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Abstract

Background

Neonates are more susceptible to acute respiratory failure than older children. It is unknown to what extent high-flow nasal cannula (HFNC) alters intrathoracic pressure (ITP), potentially decreasing cardiac output (CO) due to cardiopulmonary interactions. This study evaluated the impact of flow titration on tracheal pressure (a surrogate for ITP) and CO via HFNC in an established porcine model of neonatal respiratory failure. Unlike prior research, this study examines both ITP and CO demonstrating that although the ITP increased with higher HFNC flows, CO did not decrease.

Methods

Twenty-three neonatal Landrace-Yorkshire pigs (2–4 kg) were anesthetized, and monitoring lines were placed. Baseline vital signs, CO, mean intratracheal pressure (Ptr), and PaO₂ were measured. CO was assessed via computerized COstatus cardiac system. Lung injury was induced using oleic acid (0.08 mL/kg), resulting in ≤50% reduction in preinjury PaO₂ on 1 L/min oxygen. After injury, in random order, pigs received HFNC flows of 1, 2, and 3 L/kg/min at 100% FiO₂ for 30 min each. Measurements were repeated, and data were analyzed via mixed-effects repeated measures ANOVA.

Results

After OA injury, PaO₂ significantly decreased (414 to 125 mmHg; p < 0.001). Mean Ptr and PaO₂ increased significantly (p < .001) with increasing HFNC flow rates. CO showed no significant changes; thus, no correlation between CO with Ptr and/or HFNC flow levels was demonstrated.

Conclusions

In neonatal respiratory distress, higher HFNC flows improved oxygenation without negatively impacting CO in this neonatal porcine lung injury model, despite increasing intra-thoracic pressure (1–3 L/min/kg).

Keywords

ARDS cardiac output hemodynamics high flow nasal insufflation hypoxia neonatal respiratory failure respiratory failure

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