Please use this identifier to cite or link to this item: http://hdl.handle.net/11452/20826
Title: Influence of exercise intensify on the on- and off-transient kinetics of pulmonary oxygen uptake in humans
Authors: Rossiter, Harry
Ward, Susan Ann
Whipp, Brian J.
Uludağ Üniversitesi/Tıp Fakültesi/Fizyoloji Anabilim Dalı.
0000-0002-4606-6596
Özyener, Fadıl
AAH-1641-2021
Keywords: Cardiac-output
O-2 deficit
Muscle-fibers
Gas-exchange kinetics
Cycle ergometer exercise
Heavy exercise
Slow component
Vo2 kinetics
Submaximal exercise
Respiratory profile
Neurosciences & neurology
Physiology
Issue Date: Jun-2001
Publisher: Wiley
Citation: Rossiter, H. vd. (2001). "Influence of exercise intensify on the on- and off-transient kinetics of pulmonary oxygen uptake in humans". Journal of Physiology-London, 533(3), 891-902.
Abstract: The maximal oxygen uptake ((V) over dot (O2,peak)) during dynamic muscular exercise is commonly taken as a crucial determinant of the ability to sustain high-intensity exercise. Considerably less attention, however, has been given to the rate at which (V) over dot (O2), increases to attain this maximum (or to its submaximal requirement), and even less to the kinetic features of the response following exercise.Six, healthy, male volunteers (aged 22 to 58 years), each performed 13 exercise tests: initial ramp-incremental cycle ergometry to the limit of tolerance and subsequently, on different days, three bouts of square-wave exercise each at moderate, heavy, very heavy and severe intensities. Pulmonary gas exchange variables were determined breath by breath throughout exercise and recovery from the continuous monitoring of respired volumes (turbine) and gas concentrations (mass spectrometer). For moderate exercise, the (V) over dot O-2, kinetics were well described by a simple mono-exponential function, following a short cardiodynamic phase, with the on- and off-transients having similar time constants (tau (1)); i.e. tau (1,on) averaged 33 +/- 16 s (+/- S.D.) and tau (1,off) 29 +/- 6 s. 4. The on-transient (V) over dot (O2) kinetics were more complex for heavy exercise. The inclusion of a second slow and delayed exponential component provided an adequate description of the response; i.e. tau (1,on) = 32 +/- 17 s and tau (2,on) = 170 +/- 49 s. The off-transient (V) over dot (O2) kinetics, however, remained mono-exponential (tau (1,off) = 42 +/- 11 s). 5. For very heavy exercise, the on-transient (V) over dot (O2), kinetics were also well described by a double exponential function (tau (1,on) = 34 +/- 11 s and tau (2,on) = 163 +/- 46 s). However, a double exponential, with no delay, was required to characterise the off-transient kinetics (i.e. tau (1,off) = 33 +/- 5 s and tau (2,off) = 460 +/- 123 s). 6. At the highest intensity (severe), the on-transient Tie, kinetics reverted to a mono-exponential profile (tau (1,on) = 34 +/- 7 s), while the off-transient kinetics retained a two-component form (tau (1,off) = 35 +/- 11 s and tau (2,off) = 539 +/- 379 s). 7. We therefore conclude that the kinetics of (V) over dot (O2) during dynamic muscular exercise are strikingly influenced by the exercise intensity, both with respect to model order and to dynamic asymmetries between the on- and off-transient responses.
URI: https://doi.org/10.1111/j.1469-7793.2001.t01-1-00891.x
https://physoc.onlinelibrary.wiley.com/doi/10.1111/j.1469-7793.2001.t01-1-00891.x
http://hdl.handle.net/11452/20826
ISSN: 0022-3751
Appears in Collections:Web of Science

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