Company Filing History:
Years Active: 2016
Title: Marie-Francoise Harmand: Innovator in Bone Substitutes
Introduction
Marie-Francoise Harmand is a notable inventor based in Bordeaux, France. She has made significant contributions to the field of biomedical engineering, particularly in the development of innovative bone substitutes. Her work focuses on creating materials that can effectively replace and regenerate bone, especially in areas subjected to mechanical loads.
Latest Patents
Marie-Francoise Harmand holds a patent for her invention titled "Implants for 'load bearing' bone substitutions having hierarchical organized architecture deriving from transformation of vegetal structures." This patent describes a bone substitute that comprises a core made from hydroxyapatite (HA), derived from porous wood, or a combination of collagen fibers and hydroxyapatite. The shell of the substitute is also based on hydroxyapatite or silicon carbide, sourced from wood with lower porosity. The invention aims to provide effective solutions for the substitution and regeneration of bones, particularly long bones such as the tibia, femur, and humerus.
Career Highlights
Marie-Francoise Harmand is associated with the National Research Council of Italy (Consiglio Nazionale Delle Ricerche). Her work has been instrumental in advancing the field of bone regeneration and has garnered attention for its innovative approach to utilizing natural materials in medical applications.
Collaborations
Throughout her career, Marie-Francoise has collaborated with esteemed colleagues, including Anna Tampieri and Simone Sprio. These partnerships have contributed to the development of her groundbreaking inventions and have fostered a collaborative environment for research and innovation.
Conclusion
Marie-Francoise Harmand's contributions to the field of bone substitutes highlight her innovative spirit and dedication to advancing medical technology. Her work not only showcases the potential of natural materials in biomedical applications but also paves the way for future advancements in bone regeneration.