Material issues in additive manufacturing: A review

Journal of Manufacturing Processes

Volumn 25, Issue , 2017, Pages 185-200

  Singh, Sunpreet ^a   Ramakrishna, Seeram ^b   Singh, Rupinder ^a  

^a GURU NANAK DEV ENGINEERING COLLEGE   (India)

^b NATIONAL UNIVERSITY OF SINGAPORE   (Singapore)

Author keywords

Additive manufacturing; Biomedical; Ceramic; Digital hybrid AM; Metal; Polymer

Indexed keywords

CERAMIC MATERIALS; FUNCTIONAL POLYMERS; MANUFACTURE; MEDICAL APPLICATIONS; METALS; POLYMERS;

BIO-MANUFACTURING; BIOMEDICAL; BIOMEDICAL APPLICATIONS; CERAMIC; FLEXIBLE FILAMENTS; FUSED DEPOSITION MODELING; INCREASING THE SERVICE LIVES; THREE-DIMENSIONAL OBJECT;

3D PRINTERS;

EID: 85007035359     PISSN: 15266125     EISSN: None     Source Type: Journal    
DOI: 10.1016/j.jmapro.2016.11.006     Document Type: Review

References (144)

1. [1] Wohlers, T.T., Wohlers report: additive manufacturing and 3D printing state of the industry. Annu Worldw Prog Rep, 2013.
2. [2] Giannatsis, J., Dedoussis, V., Additive fabrication technologies applied to medicine and health care: a review. Int J Adv Manuf Technol 40:1–2 (2009), 116–127.
3. [3] Synder, J., Hamid, Q., Wang, C., Chang, R., Emami, K., Wu, H., et al. Bioprinting cell-laden matrigel for radioprotection study of liver by pro-drug conversion in a dual-tissue microfluidic chip. Biofabrication, 3(3), 2011 Paper No. 034112.
4. [4] Melchels, F.P.W., Jan, F., Grijpma, D.W., A review on stereolithography and its applications in biomedical engineering. Biomaterials 31:24 (2010), 612–6130.
5. [5] Murphy, S.V., Atala, A., 3D bioprinting of tissues and organs. Nat Biotechnol 32:8 (2014), 773–785.
6. [6] Lane, W.A., Some remarks on the treatment of fractures. Br Med J, 1, 1895, 861.
7. [7] Nag, S., Banerjee, R., Fundamentals of medical implant materials. Narayan, R., (eds.) Materials for medical devices, 23, 2012, ASM, Handbook, 6–17.
8. [8] Osman, R.B., Swain, M.V., A critical review of dental implant materials with an emphasis on titanium versus zirconia. Materials 8 (2015), 932–958.
9. [9] Brettle, J., Survey of the literature on metallic surgical implants, injury. Br J Accid Surg 1 (1970), 26–39.
10. [10] Kruth, J.P., Mercelis, P., Froyen, L., Rombouts, M., Binding mechanisms in selective laser sintering and selective laser melting. Rapid Prototyp J 11:1 (2005), 26–36.
11. [11] Simon, J.P., Febry, G., An overview of implant materials. Acta Orthop Belg 57 (1991), 1–5.
12. [12] Johansson, C.B., Han, C.H., Wennerberg, A., Albrektsson, T., A quantitative comparison of machined commercially pure titanium and titanium-aluminum-vanadium implants in rabbit bone. Int J Oral Maxillofac Implants 13:3 (1998), 315–321.
13. [13] Aherwar, A., Singh, A.K., Patnaik, A., Current and future biocompatibility aspects of biomaterials for hip prosthesis. Bioengineering 3:1 (2016), 23–43.
14. [14] Kshang, D., Lu, J., Yao, C., Haberstroh, K.M., Webster, T.J., The role of nanometer and sub-micron surface features on vascular and bone cell adhesion on titanium. Biomaterials 29 (2008), 970–983.
15. [15] Rack, H.J., Qazi, J.I., Titanium alloys for biomedical applications. Mater Sci Eng C 26 (2006), 1269–1277.
16. [16] Langer, R., Tirrell, D.A., Designing materials for biology and medicine. Nature 428 (2004), 487–492.
17. [17] Peltola, M., Kinnunen, I., Aitasalo, K., Reconstruction of orbital wall defects with bioactive glass plates. J Oral Maxillofac Surg 66 (2008), 639–646.
18. [18] Best, S.M., Porter, A.E., Thian, E.S., Huang, J., Bioceramics: past present and for the future. J Eur Ceram Soc 28 (2008), 1319–1327.
19. [19] Hench, L.L., The story of bioglass. J Mater Sci Mater Med 17 (2006), 967–978.
20. [20] Ratner, B.D., Hoffman, A.S., Schoen, F.J., Lemons, J.E., Biomaterials science: an introduction to materials in medicine. 2nd ed., 2004, Elsevier Academic Press, San Diego, CA.
21. [21] Frazier, W.E., Polakovics, D., Koegel, W., Qualifying of metallic materials and structures for aerospace applications. JOM 53 (2001), 16–18.
22. [22] Wong, K.V., Hernandez, A., A review of additive manufacturing. ISRN Mech Eng 2012 (2012), 1–10.
23. [23] Wang, X., Gong, X., Chou, K., Review on powder-bed laser additive manufacturing of Inconel 718 parts. Proc IMechE Part B: J Eng Manuf, 2016, 1–14, 10.1177/0954405415619883.
24. [24] Roy, S., Khutia, N., Das, D., Das, M., Balla, V.K., Bandyopadhyay, A., et al. Understanding compressive deformation behavior of porous Ti using finite element analysis. Mater Sci Eng C 64 (2016), 436–443.
25. [25] Hoeges, S., Development of a maraging steel powder for additive manufacturing. 2016, GKN Sinter Metals Engineering GmbH Radevormwald, Germany.
26. [26] Seifi, M., Salem, A., Beuth, J., Harrysson, O., Lewandowski, J.J., Overview of materials qualification needs for metal additive manufacturing. JOM 68 (2016), 747–764.
27. [27] Boulos, M., Plasma power can make better powders. Met Powder Rep 59 (2004), 16–21.
28. [28] Araci, K., Mangabhai, D., Akhtar, K., Production of titanium by the armstrong process. Qian, M., Froes, F.H., (eds.) Titanium powder metallurgy: science, technology and applications, 2015, Elsevier Waltham, MA, 149–162.
29. [29] Barbis, D.P., Gasior, R.M., Walker, G.P., Capone, J.A., Schaeffer, T.S., Titanium powders from the hydride-dehydride process. Qian, M., Froes, F.H., (eds.) Titanium powder metallurgy: science technology and applications, 2015, Elsevier Waltham, MA, 101–105.
30. [30] Roberts, P.R., The production of PREP titanium powder, advances in powder metallurgy. Proceeding of the 1989 powder metallurgy conference & exhibition, metal powder industries federation, San Diego, CA, 1989, 427–438.
31. [31] Gai, G., Yang, Y., Jin, L., Zou, X., Wu, Y., Particle shape modification and related property improvements. Powder Technol 183 (2008), 115–121.
32. [32] Froes, F.H., Titanium powder metallurgy: a review-part 1. Adv Mater Process 170 (2012), 16–22.
33. [33] McCracken, C.G., Motchenbacher, C., Barbis, D.P., Review of titanium powder production methods. Int J Powder Metall 46 (2010), 19–26.
34. [34] Sun, P., Fang, Z.Z., Xia, Y., Zhang, Y., Zhou, C., A novel method for production of spherical Ti–6Al–4V powder for additive manufacturing. Powder Technol 301 (2016), 331–335.
35. [35] Yolton, C.F., Froes, F.H., Conventional titanium powder production. Qian, M., Froes, F.H., (eds.) Titanium powder metallurgy: science, technology and applications, 2015, Elsevier Waltham, MA, 51–67.
36. [36] Chen, S., A new centrifugal atomization technique of spray rotation for powder preparation. Trans Nonferrous Metals Soc China 7 (1997), 12–15.
37. [37] Antony, L.V.M., Reddy, R.G., Processes for production of high-purity metal powders. JOM 2003 (2003), 14–18.
38. [38] Yukimasa, T., Takemori, S., A review of metal powder production. Metall Rev MMIJ 6 (1989), 38–53.
39. [39] Benjamin, J.S., Mechanical alloying—a perspective. Metal Powder Rep 45 (1990), 122–127.
40. [40] Sago, J.A., Newkirk, J.W., Brasel, G.M., Rapid mechanical alloying for metal powder production. Adv Powder Metall Part Mater, 2, 1997 1–3–11–15.
41. [41] Sigmund, W.M., Novel powder-processing methods for advanced ceramics. J Am Ceram Soc 83 (2000), 1557–1574.
42. [42] Ring, T.A., 1996. Ceramic powder synthesis. Fundamentals of ceramic powder processing and synthesis. Elsevier. pp. 81–83.
43. 2. Fahrenholtz, W.G., Wuchina, E.J., Lee, W.E., Zhou, Y., (eds.) Ultra-high temperature ceramics: materials for extreme environment applications, 2014, JohnWiley & Sons, Inc., Hoboken, NJ, 197–235.
44. [44] Noviyanto, A., Nishimura, T., Kitano, M., Ohashi, N., Pulverization of oxide powders utilizing thermal treatment inammonia-based atmosphere. Eur Ceram Soc 36 (2016), 4083–4088.
45. [45] Colombo, P., Cellular ceramics. Conv Philos Trans R Soc A, 364, 2006, 10.1098/rsta.2005.1683.
46. [46] Messing, G.L., Zhang, S.C., Jayanthi, G.V., Ceramic powder synthesis by spray pyrolysis. J Am Ceram Soc 76 (1993), 2707–2726.
47. 2 ceramics with high strength using boron carbide and spark plasma sintering. J Am Ceram Soc, 2016, 1–8.
48. 2 ceramics with a high dielectric constant, a core–shell structure, and a fine-grained microstructure by means of a sol-precipitation method. Ceram Int 42 (2016), 7397–7405.
49. [49] Novakova, M.L., Novak, M.J., Barna, J., Torok, J., Special materials used in FDM rapid prototyping technology applications. Intelligent engineering systems (INES). IEEE 16th international conference, 12–15th June, 2012, 73–76 E-ISBN: 978-1-4673-2693-3.
50. [50] Wu, X., Study on ceramic mold investment casting based on ice patterns made by rapid prototyping method. (Bachelor degree thesis). 1997, Tsinghua University, Beijing, China.
51. [51] Masood, S.H., Song, W.Q., Development of new metal/polymer materials for rapid tooling using fused deposition modelling. Mater Des 25 (2004), 587–594.
52. [52] Bigg, D.M., Adhesion and durability of metal-polymer bond. J Mater Sci 19 (1984), 2431–2453.
53. [53] Nikzad, M., Masood, S.H., Sbarski, I., Groth, A., Thermo-mechanical properties of a metal-filled polymer composite for fused deposition modelling applications. 5th Australasian congress on applied mechanics, ACAM, 10–12th December 2007, Brisbane, Australia, 2007.
54. [54] Thrimurthulu, K., Pandey, P.M., Reddy, N.V., Optimum part deposition orientation in fused deposition modelling. Int J Mach Tools Manuf 44 (2004), 585–594.
55. [55] Nikzad, M., Masood, S.H., Sbarski, I., Thermo-mechanical properties of a highly filled polymeric composites for fused deposition modeling. Mater Des 32 (2011), 3448–3456.
56. [56] Ilardo, R., William, C.B., Design and manufacturing of a formula SAE intake system using fused deposition modeling and fibre-reinforced composite materials. Rapid Prototyp J 16:3 (2010), 174–179.
57. [57] Agarwala, M.K., Bandyopadhyay, A., Weeren, R., Langrana, N.A., Safari, A., Danforth, S.C., et al. Fused deposition of ceramics (FDC) for structural silicon nitride components. Proceedings of the solid freeform fabrication symposium, Austin, Texas, 1996, 335–344.
58. [58] Venkataraman, N., The process-property-performance relationships of feedstock material used for fused deposition of ceramic (FDC). (PhD thesis). 2000, Department of Ceramic and Materials Science and Engineering, Rutgers University, New Brunswick.
59. [59] Reddy, B.V., Reddy, N.V., Ghosh, A., Fused deposition modelling using direct extrusion. Virtual Phys Prototyp 2 (2007), 51–60.
60. [60] Marcincinova, L.N., Application of fused deposition modeling technology in 3D printing rapid prototyping area. Manuf Ind Eng 11:4 (2012), 35–37.
61. [61] Gray, R.W., Baird, D.G., Bohn, J.H., Effects of processing conditions on short TLCP fiber reinforced FDM parts. Rapid Prototyp J 4:1 (1998), 14–25.
62. [62] Seyi, O., Susmita, B., Amit, B., Fused deposition of ceramics (FDC) and composites. Proceeding of SFF symposium held in Austin, Texas, August 6–8, 2001, 224–232.
63. [63] Dietmar, D., Sandra, C.C., Dominik, R., Suitability of PLA/TCP for fused deposition modeling. Rapid Prototyp J 18:6 (2012), 500–507.
64. [64] Reazul, H.A.H., Md, S.W., Norul, L.J., Fabrication process of polymer nano composite filament for fused deposition modeling. Appl Mech Mater 465 (2014), 8–12.
65. [65] Hutmacher, D.W., Schantz, T., Zein, I., Ng, K.W., Teoh, S.H., Tan, K.C., Mechanical properties and cell cultural response of polycaprolactone scaffolds designed and fabricated via fused deposition modeling. J Biomed Mater Res 55:2 (2000), 203–216.
66. [66] Zein, I., Hutmacher, D.W., Tan, K.C., Teoh, S.H., Fused deposition modeling of novel scaffold architectures for tissue engineering applications. Biomaterials 23:4 (2002), 1169–1185.
67. [67] Chim, H., Hutmacher, D.W., Chou, A.M., Oliveira, A.L., Reis, R.L., Lim, T.C., et al. A comparative analysis of scaffold material modifications for load-bearing applications in bone tissue engineering. Int J Oral Maxillofac Surg 35 (2006), 928–934.
68. [68] Bose, S., Suguira, S., Bandyopadhyay, A., Processing of controlled porosity ceramic structures via fused deposition. Scr Mater 41:9 (1999), 1009–1014.
69. [69] Kalita, S.J., Bose, S., Hosick, H.L., Bandyopadhyay, A., Development of controlled porosity polymer-ceramic composite scaffolds via fused deposition modeling. Mater Sci Eng: C 23:5 (2003), 611–620.
70. [70] Bose, S., Darsell, J., Kintner, M., Hosick, H., Bandyopadhyay, A., Pore size and pore volume effects on alumina and TCP ceramic scaffolds. Mater Sci Eng: C 23:4 (2003), 479–486.
71. [71] Negi, S., Dhiman, S., Sharma, R.K., Basics and applications of rapid prototyping medical models. Rapid Prototyp J 20:3 (2014), 256–267.
72. [72] Marwah, O.M.F., Halim, N.F.A., Shukri, M.S., Mohamad, E.J., Ibrahim, M., A study on palm fiber reinforces as a filament in portable FDM. ARPN J Eng Appl Sci 11 (2016), 7828–7834.
73. [73] Ning, F., Cong, W., Qiu, J., Wei, J., Wang, S., Additive manufacturing of carbon fiber reinforced thermoplastic composites using fused deposition modeling. Compos Part B 80 (2015), 369–378.
74. [74] Sa'ude, N., Masood, S.H., Nikzad, M., Ibrahim, M., Ibrahim, M.H.I., Dynamic mechanical properties of copper-ABS composites for FDM feedstock. Int J Eng Res Appl 3:3 (2013), 1257–1263.
75. [75] Burg, K.J.L., Porter, S., Kellam, J.F., Biomaterial developments for bone tissue engineering. Biomaterials 21 (2000), 2347–2359.
76. [76] Ogura, N., Kawada, M., Chang, W., Zhang, Q., Lee, S.Y., Kondoh, T., et al. Differentiation of the human mesenchymal stem cells derived from bone marrow and enhancement of cell attachment by fibronectin. J Oral Sci 46:4 (2004), 207–213.
77. [77] Xie, F., He, X., Cao, S., Qu, X., Structural and mechanical characteristics of porous 316L stainless steel fabricated by indirect selective laser sintering. J Mater Process Technol 213 (2013), 838–843.
78. [78] Cheng, A., Humayun, A., Cohen, D.J., Boyan, B.D., Schwartz, Z., Additively manufactured 3D porous Ti–Al–4V constructs mimic trabecular bone structure and regulate osteoblast proliferation, differentiation and local factor production in a porosity and surface roughness dependent manner. Biofabrication 6 (2014), 045007–045019.
79. [79] Ghita, O.R., Jamesb, E., Trimble, R., Evans, K.E., Physico-chemical behaviour of poly (ether ketone) (PEK) in high temperature laser sintering (HT-LS). J Mater Process Technol 214 (2014), 969–978.
80. [80] Wang, X.C., Laoui, T., Bonse, J., Kruth, J.P., Lauwers, B., Froyen, L., Direct selective laser sintering of hard metal powders: experimental study and simulation. Int J Adv Manuf Technol 19 (2002), 351–357.
81. [81] Shishkovsky, I.V., Volova, L.T., Kuznetsov, M.V., Morozov, Y.G., Parkin, I.P., Porous biocompatible implants and tissue scaffolds synthesized by selective laser sintering from Ti and NiTi. J Mater Chem 8 (2008), 1309–1317.
82. [82] Eosoly, S., Brabazon, D., Lohfeld, S., Looney, L., Selective laser sintering of hydroxyapatite/poly-∈-caprolactone scaffolds. Acta Biomater 6 (2010), 2511–2517.
83. [83] Salmoria, G.V., Fancello, E.A., Roesler, C.R.M., Dabbas, F., Functional graded scaffold of HDPE/HA prepared by selective laser sintering: microstructure and mechanical properties. Int J Adv Manuf Technol 65 (2013), 1529–1534.
84. [84] Shuai, C., Yang, B., Peng, S., Li, Z., Development of composite porous scaffolds based on poly(lactide-co-glycolide)/nano-hydroxyapatite via selective laser sintering. Int J Adv Manuf Technol 69 (2013), 51–57.
85. [85] XiaoHui, S., Wei, L., PingHui, S., QingYong, S., QingSong, W., YuSheng, S., et al. Selective laser sintering of aliphaticpolycarbonate/hydroxyapatite composite scaffolds for medical applications. Int J Adv Manuf Technol 81 (2015), 15–25.
86. [86] Shibli, J.A., Mangano, C., Mangano, F., Rodrigues, J.A., Cassoni, A., Bechara, K., et al. Bone-to-implant contact around immediately loaded direct laser metal-forming transitional implants in human posterior maxilla. J Periodontol 84:6 (2013), 732–737.
87. [87] Gregolin, R.F., Barbosa, F.M., da-Rocha, T.L., de-Camargo Zavaglia, C.A., Tokimatsu, R.C., Development and mechanical characterization of a mandibular prosthesis in titanium alloy fabricated by direct metal laser sintering (DMLS). Proceedings of 22nd international congress of mechanical engineering, November 3rd–7th, 2013, Ribeirão Preto, SP, Brazil, 2013.
88. [88] Pattanayak, D.K., Fukuda, A., Matsushita, T., Takemoto, M., Fujibayashi, S., Sasaki, K., et al. Bioactive Ti metal analogous to human cancellous bone: fabrication by selective laser melting and chemical treatments. Acta Biomater 7 (2011), 1398–1406.
89. [89] Majumdara, J.D., Manna, I., Kumar, A., Bhargava, P., Nath, A.K., Direct laser cladding of Co on Ti–6Al–4V with a compositionally graded interface. J Mater Process Technol 209 (2009), 2237–2243.
90. [90] Traini, T., Mangano, C., Sammons, R.L., Mangano, F., Macchi, A., Piattelli, A., Direct laser metal sintering as a new approach to fabrication of an isoelastic functionally graded material for manufacture of porous titanium dental implants. Dent Mater 24 (2008), 1525–1533.
91. [91] Nasr, E.A., Ali, K., Al-Ahmari, A., Moiduddin, K., Digital design and fabrication of customized mandible implant. 2014, World Automation Congress, TSI Press.
92. [92] Heinl, P., Müller, L., Körner, C., Singer, R.F., Müller, F.A., Cellular Ti–6Al–4V structures with interconnected macro porosity for bone implants fabricated by selective electron beam melting. Acta Biomater 4 (2008), 1536–1544.
93. [93] Liu, Y., Li, S., Hou, W., Wang, S., Hao, Y., Yang, R., et al. Electron beam melted beta-type Ti–24Nb–4Zr–8Sn porous structures with high strength-to-modulus ratio. J Mater Sci Technol 32 (2016), 505–508, 10.1016/j.jmst.2016.03.020.
94. [94] Ruiz, M.S.I., Frías, M.A.N., Rider, R.M., Guillén, A.P., Rangel, A.G., Fundamentals of stereolithography, an useful tool for diagnosis in dentistry. Int J Dent Sci, 17(1), 2015 ISSN: 1659-1046.15.
95. [95] Yan, Y., Li, S., Zhang, R., Lin, F., Wu, R., Lu, Q., et al. Rapid prototyping and manufacturing technology: principle, representative technics, applications, and development trends. Tsinghua Sci Technol 14:1 (2009), 1–12.
96. [96] Winder, J., Bibb, R., Medical rapid prototyping technologies: state of the art and current limitations for application in oral and maxillofacial surgery. J Oral Maxillofac Surg 63:7 (2005), 1006–1015.
97. [97] Nayar, S., Bhuminathan, S., Bhat, W.M., Rapid prototyping and stereolithography in dentistry. J Pharm Bioallied Sci 7 (2015), S216–S219.
98. [98] Matsuda, T., Mizutani, M., Arnold, S.C., Molecular design of photocurable liquid biodegradable copolymers: synthesis and photocuring characteristics. Macromolecules 33:3 (2000), 795–800.
99. [99] Maji, P.K., Banerjee, P.S., Sinha, A., Application of rapid prototyping and rapid tooling for development of patient-specific craniofacial implant: an investigative study. Int J Adv Manuf Technol 36 (2008), 510–515.
100. [100] Balla, V.K., Bandyopadhyay, P.P., Bose, S., Bandyopadhyay, A., Compositionally graded yttria-stabilized zirconia coating on stainless steel using laser engineered net shaping (LENSTM). Scr Mater 57 (2007), 861–864.
101. [101] Krishna, B.V., Bose, S., Bandyopadhyay, A., Fabrication of Porous NiTi shape memory alloy structures using laser engineered net shaping. J Biomed Mater Res B Appl Biomater 89:2 (2009), 481–490.
102. 2 structures using laser engineered net shaping (LENS). Acta Biomater 5 (2009), 1831–1837.
103. [103] Bakar, N.S.A., Alkahari, M.R., Boejang, H., Analysis on fused deposition modeling performance. J Zhejiang Univ Sci A 11 (2010), 972–977.
104. [104] Kumar, P., Ahuja, I.P.S., Singh, R., Application of fusion deposition modelling for rapid investment casting—a review. Int J Mater Eng Innov 3 (2012), 204–227.
105. [105] Liou, F.W., Rapid prototyping and engineering applications. A toolbox for prototype development. 2008, CRC Press, Taylor & Francis Group, London.
106. [106] Grimm, T., Fused deposition modelling: a technology evaluation. Time-Compress Technol 11 (2003), 1–6.
107. [107] Bellini, A., Güçeri, S., Bertoldi, M., Liquefier dynamics in fused deposition. J Manuf Sci Eng 126 (2004), 237–246.
108. [108] Upcraft, S., Fletcher, R., The rapid prototyping technologies. Assem Autom 23 (2003), 318–330.
109. [109] Greul, M., Pintat, T., Greulich, M., Rapid prototyping of functional metallic parts. Comput Ind 28:1 (1995), 23–28.
110. [110] Woodfield, T.B.F., Malda, J., de Wijn, J., Péters, F., Riesle, J., van Blitterswijk, C.A., Design of porous scaffolds for cartilage tissue engineering using a three-dimensional fiber-deposition technique. Biomaterials 25 (2004), 4149–4161.
111. [111] Wang, F., Shor, L., Darling, A., Khalil, S., Güçeri, S., Lau, A., Precision deposition and characterization of cellular poly-caprolactone tissue scaffolds. Rapid Prototyp J 10 (2004), 42–49.
112. [112] Ang, T.H., Sultana, F.S.A., Hutmacher, D.W., Wong, Y.S., Fuh, J.Y.H., Mo, X.M., et al. Fabrication of 3D chitosan-hydroxyapatite scaffolds using a robotic dispersing system. Mater Sci Eng C 20 (2002), 35–42.
113. [113] Zeng, W., Lin, F., Shi, T., Zhang, R., Nian, Y., Ruan, J., et al. Fused deposition modelling of an auricle framework for microtia reconstruction based on CT images. Rapid Prototyp J 14/5 (2008), 280–284.
114. [114] Gronet, P.M., Waskewicz, G.A., Richardson, C., Preformed acrylic cranial implants using fused deposition modeling: a clinical report. J Prosthet Dent 90 (2003), 429–433.
115. [115] Zeltinger, J., Sheerwood, J.K., Graham, D.M., Mueller, R., Griffith, L.G., Effects of pore size and void fraction on cellular adhesion, proliferation and matrix deposition. Tissue Eng 7 (2001), 557–572.
116. [116] Lam, C.X.F., Mo, X.M., Teoh, S.H., Hutmacher, D.W., Scaffold development using 3D printing with a starch-based polymer. Mater Sci Eng 20 (2002), 49–56.
117. [117] Drescher, P., Spath, S., Seitz, H., Fabrication of biodegradable, porous scaffolds using a low-cost 3D printer. Int J Rapid Manuf 4 (2014), 140–147.
118. [118] Zahn, H., Hles, J.F., Nlenhaus, M., Wool as a biological composite structure. Ind Eng Chem Res 19 (1980), 496–501.
119. [119] Simpson, W.S., Crawshaw, G.H., Wool: science and technology. 2002, England Woodhead Publishing, Cambridge.
120. [120] Feughelman, M., Mechanical properties and structure of alpha-keratin fibres: wool, human hair and related fibres. 1997, University of New South Wales Press.
121. [121] Kock, J.W., Physical and mechanical properties of chicken feather materials. (Thesis). 2006, Georgia Institute of Technology.
122. [122] Canetti, M., Cacciamani, A., Bertini, F., Structural characterization and thermal behaviour of wool keratin hydrolizates-polypropylene composites. J Polym Res 20 (2013), 181–189.
123. [123] Schmidt, W.F., Innovative feather utilization strategies. National poultry waste, management symposium proceedings, 1998.
124. [124] Bitter, J., A study of erosion phenomena. Wear 6 (1963), 5–21.
125. [125] Tanase, C.E., Spiridon, I., PLA/chitosan/keratin composites for biomedical applications. Mater Sci Eng C 40 (2014), 242–247.
126. [126] Joshi, P.C., Kuruganti, T., Duty, C.E., Peter, W.H., Ott, R.D., Love, L.J., et al. Direct digital additive manufacturing technologies: path towards hybrid integration. IEEE, 2012 ISBN: 978-1-4673-2482-3/12.
127. [127] Joshi, P.C., Kuruganti, T., Duty, C.E., Printed and hybrid electronics enabled by digital additive manufacturing technologies. Srivasan, T.S., Sudarshan, T.S., (eds.) Additive manufacturing: innovations, advances, and applications, 2016, CRC Press (Taylor and Francis) (Chapter 5).
128. [128] Kerbrat, O., Mognol, P., Hascoët, J.Y., A new DFM approach to combine machining and additive manufacturing. 2011 https://arxiv.org/pdf/1106.3176. [Accessed 11 May 2015].
129. [129] Liou, F., Slattery, K., Kinsella, M., Newkirk, J., Chou, H.N., Landers, R., Applications of a hybrid manufacturing process for fabrication of metallic structures. Rapid Prototyp J 13 (2007), 236–244.
130. [130] Bonnard, R., Mognol, P., Hascoët, J.Y., A new digital chain for additive manufacturing processes. Virtual Phys Prototyp 5 (2010), 75–88.
131. [131] Kostakis, V., Papachristou, M., Commons-based peer production and digital fabrication: the case of a RepRap-based, Lego-built 3D printing-milling machine. Telemat Inform 31 (2013), 434–443.
132. [132] Li, J., Wasley, T., Nguyen, T.T., Ta, V.D., Shephard, J.D., Stringer, J., et al. Hybrid additive manufacturing of 3D electronic systems. J Micromech Microeng 26 (2016), 105005–105019.
133. [133] Friel, R.J., Harrisa, R.A., Ultrasonic additive manufacturing: a hybrid production process for novel functional products. Proced CIRP 6 (2013), 35–40.
134. [134] Karunakaran, K.P., Suryakumar, S., Pushpa, V., Akula, S., Low cost integration of additive and subtractive processes for hybrid layered manufacturing. Robot Comp-Integr Manuf 26 (2010), 490–499.
135. [142] Ho, C.M.B., Ng, S.H., Yoon, Y.J., A review on 3d printed bioimplants. Int J Precis Eng Manuf 16:5 (2015), 1035–1046.
136. [143] Bikas, H., Stavropoulos, P., Chryssolouris, G., Additive manufacturing methods and modelling approaches: a critical review. Int J Adv Manuf Technol 83 (2016), 389–405.
137. 4V implant with honeycomb-like structure for biomedical applications. Rapid Prototyp J 16 (2010), 44–49.
138. [145] Griffith, M.L., Keicher, D.M., Atwood, C.L., Romero, J.A., Smugeresky, E., Harwell, L.D., et al. Free form fabrication of metallic components using laser engineered net shaping (LENS™). Solid Freeform Symp, 1996, 125–132.
139. [146] Boyer, R., Weisch, G., Collings, E.W., Materials properties handbook: titanium alloy. 1994, ASM International ISBN: 13-978-0-87170-481-8.
140. [147] A.F. Antas, F.J. Lino, R. Neto, Utilização das tecnologias de prototipagem rápida na área médica. 5° Congresso Luso-Moçambicano de Engenharia Maputo 2008.
141. [148] F. Fischer, Thermoplastics: the best choice for 3D printing, Stratasys Inc. White Paper, 2011.
142. [149] S. Kumar and J.P. Kruth, Composites by rapid prototyping technology, Materials & Design, 31, 2010, 250-256.
143. [150] D. Williams, An Introduction to Medical and Dental Materials, Concise Encyclopedia of Medical & Dental Materials, D. Williams, Ed., Pergamon Press and The MIT Press, 1990, pp. 17-20.
144. [151] J. Li, T. Wasley, T.T. Nguyen, V.D. Ta, J.D. Shephard, J. Stringer, R. Kay, Hybrid additive manufacturing of 3D electronic systems. Journal of Micromechanics and Microengineering, 23, 2016, 105005. doi: 10.1088/0960-1317/26/10/105005.