Acute ventilatory responses to swimming at increasing intensities

BACKGROUND: Physical exercise is a source of stress to the human body, triggering different ventilatory responses through different regulatory mechanisms and the aquatic environment imposes several restrictions to the swimmer, particularly regarding the restricted ventilation. Thus, we aimed to assess the acute ventilatory responses and to characterize the adopted breathing patterns when swimming front crawl at increasing intensity domains. METHODS: Eighteen well-trained swimmers performed 7 × 200 m front crawl (0.05 m∙s(−1) velocity increments) and a maximal 100 m (30 s rest intervals). Pulmonary gas exchange and ventilation were continuously measured (breath-by-breath) and capillary blood samples for lactate concentration ([La(−)]) analysis were collected at rest, during intervals and at the end of the protocol, allowing the identification of the low, moderate, heavy, severe and extreme intensity domains. RESULTS: With the swimming velocity rise, respiratory frequency (f(R)), [La(−)] and stroke rate (SR) increased ([29.1–49.7] breaths∙min(−1), [2.7–11.4] mmol∙L(−1), [26.23–40.85] cycles; respectively) and stroke length (SL) decreased ([2.43–2.04] m∙min(−1); respectively). Oxygen uptake (VO(2)), minute ventilation (VE), carbon dioxide production (VCO(2)) and heart rate (HR) increased until severe ([37.5–53.5] mL∙kg(−1)∙min(−1), [55.8–96.3] L∙min(−1), [32.2–51.5] mL∙kg(−1)∙min(−1) and [152–182] bpm; respectively) and stabilized from severe to extreme (53.1 ± 8.4, mL∙kg(−1)∙min(-1), 99.5 ± 19.1 L∙min(−1), 49.7 ± 8.3 mL∙kg(−1)∙min(−1) and 186 ± 11 bpm; respectively) while tidal volume (V(T)) was similar from low to severe ([2.02–2.18] L) and decreased at extreme intensities (2.08 ± 0.56 L). Lastly, the f(R)/SR ratio increased from low to heavy and decreased from severe to the extreme intensity domains (1.12 ± 0.24, 1.19 ± 0.25, 1.26 ± 0.26, 1.32 ± 0.26 and 1.23 ± 0.26). CONCLUSIONS: Our findings confirm a different ventilatory response pattern at extreme intensities when compared to the usually evaluated exertions. This novel insight helps to understand and characterize the maximal efforts in swimming and reinforces the importance to include extreme efforts in future swimming evaluations.