in order to keep external deadspace

in order to keep external deadspace constant. Mean values from the last minute of sampling were used for subsequent calculations. Alveolar /'o; was calculated using the alveolar gas equation with water vapour pressure corrected for temperature. Alveolar ventilation was calculated from Vco2 and PAco2 while deadspace ventilation (VD) was determined from the difference between VE and CA (West, 2000b).
2.8. Echocardiography
Two-dimensional trans-thoracic echocardiograms were performed using ultrasound (Hewlett Packard, Sonos 5500, Andover, MA) with a 3.5 MHz transducer. During data acquisition, subjects were instructed to maintain a consistent position with their hands resting on the tops of their bicycle handlebars. As the intensity was below the LT, there was minimal interference from high ventilatory rates. As well, the typical slight body-build of the endurance cyclists allowed for the acquisition of good quality images. Measurements were completed in accordance with the American Society of Echocardiography guidelines (Sahn et al., 1978). The two-dimensional echocardiographic images were obtained from the parastemal short axis view just apical to the mitral valve leaflets. LV images recorded included end-diastolic cavity area (EDCA. largest cavity area) and end-systolic cavity area (ESCA, smallest cavity area). Stroke volume (SV) was calculated from the product of the velocity time integral and aortic cross-sectional area measured at rest (Rowland et al., 2001), cardiac output (0) was determined from the product of heart rate and SV. It should be noted that aortic cross-sectional area was obtained at all points during exercise, and was not found to be different from rest. Fractional area change was quantified as (EDCA-ESCA)/EDCA, systolic blood pressure divided by ESCA (SBP/ESCA) was used as a measure of contractility index while LV end-systolic wall stress was taken as 1.33 x systolic blood pressure x (end-systolic cavity/end-systolic myocardial area) (Haykowsky et al., 2001)All images were acquired and subsequently analyzed in triplicate by the same experienced sonographer who was naive as to the hypothesis of the study. Within subject coefficient of variation for aortic velocity time integral, ESCA and EDCA obtained at each time point averaged 3.1,4.5 and 4.9%, respectively. Within subject coefficient of variation for aortic diameter obtained at rest was 2.0%. Blood pressure (BP) was taken at the time of imaging using either intra-arterial blood pressure recorded by an arterial pressure transducer (N = 9, Hewlett Packard, Viridian CMS, Andover, MA) or non-invasively by a blood-pressurc cuff (N = 2) with the same technician obtaining the readings for each subject.
2.9. Hematology
A second arterial blood sample was drawn for determination of arterial blood lactate and glucose. Blood was analyzed in duplicate with the same YSI 2300 analyzer used for lactate determination in the graded exercise test. Venous blood samples were taken immediately before exercise, and 20-24h after the endurance ride. Troponin-I was used as a biochemical marker of cardiac myocyte damage (ADVIA Centaur cTnI assay). This post-exercise time was selected because cardiac troponin-I levels are most sensitive and specific within this time period (Ebell et al., 2000). Changes in [Hb] and hematocrit observed between baseline and end-exercise were used to estimate relative changes in blood volume and plasma volume
(Dili and Costill, 1974).
2.10. Statistical analysis
An arterial catheter could not be placed in one subject, therefore only his cardiovascular data are reported. ANOVA for repeated measures was used to test for changes over the endurance ride. Upon detection of an effect, pre-planned comparisons were made between: pre-exercise and l5min, I5min and end-exercise, and pre-exercise and post-exercise. A Bonfcrroni correction factor was applied to maintain family-wise error rate at 0.05 (for each comparison P = 0.017). Pearson product-moment correlation coefficients were calculated to estimate the strength of relationships. For all inferential analyses, the probability of Type I error was set at 0.05.