Multi-material 3D printing with electrically functional materials including conducting, sensing, insulating and semiconducting materials has led to the development of smart devices such as 3D structural electronics, sensors, batteries, etc. Electronically smart devices are a hot issue in 3D printing because they can certainly benefit from 3D printing technology, providing high design flexibility and customized functions. Shape-changing materials (e.g. shape memory polymers) incorporated in 3D printing have given birth to 4D printing, where 3D printed structures change in their shapes by external stimuli (temperature, light, water, etc.). The motivation of this review paper is to discuss mutual benefits from both 3D printed smart devices and 4D printed features, which can be built in a single body. It is expected that the combination of 3D printed smart devices and 4D printing would contribute to the development of high performance, adaptability to the environment and programmable 3D smart devices, which have not yet existed. This paper has reviewed the background of 3D printing, smart device fabrication using 3D printing, development into 4D printing, and future applications of 4D printing.

1 Layani, M., "UV Crosslinkable Emulsions with Silver Nanoparticles for Inkjet Printing of Conductive 3D Structures" 1 (1): 3244-3249, 2013

2 Seitz, H., "Three-Dimensional Printing of Porous Ceramic Scaffolds for Bone Tissue Engineering" 74 (74): 782-788, 2005

3 Jakus, A. E., "Three-Dimensional Printing of High-Content Graphene Scaffolds for Electronic and Biomedical Applications" 9 (9): 4636-4648, 2015

4 Deng, D., "Three-Dimensional Circuit Fabrication Using Four-Dimensional Printing and Direct Ink Writing" 286-291, 2016

5 Long, J. W., "Three-Dimensional Battery Architectures" 104 (104): 4463-4492, 2004

6 Nikzad, M., "Thermo-Mechanical Properties of a Highly Filled Polymeric Composites for Fused Deposition Modeling" 32 (32): 3448-3456, 2011

7 Mu, Q., "Thermal Cure Effects on Electromechanical Properties of Conductive Wires by Direct Ink Write for 4D Printing and Soft Machines" 26 (26): 045008-, 2017

8 Zhu, C., "Supercapacitors Based on Three-Dimensional Hierarchical Graphene Aerogels with Periodic Macropores" 16 (16): 3448-3456, 2016

9 강형석, "Smart Manufacturing: Past Research, Present Findings, and Future Directions" 한국정밀공학회 3 (3): 111-128, 2016

10 Smay, J. E., "Piezoelectric Properties of 3-X Periodic Pb(ZrxTi1-x)O-3-Polymer Composites" 92 (92): 6119-6127, 2002

11 Price, A. D., "Photopolymerization of 3D Conductive Polypyrrole Structures Via Digital Light Processing" 97981A-1-7-, 2016

12 Ryu, J., "Photo-Origami-Bending and Folding Polymers with Light" 100 (100): 161908-, 2012

13 Katstra, W., "Oral Dosage Forms Fabricated by Three Dimensional Printing™" 66 (66): 1-9, 2000

14 Kokkinis, D., "Multimaterial Magnetically Assisted 3D Printing of Composite Materials" 6 : 8643-, 2015

15 Sitthi-Amorn, P., "Multifab : A Machine Vision Assisted Platform for Multi-Material 3D Printing" 34 (34): 129-, 2015

16 Choi, J. -W., "Multi-Material Stereolithography" 211 (211): 318-328, 2011

17 Palmer, J. A., "Methods and Systems for Rapid Prototyping of High Density Circuits"

18 Palmer, J., "Mesoscale RF Relay Enabled By Integrated Rapid Manufacturing" 12 (12): 148-155, 2006

19 Yuan, S., "Material Evaluation and Process Optimization of CNT-Coated Polymer Powders for Selective Laser Sintering" 8 (8): 370-, 2016

20 Joe Lopes, A., "Integrating Stereolithography and Direct Print Technologies for 3D Structural Electronics Fabrication" 18 (18): 129-143, 2012

21 Seerden, K. A., "Ink-Jet Printing of Wax-Based Alumina Suspensions" 84 (84): 2514-2520, 2001

22 Gao, G., "Improved Properties of Bone and Cartilage Tissue from 3D Inkjet-Bioprinted Human Mesenchymal Stem Cells by Simultaneous Deposition and Photocrosslinking in Peg-Gelma" 37 (37): 2349-2355, 2015

23 Medina, F., "Hybrid Manufacturing : Integrating Direct-Write and Stereolithography" 129-143, 2005

24 Melocchi, A., "Hot-Melt Extruded Filaments Based on Pharmaceutical Grade Polymers for 3D Printing by Fused Deposition Modeling" 509 (509): 255-263, 2016

25 Zhu, C., "Highly Compressible 3D Periodic Graphene Aerogel Microlattices" 6 : 6962-, 2015

26 Fu, K., "Graphene Oxide-Based Electrode Inks for 3D-Printed Lithium-Ion Batteries" 28 (28): 2587-2594, 2016

27 Malone, E., "Freeform Fabrication of Ionomeric Polymer-Metal Composite Actuators" 12 (12): 244-253, 2006

28 Song, J. H., "Formulation and Multilayer Jet Printing of Ceramic Inks" 82 (82): 3374-3380, 1999

29 Emon, M. O. F., "Flexible Piezoresistive Sensors Embedded in 3D Printed Tires" 17 (17): 656-, 2017

30 Saari, M., "Fiber Encapsulation Additive Manufacturing : An Enabling Technology for 3D Printing of Electromechanical Devices and Robotic Components" 2 (2): 32-39, 2015

31 Saari, M., "Fabrication and Analysis of a Composite 3D Printed Capacitive Force Sensor" 3 (3): 136-141, 2016

32 Trachtenberg, J. E., "Extrusion-Based 3D Printing of Poly(Propylene Fumarate)in a Full-Factorial Design" 2 (2): 1771-1780, 2016

33 Muth, J. T., "Embedded 3D Printing of Strain Sensors within Highly Stretchable Elastomers" 26 (26): 6307-6312, 2014

34 Lee, J., "Effect of Degree of Crosslinking and Polymerization of 3D Printable Polymer/Ionic Liquid Composites on Performance of Stretchable Piezoresistive Sensors" 26 (26): 035043-, 2017

35 Weller, C., "Economic Implications of 3D Printing : Market Structure Models in Light of Additive Manufacturing Revisited" 164 : 43-56, 2015

36 Yanfeng Lu, "Direct-print/cure as a molded interconnect device (MID) process for fabrication of automobile cruise controllers" 대한기계학회 29 (29): 5377-5385, 2015

37 Duoss, E, "Direct-Write Assembly of Functional Inks for Planar and 3D Microstructures"

38 Vatani, M., "Direct-Print Photopolymerization for 3D Printing" 23 (23): 337-343, 2017

39 Hon, K., "Direct Writing Technology-Advances and Developments" 57 (57): 601-620, 2008

40 Hon, K., "Direct Writing Technology-Advances and Developments" 57 (57): 601-620, 2008

41 김민생, "Direct Metal Printing of 3D Electrical Circuit using Rapid Prototyping" 한국정밀공학회 10 (10): 147-150, 2009

42 Lewis, J. A., "Direct Ink Writing of 3D Functional Materials" 16 (16): 2193-2204, 2006

43 L. Jay Deiner, "Diffuse Reflectance Infrared Spectroscopic Identification of Dispersant/Particle Bonding Mechanisms in Functional Inks" MyJove Corporation (99) : 2015

44 Laszczak, P., "Development and Validation of a 3D-Printed Interfacial Stress Sensor for Prosthetic Applications" 37 (37): 132-137, 2015

45 Woodfield, T. B., "Design of Porous Scaffolds for Cartilage Tissue Engineering Using a Three-Dimensional Fiber-Deposition Technique" 25 (25): 4149-4161, 2004

46 Blumenthal, T., "Conformal Printing of Sensors on 3D and Flexible Surfaces Using Aerosol Jet Deposition" 2013

47 Adams, J. J., "Conformal Printing of Electrically Small Antennas on Three-Dimensional Surfaces" 23 (23): 1335-1340, 2011

48 Morteza Vatani, "Combined 3D Printing Technologies and Material for Fabrication of Tactile Sensors" 한국정밀공학회 16 (16): 1375-1383, 2015

49 Leong, K., "Building Porous Biopolymeric Microstructures for Controlled Drug Delivery Devices Using Selective Laser Sintering" 31 (31): 483-489, 2006

50 Hiroki Ota, "Application of 3D Printing for Smart Objects with Embedded Electronic Sensors and Systems" Wiley-Blackwell 1 (1): 1600013-, 2016

51 Yong-Jin Yoon, "Application of 3D Printing Technology for Designing Light-weight Unmanned Aerial Vehicle Wing Structures" 한국정밀공학회 1 (1): 223-228, 2014

52 Prasad, D., "Additive Manufacturing-A Brief Foray into the Advancements in Manufacturing Technologies" 3 : 115-119, 2015

53 Raviv, D., "Active Printed Materials for Complex Self-Evolving Deformations" 4 : 7422-, 2014

54 Ge, Q., "Active Origami by 4D Printing" 23 (23): 094007-, 2014

55 Ge, Q., "Active Materials by Four-Dimension Printing" 103 (103): 131901-, 2013

56 Saari, M., "Active Device Fabrication Using Fiber Encapsulation Additive Manufacturing" 26-39, 2015

57 Govindarajan, S. R., "A Solvent and Initiator Free, Low-Modulus, Degradable Polyester Platform with Modular Functionality for Ambient-Temperature 3D Printing" 49 (49): 2429-2437, 2016

58 Simon J. Leigh, "A Simple, Low-Cost Conductive Composite Material for 3D Printing of Electronic Sensors" Public Library of Science (PLoS) 7 (7): e49365-, 2012

59 Chee Meng Benjamin Ho, "A Review on 3D Printed Bioimplants" 한국정밀공학회 16 (16): 1035-1046, 2015

60 Mark Vehse, "A New Micro-Stereolithography-System based on Diode Laser Curing (DLC)" 한국정밀공학회 15 (15): 2161-2166, 2014

61 Bartlett, N. W., "A 3D-Printed, Functionally Graded Soft Robot Powered by Combustion" 349 (349): 161-165, 2015

62 Bakarich, S. E., "4D Printing with Mechanically Robust, Thermally Actuating Hydrogels" 36 (36): 1211-1217, 2015

63 Choi, J., "4D Printing Technology : A Review" 2 (2): 159-167, 2015

64 Tibbits, S., "4D Printing : Multi-Material Shape Change" 84 (84): 116-121, 2014

65 Pei, E., "4D Printing : Dawn of an Emerging Technology Cycle" 34 (34): 310-314, 2014

66 Wu, S. -Y., "3D-Printed Microelectronics for Integrated Circuitry and Passive Wireless Sensors" 1 : 15013-, 2015

67 Guo, S. -Z., "3D Printing of a Multifunctional Nanocomposite Helical Liquid Sensor" 7 (7): 6451-6456, 2015

68 Khoo, Z. X., "3D Printing of Smart Materials : A Review on Recent Progresses in 4D Printing" 10 (10): 103-122, 2015

69 Zarek, M., "3D Printing of Shape Memory Polymers for Flexible Electronic Devices" 28 (28): 4449-4454, 2016

70 Wang, X., "3D Printing of Polymer Matrix Composites : A Review and Prospective" 110 : 442-458, 2017

71 Sun, K., "3D Printing of Interdigitated Li-Ion Microbattery Architectures" 25 (25): 4539-4543, 2013

72 Fantino, E., "3D Printing of Conductive Complex Structures with in Situ Generation of Silver Nanoparticles" 28 (28): 3712-3717, 2016

73 Tan, W. S., "3D Printing by Selective Laser Sintering of Polypropylene Feed Channel Spacers for Spiral Wound Membrane Modules for the Water Industry" 11 (11): 151-158, 2016

74 Espalin, D., "3D Printing Multifunctionality : Structures with Electronics" 72 (72): 963-978, 2014

75 Bogue, R., "3D Printing : The Dawn of a New Era in Manufacturing?" 33 (33): 307-311, 2013

76 Hoy, M. B., "3D Printing : Making Things at the Library" 32 (32): 93-99, 2013

77 Foster, C. W., "3D Printed Graphene Based Energy Storage Devices" 7 : 42233-, 2017