Maximal oxygen consumption (VO₂max)
The subjects underwent a maximal exercise test to determine maximal O₂ consumption. All subjects performed an incremental test on a treadmill (Runrace HC 1400, Technogym, Gambettola, Italy) using a standard protocol test. Expired gas was analyzed continuously using an online system (TrueMax 2400, ParvoMedics, East Sandy, Utah, USA). The subjects were required to meet two of three standard criteria for having achieved VO₂max (heart rate > age-predicted maximum heart rate, respiratory exchange ratio > 1.10, rating of perceived exertion > 19) (6-20 points, 19 is equal to 100% effort or extremely hard; 20 points is equal to exhaustion) (Davis, 2006). The exercise tests were carried out 2-4 h after breakfast.

Anthropometric measurements
The subjects' height and weight were determined by the Martin metal anthropometer (±0.1 cm) and clinical scales (±0.05 kg), respectively. The body mass index (BMI) was calculated (kg·m^-2). The near infrared interactance method (Futrex-A/WL 5000, USA) was used to estimate body fat percentage.

Laboratory procedures
Venous blood samples were drawn from the antecubital vein. The pre-competition level samples (pre-COMP) were obtained two days prior to the competition. Samples were also taken immediately after the competition (post-COMP), and after an 18-hour recovery period (RECOV).

Haemoglobin and haematocrit were estimated by the Ssmex XE 2100 autoanalyser (Sysmex Corporation, Japan). The values obtained were used to calculate changes in plasma and blood volume (Dill and Costill, 1974).

Vitamin C was analyzed in serum using the automatic oxidation method of Tulley with the use of the free radical of 4-hydroxy-2,2,6,6-tetramethylpiperidinyloxy and o-phenylenediamine (Ihara et al., 2000).

Oxidized and reduced glutathione. In order to measure whole blood glutathione after drawing a blood sample, 500 µL of whole blood was immediately transferred into a tube containing metaphosphoric acid. The solution was mixed and centrifuged (4000 rpm, 4ºC, 10 minutes), the supernatant was collected. For the measurement of glutathione in erythrocytes, the whole blood was centrifuged for 10 minutes at 3000 rpm and the plasma was aspirated. Then the equal volume of the 10% solution of metaphosphoric acid and the precipitate was mixed and kept at room temperature for 10 min. The sample was centrifuged at 7000 rpm for 10 min and the supernatant was collected. Samples for reduced and oxidized glutathione (GSH, GSSG, respectively) were stored at -70ºC until the analysis. Total glutathione (tGSH) and GSSG were measured by the enzymatic method of Tietze, 1969, which was modified and described by Kullisaar et al., 2003. The content of GSH was calculated as the difference between tGSH and GSSG. The glutathione system redox potency was expressed as the glutathione redox ratio (GSSG·GSH^-1).

Dietary intake
All subjects assessed their usual dietary habits three days before the competition (in addition to breakfast on the competition day). The scales were used (± 2.0 g) for quantified records. All food items consumed were transformed into nutrients using the adapted MicroNutrica program version 2.0 (Finland). The following food characteristics were used: total energy intake of carbohydrates, fats and proteins, vitamin C, E, A, and B-group intake.

Statistical analysis
The results are presented as a mean ± standard deviation. All the data were tested for their normal distribution. ANOVA for repeated measures was used to determine the significance of the differences in parameters measured in pre-COMP, post-COMP, and RECOV. When significant ANOVA was found, the paired t-test for dependent data was used. Pearson correlation coefficients (r) were used to evaluate associations between different variables of interest. Calculations were performed with the SPSS, Version 11.0 (SSPS Inc, Chicago, IL) statistical package. Statistical significance was defined as p<0.05.

Table 1 provides descriptive information about mean age, anthropometric and physical working capacity data (VO₂max, VO₂max·kg^-1) as well as individual maximal heart rate (HR), mean HR and percentage of the maximal HR during the ski marathon. The selected nutritional characteristics of the subjects are presented in Table 2. Daily nutritional intake of vitamin C varied individually ? from 40.4 mg to 340.1 mg. Table 3 shows the changes in haemoglobin, haematocrit, plasma volume, GSSG, GSH and tGSH in whole blood and RBCs following the competition. There was a slight decrease in reduced glutathione in whole blood as well as in RBCs immediately after the competition (statistically non-significant). The recovery period data demonstrate that the GSH level in whole blood was continuously reduced (a statistically significant difference in comparison with pre-COMP level). At the same time, the reduced glutathione level in RBCs (eGSH) was significantly elevated (a statistically significant difference as compared to pre-COMP level).

The mean values of GSSG·GSH^-1 in whole blood and in RBCs are presented in Figure 1. The post-COMP GSSG·GSH^-1 in whole blood did not significantly increase, but the increase was statistically significant (from 0.08 up to 0.11, in pre-COMP vs. RECOV, respectively) during the 18-hour recovery period. In RBCs, GSSG·GSH^-1 baseline value (pre-COMP) was lower than in whole blood (statistically non-significant). The post-COMP data did not show significant changes in comparison with pre-COMP values. Mean GSSG·GSH^-1 in RBCs slightly decreased in the recovery period in comparison with the pre-competition level.

Mean vitamin C concentration in serum significantly increased after the ski marathon (post-COMP) (49% in comparison with pre-COMP) and practically decreased to the baseline level during the recovery period (RECOV) (Figure 1). The change in vitamin C concentration (C_change1= vitamin C during post-COMP - vitamin C pre-COMP) varied individually (-5.7 mg·L^-1 to 12.1 mg·L^-1, mean value 3.1 ± 5.1 mg·L^-1). Nutritional intake of vitamin C did not show statistically significant relationships between vitamin C concentrations in the serum.

An inverse association was found between mean HR during the marathon and serum C_change1 (r = -0.670; p = 0.006). Relative HR (% of the maxHR during the marathon, Table 1) also showed a statistically significant inverse association with C_change1 (r = -0.563; p = 0.029). There were no statistically significant associations between nutritional intake of vitamin C (mg, mg·kg^-1), (C_{dietary+suppl}, mg·kg^-1) and glutathione redox ratio in whole blood and in RBCs.

• The glutathione system is a principal cellular non-enzymic antioxidant system in the organism. Long-term or high-intensity exercise may lead to a decreased level of reduced glutathione (GSH), and thereby increase the glutathione redox ratio (GSSG·GSH^-1).
• Limited data are available about the glutathione redox (GSSG·GSH^-1) status measured simultaneously in red blood cells (RBCs) and blood concerning acute high-intensity exercise.
• Acute high-intensity exercise slightly increases the GSSG·GSH^-1 in whole blood, while GSSG·GSH^-1 significantly decreases in RBCs.
• Our descriptive data show that exercise-induced changes in the non-enzymatic glutathione system seem to be more effective in RBCs and may prevent the damages resulting from reactive oxygen species during exercise.