Solid freeform techniques are revolutionising technology with great potential to fabricate highly organized biodegradable scaffolds for damaged tissues and organs. Scaffolds fabricated via Solid freeform (SFF) techniques have more pronounced effect in bone tissue engineering. SFF techniques produce various types of scaffolds from different biomaterials with specific pore size, geometries, orientation, interconnectivity and anatomical shapes. Scaffolds needs to be designed from such biomaterials which can attach directly to natural tissues and mimic its properties, so ideally mechanical properties of scaffolds should be same as that of regenerating tissues for best results. The scaffolds designed without optimized mechanical properties would lead to the reduced nutrition diffusion within tissue engineered constructs (TECs) causing tissue necrosis. These scaffolds are mainly processed from ceramics and polymers like calcium phosphate, polydioxane, €-polycaprolactone, polylactic and polyglycolic acids etc. While, hydrogel scaffolds provide bridge for encapsulated cells and tissues to integrate with natural ECM. Likewise, 2D images from radiography were not sufficient for the prediction of the brain structure, cranial nerves, vessel and architecture of base of the skull and bones, which became possible using the 3D prototyping technologies. Any misrepresentation can lead to fatal outcomes. Biomodelling from these techniques for spinal surgery and preoperative planning are making its way toward successful treatment of several spinal deformities and spinal tumor. In this review we explored laser based and printing SFF techniques following its methodologies, principles and most recent areas of application with its achievements and possible challenges faced during its applications.

1 Haumont T, "Wilmington robotic exoskeleton : a novel device to maintain arm improvement in muscular disease" 31 : 44-49, 2011

2 Ahlqvist A, "Using stereolithography models in planning spinal surgery" American Society of Mechanical Engineers 403-404, 2002

3 Cooke MN, "Use of stereolithography to manufacture critical-sized 3D Biodegradable scaffolds for bone ingrowth" 64 : 65-69, 2002

4 "Transplant jaw made by 3D printer claimed as first"

5 Tellis BC, "Trabecular scaffolds using miro CT guided fused deposition modelling" 10 : 171-178, 2009

6 Duan B, "Three-dimensional nanocomposites scaffolds fabricated via selected laser sintering for bone tissue engineering" 6 : 4495-4505, 2010

7 Cui X, "Thermal inkjet printing in tissue engineering and regenerative medicine" 6 : 149-155, 2012

8 Izatt MT, "The use of physical biomodelling in complex spinal surgery" 16 : 1507-1518, 2007

9 Murphy CM, "The effect of mean pore size on cell attachment, proliferation and migration in collagen glycosaminoglycan scaffolds for tissue engineering" 31 : 461-466, 2010

10 Staiger MP, "Synthesis of topological ordered open cell porous magnesium" 64 : 2572-2574, 2010

11 Despa V, "Study of selective laser sintering : a qualitative and objective approach" 6 : 150-155, 2011

12 Shuai C, "Structure and properties of nanohydroxypatite scaffolds for bone tissue engineering with a selective laser sintering system" 22 : 285703-, 2011

13 Bourell DL, "Selective laser sintering of metals and ceramics" 28 : 369-381, 1992

14 Tan KH, "Selective laser sintering of biocompatible polymers for applications in tissue engineering" 15 : 113-124, 2005

15 Hutmacher DW, "Scaffolds in tissue engineering bone and cartilage" 21 : 2529-2543, 2000

16 Hutmacher DW, "Scaffold-based tissue engineering : rationale for computer-aided design and solid freeform fabrication systems" 22 : 354-362, 2004

17 Hart GW, "Rapid prototyping web page"

18 Miller JS, "Rapid casting of patterned vascular networks for perfusable engineered three-dimensional tissues" 11 : 768-774, 2012

19 Dewidar MM, "Properties of solid core and porous surface Ti–6Al–4V implants manufactured by powder metallurgy" 454 : 442-446, 2008

20 Xianmiao C, "Properties and in vitro biological evaluation of nano-hydroxyapatite/chitosan membranes for bone guided regeneration" 29 : 29-35, 2009

21 Liu X, "Porous and strong bioactive glass(13–93)scaffolds prepared by unidirectional freezing of camphene-based suspensions" 8 : 415-423, 2012

22 Tampieri A, "Porosity graded hydroxyapatite ceramics to replace natural bone" 22 : 1365-1370, 2001

23 Lee KW, "Poly(propylene fumarate)bone tissue engineering scaffold fabrication using stereolithography : effects of resin formulations and laser parameters" 8 : 1077-1084, 2007

24 Nguyen KT, "Photopolymerizable hydrogels for tissue engineering applications" 23 : 4307-4314, 2002

25 Elisseeff J, "Photoencapsulation of chondrocytes in poly(ethylene oxide)-based semi-interpenetrating networks" 51 : 164-171, 2000

26 Fisher JP, "Photocrosslinking characteristics and mechanical properties of diethyl fumarate/poly(propylene fumarate)biomaterials" 23 : 4333-4343, 2002

27 Endres M, "Osteogenic induction of human bone marrow-derived mesenchymal progenitor cells in novel synthetic polymer-hydrogel matrices" 9 : 689-702, 2003

28 Silverstein J, "Organ Printing’ Could Drastically Change Medicine (ABC News, 2006)"

29 Liu CZ, "Novel 3D collagen scaffolds fabricated by indirect printing technique for tissue engineering" 85 : 519-528, 2008

30 Ventola CL, "Medical applications for 3D printing : current and projected uses" 39 : 704-711, 2014

31 Werner J, "Mechanical properties and in-vitro cell compatibility of hydroxyapatite ceramics with graded post structure" 23 : 4285-4294, 2002

32 Perry K, "Man makes surgical history after having his shattered face rebuilt using 3Dprinted parts"

33 Mapili G, "Laser-layered microfabrication of spatially patterned functionalized tissue-engineering scaffolds" 75B : 414-424, 2005

34 Odde DJ, "Laser guided direct writing of living cells" 67 : 312-318, 2000

35 Odde DJ, "Laser guided direct writing for applications in biotechnology" 17 : 385-389, 1999

36 BBC News, "Inverness girl Hayley Fraser gets 3D-printed hand"

37 Derby B, "Inkjet printing of functional and structural materials : fluid property requirements, feature stability, and resolution" 40 : 395-414, 2010

38 Simon JL, "In vivo bone response to 3D periodic hydroxyapatites caffolds assembled by direct ink writing" 83 : 747-758, 2007

39 Wiria F, "Improved biocomposite development of poly(vinyl alcohol)and hydroxyapatite for tissue engineering scaffold fabrication using selective laser sintering" 19 : 989-996, 2008

40 Leukers B, "Hydroxyapatite scaffold for bone tissue engineering made by 3D printing" 16 : 1121-1124, 2005

41 Bryant SJ, "Hydrogel properties influence ECM production by chondrocytes photoencapsulated in poly(ethylene glycol)hydrogels" 59 : 63-72, 2002

42 Wei C, "High-precision flexible fabrication of tissue engineering scaffolds using distinct polymers" 4 : 025009-, 2012

43 Liu C, "Gradient collagen/nanohydroxyapatite composite scaffold : development and characterization" 5 : 661-669, 2009

44 Savalani MM, "Fabrication of porous bioactive structures using the selective laser sintering technique" 221 : 873-886, 2007

45 Yin L, "Fabrication of 3D inter-connective porous ceramics via ceramic green machining and bonding" 28 : 531-537, 2008

46 Tan KH, "Fabrication and characterization of three-dimensional poly(etherether-ketone)/hydroxyapatite biocomposite scaffolds using laser sintering" 219 : 183-194, 2005

47 Liu VA, "Engineering protein and cell adhesivity using PEO-terminated triblock polymers" 60 : 126-134, 2002

48 Fielding GA, "Effects of silica and zinc oxide doping on mechanical and biologicalpropertiesof 3D printed tricalcium phosphate tissue engineering scaffolds" 28 : 113-122, 2012

49 Stein R, "Doctors use 3-D printing to help a baby breathe"

50 Chua CK, "Development of tissue scaffolds using selective laser sintering of polyvinyl alcohol/hydroxyapatite biocomposite for craniofacial and joint defects" 15 : 1113-1121, 2004

51 Gabbrielli R, "Development of modelling methods for materials to be used as bone substitutes" 361–363 : 901-906, 2008

52 Kang HW, "Development of an indirect solid freeform fabrication process based on microstereolithography for 3D porous scaffolds" 3 : 85-95, 2010

53 Bondy M, "Development of a finite element/multi-body model of anewborn infant for restraint analysis and design" 17 : 149-162, 2014

54 Simpson RL, "Development of a 95/5 poly(L-lactide-co-glycolide)/ hydroxyapatite and beta-tricalcium phosphate scaffold as bone replacement material via selective laser sintering" 84 : 17-25, 2008

55 Lipowiecki M, "Design of bone scaffolds structures for rapid prototyping with increased strength and osteoconductivity" 83 : 914-922, 2010

56 BBC, "D-printed sugar network to help grow artificial liver’’"

57 Duan B, "Customized Ca–P/PHBV nanocomposite scaffolds for bone tissue engineering: design, fabrication, surface modification and sustained release of growth factor" 7 : S615-S622, 2010

58 Wahl DA, "Controlling the processing of collagen hydroxyapatite scaffolds for bone tissue engineering" 19 : 015011-, 2007

59 Hedberg EL, "Controlled release of an osteogenic peptide from injectable biodegradable polymeric composites" 84 : 137-150, 2002

60 Sah MK, "Computational approaches in tissue engineering" 27 : 13-20, 2012

61 Zhao L, "Comparison of multipotent differentiation potentials of murineprimary bone marrow stromal cells and mesenchymal stem cell line C3H10T1/2" 84 : 56-64, 2009

62 Mao K, "Clinical application of computer-designed polystyrene models in complex severe spinal deformities : a pilot study" 19 : 797-802, 2010

63 The Engineer, "Building body parts with 3D printing’’"

64 Williams JM, "Bone tissue engineering using polycaprolactone scaffolds fabricated via selective laser sintering" 26 : 4817-4827, 2005

65 Lee JW, "Bone regeneration using a microstereolithography-produced customized poly(propylene fumarate)/diethyl fumarate photopolymer 3-D scaffold incorporating BMP-2 loaded PLGA microspheres" 32 : 744-752, 2011

66 Ozbolat IT, "Bioprinting toward organ fabrication : challenges and future trends" 60 : 691-699, 2013

67 Mironov V, "Bioprinting : a beginning" 12 : 631-634, 2006

68 Vlierberghe SV, "Biopolymer-based hydrogels as Scaffolds for tissue engineering application : a review" 12 : 1387-1408, 2011

69 Fu Q, "Bioactive glass scaffolds for bone tissue engineering : state of the art and future perspectives" 31 : 1245-1256, 2011

70 Shea CM, "BMP treatment of C3H10T1/2 mesenchymal stem cells induces both chondrogenesis and osteogenesis" 90 : 1112-1127, 2003

71 Li C, "Application of the polystyrene model made by 3-D printing rapid prototyping technology for operation planning in revision lumbar discectomy" 20 : 475-480, 2015

72 HULL CW, "Apparatus for production of three-dimensional objects by stereolithography. U.S. Patent No 4,575,330"

73 Melchels FPW, "Additive manufacturing of tissues and organs" 37 : 1079-1104, 2012

74 Melchels FPW, "A review on stereolithography and its applications" 31 : 6121-6130, 2010

75 "3D-Bioprinting may soon produce transplantable human tissues"

76 Geraldine TK, "3D printing and neurosurgery— ready for prime time?" 80 : 233-235, 2013

77 Mannoor MS, "3D printed bionic ears" 13 : 2634-2639, 2013

78 Seunarine K, "3D polymer scaffolds for tissue engineering" 1 : 281-296, 2006

79 Xu N, "3D artificial bones for bone repair prepared by computed tomography-guided fused deposition modeling for bone repair" 6 : 14952-14963, 2014