Additive manufacturing of bone scaffolds
           16.  Abdkhorsand S, Sabersamandari S, 2017, Development of   Eng, 3(4): 649–657.
               nanocomposite  scaffolds  based  on  TiO   doped in  grafted   31.  Feng J, Fu J, Shang C, et al., 2018, Porous scaffold design by
                                            2
               chitosan/hydroxyapatite by freeze drying method and evaluation   solid T–splines and triply periodic minimal surfaces. Comput
               of biocompatibility. Int J Biol Macromol, 101: 51–58.  Methods Appl Mech Eng, 336, 333–352.
           17.  Fereshteh Z, Fathi M, Bagri A, et al., 2016, Preparation and   32.  Probst F  A, Hutmacher D  W, Müller D F,  et al., 2010,
               characterization of aligned porous PCL/zein scaffolds as drug   Calvarial  reconstruction  by customized  bioactive  implant.
               delivery systems via improved unidirectional freeze–drying   Handchir Mikrochir Plast Chir, 42(6): 369.
               method. Mater Sci Eng C Mater Biol Appl, 68: 613–622.  33.  Naing M W, Chua C K, Leong K F, et al., 2005, Fabrication
           18.  Janik H M, 2015, A review: Fabrication of porous polyurethane   of customised scaffolds using computer-aided design and
               scaffolds. Mater Sci Eng C Mater Biol Appl, 48: 586.  rapid prototyping techniques. Rapid Prototyp J, 11(4): 249–
           19.  Bose S, Ke D, Sahasrabudhe H,  et al.,  2017, Additive   259.
               manufacturing of biomaterials. Prog Mater Sci, 93:1-310.  34.  Ovsianikov  A,  Deiwick  A,  Vlierberghe  S  V,  et al., 2011,
           20.  Parthasarathy J, 2014, 3D modeling, custom implants and its   Laser fabrication of three–dimensional CAD scaffolds from
               future perspectives  in craniofacial  surgery.  Ann Maxillofac   photosensitive gelatin for applications in tissue engineering.
               Surg, 4(1): 9.                                      Biomacromolecules, 12(4): 851–858.
           21.  Jardini  A L, Larosa  M  A, Bernardes  L F,  et al., 2014,   35.  Yu K M, Chiu W K, Yeung Y C, 2006, Toolpath generation
               Customised  titanium  implant  fabricated  in additive   for layer manufacturing of fractal objects. Rapid Prototyp J,
               manufacturing for craniomaxillofacial surgery. Virtual Phys   12(4): 214–221.
               Prototyp, 9(2): 115–125.                        36.  Sing S L, Wiria F Eand Yeong W Y, 2018, Selective laser
           22.  Avaliable from: http://www.csiro.au/en/News/News–releases/   melting  of lattice structures:  A statistical  approach  to
               2014/3D–Heel–In–World–First–Surgery2014.            manufacturability  and mechanical  behavior.  Robot Comput
           23.  Song  W, Chen L, Seta J,  et al., 2017, Corona discharge:   Integr Manuf, 49: 170–180.
               A novel approach to fabricate three–dimensional electrospun   37.  Duan B, Cheung W, Land W M, 2011, Optimized fabrication
               nanofibers. Acs Biomater Sci Eng, 3(6): 1146–1153.  of Ca–P/PHBV nanocomposite scaffolds via selective laser
           24.  Hollister  S J, Flanagan  C  L,  Morrison  R  J,  et al.,  2016,   sintering for bone tissue engineering.  Biofabrication,  3(1):
               Integrating image–based design and 3D biomaterial printing   15001.
               to  create  patient  specific  devices  within  a  design  control   38.  Melchels  F P,  Bertoldi  K, Gabbrielli  R,  et al.,  2010,
               framework for clinical  translation.  Acs Biomater Sci Eng,   Mathematically  defined  tissue  engineering  scaffold
               2(10): 1658-1661.                                   architectures  prepared by stereolithography.  Biomaterials,
           25.  Shuai C, Guo W, Gao C, et al., 2018, An nMgO containing   31(27): 6909.
               scaffold:  Antibacterial  activity, degradation  properties  and   39.  Sercombe T B, Xu X, Challis V J, et al., 2015, Failure modes
               cell responses. Int J Bioprint, 4(1): 34-578.       in high strength and stiffness to weight scaffolds produced by
           26.  He J, Xu F, Dong R, et al., 2017, Electrohydrodynamic 3D   selective laser melting. Mater Des, 67: 501–508.
               printing of microscale poly (ε–caprolactone) scaffolds with   40.  Murr L E, Gaytan S  M, Medina F,  et al., 2010, Next–
               multi–walled carbon nanotubes. Biofabrication, 9(1): 15007.  generation biomedical implants using additive manufacturing
           27.  Guvendiren M, Molde J, Soares R, et al., 2016, Designing   of complex, cellular  and functional  mesh arrays.  Philos
               biomaterials for 3D printing. Acs Biomater Sci Eng, 2(10):   Trans, 368(1917): 1999.
               1679–1693.                                      41.  Cheah C M, Chua C K, Leong K F, et al., 2004, Automatic
           28.  Calignano F, 2014, Design optimization  of supports for   algorithm  for generating  complex  polyhedral  scaffold
               overhanging structures in aluminum and titanium alloys by   structures for tissue engineering. Tissue Eng, 10(4): 595–610.
               selective laser melting. Mater Design, 64(9): 203–213.  42.  Lu G, Xu S, Yan Q S, et al., 2013, Study on dimension change
           29.  Yan R, Luo D, Huang H, et al., 2018, Electron beam melting   law  from  CAD model  to  prototype  of  rapid  investment
               in  the  fabrication  of  three–dimensional  mesh  titanium   casting  based on selective  laser sintering.  Adv Mater Res,
               mandibular prosthesis scaffold. Sci Rep, 8(1): 750.  774–776(774–776): 1046–1050.
           30.  Yu G Z, Chou D T, Hong D, et al., 2017, Biomimetic rotated   43.  Florczyk S J, Simon M, Juba D, et al., 2017, A bioinformatics
               lamellar plywood motifs by additive manufacturing of metal   3D cellular morphotyping strategy for assessing biomaterial
               alloy scaffolds for bone tissue engineering. Acs Biomater Sci   scaffold niches. Acs Biomater Sci Eng, 3(10): 2302-2313.

           18                          International Journal of Bioprinting (2019)–Volume 5, Issue 1