Development of an ultrasound-capable phantom with patient-specific 3D-printed vascular anatomy to simulate peripheral endovascular interventions.

PURPOSE: Today, ultrasound-guided peripheral endovascular interventions have the potential to be an alternative to conventional interventions that are still X-ray and contrast agent based. For the further development of this approach, a research environment is needed that represents the individual patient-specific endovascular properties as realistically as possible. Aim of the project was the construction of a phantom that combines ultrasound capabilities and the possibility to simulate peripheral endovascular interventions. MATERIAL AND METHODS: We designed a modular ultrasound-capable phantom with exchangeable patient specific vascular anatomy. For the manufacturing of the vascular pathologies, we used 3D printing technology. Subsequently, we evaluated the constructed simulator with regards to its application for endovascular development projects. RESULTS: We developed an ultrasound-capable phantom with an exchangeable 3D-printed segment of the femoral artery. This modality allows the study of several patient-specific 3D-printed pathologies. Compared to the flow properties of a human artery (male; age 28) the phantom shows realistic flow properties in the duplex ultrasound image. We proved the feasibility of the simulator by performing an ultrasound-guided endovascular procedure. Overall, the simulator showed realistic intervention conditions. CONCLUSIONS: With the help of the constructed simulator, new endovascular procedures and navigation systems, such as ultrasound-guided peripheral vascular interventions, can be further developed. Additionally, in our opinion, the use of such simulators can also reduce the need for animal experiments.

Prediction of individual prosthesis size for valve-sparing aortic root reconstruction based on geometric features.

Valve-sparing aortic root reconstruction is an up- and-coming approach for patients suffering from aortic valve insufficiencies which promises to significantly reduce complications. However, the success of the treatment strongly depends on the challenging task of choosing the correct size of the prosthesis, for which, up to now, surgeons solely have to rely on their experience. Here, we present a novel machine learning based approach, which might make it possible to predict the size of the prosthesis from pre-operatively acquired ultrasound images. We utilize support vector regression to train a prediction model on three geometric features extracted from the ultrasound data. In order to evaluate the accuracy and robustness of our approach we created a large data base of porcine aortic root geometries in a healthy state and an artificially dilated state. Our results indicate that prediction of correct prosthesis sizes is feasible. Furthermore, they suggest that it is crucial that the training data set faithfully represents the diversity of aortic root geometries.

Impact of graft size and commissural resuspension height on aortic valve competence in valve-sparing aortic replacement under physiological pressures.

BACKGROUND: Valve competence in valve-sparing aortic root replacement has been described as being influenced by commissural height as well as graft size. The aim of this study was to investigate the impact of a gradual reduction of commissural height and graft diameter on aortic insufficiency under physiological conditions in an IN VITRO model. METHODS: Porcine aortic valves were reimplanted into a tubular graft and a native commissural height was obtained. Subsequently the height was reduced by 10 % and 20 %, respectively. To investigate the impact of graft size, a 30 % reduction of the prosthesis diameter was carried out in valves with both native and reduced commissural heights. All conditions were investigated under pulsatile flow simulation and static pressure exposure. RESULTS: Reduction of commissural height caused regurgitation at both 10 % and 20 % lower heights, which was more pronounced in grafts with 20 % reduction. Graft undersizing resulted in significant reflux, with regurgitation even occurring with valves in a native commissural position. CONCLUSIONS: Valve competence is impaired both by the reduction of commissural height and by reduced graft size. In particular, reimplantation of aortic valves into undersized grafts promotes valve insufficiency even if commissural height is well adjusted.