Evaluation of four pediatric cardiopulmonary bypass circuits in terms of perfusion quality and capturing gaseous microemboli.

This study compared four pediatric cardiopulmonary bypass (CPB) circuits with four different hollow-fiber membrane oxygenators and their specific reservoirs, Capiox RX15, Quadrox-i pediatric, Quadrox-i pediatric with integrated arterial filter (IAF) and KIDS D101, in a simulated CPB circuit identical to that used in the clinical setting at our institution to test their ability to maintain hemodynamic properties, remove gaseous microemboli (GME), and to test the amount of blood "stolen" by the arterial filter purge line. The circuit was first primed with Ringer's Lactate solution, then red blood cells were added and the hematocrit was maintained at 30%. A 5-cc bolus of air was injected just proximal to the venous reservoir over a thirty-second interval and GME were monitored using an Emboli Detection and Classification quantifier. Transducers were placed at pre-oxygenator, post-oxygenator and distal arterial line (post-filter) positions. Flow probes were also placed both pre and post filter. The injections were made at three flow rates, hypothermic and normothermic temperatures, and with the purge line in both the opened and closed positions. Six injections were done at each of the 12 experimental conditions. Results demonstrated that GME in the arterial line increased with increasing temperature and flow rate. The Capiox RX15 had the least GME in the arterial line at all experimental conditions. The KIDS D101 had the largest pressure drop and the lowest retention of hemodynamic energy, while the Capiox had the lowest pressure drop. All of the oxygenators had a similar amount of "stolen" blood flow and it was consistently under 10% of the total flow reaching the patient.

Evaluation of Quadrox-i and Capiox FX neonatal oxygenators with integrated arterial filters in eliminating gaseous microemboli and retaining hemodynamic properties during simulated cardiopulmonary bypass.

Perfusion quality during cardiopulmonary bypass (CPB) procedures can contribute to postoperative neurological complications and influence patient recovery and outcome. Gaseous microemboli generated in the circuit and hemodynamic properties of blood reaching the patient can be monitored during CPB to optimize perfusion. Oxygenators that oxygenate the blood during CPB can significantly influence the quality of blood reaching the patient by their manufacturing designs. New hollow-fiber membrane oxygenators are developed with integrated arterial filters to reduce priming volume and eliminate a separate arterial filter in the circuit. To evaluate the performance of these new oxygenators, we used a simulated model to compare the Quadrox-i Neonatal and the Capiox Baby FX05 neonatal oxygenators and to provide a review of these oxygenators with their respective counterparts which have separate arterial filters. We found that microemboli counts for the new Quadrox-i and Capiox FX05 oxygenators are similar in the arterial line, but different across the oxygenator for all experimental conditions. The arterial purge line diverting blood from the patient reduces microemboli count for the Capiox FX05, but is inconsistent for the Quadrox-i Neonatal. While hemodynamic energy delivered to the patient is similar for both oxygenators, shunted blood flow for the Quadrox-i Neonatal oxygenator is three times higher than the Capiox FX05 (103.6 mL/min vs 33.0 mL/min at 400 mL/min and 35°C) (p<0.001).

Evaluation of three hollow-fiber membrane oxygenators without integrated arterial filters for neonatal cardiopulmonary bypass.

The cardiopulmonary bypass (CPB) procedure has been shown to be a possible cause of postoperative neurological morbidity for various reasons, including: large amounts of gaseous microemboli (GME) reaching the patient and hypoperfusion of the patient due to "stolen" blood flow. This study used a simulated CPB circuit identical to that in a clinical setting to examine three different hollow-fiber membrane oxygenators without intergrated arterial filters - the Capiox RX05, the Quadrox-i neonatal, and the KIDS D100 - to determine their ability to reduce the number of GME delivered to the neonatal patient and their hemodynamic properties in response to varying flow rates, normothermic vs hypothermic conditions, and open vs closed purge line. The circuit was primed with Ringer's Lactate and then human blood with a hematocrit of 30%. Injections of 5cc bolusses of air were injected into the venous line proximal to the venous reservoir over a thirty-second interval. Six injections were done for each oxygenator at each of the eight different experimental conditions for a total of 64 experiments per oxygenator (192 total injections). A flow probe, pressure transducer, and Emboli Detection and Classification (EDAC) quantifier transducer were positioned both upstream and downstream of the oxygenator to measure differences in each parameter. Results demonstrated that the Capiox RX05 is the most effective oxygenator at reducing the number of microemboli that potentially can be delivered to the neonatal patient. In regards to the hemodynamic properties, the Quadrox-i has the most favorable results, with the lowest mean pressure drop and the best energy retention across the oxygenator.