Objective: Investigating accuracy of cardiac tomography (CT) derived post-processing3D reconstruction (CT-PPR) and 3D printing to predict percutaneous pulmonary valve implantation (PPVI) feasibility. Background: PPVI feasibility remains challenging in large native regurgitant right ventricle outflow tract (RVOT). Methods: Fifteen patients with large native RVOT were investigated. CT-PPR consisted in RVOT long-axis curvilinear reconstruction (LACR) to measure the landing zone (LZ), and 3D volume rendering for morphological evaluation. A STL was generated to create 3D printed model (flexible resin). Balloon sizing was subsequently performed to measure LZ diameter (3D-MBD), compared to invasive balloon diameter (IBD) during catheterization, considered as the Gold Standard. Two operators predicted the feasibility of PPVI using CT-PPR and 3D printed models independently and blinded to outcome. Results: On 3D printed models, RVOT shape was tubular in 5 patients, divergent in 5 patients, concave in 4 patients and convergent in one. Agreement with CT-PPR RVOT shape morphology assessment was observed in 93% of cases (Kappa coefficient 0.91, p