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RAS PhysiologyФизиология человека Human Physiology

  • ISSN (Print) 0131-1646
  • ISSN (Online) 3034-6150

Relationship Between Working Capacity and Heart Rate Dynamics During Work and Recovery in Maximal Incremental Test

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PII
S3034615025050104-1
DOI
10.7868/S3034615025050104
Publication type
Article
Status
Published
Authors
T. S. Spirin
  • Occupation: Head of Laboratory
  • Affiliation: Siberian Federal University (SibFU)
A. V. Kozlov
  • Occupation: Ph. D. (Biology), Chief specialist
  • Affiliation: Center for Sports Innovative Technologies and Training of National Teams of Moskomsport
M. S. Molokeev
  • Occupation: Ph.D. in Physical and Mathematical Sciences, Associate professor
  • Affiliation: Siberian Federal University (SibFU)
Volume/ Edition
Volume 51 / Issue number 5
Pages
108-120
Abstract
The purpose of the work is to determine the interrelationships of parameters approximation equations of heart rate (HR) dynamics during work and recovery with various performance characteristics in the maximal incremental test. The study analyzed 87 HR dynamics of subjects who performed the maximal incremental running test with a second-by-second recording of HR dynamics during the test and recovery. The HR approximation was performed using the least squares method. For each case, the maximal working time in test was recorded and 6 parameters of the approximation equations were determined (R = 0.986 ± 0.010). A quantitative indicator for estimating the curvature of the HR dynamics in maximal incremental test is proposed. Identified two variants of acute adaptation to physical work with increasing power, which are reflected in the form of the working HR dynamics. Interrelationships of the parameters of the equations for approximating the dynamics of HR during work and recovery with the HR cost of work, the intensity of physiological costs, the relative contribution of physiological costs incurred due to anaerobic energy supply mechanisms and the maximal working time in the maximal incremental test are shown. An analogy is noted between exponential dependencies describing the HR dynamics and transition processes in electrical circuits.
Keywords
ЧСС ступенчатый тест бег аэробная выносливость восстановление ЧСС
Date of publication
10.03.2026
Year of publication
2026
Number of purchasers
0
Views
38

References

  1. 1. Федотова Е.В. Научно-методическое обеспечение подготовки спортивного резерва: монография. М.: Принтлето, 2023. 480 с.
  2. 2. Грушин А.А., Зоткин С.В., Шаракин С.А. и др. Справочник тестов по оценке различных сторон подготовленности спортсменов. М.: Спорт, 2020. 192 с.
  3. 3. Jannick N.A., Pettitt R.W., Granata C. et al. An examination and critique of current methods to determine exercise intensity // Sports Med. 2020. V. 50. № 10. P. 1729.
  4. 4. Glaab T., Taube C. Practical guide to cardiopulmonary exercise testing in adults // Respir. Res. 2022. V. 23. № 1. P. 9.
  5. 5. Bentley D.J., Newell J., Bishop D. Incremental exercise test design and analysis: implications for performance diagnostics in endurance athletes // Sports Med. 2007. V. 37. № 7. P. 575.
  6. 6. Roecker K., Schotte O., Niess A.M. et al. Predicting competition performance in long-distance running by means of a treadmill test // Med. Sci. Sports Exerc. 1998. V. 30. № 12. P. 1750.
  7. 7. Poole D.C., Rossiter H.B., Brooks G.A. et al. The anaerobic threshold: 50+ years of controversy // J. Physiol. 2020. V. 599. № 3. P. 737.
  8. 8. Спирин Т.С., Прокопьева Е.Л. Сравнение скорости бега на лактатном анаэробном пороге, установленном различными методами у бегунов-любителей со средней соревновательной скоростью на дистанциях 10 и 21.1 км // Человек. Спорт. Медицина. 2023. Т. 23. № 4. С. 14.
  9. 9. Козлов А.В., Ваваев А.В., Якушкин А.В. и др. Удельная интенсивность физиологических затрат при циклической работе различной мощности // Физиология человека. 2022. Т. 48. № 1. С. 18.
  10. 10. Волков Н.И., Волков А.Н. Физиологические критерии выносливости спортсменов // Физиология человека. 2004. Т. 30. № 4. С. 103.
  11. 11. Волков Н.И., Попов О.И., Самборский А.Г. Пульсовые критерии энергетической стоимости упражнения // Физиология человека. 2003. Т. 29. № 3. С. 98.
  12. 12. Hnízdil J., Škopek M., Balko Š. et al. The Conconi test – searching for the deflection point // Phys. Act. Rev. 2019. V. 7. P. 160.
  13. 13. Bodner M.E., Rhodes E.C. A review of the concept of the heart rate deflection point // Sports Med. 2012. V. 30. № 1. P. 31.
  14. 14. Birnbaumer P., Dostal T., Cipryan L., Hofmann P. Pattern of the heart rate performance curve in maximal graded treadmill running from 1100 healthy 18–65 years old men and women: The 4HAIE study // Front. Physiol. 2023. V. 14. P. 1178913.
  15. 15. Hofmann P., Wonisch M., Pokan R. et al. Beta-adrenoceptor mediated origin of the heart rate performance curve deflection // Med. Sci. Sports Exerc. 2005. V. 37. № 10. P. 1704.
  16. 16. Velicka D., Kairiukstiene Z., Poderiene K. et al. Interaction between cardiac functional indices during incremental exercise test reveals the peculiarities of adaptation to exercising // Medicina (Kaunas). 2019. V. 55. № 7. P. 314.
  17. 17. Noble D. From the Hodgkin-Huxley axon to the virtual heart // J. Physiol. 2007. V. 580. № 1. P. 15.
  18. 18. Trayanova N.A. Whole-heart modeling: Applications to cardiac electrophysiology and electromechanics // Circ Res. 2011. V. 108. № 1. P. 113.
  19. 19. Brooks G.A., Arevalo J.A., Osmond A.D. et al. Lactate in contemporary biology: A phoenix risen // J. Physiol. V. 600. № 5. P. 1229.
  20. 20. Stirling J.R., Zakynthinaki M.S., Saltin B. A model of oxygen uptake kinetics in response to exercise: Including a means of calculating oxygen demand/deficit/debt // Bull. Math. Biol. 2005. V. 67. № 5. P. 989.
  21. 21. Margaria R. Biomechanics and energetics of muscular exercise. Oxford: Oxford university press, 1976. 146 p.
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