剧烈运动马匹动脉血、混合静脉血及红细胞内离子浓度的变化

Bayly W M, Kingston J K, Brown J A, Keegan R D, Greene S A, Sides R H

Department of Veterinary Clinical Sciences, College of Veterinary Medicine. Washington State University, Pullman, Washington 99164-6610, USA.

Equine Vet J Suppl. 2006 Aug(36):294-7. doi: 10.1111/j.2042-3306.2006.tb05556.x.

REASONS FOR PERFORMING STUDY

Horses experience major perturbations in acid-base balance during supramaximal exercise. Ion movement in and out of erythrocytes (RBCs) is believed to be important in maintaining acid-base balance but it is unclear as to the extent to which this happens, nor how it affects single measurements of ion concentrations in arterial and venous blood.

OBJECTIVES

To clarify the role RBCs play in mitigating perturbations in acid-base balance during high speed exercise in horses, and to describe associated differences in arterial (a) and mixed venous (v) concentrations of key ions.

METHODS

Six exercise-trained Thoroughbreds galloped to fatigue at speeds calculated to have an oxygen demand that was 115% of the VO2max. Blood samples (a and v) were collected pre-exercise, during warm-up, at fatigue, and immediately post exercise. Packed cell volume (PCV), pH, PCO2, and plasma concentrations of bicarbonate (HCOP3-), chloride (Cl-), sodium (Na+), potassium (K+), and lactate (Lac-) and strong ion difference (SID) were determined, and RBC concentrations of Lac- and electrolytes calculated for each sample. Data were analysed using a 2-way ANOVA for repeated measures testing for effects of sampling time and site (P<0.05).

RESULTS

Plasma and RBC [Cl-] were increased with hypercapnoea and acidaemia. [HCO3-]v was greater than pre-exercise values at fatigue, although [HCO3l]a was lower. Hyperkalaemia and decreased RBC [K+] were evident at fatigue, as was an increased RBC [Na+]. Plasma [K+] started to decrease as soon as exercise ceased and Na+ began to move back onto RBCs in exchange for K+. Concentrations of all measures of Lac- rose from fatigue to post exercise. The SID decreased with exercise and was higher in v at fatigue and post exercise, reflecting the decrease in pH.

CONCLUSIONS

RBCs act as a repository for lactate, and therefore the increase in PCV facilitates the maintenance of the muscle to plasma Lac- diffusion gradient during exercise.

POTENTIAL RELEVANCE

This serves to keep intramuscular [Lac-] lower than it would otherwise be and, because of the link between Lac- accumulation, pH decrease and the onset of fatigue, may help delay the onset of fatigue.

开展本研究的原因

马匹在进行超最大强度运动时会经历酸碱平衡的重大扰动。离子进出红细胞（RBC）的运动被认为对维持酸碱平衡很重要，但目前尚不清楚这种情况发生的程度，也不清楚其如何影响动脉血和静脉血中离子浓度的单次测量。

目的

阐明红细胞在减轻马匹高速运动期间酸碱平衡扰动中所起的作用，并描述关键离子的动脉血（a）和混合静脉血（v）浓度的相关差异。

方法

六匹经过运动训练的纯种马以计算得出的需氧量为最大摄氧量（VO2max）的115%的速度疾驰至疲劳。在运动前、热身期间、疲劳时和运动后立即采集血样（a和v）。测定血细胞比容（PCV）、pH值、二氧化碳分压（PCO2）以及血浆中碳酸氢盐（HCOP3-）、氯离子（Cl-）、钠离子（Na+）、钾离子（K+）和乳酸（Lac-）的浓度以及强离子差（SID），并计算每个样本中红细胞内乳酸和电解质的浓度。使用双向方差分析对重复测量数据进行分析，以检验采样时间和部位的影响（P<0.05）。

结果

随着高碳酸血症和酸血症的出现，血浆和红细胞内的[Cl-]升高。尽管动脉血中的[HCO3l]降低，但混合静脉血中的[HCO3-]在疲劳时高于运动前值。疲劳时出现高钾血症且红细胞内[K+]降低，红细胞内[Na+]也升高。运动一停止，血浆[K+]就开始下降，Na+开始进入红细胞以交换K+。从疲劳到运动后，所有乳酸测量指标的浓度均升高。SID随运动降低，在疲劳和运动后混合静脉血中的SID更高，这反映了pH值的下降。