TPMS for interactive modelling of trabecular scaffolds for Bone Tissue Engineering

The aim of regenerative medicine is replacing missing or damaged bone tissues with synthetic grafts based on porous interconnected scaffolds, which allow adhesion, growth, and proliferation of the human cells. The optimal design of such scaffolds, in the Bone Tissue Engineering field, should meet several geometrical requirements. First, they have to be customized to replicate the skeletal anatomy of the patient, and then they have to provide the proper trabecular structure to be successfully populated by the cells. Therefore, for modelling such scaffolds, specific design methods are needed to conceive extremely complex structures by controlling both macro and micro shapes. For this purpose, in the last years, the Computer Aided Design of Triply Periodic Minimal Surfaces has received considerable attention, since their presence in natural shapes and structures. In this work, we propose a method that exploit Triply Periodic Minimal Surfaces as unit cell for the development of customized trabecular scaffolds. The aim is to identify the mathematical parameters of these surfaces in order to obtain the target requirements of the bone grafts. For that reason, the method is implemented through a Generative Design tool that allow to interactively controlling both the porosity and the pores size of the scaffolds.

[1]  C. Cornell,et al.  Osteoconductive materials and their role as substitutes for autogenous bone grafts. , 1999, The Orthopedic clinics of North America.

[2]  Binil Starly,et al.  Bio-CAD modeling and its applications in computer-aided tissue engineering , 2005, Comput. Aided Des..

[3]  J. Grotowski,et al.  Prototypes for Bone Implant Scaffolds Designed via Topology Optimization and Manufactured by Solid Freeform Fabrication , 2010 .

[4]  E. Yuksel,et al.  Bone-derived CAD library for assembly of scaffolds in computer-aided tissue engineering , 2008 .

[5]  S F Hulbert,et al.  Potential of ceramic materials as permanently implantable skeletal prostheses. , 1970, Journal of biomedical materials research.

[6]  K. Leong,et al.  The design of scaffolds for use in tissue engineering. Part I. Traditional factors. , 2001, Tissue engineering.

[7]  D. Kaplan,et al.  Porosity of 3D biomaterial scaffolds and osteogenesis. , 2005, Biomaterials.

[8]  Alan L. Mackay,et al.  Periodic minimal surfaces of cubic symmetry , 2003 .

[9]  Minna Kellomäki,et al.  A review of rapid prototyping techniques for tissue engineering purposes , 2008, Annals of medicine.

[10]  Colleen L Flanagan,et al.  Bone tissue engineering using polycaprolactone scaffolds fabricated via selective laser sintering. , 2005, Biomaterials.

[11]  N. Kikuchi,et al.  Homogenization theory and digital imaging: A basis for studying the mechanics and design principles of bone tissue , 1994, Biotechnology and bioengineering.

[12]  A M Weinstein,et al.  Interface mechanics of porous titanium implants. , 1981, Journal of biomedical materials research.

[13]  Dong-Jin Yoo,et al.  Computer-aided porous scaffold design for tissue engineering using triply periodic minimal surfaces , 2011 .

[14]  Chee Kai Chua,et al.  Development of a Tissue Engineering Scaffold Structure Library for Rapid Prototyping. Part 1: Investigation and Classification , 2003 .

[15]  S. Hollister Porous scaffold design for tissue engineering , 2005, Nature materials.

[16]  M. Curto,et al.  A method to design biomimetic scaffolds for bone tissue engineering based on Voronoi lattices , 2016 .

[17]  Katia Bertoldi,et al.  Mathematically defined tissue engineering scaffold architectures prepared by stereolithography. , 2010, Biomaterials.

[18]  Rui L Reis,et al.  Bone tissue engineering: state of the art and future trends. , 2004, Macromolecular bioscience.

[19]  H. Takita,et al.  Pore size of porous hydroxyapatite as the cell-substratum controls BMP-induced osteogenesis. , 1997, Journal of biochemistry.