Experience

3Deus Dynamics

• France
• Manufacturing
• 1 - 100 Employee

• Co-Founder & CTO

  • Oct 2020 - Present



3d.FAB platform

• France
• Biotechnology
• 1 - 100 Employee

• Research engineer (CNRS)

  • Nov 2016 - Present

  3D printing, 3D bioprinting and 4D printing using deposition or photopolymerization techniques. Quality : ISO 13485:2016 3D printing, 3D bioprinting and 4D printing using deposition or photopolymerization techniques. Quality : ISO 13485:2016



TECHTERA

• France
• Textile Manufacturing
• 1 - 100 Employee

• R&D project Manager

  • Jul 2015 - Oct 2016

  Technical textiles and soft materials R&D projects Technical textiles and soft materials R&D projects



INSA Lyon - Institut National des Sciences Appliquées de Lyon

• France
• Higher Education
• 700 & Above Employee

• Post-doctoral researcher

  • Feb 2015 - Jun 2015

  MATEIS Laboratory (UMR CNRS 5510) MATEIS Laboratory (UMR CNRS 5510)



SEGULA Technologies

• France
• Engineering Services
• 700 & Above Employee

• PHD Graduate Student

  • Dec 2011 - Jan 2015

  Segula Matra Technologies - IMP (Lyon1 - UMR CNRS 5223) and CREATIS (UMR CNRS 5220, INSERM U1044), laboratories Thesis title : "Elaboration of silicone materials with a mechanical behavior tailored for manufacturing patient-specific aortic phantom" The present work deals with the producing of patient-specific aortic phantoms using an additive manufacturing technique by 3D printing. Phantoms are manufactured from synthetic materials with morphological and mechanical characteristics which should be close to these identified on a patient. They can be used to develop techniques of medical imaging, to understand the relationship between aortic mechanical behavior and hemodynamic properties of blood flow, as well as to perform a preoperative training of interventions, such as endovascular treatment. In this study, the hyper-viscoelastic aortic mechanical behavior was described using a generalized solid Maxwell model. Silicone materials were developed based on the model’s mechanical parameters to mimic various aortic mechanical behaviors. These materials were formulated from commercials silicones, and then mixing rules were compared to define the ideal mixture which can mimic the specific mechanical behavior. A nondestructive method based on medical imaging by ultrasound was developed to identify the parameters of a blood vessel hyper-viscoelastic model. Silicone tubes made of our formulations with known reference mechanical parameters, were used to validate this method. Then, these silicone materials were used in an additive manufacturing process using indirect 3D printing. A work of computer aided design was done to produce a patient-specific aortic phantom with a thoracic fusiform aneurysm without thrombosis. Show less



INSA Lyon - Institut National des Sciences Appliquées de Lyon

• France
• Higher Education
• 700 & Above Employee

• Teacher of Science

  • Jan 2013 - Dec 2014

  Pratical works in physic and chemistry (1st and 2nd cycle of engineer) : Introduction of good laboratory pratice. Calorimetry, acid-base, potentiometry, GPC and thermodynamic. Pratical works in physic and chemistry (1st and 2nd cycle of engineer) : Introduction of good laboratory pratice. Calorimetry, acid-base, potentiometry, GPC and thermodynamic.



Arkema

• France
• Chemical Manufacturing
• 700 & Above Employee

• Research Development Engineer

  • Oct 2010 - Sep 2011

  New method for Volatile Organic Compounds measurement in thermoplastic elastomer production for electrical application

• Assistant Research Engineer

  • Apr 2010 - Sep 2010

  Thermoplastic process optimization using organic peroxide