Hemodynamic design requirements for in-series thoracic artificial lung attachment in a model of pulmonary hypertension.

Recent thoracic artificial lung (TAL) prototypes have impedances lower than the natural lung. With these devices, proximal pulmonary artery (PA) to distal PA TAL attachment may be possible in patients without right ventricular dysfunction. This study examined the relationship between pulmonary system impedance and cardiac output (CO) to create TAL design constraints. A circuit with adjustable resistance and compliance (C) was attached in a PA-PA fashion with the pulmonary circulation of seven sheep with chronic pulmonary hypertension. The pulmonary system zeroth harmonic impedance modulus (Z(0)) was increased by 1, 2.5, and 4 mmHg/(L/min) above baseline. At each Z(0), C was set to 0, 0.34, and 2.1 ml/mmHg. The change in pulmonary system zeroth and first harmonic impedance moduli (ΔZ(0) and ΔZ(1)), the percent change in CO (%ΔCO), and the inlet and outlet anastomoses resistances were calculated for each situation. Results indicate that ΔZ(0) (p < 0.001) but not ΔZ(1) (p = 0.5) had a significant effect on %ΔCO and that %ΔCO = -7.45*ΔZ(0) (R(2) = 0.57). Inlet and outlet anastomoses resistances averaged 0.77 ± 0.16 and 0.10 ± 0.19 mmHg/(L/min), respectively, and the relationship between %ΔCO and TAL resistance, R(T), in mmHg/(L/min) was determined to be %ΔCO = -(7.45f)×(R(T) + 0.87), in which f = the fraction of CO through the TAL. Thus, newer TAL designs can limit %ΔCO to less than 10% if f < 0.75.

In-parallel artificial lung attachment at high flows in normal and pulmonary hypertension models.

BACKGROUND: End-stage lung disease patients who require a thoracic artificial lung (TAL) must be extubated and rehabilitated prior to lung transplantation. The purpose of this study is to evaluate hemodynamics and TAL function under simulated rest and exercise conditions in normal and pulmonary hypertension sheep models. METHODS: The TAL, the MC3 Biolung (MC3, Inc, Ann Arbor, MI), was attached between the pulmonary artery and left atrium in nine normal sheep and eight sheep with chronic pulmonary hypertension. An adjustable band was placed around the distal pulmonary artery to control the percentage of cardiac output (CO) diverted to the TAL. Pulmonary system hemodynamics and TAL function were assessed at baseline (no flow to the TAL) and with approximately 60%, 75%, and 90% of CO diverted to the TAL. Intravenous dobutamine (0, 2, and 5 mcg . kg(-1). min(-1)) was used to simulate rest and exercise conditions. RESULTS: At 0 and 2 mcg . kg(-1). min(-1), CO did not change significantly with flow diversion to the TAL for both models. At 5 mcg . kg(-1). min(-1), CO decreased with increasing TAL flow up to 28% +/- 5% in normal sheep and 23% +/- 5% in pulmonary hypertension sheep at 90% flow diversion to the artificial lung. In normal sheep, the pulmonary system zeroth harmonic impedance modulus, Z(0), increased with increasing flow diversion. In hypertensive sheep, Z(0) decreased at 60% and 75% flow diversion and returned to baseline levels at 90%. The TAL outlet blood oxygen saturation was 95% or greater under all conditions. CONCLUSIONS: Pulmonary artery to left atrial TAL use will not decrease CO during rest or mild exercise but may not allow more vigorous exercise.