The purpose was to monitor high-performance athletes throughout training macrocycles and competitions and examine the changes in plasma glutamine (Gm) and glutamate (Ga) concentrations in order to develop a model of tolerance to training.Methods:
Plasma glutamine and glutamate concentrations of 52 National team athletes (31 male and 21 female) divided into male and female groups of speed skating, swimming, and cross-country skiing were measured in an early season rested condition to determine highest Gm and lowest Ga concentrations and over 2–4 macrocycles, which included heavy training to establish lowest Gm and highest Ga concentrations.Results:
In the rested condition, there were no differences within and between the male and female groups, excluding five athletes (OTA) who became overtrained in heavy training. The mean (±SD) Gm concentration was 585 ± 54 μmol·L−1, Ga concentration 101 ± 16 μmol·L−1, and Gm/Ga ratio 5.88 ± 0.84 μmol·L−1. The OTA had a significantly higher Ga concentration of 128 ± 16 μmol·L−1 and lower Gm/Ga ratio of 4.43 ± 0.49 μmol·L−1 than all the other groups. In heavy training, there was a significant decrease (P < 0.05) in Gm concentration to 522 ± 53 μmol·L−1, significant increase in Ga concentration to 128 ± 19 μmol·L−1 and significant decrease in Gm/Ga ratio to 4.15 ± 0.57 μmol·L−1. The OTA Gm concentration of 488 ± 31 μmol·L−1 was significant lower than only the male speed skating and swimming groups. However, the Ga concentration of 171 ± 17 μmol·L−1 and Gm/Ga ratio of 2.88 ± 0.27 μmol·L−1 were significantly higher and lower respectively than all other groups.Conclusions:
Based on the changes in Gm and Ga concentration under different training conditions, we propose an athlete tolerance to training model where glutamine concentration reflects tolerance to volume of work and glutamate concentration reflects tolerance to high intensity training. We suggest that the Gm/Ga ratio may globally represent overall tolerance to training.