Design and properties of biomimetic irregular scaffolds for bone tissue engineering

The treatment of sizeable segmental bone defects remains a challenge encountered by surgeons. In addition to bone transplantation, porous scaffolds have become a common option. Although the mechanical and biological properties of porous scaffold have recently been the subject of intense research, pore irregularity as a critical characteristic has been poorly explored. Therefore, this study aimed to design an irregular biomimetic scaffold for use in bone tissue engineering applications. The irregular scaffold was based on the Voronoi tessellation method for similarity with the primary histomorphological indexes of bone (porosity, trabecular thickness, cortical bone thickness, and surface to volume ratio). Moreover, a new gradient method was adopted, in which porosity was maintained constant, and the strut diameter was changed to generate a gradient in the irregular scaffold. The permeability and stress concentration characteristics of the irregular scaffold were compared against three conventional scaffolds (the octet, body-centered cubic, pillar body-centered cubic). The results illustrated that the microstructure of the irregular scaffold could be controlled similarly to that of the cortical/cancellous bone unit. Simultaneously, a broad range of permeability was identified for the irregular scaffold, and gradient irregular scaffolds performed better in terms of both permeability and stress distribution than regular scaffolds. This study describes a novel method for the design of irregular scaffolds, which have good controllability and excellent permeability.

[1]  Gerry L. Koons,et al.  Materials design for bone-tissue engineering , 2020, Nature Reviews Materials.

[2]  S. Hofmann,et al.  A multiscale computational fluid dynamics approach to simulate the micro-fluidic environment within a tissue engineering scaffold with highly irregular pore geometry , 2019, Biomechanics and Modeling in Mechanobiology.

[3]  S. M. Ahmadi,et al.  Additively Manufactured Open-Cell Porous Biomaterials Made from Six Different Space-Filling Unit Cells: The Mechanical and Morphological Properties , 2015, Materials.

[4]  Junjie Jiang,et al.  Functionally graded porous scaffolds in multiple patterns: New design method, physical and mechanical properties , 2018, Materials & Design.

[5]  D. Pasini,et al.  High-strength porous biomaterials for bone replacement: A strategy to assess the interplay between cell morphology, mechanical properties, bone ingrowth and manufacturing constraints. , 2016, Acta biomaterialia.

[6]  Alessandro Naddeo,et al.  Irregular Load Adapted Scaffold Optimization: A Computational Framework Based on Mechanobiological Criteria. , 2019, ACS biomaterials science & engineering.

[7]  G. Niebur,et al.  Anisotropic Permeability of Trabecular Bone and its Relationship to Fabric and Architecture: A Computational Study , 2017, Annals of Biomedical Engineering.

[8]  Andreas Öchsner,et al.  Permeability studies of artificial and natural cancellous bone structures. , 2013, Medical engineering & physics.

[9]  X. Guo,et al.  High-Resolution Peripheral Quantitative Computed Tomography Can Assess Microstructural and Mechanical Properties of Human Distal Tibial Bone , 2009, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[10]  David P Fyhrie,et al.  The effect of microcomputed tomography scanning and reconstruction voxel size on the accuracy of stereological measurements in human cancellous bone. , 2004, Bone.

[11]  S. Blanquer,et al.  Permeability and fluid flow-induced wall shear stress in bone scaffolds with TPMS and lattice architectures: A CFD analysis , 2020, European Journal of Mechanics - B/Fluids.

[12]  M. Benedetti,et al.  Fatigue and biological properties of Ti-6Al-4V ELI cellular structures with variously arranged cubic cells made by selective laser melting. , 2018, Journal of the mechanical behavior of biomedical materials.

[13]  Sylvain Lefebvre,et al.  Procedural voronoi foams for additive manufacturing , 2016, ACM Trans. Graph..

[14]  Massimiliano Fantini,et al.  Interactive design and manufacturing of a Voronoi-based biomimetic bone scaffold for morphological characterization , 2018 .

[15]  Deqiao Xie,et al.  Finite element analysis of mechanical behavior, permeability of irregular porous scaffolds and lattice-based porous scaffolds , 2019, Materials Research Express.

[16]  Li Yang,et al.  Experimental-assisted design development for an octahedral cellular structure using additive manufacturing , 2015 .

[17]  X. Y. Kou,et al.  A simple and effective geometric representation for irregular porous structure modeling , 2010, Comput. Aided Des..

[18]  Deqiao Xie,et al.  Design and statistical analysis of irregular porous scaffolds for orthopedic reconstruction based on voronoi tessellation and fabricated via selective laser melting (SLM) , 2020 .

[19]  Ajeet Kumar,et al.  A state-of-the-art review on types, design, optimization, and additive manufacturing of cellular structures , 2019, The International Journal of Advanced Manufacturing Technology.

[20]  P. Rüegsegger,et al.  The ability of three-dimensional structural indices to reflect mechanical aspects of trabecular bone. , 1999, Bone.

[21]  Cheng Yan,et al.  3D-printed cellular structures for bone biomimetic implants , 2017 .

[22]  Changsheng Liu,et al.  Biomimetic porous scaffolds for bone tissue engineering , 2014 .

[23]  Qiang Zhang,et al.  The select of internal architecture for porous Ti alloy scaffold: A compromise between mechanical properties and permeability , 2020 .

[24]  Qing Han,et al.  Customized reconstructive prosthesis design based on topological optimization to treat severe proximal tibia defect , 2020 .

[25]  C J Damien,et al.  Bone graft and bone graft substitutes: a review of current technology and applications. , 1991, Journal of applied biomaterials : an official journal of the Society for Biomaterials.

[26]  V. Kilappa,et al.  BMD-based assessment of local porosity in human femoral cortical bone. , 2018, Bone.

[27]  Tingting Xu,et al.  A review of fabrication strategies and applications of porous ceramics prepared by freeze-casting method , 2016 .

[28]  M. Shukla,et al.  Lattice Modeling and CFD Simulation for Prediction of Permeability in Porous Scaffolds , 2018 .

[29]  Sharmila Majumdar,et al.  Age- and Gender-Related Differences in the Geometric Properties and Biomechanical Significance of Intracortical Porosity in the Distal Radius and Tibia , 2009, Journal of bone and mineral research : the official journal of the American Society for Bone and Mineral Research.

[30]  Chenyu Wang,et al.  Porous Scaffold Design for Additive Manufacturing in Orthopedics: A Review , 2020, Frontiers in Bioengineering and Biotechnology.

[31]  M. D. Vlad,et al.  Design and properties of 3D scaffolds for bone tissue engineering. , 2016, Acta biomaterialia.

[32]  Yuyi Lin,et al.  Modeling structures of open cell foams , 2017 .

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

[34]  Liangchi Zhang,et al.  A review on metallic porous materials: pore formation, mechanical properties, and their applications , 2018 .

[35]  Shujun Li,et al.  Mechanistic understanding of compression-compression fatigue behavior of functionally graded Ti-6Al-4V mesh structure fabricated by electron beam melting. , 2020, Journal of the mechanical behavior of biomedical materials.

[36]  D. C. Blaine,et al.  Numerical comparison of lattice unit cell designs for medical implants by additive manufacturing , 2018, Virtual and Physical Prototyping.

[37]  D. Harvie,et al.  Estimation of anisotropic permeability in trabecular bone based on microCT imaging and pore-scale fluid dynamics simulations , 2016, Bone reports.

[38]  H. Pape,et al.  Bone defects caused by high-energy injuries, bone loss, infected nonunions, and nonunions. , 2010, The Orthopedic clinics of North America.

[39]  Guanjun Wang,et al.  Design and Compressive Behavior of Controllable Irregular Porous Scaffolds: Based on Voronoi-Tessellation and for Additive Manufacturing. , 2018, ACS biomaterials science & engineering.