Acid-base imbalances during a 120 km endurance race compared by traditional and simplified strong ion difference methods.
Abstract: Acid-base disturbances are traditionally assessed using the Henderson-Hasselbach equation. The simplified strong ion approach describes more accurately the complex acid-base and electrolyte abnormalities present in endurance horses. Objective: To describe acid-base and electrolytes changes in fit horses competing in a FEI*** 120 km endurance race and to compare the traditional vs. strong ion approaches. Methods: Thirty horses were initially enrolled in the study. Venous blood samples were obtained before the race (n = 25), at the second (n = 29; 65.4 km) and third vet-gates (n = 23, 97.4 km) and upon race completion (n = 17). Blood gas analysis was performed to determine pH, PCO(2), PO(2), Na(+), K(+) and iCa(++), and calculate HCO(3)(-), base excess and tCO(2). Packed cell volume and total protein, globulin, albumin, lactate, phosphate, glucose and creatinine concentrations, as well as muscle enzymes activities, were also determined. Calculated variables included strong ion difference (SIDm), strong ion gap (SIG) and nonvolatile buffer concentration (A(tot)). A longitudinal linear model using the general estimating equation methodology was used for statistical analysis. Results: Mild but significant increases in PCO(2), SIDm, lactate, plasma protein, globulins and A(tot), as well as a decrease in potassium concentrations were observed from the second vet-gate to race finish when compared to prerace values (P < 0.05). Using the strong ion approach, 67% samples showed acid-base disturbances vs. 70% when using the traditional method, but their interpretations only matched in 24% of measurements. Conclusions: A complex acid-base imbalance characterised by a mild strong ion alkalosis (hypochloraemia attenuated by hyperlactataemia), nonvolatile buffer acidosis and compensatory mild respiratory acidosis were present in most horses, although pH did not significantly change during a 120 km endurance race. The strong ion approach to interpretation of acid-base balance should be favoured over the traditional approach in endurance horses, given the frequent and complex alterations in PCO(2), SIDm and A(tot) during a race.
© 2010 EVJ Ltd.
Publication Date: 2011-05-27 PubMed ID: 21058986DOI: 10.1111/j.2042-3306.2010.00213.xGoogle Scholar: Lookup
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- Journal Article
Summary
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The research article investigates how acid-base and electrolyte changes occur in horses during a 120 km endurance race, comparing traditional and more recent approaches to understanding these changes. The researchers found complex acid-base imbalances during the race, and suggested that the newer “strong ion” approach provides more accurate results than traditional methods.
Methodology
- Horses were enrolled for a 120km race. Their venous blood samples were taken at various intervals: before the race, at 65.4km and 97.4km mark and upon completion.
- The blood gas analysis was conducted to determine pH, PCO(2), PO(2), Na(+), K(+) and iCa(++), and calculate HCO(3)(-), base excess and tCO(2).
- The packed cell volume and total protein, globulin, albumin, lactate, phosphate, glucose and creatine concentrations, and muscle enzyme activities were also measured.
- The variables calculated included strong ion difference (SIDm), strong ion gap (SIG) and nonvolatile buffer concentration (A(tot)).
- A longitudinal linear model using the general estimating equation methodology was used for statistical analysis.
Results
- Minor but statistically significant increases in PCO(2), SIDm, lactate, plasma protein, globulins and A(tot), and a reduction in potassium concentrations were noted from the second measurement stage to the end of the race, compared to the pre-race values.
- When using the strong ion approach, 67% of samples indicated acid-base imbalances, versus 70% when using the traditional approach; however, these two methods agreed only 24% of the time.
Conclusions
- Most horses displayed a complex acid-base imbalance characterised by a slight strong ion alkalosis (reduced chloride levels balanced by increased lactate), non-volatile buffer acidosis and a compensatory minor respiratory acidosis, even though the pH level did not significantly change during the race.
- The strong ion approach to understanding acid-base balance is recommended over the traditional approach in endurance horses, due to the frequent and complex changes in PCO(2), SIDm and A(tot) during a race.
Cite This Article
APA
Viu J, Jose-Cunilleras E, Armengou L, Cesarini C, Tarancón I, Rios J, Monreal L.
(2011).
Acid-base imbalances during a 120 km endurance race compared by traditional and simplified strong ion difference methods.
Equine Vet J Suppl(38), 76-82.
https://doi.org/10.1111/j.2042-3306.2010.00213.x Publication
Researcher Affiliations
- Servei de Medicina Interna Equina, Departament de Medicina i Cirurgia Animals, Facultat de Veterinària, Universitat Autònoma de Barcelona, Barcelona, Spain.
MeSH Terms
- Acid-Base Equilibrium / physiology
- Acid-Base Imbalance
- Animals
- Electrolytes / blood
- Female
- Horse Diseases / blood
- Horse Diseases / diagnosis
- Horses
- Male
- Physical Conditioning, Animal / physiology
- Physical Endurance / physiology
- Sports
Citations
This article has been cited 8 times.- Sandersen C, Dmitrovic P, Dupont J, Cesarini C, Guyot H, Serteyn D, Kirsch K. Analytical Performance Evaluation of the New GEM(®) Premier™ 5000 in Comparison to the Epoc(®) Blood Gas Analyzer in Horses.. Vet Sci 2023 Feb 3;10(2).
- Dzięgielewska A, Dunislawska A. Mitochondrial Dysfunctions and Potential Molecular Markers in Sport Horses.. Int J Mol Sci 2022 Aug 4;23(15).
- Lindinger MI, Waller AP. Physicochemical Analysis of Mixed Venous and Arterial Blood Acid-Base State in Horses at Core Temperature during and after Moderate-Intensity Exercise.. Animals (Basel) 2022 Jul 22;12(15).
- Pohlin F, Buss P, Hooijberg EH, Meyer LCR. Midazolam Alters Acid-Base Status Less than Azaperone during the Capture and Transport of Southern White Rhinoceroses (Ceratotherium simum simum).. Animals (Basel) 2020 Jul 31;10(8).
- Kirsch K, Sandersen C. Traditional and quantitative analysis of acid-base and electrolyte imbalances in horses competing in cross-country competitions at 2-star to 5-star level.. J Vet Intern Med 2020 Mar;34(2):909-921.
- Kirsch K, Detilleux J, Serteyn D, Sandersen C. Comparison of two portable clinical analyzers to one stationary analyzer for the determination of blood gas partial pressures and blood electrolyte concentrations in horses.. PLoS One 2019;14(2):e0211104.
- Izzati MRNZ, Noraniza MA, Adamu L, Rasedee A. Validity of an established metabolic disorder index as a predictor for metabolic eliminations in endurance horses.. Int J Vet Sci Med 2018 Dec;6(2):227-232.
- Burchell RK, Schoeman JP, Leisewitz AL. The central role of chloride in the metabolic acid-base changes in canine parvoviral enteritis.. Vet J 2014 Apr;200(1):152-6.
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