OBJECTIVE: We present a series of cases where we used 3D printing in planning of complex liver surgery. BACKGROUND: In liver surgery, three-dimensional reconstruction of the liver anatomy, in particular of vascular structures, has shown to be helpful in operation planning. So far, 3D printing has been used for medical applications only rarely. METHODS AND PATIENTS: From December 2017 to December 2019, in 10 cases where surgery was assumed to be challenging operation planning was performed using full size 3D prints in addition to standard 3 phase CT scans. Models included transparent parenchyma, hepatic veins, vena cava, portal vein, hepatic artery, (biliary tree if requested), and tumors. In 7/10 cases vascular reconstructions were needed during the procedure. Nonstructured feedback of the surgical team revealed that the major benefit was visualization of the critical areas of vascular reconstruction, the expected dimensions of tangential vascular infiltration and the planning of reconstruction. In the multifocal tumors, 3D prints were considered to be helpful for intraoperative orientation to detect metastases and to improve planning of the resection. CONCLUSIONS: In complex liver surgery with potential need for vascular reconstructions operation planning may be optimized using a 3D printed liver model. Prospective studies are needed to evaluate the clinical impact of 3D printing in liver surgery compared to other 3D visualizations.
OBJECTIVE: We present a series of cases where we used 3D printing in planning of complex liver surgery. BACKGROUND: In liver surgery, three-dimensional reconstruction of the liver anatomy, in particular of vascular structures, has shown to be helpful in operation planning. So far, 3D printing has been used for medical applications only rarely. METHODS AND PATIENTS: From December 2017 to December 2019, in 10 cases where surgery was assumed to be challenging operation planning was performed using full size 3D prints in addition to standard 3 phase CT scans. Models included transparent parenchyma, hepatic veins, vena cava, portal vein, hepatic artery, (biliary tree if requested), and tumors. In 7/10 cases vascular reconstructions were needed during the procedure. Nonstructured feedback of the surgical team revealed that the major benefit was visualization of the critical areas of vascular reconstruction, the expected dimensions of tangential vascular infiltration and the planning of reconstruction. In the multifocal tumors, 3D prints were considered to be helpful for intraoperative orientation to detect metastases and to improve planning of the resection. CONCLUSIONS: In complex liver surgery with potential need for vascular reconstructions operation planning may be optimized using a 3D printed liver model. Prospective studies are needed to evaluate the clinical impact of 3D printing in liver surgery compared to other 3D visualizations.
Authors: Andrea Ruzzenente; Laura Alaimo; Simone Conci; Mario De Bellis; Andrea Marchese; Andrea Ciangherotti; Tommaso Campagnaro; Alfredo Guglielmi Journal: Updates Surg Date: 2022-08-25
Authors: Florentine Huettl; Patrick Saalfeld; Christian Hansen; Bernhard Preim; Alicia Poplawski; Werner Kneist; Hauke Lang; Tobias Huber Journal: Ann Transl Med Date: 2021-07
Authors: Christian Boedecker; Florentine Huettl; Patrick Saalfeld; Markus Paschold; Werner Kneist; Janine Baumgart; Bernhard Preim; Christian Hansen; Hauke Lang; Tobias Huber Journal: Langenbecks Arch Surg Date: 2021-03-12 Impact factor: 3.445