Intrapulmonary gas mixing and dead space in artificially ventilated dogs

In this study we have investigated the effects of breath holding and of the physical properties of gases on four different respiratory dead spaces (V_D): the Fowler, the physiological, the washout and the inert gas dead space. The experiments were performed with dogs which were ventilated artifically with breathing patterns with different post-inspiratory breath holding times (t_a) of 0, 0.5, 1.0 and 2.0 s. Tracer amounts of acetone, ether and enflurane were infused continuously into a peripheral vein and a bolus of a mixture of krypton, Freon12 and SF₆ was introduced into the peritoneal cavity. After reaching steady state, samples of arterial blood, mixed venous blood and mixed expired air were taken simultaneously. From the partial pressures (P_a, P_¯V and P respectively) we determined the excretion (=P/P_¯V), retention (R=P_a/P_¯V) and the physiological dead space fraction (V_D,phys/V_T=(1 P/P_a) for each gas, where V_T is tidal volume. Further, we recorded the expirograms of the six tracer gases and of CO₂ from which the Fowler dead space fractions (V_D,Fowler/V_T) of the different gases were determined. Also the washout dead space fractions (V_D,washout/V_T) for He and SF₆ were determined as well as the inert gas dead space fraction (V_D,MIGET/V_T) with the use of the multiple inert gas elimination technique (MIGET).With the exception of V_D,phys/V_T for SF₆, all dead space fractions decreased with increasing t_a. V_D,phys/V_T for the poorly soluble gas SF₆ was considerably larger than V_D,phys/V_T for the remaining gases. For the highly soluble acetone V_Fowler/V_T was considerably smaller than V_D,Fowler/V_T for the other gases. V_{D,washout,SF6}/V_T was always larger than V_D,washout,He/V_T and V_D,Fowler,SF6/V_T. Further, V_D,phys/V_T was larger than V_D,Fowler/V_T for SF₆ and acetone. However, for gases with intermediate solubility in blood V_D,phys/V_T tended to be smaller than V_D,Fowler/V_T. We conclude that the respiratory dead spaces are affected by the breathing pattern and by the physical properties of gases, i.e. their diffusivity in alveolar gas and their solubility in blood or lung tissue.