aim to enhance understanding and foster innovation to develop novel therapeutic systems. The scientific approach is interdisciplinary and integrates experimental, theoretical, and numerical methodologies.

The research focuses on the development of eco-friendly processes using natural products to design therapeutic systems, as well as on numerical modeling of fluid phenomena to improve the understanding and treatment of pathologies. 

The scientific work relies on the conception and implementation of innovative and environmentally friendly technologies and processes (supercritical processes, microfluidic processes, membrane processes, etc.) and on the development of multiscale digital twins (from the cellular to the organ level), involving fluid-structure interactions with complex behavior laws (non-isotropic and hyperelastic living tissue models, non-Newtonian and viscoelastic fluids, etc.).

• Engineering sciences

• Process and chemical engineering

• Physical chemistry

• Fluid mechanics

• Thermodynamics

• Supercritical processes (particle generation, crystallization, encapsulation, liposomes, sterilization, decellularization, etc.)

• Microfluidic processes (encapsulation, vesicles, emulsions, etc.)

• Membrane processes (crystallization, microfiltration, ultrafiltration, nanofiltration, reverse osmosis, pervaporation)

• Multiphase flow modeling

• Fluid-structure interactions

• Multiscale approaches and coupling

• Lattice-Boltzmann method

• Statistical modeling

These original and innovative technologies and methods contribute to addressing scientific and technological challenges to shape the therapeutic systems of tomorrow.