RESUMO
BACKGROUND: A wearable artificial lung could improve lung transplantation outcomes by easing implementation of physical rehabilitation during long-term pretransplant respiratory support. The Modular Extracorporeal Lung Assist System (ModELAS) is a compact pumping artificial lung currently under development. This study evaluated the long-term in vivo performance of the ModELAS during venovenous support in awake sheep. Feedback from early trials and computational fluid dynamic analysis guided device design optimization along the way. METHODS: The ModELAS was connected to healthy sheep via a dual-lumen cannula in the jugular vein. Sheep were housed in a fixed-tether pen while wearing the device in a holster during support. Targeted blood flow rate and support duration were 2-2.5 L/min and 28-30 days, respectively. Anticoagulation was maintained via systemic heparin. Device pumping and gas exchange performance and hematologic indicators of sheep physiology were measured throughout support. RESULTS: Computational fluid dynamic-guided design modifications successfully decreased pump thrombogenicity from initial designs. For the optimized design, 4 of 5 trials advancing past early perioperative and cannula-related complications lasted the full month of support. Blood flow rate and CO2 removal in these trials were 2.1 ± 0.3 L/min and 139 ± 15 mL/min, respectively, and were stable during support. One trial ended after 22 days of support due to intradevice thrombosis. Support was well tolerated by the sheep with no signs of hemolysis or device-related organ impairment. CONCLUSIONS: These results demonstrate the ability of the ModELAS to provide safe month-long support without consistent deterioration of pumping or gas exchange capabilities.
Assuntos
Órgãos Artificiais , Circulação Extracorpórea/instrumentação , Transplante de Pulmão , Pulmão/cirurgia , Troca Gasosa Pulmonar , Respiração , Animais , Desenho de Equipamento , Circulação Extracorpórea/efeitos adversos , Pulmão/fisiopatologia , Circulação Pulmonar , Carneiro Doméstico , Fatores de TempoRESUMO
Ambulating patients on extracorporeal membrane oxygenation (ECMO) or extracorporeal CO2 removal (ECCO2R) improves outcomes. These systems would further simplify ambulation if made more compact. This study investigates blood recirculation to decrease device size by increasing efficiency. The required hollow fiber membrane (HFM) area was determined by numerically modeling gas transfer. An oxygenation device with recirculating blood flow was designed using computational fluid dynamics (CFD). Hydrodynamic performance and shear stresses of the device were analyzed using CFD at 2,000, 2,250 and 2,500 RPM. A prototype (0.38 m) was manufactured for in-vitro oxygenation testing. Oxygenation was measured at a constant 3.5 L/min blood flow while recirculation flow rate varied up to 6.5 L/min. Hemolysis was measured at 3.5 L/min blood flow and 6.5 L/min recirculation flow. A 0.3 m prototype device was used to test in-vitro ECCO2R recirculation at a constant 500 ml/min blood flow rate and recirculation flow rates up to 5.5 L/min. Computational fluid dynamics analysis showed that the oxygenation device could produce over 250 mm Hg while maintaining 3.5 L/min blood flow and 6.5 L/min recirculation flow. The model predicted oxygenation within 8% and overestimated ECCO2R by up to 32%. Measured gas transfer was 180 ml O2/min and 62 ml CO2/min. Normalized index of hemolysis contribution of the HFM was 0.012 gm/100 L.