Company Filing History:
1 out of 3,400 
1 out of 833,002 Years Active: 2006-2007
Title: Innovations of Juan M Taboas in Tissue Engineering
Introduction
Juan M Taboas is a notable inventor based in Ann Arbor, MI (US). He has made significant contributions to the field of tissue engineering, particularly in the design of biomaterial scaffolds and implants. With a total of 2 patents, Taboas has developed methodologies that enhance the functionality of medical implants.
Latest Patents
One of Taboas's latest patents is a design methodology for tissue engineering scaffolds and biomaterial implants. This innovative method focuses on creating biomaterial scaffolds that are optimized for in vivo function, accommodating any 3D anatomic shape. The design process utilizes voxel-based techniques, allowing for the integration of complex anatomical data obtained from CT or MRI scans. Additionally, Taboas's work includes the optimization of implant and scaffold microstructures to effectively deliver biofactors such as cells, genes, and proteins. Another significant patent involves controlled local/global and micro/macro-porous 3D plastic, polymer, and ceramic/cement composite scaffold fabrication. This invention provides a comprehensive set of molds, casting methods, and surface modification techniques that align with image-based design methods.
Career Highlights
Throughout his career, Taboas has worked at the University of Michigan, where he has contributed to various research initiatives in tissue engineering. His innovative approaches have positioned him as a key figure in the development of advanced biomaterials.
Collaborations
Taboas has collaborated with notable colleagues such as Scott J Hollister and Gabriel Tien-Min Chu. These partnerships have furthered research and development in the field of biomaterials and tissue engineering.
Conclusion
Juan M Taboas's contributions to tissue engineering through his innovative patents and collaborations highlight his significant role in advancing medical technology. His work continues to influence the design and functionality of biomaterial implants, paving the way for future innovations in the field.