Gaelle Corne

Title: Gaelle Corne: A Pioneer in Nanotechnology

Introduction

Gaelle Corne, an innovative inventor based in Audun-le-Tiche, France, has made significant contributions to the field of nanotechnology. With a total of three patents to her name, she has demonstrated her expertise and commitment to advancing the science of nanocapsules and supported lipid bilayers, paving the way for future discoveries.

Latest Patents

Corne's latest patents include groundbreaking methods for manufacturing nanocapsules. One notable patent details a method for producing a supported lipid bilayer on a porous silica nanoparticle, which maintains a ζ-potential between -10 mV and +10 mV. This method involves providing a negatively charged supported lipid bilayer consisting of at least one phospholipid, followed by the incorporation of a lipid formulation using ultra-sonication technology, highlighting her innovative approach to nanoparticle engineering.

Another patent focuses on a method for synthesizing negatively charged supported lipid bilayers on mesoporous silica nanoparticles. This patent emphasizes the careful balance of lipids in the formulation, revealing a specific ratio of cholesterol to DOPS, further advancing the capabilities of nanovectors in therapeutic applications.

Career Highlights

Gaelle Corne currently works at the Luxembourg Institute of Science and Technology, where she channels her scientific acumen into research and development. Her work has garnered attention for its potential applications in drug delivery systems and biomedical engineering, showcasing her as a leader in her field.

Collaborations

Throughout her career, Corne has collaborated with fellow researchers such as Jean-Sebastien Thomann and Damien Lenoble. These partnerships have enabled her to enhance her research, facilitate innovative solutions, and drive the collective pursuit of knowledge in nanotechnology.

Conclusion

Gaelle Corne's contributions to the field of nanotechnology through her innovative patents reflect her dedication to scientific advancement. Her research not only enriches the academic community but also holds promise for practical applications that could revolutionize industries such as medicine and materials science. As she continues her pioneering work, the impact of her inventions is sure to resonate far beyond her current achievements.