Ventilatory and arterial blood gas tension adjustments to strenuous exercise in standardbreds.
Abstract: Five healthy, fit Standardbreds (mean +/- SEM, 490.4 +/- 15.0 kg, 4.0 +/- 0.5 years) were studied during a standardized test carried out on a treadmill. The test consisted of an 8-minute warm-up and a 9-minute exercise period (1 minute at 1.7, 4, 7, 8, 9, and 10 m/s; 2 minutes at 4 m/s; and a 1-minute walk at a 6% slope). Respiratory airflow, tidal volume (V(T)), and respiratory frequency (f) were continuously recorded, using 2 ultrasonic pneumotachographs connected to a face mask and mass spectrometer. Oxygen uptake, carbon dioxide output, and expired minute volume (V(E)) were obtained on a breath by breath basis. Arterial blood was tested at the end of each step for O2 and CO2 partial pressures. Heart rate was continuously recorded, using a heart rate recording system. Stride frequency was measured at each step, and the stride frequency-to-f ratio was calculated. Venous blood was tested for plasma lactate concentration be fore and 2 minutes after completion of the test. Some horses had a locomotion-respiration coupling (LRC), but this coupling was occasional and intermittent. The f was lower and V(T) was higher than values reported for thoroughbreds working under similar experimental conditions. Nevertheless, maximal V(E) did not overshoot maximal V(E) reported in Thoroughbreds. All horses were hypoxemic and hypercapnic, but there was wide variability between subjects. The horses with the highest oxygen uptake and the lowest plasma lactate concentration were more hypoxemic and hypercapnic. The Standardbreds, studied under our laboratory conditions, did not have constant LRC and had lower f with higher V(T) than did Thoroughbreds under similar experimental conditions. Despite these differences in breathing strategy, the Standardbreds did not have higher V(E) than did Thoroughbreds, and they were hypoxemic and hypercapnic. The fact that these Standardbreds, which obviously freely selected their breathing strategy, were unable or unwilling to adopt compensatory hyperventilation reinforces the hypothesis that, in strenuous exercising horses, there could be a physiologic limit to ventilation, most probably related to mechanical factors, but independent of any LRC.
Publication Date: 1995-10-01 PubMed ID: 8928951
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- Journal Article
- Research Support
- Non-U.S. Gov't
Summary
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The study examines how healthy Standardbred horses adjust their respiratory and arterial blood gas responses to intense exercise performed on a treadmill. The findings show that although these horses freely choose their breathing strategies, they often tend not to adopt compensatory hyperventilation in strenuous exercise, suggesting a potential physiological limitation to ventilation.
Methodology
- The research involved five fit Standardbred horses which were put through a standardized exercise test on a treadmill. The test included an 8-minute warm-up, followed by a 9-minute exercise period featuring a range of speeds and one-minute walking period on a 6% slope.
- The researchers monitored several parameters throughout the test, including respiratory airflow, tidal volume (V(T)), respiratory frequency (f), oxygen uptake, carbon dioxide output, arterial and venous blood gas metrics, heart rate, and stride frequency.
Results
- Unlike in other species, in these Standardbreds the stride frequency and respiratorial frequency were not constantly linked (referred to as locomotion-respiration coupling or LRC). Moreover, this coupling occurred sporadically and erratically whenever it appeared.
- In terms of breathing strategy, these Standardbreds demonstrated lower respiratory frequency but higher tidal volume compared to Thoroughbreds in similar exercise settings.
- All horses displayed symptoms of hypoxemia (low oxygen) and hypercapnia (excess carbon dioxide), with significant variability between the individuals under study.
- The most hypoxemic and hypercapnic horses had the highest oxygen uptake and lowest blood lactate levels.
Conclusions
- The findings support the idea that horses may have a physiological limit to ventilation, as, even under strenuous exercise, they did not always adopt compensatory hyperventilation (increased breathing to make up for increased oxygen demand). This suggests a distinct approach to breathing strategy in Standardbred horses in comparison to Thoroughbreds.
- This limitation to ventilation could be due to mechanical factors, and the study affirms it to be independent of any locomotion-respiration coupling.
Cite This Article
APA
Art T, Lekeux P.
(1995).
Ventilatory and arterial blood gas tension adjustments to strenuous exercise in standardbreds.
Am J Vet Res, 56(10), 1332-1337.
Publication
Researcher Affiliations
- Equine Sports Medicine Unit, Faculty of Veterinary Medicine, University of Liege, Belgium.
MeSH Terms
- Animals
- Arteries
- Blood Gas Analysis / veterinary
- Blood Pressure
- Carbon Dioxide / blood
- Female
- Heart Rate / physiology
- Horse Diseases / physiopathology
- Horses / physiology
- Hydrogen-Ion Concentration
- Hypercapnia / physiopathology
- Hypercapnia / veterinary
- Hypoxia / physiopathology
- Hypoxia / veterinary
- Lung / physiology
- Male
- Oxygen / blood
- Oxygen Consumption / physiology
- Physical Conditioning, Animal / physiology
- Respiration / physiology
Citations
This article has been cited 8 times.- Gołyński M, Metyk M, Ciszewska J, Szczepanik MP, Fitch G, Bęczkowski PM. Homocysteine-Potential Novel Diagnostic Indicator of Health and Disease in Horses. Animals (Basel) 2023 Apr 11;13(8).
- Greco-Otto P, Bond S, Sides R, Bayly W, Leguillette R. Conditioning equine athletes on water treadmills significantly improves peak oxygen consumption. Vet Rec 2020 Feb 29;186(8):250.
- Greco-Otto P, Bond S, Sides R, Kwong GPS, Bayly W, Léguillette R. Workload of horses on a water treadmill: effect of speed and water height on oxygen consumption and cardiorespiratory parameters. BMC Vet Res 2017 Nov 28;13(1):360.
- Takahashi K, Mukai K, Takahashi Y, Ebisuda Y, Sugiyama F, Hatta H, Kitaoka Y. Effects of hypoxia and hyperoxia on exercise-induced metabolomic and transcriptomic profiles in equine skeletal muscle. J Exp Biol 2025 Dec 15;228(24).
- Lendl L, Wirth C, Merle R, Barton AK. Influence of a Standardized Lunging Exercise Test on BALF Cytology in Horses Suffering from Mild-Moderate Equine Asthma. Animals (Basel) 2025 Aug 19;15(16).
- Lendl L, Barton AK. Equine Asthma Diagnostics: Review of Influencing Factors and Difficulties in Diagnosing Subclinical Disease. Animals (Basel) 2024 Dec 4;14(23).
- Leguillette R, McCrae P, Massie S, Filho SA, Bayly W, David F. Workload and spirometry associated with untethered swimming in horses. BMC Vet Res 2024 Jul 19;20(1):327.
- Sanigavatee K, Poochipakorn C, Huangsaksri O, Wonghanchao T, Yalong M, Poungpuk K, Thanaudom K, Chanda M. Hematological and physiological responses in polo ponies with different field-play positions during low-goal polo matches. PLoS One 2024;19(5):e0303092.
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