Difference between revisions of "Projects:IHU"
Jump to navigation
Jump to search
David.cazier (talk | contribs) |
David.cazier (talk | contribs) |
||
Line 1: | Line 1: | ||
{{PAGE_Begin}} | {{PAGE_Begin}} | ||
− | *'''3D-Surg | + | *'''3D-Surg''' (Surgery in 3D): The IGG team (D. Bechmann, A. Capobianco, T. Blandet) participates in '''BPI 3D-Surg project: Surgery in 3D''' from 2015 to 2019, driven by Luc Soler. Task 3.4.1- New 3D interaction models contactless (financing of a PhD student) and Task 3.4.2- Optimization and prototyping for real-time interaction (financing of an engineer over 2 years). IGG budget for around 262k€. |
− | *'''HAYSTACK | + | *'''HAYSTACK''' (Simulation and planning of percutaneous procedures for liver tumor ablation): IGG team (C. Essert) participates to project '''Haystack''' 2012-2015, PI Stéphane Cotin (EPI Inria Shacra), co-PI Caroline Essert. Budget 200 k€. This project aims at developing a biomechanical model of needle insertion in abdominal soft tissue, and the elaboration of a new automatic needle trajectory planning method taking into account a prediction of the deformation of the needle and organs in order to anticipate them. The applications are percutaneous thermal ablations of abdominal tumours. |
{{PAGE_End}} | {{PAGE_End}} | ||
[[fr:Projets:IHU]] | [[fr:Projets:IHU]] |
Revision as of 16:56, 21 March 2016
- 3D-Surg (Surgery in 3D): The IGG team (D. Bechmann, A. Capobianco, T. Blandet) participates in BPI 3D-Surg project: Surgery in 3D from 2015 to 2019, driven by Luc Soler. Task 3.4.1- New 3D interaction models contactless (financing of a PhD student) and Task 3.4.2- Optimization and prototyping for real-time interaction (financing of an engineer over 2 years). IGG budget for around 262k€.
- HAYSTACK (Simulation and planning of percutaneous procedures for liver tumor ablation): IGG team (C. Essert) participates to project Haystack 2012-2015, PI Stéphane Cotin (EPI Inria Shacra), co-PI Caroline Essert. Budget 200 k€. This project aims at developing a biomechanical model of needle insertion in abdominal soft tissue, and the elaboration of a new automatic needle trajectory planning method taking into account a prediction of the deformation of the needle and organs in order to anticipate them. The applications are percutaneous thermal ablations of abdominal tumours.