Composite Bioprinting for Bio-fabrication
               Some research results in the field of tissue damage   References
           repairing  demonstrated  a  technology  with  broad
           application  prospects.  For  example,  3D  composite   1.   Groll J, Burdick JA, Cho DW, et al., 2018, A Definition of
           bioprinting  which  combines  extrusion  forming  with   Bioinks  and  their  Distinction  from  Biomaterial  Inks  [J].
           electrospinning technology has been proven to be able to   Biofabrication, 11(1):013001.
           effectively prepare tissue scaffold with a multiscale pore      https://doi.org/10.1088/1758-5090/aaec52
           structure, showing obvious advantages in the formation   2.   Gungor-Ozkerim PS, Inci I, Zhang YS, et al., 2018, Bioinks for
           of multi-scale micro-nano composite structure. Besides,   3D Bioprinting: An Overview [J]. Biomater Sci, 6(5):915–46.
           hybrid additive/subtractive manufacturing has been proven
           to have great potential in the construction of vessel-like      https://doi.org/10.1039/c7bm00765e
           microchannel structure, which is of great significance in   3.   Ng WL, Chua CK, Shen YF, 2019, Print Me An Organ! Why
           the formation of vascularized bioconstructs. Moreover, the   We Are Not There Yet [J]. Prog Polym Sci, 97:101145.
           printing of sacrificial materials into the whole biological      https://doi.org/10.1016/j.progpolymsci.2019.101145
           structure not only helps provide mechanical support in   4.   Ng WL, Chan A, Ong YS, et al., 2020, Deep Learning for
           the  manufacturing  process  but  also  is  very  important   Fabrication  and  Maturation  of  3D  Bioprinted  Tissues  and
           for the construction of microchannel structures. On the
           other hand, the 3D composite bioprinting integrated with   Organs [J]. Virtual Phys Prototyp 15(3):340–58
           light,  magnetic,  and  acoustic  field  control  would  have   5.   Ozbolat  IT,  Hospodiuk  M,  2016,  Current  Advances  and
           a  greater  development  potential  if  it  is  combined  with   Future  Perspectives  in  Extrusion-based  Bioprinting  [J].
           environmentally  responsive  smart  materials.  Recently,   Biomaterials, 76:321–43.
           some  innovative  research  achievements  have  been      https://doi.org/10.1016/j.biomaterials.2015.10.076
           made, such as the manufacture of artificial blood vessels.   6.   Emmermacher  J,  Spura  D,  Cziommer  J,  et  al.,  2020,
           However,  it  is  still  limited  by  the  difficulties  in  the
           construction of large-scale artificial regeneration tissue as   Engineering Considerations on Extrusion-based Bioprinting:
           well as repairing large area tissue damage. Furthermore,   Interactions  of  Material  Behavior,  Mechanical  Forces  and
           how to attain rapid vascularization of large-scale artificial   Cells in the Printing Needle [J]. Biofabrication, 12(2):025022.
           regeneration tissue remains an urgent question to address.     https://doi.org/10.1088/1758-5090/ab7553
               In terms of 3D composite bioprinting process and   7.   Gao  G,  Kim  BS,  Jang  J,  et al.,  2019,  Recent  Strategies
           system research, the printing process, whether extrusion   in  Extrusion-Based  Three-Dimensional  Cell  Printing
           printing,  electrospinning  or  the  existing  3D  composite   toward Organ Biofabrication [J]. ACS Biomater Sci Eng,
           bioprinting technology, is being further integrated with
           the  technologies  such  as  direct  cell  assembly,  dynamic   5(3):1150–69.
           cross-linking formation, cell behavior guiding, controlled      https://doi.org/10.1021/acsbiomaterials.8b00691
           drug-releasing, etc. as required. The constant expansion   8.   Gudapati  H,  Dey  M,  Ozbolat  I,  2016,  A  Comprehensive
           and enrichment of the research scope of 3D composite    Review  on  Droplet-based  Bioprinting:  Past,  Present  and
           bioprinting promote further application and innovation of   Future [J]. Biomaterials, 102:20–42.
           this technology in the field of tissue and organ repairing      https://doi.org/10.1016/j.biomaterials.2016.06.012
           and regeneration. The existing interface problems in the
           integration  of  multiscale  structure  and  multi-gradient   9.   Ng WL, Lee JM, Yeong WY, et al., 2017, Microvalve-based
           components  and  in  the  technical  feasibility  of  multi-  Bioprinting Process, Bio-inks and Applications [J]. Biomater
           process  integration  remain  to  be  addressed  in  parallel   Sci, 5(4):632–47.
           with  the  continuous  innovation  of  the  3D  composite      https://doi.org/10.1039/c6bm00861e
           bioprinting process and system.                     10.  Koch  L,  Brandt  O,  Deiwick A,  et  al.  2017,  Laser-assisted
           Acknowledgments                                         Bioprinting  at  Different  Wavelengths  and  Pulse  Durations
                                                                   with a Metal Dynamic Release Layer: A Parametric Study
           This  work  was  supported  by  grants  from  the  National   [J]. Int J Bioprint, 3(1):42–53.
           Natural  Science  Foundation  of  China  (No.  61973206,      https://doi.org/10.18063/ijb.2017.01.001
           61703265, 61803250, 61933008) and Shanghai Science
           and  Technology  Committee  Rising-Star  Program  (No.   11.  Onses  MS,  Sutanto  E,  Ferreira  PM,  et al.,  2015,
           19QA1403700).                                           Mechanisms,  Capabilities,  and  Applications  of  High-
                                                                   Resolution  Electrohydrodynamic  Jet  Printing  [J].  Small,
           Conflict of interest                                    11(34):4237–66.
           The authors declare no conflicts of interest.           https://doi.org/10.1002/smll.201500593

           16                          International Journal of Bioprinting (2021)–Volume 7, Issue 1