical Education and Sport. 27(2), 85-92.
• 20. ⁠Castagna C., Manzi V., Rampini E., D’Ottavio S. (2008). The Yo-Yo intermittent recovery test in basketball players. Journal of Science and Medicine in Sport. 11, 202-208. doi: 10.1016/j.jsams.2007.02.001.
• 21. ⁠Boussetta N., Abedelmalek S., Aloui K., Souissi N. (2017). The effect of air pollution on diurnal variation of performance in anaerobic tests, cardiovascular and hematological parameters, and blood gases on soccer players following the Yo-Yo Intermittent Recovery Test Level-1. Chronobiology International. 34(7), 903-920. doi: 10.1080/07420528.2017.1325896.
• 22. Chaouachi A., Manzi V., Wong D., Chaalali A., Laurencelle L., Chamari K., Castagna C. (2010). Intermittent endurance and repeated sprint ability in soccer players. Journal of Strength and Conditioning Research. 24, 2663-2669. doi: 10.1519/JSC.0b013e3181e347f4.
• 23. ⁠Hermassi S., Schwesig R., Aloui G., Shephard RJ., Chelly MS. (2019). Effects of short-term in-season weightlifting training on the muscle strength, peak power, sprint performance, and ball throwing velocity of male handball players. Journal of Strength and Conditioning Research. 33(12), 3309-3321. doi: 10.1519/JSC.0000000000003068.
• 24. McLellan CP., Lovell DI., Gass GC. (2011). Biochemical and endocrine response to impact and collision during elite rugby league match play. Journal of Strength and Conditioning Research. 25, 1553-1562. doi: 10.1519/JSC.0b013e3181db9bdd.
• 25. Gerosa-Neto J., Rossi FE., Silva CB., Campos EZ., Fernandes RA., Freitas Júnior IF. (2014). Body composition analysis of athletes from the elite of Brazilian soccer players. Motricidade. 10(4), 105-110. doi: 10.6063/motricidade3567.
• 26. Gorla JI., Silva AA., Campos LF., Santos CF., Almeida JJ., Duarte E. (2017). Body composition and somatotypic profile of athletes from the Brazilian 5-a-side football team. Revista Brasileira de Ciências do Esporte. 39(1), 79-84. doi: 10.1016/j.rbce.2015.12.016.
• 27. Simmonds MJ., Connes P., Sabapathy S. (2013). Exercise-induced blood lactate increase does not change red blood cell deformability in cyclists. PLoS One. 8(8), e71219. doi: 10.1371/journal.pone.0071219.
• 28. Heidari N., Dortaj E., Karimi M., Karami S., Kordi N. (2016). The effects of acute high intensity interval exercise of judo on blood rheology factors. Turkish Journal of Kinesiology. 2, 6-10. doi: 10.3390/medsci5030015.
• 29. ⁠Krustrup P., Mohr M., Amstrup T., Rysgaard T., Johansen J., Steensberg A. (2003). The Yo-Yo intermittent recovery test: Physiological response, reliability, and validity. Medicine & Science in Sports & Exercise. 35, 697-705. doi: 10.1249/01.MSS.0000058441.94520.32.
• 30. Hardeman MR., Goedhart PT., Dobbe JGG., Lettinga KP. (1994). Laser-assisted optical rotational cell analyzer (LORCA): A new instrument for measurement of various structural hemorheological parameters. Clinical Hemorheology. 14, 605-618.
• 31. Baskurt OK., Meiselman HJ., Kayar E. (1998). Measurement of red blood cell aggregation in a “plate-plate” shearing system by analysis of light transmission. Clinical Hemorheology. 19, 307-314.
• 32. ⁠Baskurt OK., Yalcın O., Meiselman HJ., Armstrong JK. (2000). Standard aggregating media to test the “aggregability” of rat red blood cells. Clinical Hemorheology and Microcirculation. 22, 161-166.
• 33. Caimi G., Carlisi M., Presti RL. (2023). Red blood cell distribution width, erythrocyte indices, and elongation index at baseline in a group of trained subjects. Journal of Clinical Medicine. 13(1), 151. doi: 10.3390/jcm13010151.
• 34. Ammar A., Chtourou H., Trabelsi K., Padulo J., Turki M., El Abed K., Hoekelmann A., Hâkim A. (2015). Temporal specificity of training: Intra-day effects on biochemical responses and Olympic weightlifting performances. Journal of Sports Sciences. 33(4), 358-368. doi: 10.1080/02640414.2014.944559.
• 35. ⁠Andelkovic M., Baralić I., Đorđević B., Stevuljević JK., Radivojević N., Dikić N. (2015). Hematological and biochemical parameters in elite soccer players during a competitive half season. Journal of Medical Biochemistry. 34, 460-466. doi: 10.2478/jomb-2014-0057.
• 36. Ernst E., Marschall M. (1991). Reduced leukocyte filterability after acute physical stress. Clinical Hemorheology and Microcirculation. 11, 129-132.
• 37. ⁠Bouix D., Peyreigne C., Raynaud E., Micallef JP., Brun JF. (1998). Relationships among body composition, hemorheology and exercise performance. Clinical Hemorheology and Microcirculation. 19, 245-254.
• 38. Nageswari K., Banerjee R., Gupte RV., Puniyani RR. (2000). Effects of exercise on rheological and microcirculatory parameters. Clinical Hemorheology and Microcirculation. 23, 243-247.
• 39. Abe K., Haga S., Kato M., Nakatani T., Ikarugi H., Ushiyama Y., Togashi K. (1990). The work intensity of a badminton match in Japanese top female athletes. Bulletin of Institute of Health and Sports Sciences, University of Tsukuba. 12, 107-114.
• 40. ⁠Ghosh AK., Mazumdar P., Goswami A. (1990). Heart rate and blood lactate response in competitive badminton. American Journal of Sports Medicine. 5, 85.
• 41. ⁠Cabello D., Padial P., Lees A., Rivas F. (2004). Temporal and physiological characteristics of elite women’s and men’s single badminton. International Journal of Applied Sports Sciences. 16, 1-12.
• 42. Cabello D., Gonzalez-Badillo JJ. (2003). Analysis of the characteristics of competitive badminton. British Journal of Sports Medicine. 37, 62-66. doi: 10.1136/bjsm.37.1.62.
• 43. Faude O., Meyer T., Rosenberger F., Fries M., Huber G., Kindermann W. (2007). Physiological characteristics of badminton match play. European Journal of Applied Physiology. 100, 479-485. doi: 10.1007/s00421-007-0441-8.
• 44. ⁠Scott J., Dormandy TL. (1996). The autooxidation of human red cell lipids induced by hydrogen peroxide. British Journal of Haematology. 20, 95-111.
• 45. Achten J., Jeukendrup AE. (2003). Heart rate monitoring: Applications and limitations. Sports Medicine. 33(7), 517-538. doi: 10.2165/00007256-200333070-00004.
• 46. ⁠Cabello M., Gonzalez J. (2003). Analysis of the characteristics of competitive badminton. British Journal of Sports Medicine. 37(1), 62-66. doi: 10.1136/bjsm.37.1.62.
• 47. ⁠Perez CJ., Nemet D., Mills PJ. (2001). Effects of laboratory versus field exercise on leukocyte subsets and cell adhesion molecule expression in children. European Journal of Applied Physiology. 86, 34-39.
• 48. Wiik P., Opstad A., Boyum A. (1996). Granulocyte chemiluminescence response to serum opsonized particles ex vivo during long-term strenuous exercise, energy and sleep depletion in humans. European Journal of Applied Physiology. 73, 251-258.
• 49. Smith JA. (1995). Exercise, training and red blood cell turnover. Sports Medicine. 19, 9-31. doi: 10.2165/00007256-199519010-00002.
• 50. ⁠Ciekot-Sołtysiak M., Kusy K., Podgórski T., Pospieszna B., Zieliński J. (2024). Changes in red blood cell parameters during incremental exercise in highly trained athletes of different sport specializations. PeerJ. 12, e17040. doi: 10.7717/peerj.17040.
• 51. Vicaut E., Hou X., Decuypere L., Taccoen A., Duvelleroy M. (1994). Red blood cell aggregation and microcirculation in rat cremaster muscle. International Journal of Microcirculation. 14, 14-21.
• 52. ⁠Krustrup P., Mohr M., Nybo L., Jensen JM., Nielsen JJ., Bangsbo J. (2003). The Yo-Yo R2 test: Physiological response, reliability and application to elite soccer. Medicine & Science in Sports & Exercise. 35, 697-705.
• 53. ⁠Giannopoulou I., Fernhall B., Carhart R. (2005). Effects of diet and/or exercise on the adipocytokine and inflammatory cytokine levels of postmenopausal women with type 2 diabetes. Metabolism. 54, 866-875. doi: 10.1016/j.metabol.2005.01.033.
• 54. Saldanha C., de Almeida JP. (2011). Erythrocyte as a link between basic and clinical research. Clinical Hemorheology and Microcirculation. 49(1-4), 463-472. doi: 10.3233/CH-2011-1496.
• 55. ⁠Wang JS., Fu TC., Lien HY., Wang CH., Hsu CC., Wu WC. 2013). Effect of aerobic interval training on erythrocyte rheological and hemodynamic functions in heart failure patients with anemia. International Journal of Cardiology. 168(2), 1243-1250. doi: 10.1016/j.ijcard.2012.11.053.
• 56. Weng TP., Huang SC., Chuang YF., Wang JS. (2013). Effects of interval and continuous exercise training on CD4 lymphocyte apoptotic and autophagic responses to hypoxic stress in sedentary men. PLoS One. 8(11), e80248. doi: 10.1371/journal.pone.0080248.