3D printed gene-activated implants for bone regeneration
           References                                              of Treatment for Patients with Chronic Lower Limb Ischemia.
                                                                   J Cardiovasc Pharmacol Ther, 20:473–82.
           1.   Number of All-listed Procedures for Discharges from Shortly-  14.  Bozo IY, Komlev VS, Drobyshev AY, et al., 2015, Method
               stay  Hospitals,  2010.  Available  from:  http//www.cdc.gov/  for Creating  a Personalized  Gene-activated  Implant  for
               nchs/data/nhds/10Detaileddiagnosesprocedures/2010det10_  Regenerating Bone Tissue. Patent No. EP3130342.
               alllistedprocedures.pdf. [Last accessed on 2020 March 01].  15.  Fowler  BO,  Marković  M,  Brown  WE,  1993,  Octacalcium
           2.   Rogers GF, Greene AK, 2017, Autogenous Bone Graft: Basic   Phosphate. 3. Infrared and Raman Vibrational Spectra. Chem
               Science and Clinical Implications. J Craniofac Surg, 23:323–7.  Mater, 5:1417–23.DOI: 10.1021/cm00034a009.
           3.   Hernandez I, Kumar A, Joddar B, 2017, A Bioactive Hydrogel   16.  Kang HW, Lee  SJ, Ko IK,  et  al., 2016, A 3D Bioprinting
               and 3D-Printed Polycaprolactone  System for Bone  Tissue   System  to  Produce  Human-scale  Tissue  Constructs  with
               Engineering. Gels, 3:26.DOI: 10.3390/gels3030026.   Structural Integrity. Nat Biotechnol, 34:312–9.DOI: 10.1038/
           4.   Ge Z, Tian X, Heng BC, et al., 2009, Histological Evaluation   nbt.3413.
               of Osteogenesis of 3D-Printed Poly-lactic-co-glycolic   17.  Daly  AC, Pitacco  P, Nulty J,  et al., 2018, 3D-printed
               Acid (PLGA) Scaffolds in a Rabbit Model. Biomed Mater,   Microchannel  Networks to Direct  Vascularisation  during
               4:021001.DOI: 10.1088/1748-6041/4/2/021001.         Endochondral Bone Repair.  Biomaterials, 162:34–46.DOI:
           5.   Shim JH, Kim SE, Park JY, et al., 2014, Three-dimensional   10.1016/j.biomaterials.2018.01.057.
               Printing of rhBMP-2-loaded Scaffolds with Long-term   18.  Lal H, Patralekh MK, 2018, 3D-Printing and its Applications
               Delivery  for Enhanced  Bone Regeneration  in a  Rabbit   in  Orthopaedic  Trauma:  A  Technological  Marvel.  J  Clin
               Diaphyseal  Defect.  Tissue Eng Part  A, 20:1980–92.DOI:   Orthop Trauma, 9:260–8.DOI: 10.1016/j.jcot.2018.07.022.
               10.1089/ten.tea.2013.0513.                      19.  Huang KH, Lin  YH, Shie MY,  et  al., Effects  of Bone
           6.   Ahlfeld T, Doberenz F, Kilian D, et al., 2018, Bioprinting of   Morphogenic  Protein-2  Loaded  on  the  3D-Printed
               Mineralized  Constructs  Utilizing  Multichannel  Plotting  of   MesoCSScaffolds.  J  Formos  Med Assoc, 117:879-87.DOI:
               a Self-setting Calcium Phosphate Cement and a Cell-laden   10.1016/j.jfma.2018.07.010.
               Bioink.  Biofabrication,  10:045002.  DOI:  10.1088/1758-  20.  Lee SJ, Lee D, Yoon TR, et al., 2016, Surface Modification
               5090/aad36d.                                        of 3D-Printed Porous  Scaffolds via Mussel-inspired
           7.   Dorozhkin  SV,  2009,  Calcium  Orthophosphates  in  Nature   Polydopamineand  Effective  Immobilization  of rhBMP-2
               Biology and Medicine. Materials, 2:399–498.DOI: 10.3390/  to Promote Osteogenic  Differentiation  for Bone  Tissue
               ma2020399.                                          Engineering.  Acta Biomater,  40:182–191.DOI:  10.1016/j.
           8.   Liu  Y, Cooper  PR, Barralet  JE,  et  al.,  2007,  Influence  of   actbio.2016.02.006.
               Calcium Phosphate Crystal Assemblies on the Proliferation   21.  Du  M,  Chen  B,  Meng  Q,  et  al.,  2015,  3D Bioprinting  of
               and  Osteogenic  Gene  Expression of Rat  Bone  Marrow   BMSC-laden Methacrylamide Gelatin Scaffolds with CBD-
               Stromal Cells. Biomaterials, 28:1393–1403.DOI: 10.1016/j.  BMP2-collagen Microfibers. Biofabrication, 7:044104.DOI:
               biomaterials.2006.11.019.                           10.1088/1758-5090/7/4/044104.
           9.   Deev RV, Drobyshev AY, Bozo IY,  et al., 2015, Ordinary   22.  Deev RV, Drobyshev RV, Bozo IY, et al., 2013, Construction
               and  Activated  Bone  Grafts:  Applied  Classification  and   and Biological  Effect Evaluation  of Gene-activated
               the  Main Features.  Biomed  Res Int, 2015:365050.DOI:   Osteoplastic Material  with Human  VEGF Gene.  Cell
               10.1155/2015/365050.                                Transplant Tissue Eng, 8:78–85.
           10.  Murphy SV, Atala A, 2014, 3D Bioprinting of Tissues and   23.  Feichtinger  GA, Hofmann  AT, Slezak  P,  et  al., 2014,
               Organs. Nat Biotechnol, 32:773–85.DOI: 10.1038/nbt.2958.  Sonoporation  Increases  Therapeutic  Efficacy  of  Inducible
           11.  Komlev  VS,  Popov VK,  Mironov  AV,  et  al., 2015, 3D   and Constitutive BMP2/7 In Vivo Gene Delivery. Hum Gene
               Printing of Octacalcium Phosphate Bone Substitutes. Front   Ther Methods, 25:57–71.DOI: 10.1089/hgtb.2013.113.
               Bioeng Biotechnol, 3:81.                        24.  Evans CH, Huard J, 2015, Gene  Therapy  Approaches
           12.  Barinov SM, Vakhrushev IV, Komlev VS, et al., 2015, 3D   to  Regenerating  the  Musculoskeletal  System.  Nat  Rev
               Printing of Ceramic Matrices for Engineering of Bone Tissue.   Rheumatol, 11:234–42.DOI: 10.1038/nrrheum.2015.28.
               Inorg Mater, 6:316–322.DOI: 10.1177/1074248415574336.  25.  Cunniffe GM, Gonzalez-Fernandez  T, Daly  A,  et  al.,
           13.  Deev RV, Bozo IY, Mzhavanadze ND, et al., 2015, pCMV-  2017,  Three-dimensional  Bioprinting  of Polycaprolactone
               vegf165 Intramuscular Gene Transfer is an Effective Method   Reinforced  Gene  Activated  Bioinksfor Bone  Tissue

           108                         International Journal of Bioprinting (2020)–Volume 6, Issue 3