Abstract
Potts shunt (PS) was suggested as palliation for patients with suprasystemic pulmonary arterial hypertension (PAH) and right ventricular (RV) failure. PS, however, can result in poorly understood mortality. Here, a patient-specific geometrical multiscale model of PAH physiology and PS is developed for a paediatric PAH patient with stent-based PS. In the model, 7.6mm-diameter PS produces near-equalisation of the aortic and PA pressures and Q(p)/Q(s) (oxygenated vs deoxygenated blood flow) ratio of 0.72 associated with a 16% decrease of left ventricular (LV) output and 18% increase of RV output. The flow from LV to aortic arch branches increases by 16%, while LV contribution to the lower body flow decreases by 29%. Total flow in the descending aorta (DAo) increases by 18% due to RV contribution through the PS with flow into the distal PA branches decreasing. PS induces 18% increase of RV work due to its larger stroke volume pumped against lower afterload. Nonetheless, larger RV work does not lead to increased RV end-diastolic volume. Three-dimensional flow assessment demonstrates the PS jet impinging with a high velocity and wall shear stress on the opposite DAo wall with the most of the shunt flow being diverted to the DAo. Increasing the PS diameter from 5mm up to 10 mm results in a nearly linear increase in post-operative shunt flow and a nearly linear decrease in shunt pressure-drop. In conclusion, this model reasonably represents patient-specific haemodynamics pre- and post-creation of the PS, providing insights into physiology of this complex condition, and presents a predictive tool that could be useful for clinical decision-making regarding suitability for PS in PAH patients with drug-resistant suprasystemic PAH.
Original language | English |
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Pages (from-to) | 471-511 |
Number of pages | 41 |
Journal | Biomechanics and modeling in mechanobiology |
Volume | 21 |
Issue number | 2 |
Early online date | 9 Jan 2022 |
DOIs | |
Publication status | Published - Apr 2022 |
Keywords
- Pulmonary artery hypertension
- Potts shunt
- Lumped parameter model
- Multiscale model
- Computational haemodynamics
- BOUNDARY-CONDITIONS
- BLOOD-FLOW
- CHILDREN
- SIMULATIONS
- HEMODYNAMICS
- CIRCULATION
- PRESSURE
- STRESS