Reduced arterial O2 saturation during supine exercise in highly trained cyclists

Performance of intense dynamic exercise in highly trained athletes is associated with a reduced arterial haemoglobin saturation for O₂ (SaO ₂) and lower arterial PO ₂ (PaO ₂). We hypothesized that compared with upright exercise, supine exercise would be accompanied by a smaller reduction in SaO ₂ because of a lower maximal O₂ uptake (VPO _2max) and/or a more even ventilation–perfusion distribution. Eight elite bicyclists completed progressive cycle ergometry to exhaustion in both positions with concomitant determinations of ventilatory data, arterial blood gases and pH. During upright cycling VPO _2max averaged 75±1.6 mL O₂ min^-1 kg^-1 (±SEM) and it was 10.6±1.7% lower during supine cycling (P<0.001). Also the maximal pulmonary and alveolar ventilation were lower during supine cycling (by 15±2% and 21±3%, respectively; P< 0.001) which related to a 0.8±0.1 L lower tidal volume (P<0.001). In all subjects and independent of work posture PaO ₂ and SaO ₂ decreased from rest to exhaustion (from 99±3 to 82±2 Torr and 98.1±0.2 to 95.2±0.4%, respectively; P<0.001); alveolar–arterial PO ₂ difference increased from 6±2 to 37±3 Torr in both body positions. At exhaustion arterial PCO ₂ was lower in upright than in supine (33.4±0.6 vs. 35.9±0.9 Torr; P<0.01), suggesting a greater relative hyperventilation in upright. Arterial pH was similar in upright and supine at rest (both 7.41±0.01) and at exhaustion (7.31±0.01 vs. 7.32±0.01, respectively). We conclude that despite a lower VPO _2max and supposedly an improved ventilation–perfusion distribution, altering body position from upright to supine does not influence arterial O₂ desaturation during intense exercise.