Modeling of the Norwood circulation: effects of shunt size, vascular resistances, and heart rate

Abstract

Hypoplastic left heart syndrome is the most common lethal cardiac malformation of the newborn. Its treatment, apart from heart transplantation, is the Norwood operation. The initial procedure for this staged repair consists of reconstructing a circulation where a single outlet from the heart provides systemic perfusion and an interpositioning shunt contributes blood flow to the lungs. To better understand this unique physiology, a computational model of the Norwood circulation was constructed on the basis of compartmental analysis. Influences of shunt diameter, systemic and pulmonary vascular resistance, and heart rate on the cardiovascular dynamics and oxygenation were studied. Simulations showed that1) larger shunts diverted an increased proportion of cardiac output to the lungs, away from systemic perfusion, resulting in poorer O₂ delivery, 2) systemic vascular resistance exerted more effect on hemodynamics than pulmonary vascular resistance,3) systemic arterial oxygenation was minimally influenced by heart rate changes, 4) there was a better correlation between venous O₂ saturation and O₂ delivery than between arterial O₂ saturation and O₂delivery, and 5) a pulmonary-to-systemic blood flow ratio of 1 resulted in optimal O₂ delivery in all physiological states and shunt sizes.