[1] HEN H,HAN Q,WANG C Y,et al. Porous scaffold design for additive manufacturing in orthopedics: a review[J]. Frontiers in Bioengineering and Biotechnology,2020,8: 609.
[2] BABILOTTE J,GUDURIC V,LE NIHOUANNEN D,et al. 3D printed polymer-mineral composite biomaterials for bone tissue engineering: fabrication and characterization[J]. Journal of Biomedical Materials Research Part B,Applied Biomaterials,2019,107(8): 2579-2595.
[3] BRACAGLIA L G,SMITH B T,WATSON E,et al. 3D printing for the design and fabrication of polymer-based gradient scaffolds[J]. Acta Biomaterialia,2017,56: 3-13.
[4] VARMA M V,KANDASUBRAMANIAN B,IBRAHIM S M. 3D printed scaffolds for biomedical applications[J]. Materials Chemistry and Physics,2020,255: 123642.
[5] ZHENG X Y,LI N,XU Y,et al. A bilayer collagen scaffold with bevacizumab stabilizes chondrogenesis and promotes osteochondral regeneration[J]. Materials & Design,2022,221: 110981.
[6] ABDEL-HADY G M,NIINOMI M. Biocompatibility of Ti-alloys for long-term implantation[J]. Journal of the Mechanical Behavior of Biomedical Materials,2013,20: 407-415.
[7] CHEN G P,USHIDA T,TATEISHI T. Scaffold design for tissue engineering[J]. Macromolecular Bioscience,2002,2(2): 67-77.
[8] KAPFER S C,HYDE S T,MECKE K,et al. Minimal surface scaffold designs for tissue engineering[J]. Biomaterials,2011,32(29): 6875-6882.
[9] NOAILLY J,KOLDITZ,D,LACROIX D,et al. Influence of scaffold design on the mechanics and cell-seeding efficiency of tissue-engineered cartilage: A computational exploration using the triply periodic minimal surface structure[J]. Journal of the Mechanical Behavior of Biomedical Materials,2018,77: 661-671.
[10] HABIBI M,TURAN E,CUIJPERS V,et al. Triply periodic minimal surface architecture from additive manufacturing for enhanced functionalization of orthopedic implants[J]. Journal of the Mechanical Behavior of Biomedical Materials,2019,96: 78-88.
[11] HOLLANDER L,KOHL B,REISINGER A,et al. Optimization of triply periodic minimal surface architectures for biomedical applications[J]. Journal of the Mechanical Behavior of Biomedical Materials,2020,103: 103574.
[12] HE C,ZHU Y,LOU T,et al. Design of a novel 3D-printed porous bone scaffold with controlled permeability using triply periodic minimal surface (TPMS) structures[J]. Materials Science and Engineering,2020,116: 111203.
[13] YU X,LI M,LI X,et al. Preparation and evaluation of a novel triply periodic minimal surface (TPMS) structure-based porous scaffold for bone tissue engineering[J]. Journal of Materials Science: Materials in Medicine,2022,33: 32.
[14] LI X,WU Y,OU Y,et al. A biodegradable bone scaffold with controlled degradation and sustained release profile based on trimethyl chitosan and triply periodic minimal surface (TPMS) structure[J]. RSC Advances,2022,12: 3083-3092.
[15] YANG N,QUAN Z,ZHANG D W,et al. Multi-morphology transition hybridization CAD design of minimal surface porous structures for use in tissue engineering[J]. Computer-Aided Design,2014,56: 11-21.
[16] AFSHAR M,ANARAKI A P,MONTAZERIAN H,et al. Additive manufacturing and mechanical characterization of graded porosity scaffolds designed based on triply periodic minimal surface architectures[J]. Journal of the Mechanical Behavior of Biomedical Materials,2016,62: 481-494.
[17] LIU Z Q,GONG H,GAO J Z,et al. Topological design,mechanical responses and mass transport characteristics of high strength-high permeability TPMS-based scaffolds[J]. International Journal of Mechanical Sciences,2022,217: 107023.
