Abstract
Locomotor respiratory coupling patterns in humans have been assessed on the basis of the interaction between different physiological and motor subsystems; these interactions have implications for movement economy. A complex and dynamical systems framework may provide more insight than entrainment into the variability and adaptability of these rhythms and their coupling. The purpose of this study was to investigate the relationship between steady state locomotor-respiratory coordination dynamics and oxygen consumption \( (\dot{V}O_{2}) \) of the movement by varying walking stride frequency from preferred. Twelve male participants walked on a treadmill at a self-selected speed. Stride frequency was varied from −20 to +20% of preferred stride frequency (PSF) while respiratory airflow, gas exchange variables, and stride kinematics were recorded. Discrete relative phase and return map techniques were used to evaluate the strength, stability, and variability of both frequency and phase couplings. Analysis of \( \dot{V}{\text{O}}_{2} \) during steady-state walking showed a U-shaped response (P = 0.002) with a minimum at PSF and PSF − 10%. Locomotor-respiratory frequency coupling strength was not greater (P = 0.375) at PSF than any other stride frequency condition. The dominant coupling across all conditions was 2:1 with greater occurrences at the lower stride frequencies. Variability in coupling was the greatest during PSF, indicating an exploration of coupling strategies to search for the coupling frequency strategy with the least oxygen consumption. Contrary to the belief that increased strength of frequency coupling would decrease oxygen consumption; these results conclude that it is the increased variability of frequency coupling that results in lower oxygen consumption.
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Abbreviations
- DC:
-
Dominant coupling
- DRP:
-
Discrete relative phase
- EI:
-
End inspiration
- HS:
-
Heel strike
- LRC:
-
Locomotor-respiratory coupling
- NC:
-
Non coupling
- PC:
-
Phase coupling
- PSF:
-
Preferred stride frequency
- PWS:
-
Preferred walking speed
- SDC:
-
Second dominant coupling
- SF:
-
Stride frequency
- \( \dot{V}{\text{O}}_{2} \) :
-
Oxygen consumption
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Acknowledgments
We thank the study participants and Christopher Palmer and Molly Johnson for their work in data management. We also acknowledge the support of an NSF research grant (BCS-0341767) which funded this work.
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Communicated by Susan A. Ward.
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O’Halloran, J., Hamill, J., McDermott, W.J. et al. Locomotor-respiratory coupling patterns and oxygen consumption during walking above and below preferred stride frequency. Eur J Appl Physiol 112, 929–940 (2012). https://doi.org/10.1007/s00421-011-2040-y
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DOI: https://doi.org/10.1007/s00421-011-2040-y