LIFT hydrogel printing: A defined route for highly controlled process
               DOI: 10.1088/1758-5082/2/1/014104.                  10.1186/1475-925x-10-19.
           43.  Gruene M, Pflaum M, Deiwick A, et al., 2011, Adipogenic   55.  Brown  MS,  Brasz  CF,  Ventikos  Y,  Arnold  CB,  2012,
               Differentiation of Laser-printed 3D Tissue Grafts Consisting   Impulsively Actuated Jets from thin Liquid Films for High-
               of  Human  Adipose-derived  Stem  Cells.  Biofabrication,   resolution Printing Applications. J Fluid Mech, 709:341–370.
               3:015005. DOI: 10.1088/1758-5082/3/1/015005.        DOI: 10.1017/jfm.2012.337.
           44.  Yusupov  VI,  Gorlenko  MV,  Cheptsov  VS,  et  al.,  2018,   56.  Hölzl  K,  Lin  S,  Tytgat  L,  et al.,  2016,  Bioink  Properties
               Laser  Engineering  of  Microbial  Systems.  Laser Phys Lett,   before,  during  and  after  3D  Bioprinting.  Biofabrication,
               15:015604.                                          8:032002. DOI: 10.1088/1758-5090/8/3/032002.
           45.  Unger C, Koch J, Overmeyer L, et al., 2012, Time-resolved   57.  Ringeisen  BR,  Spargo  BJ,  Wu  PK,  2010,  Cell  and  Organ
               Studies of Femtosecond-laser Induced Melt Dynamics. Opt   Printing. Springer Science and Business Media, Berlin.
               Express, 20:24864. DOI: 10.1364/oe.20.024864.   58.  Nasatto PL, Pignon F, Silveira JL, et al., 2015, Methylcellulose,
           46.  Hill C, 2016, Liquid-Phase Laser Induced Forward Transfer   a Cellulose Derivative with Original Physical Properties and
               for  Complex  Organic  Inks  and  Tissue  Engineering.  Ann   Extended Applications. Polymers (Basel), 7:777–803. DOI:
               Biomed Eng, 45:84–99. DOI: 10.1007/s10439-016-1617-3.  10.3390/polym7050777.
           47.  Akhatov W, Lindau I, Topolnikov O, et al., 2001, Collapse   59.  Shafiee  A,  Elham  G,  Ramesh  H,  et  al.,  2019,  Physics  of
               and  Rebound  of  a  Laser-induced  Cavitation  Bubble.  Phys   Bioprinting. Appl Phys Rev, 6:021315.
               Fluids, 13:29–32. DOI: 10.1063/1.1401810.       60.  McKinley GH, Renardy M, 2011, Wolfgang von Ohnesorge.
           48.  Mézel C, Hallo L, Souquet A, et al., 2009, Self-consistent   Phys Fluids, 23:127101. DOI: 10.1063/1.3663616.
               Modeling  of  Jet  Formation  Process  in  the  Nanosecond   61.  Yan J, Huang Y, Xu C, et al., 2012, Effects of Fluid Properties
               Laser  Pulse  Regime.  Phys Plasmas,  16:123112.  DOI:   and  Laser  Fluence  on  Jet  Formation  during  Laser  Direct
               10.1063/1.3276101.                                  Writing of Glycerol Solution. J Appl Phys, 112:083105. DOI:
           49.  Ali M, Pages E, Ducom A, et al., 2014, Controlling Laser-  10.1063/1.4759344.
               induced  Jet  Formation  for  Bioprinting  Mesenchymal  Stem   62.  Bush JW, 2004, Rayleigh Instability. In: MIT Lecture Notes
               Cells with High Viability and High Resolution. Biofabrication,   on Surface Tension, Lecture 5 (PDF) Massachusetts Institute
               6:045001. DOI: 10.1088/1758-5082/6/4/045001.        of Technology.
           50.  Wang  W,  Chrisey  DB,  2008,  Study  of  Impact-Induced   63.  Gorlenko M, Chutko EA, Churbanova ES, et al., 2018, Laser
               Mechanical Effects in Cell Direct. J Manuf Sci Eng, 130:1–10.  Microsampling  of  Soil  Microbial  Community.  J Biol  Eng,
           51.  Ringeisen BR, Pages E, Ducom A, et al., 2004, Laser Printing   12:1–11.
               of  Pluripotent  Embryonal  Carcinoma  Cells.  Tissue Eng,   64.  Minaev  NV,  Chutko  EA,  Churbanova  ES,  et al.,  2018,
               10:483–491.                                         Laser  Printing  of  Gel  Microdrops  with  Living  Cells  and
           52.  Kawecki  F,  Clafshenkel WP, Auger  FA,  et  al.,  2018,  Self-  Microorganisms.  KnE Energy Phys,  2018:23–31.  DOI:
               assembled Human Osseous Cell Sheets as Living Biopapers   10.18502/ken.v3i3.2010.
               for  the  Laser-assisted  Bioprinting  of  Human  Endothelial   65.  Koch L, Deiwick A, Franke A, et al., 2018, Laser Bioprinting
               Cells. Biofabrication, 10:035006. DOI: 10.1088/1758-5090/  of  Human  Induced  Pluripotent  Stem  Cells  the  Effect  of
               aabd5b.                                             Printing  and  Biomaterials  on  Cell  Survival,  Pluripotency,
           53.  Vass  C,  Smausz  T,  Hopp  B,  2004,  Wet  Etching  of  Fused   and  Differentiation.  Biofabrication,  10:035005.  DOI:
               Silica: A  Multiplex  Study.  J Phys D  Appl Phys,  37:2449–  10.1088/1758-5090/aab981.
               2454. DOI: 10.1088/0022-3727/37/17/018.         66.  Cheptsov  VS,  Tsypina  SI,  Minaev  NV,  et  al.,  2019,  New
           54.  Gruene  M,  Unger  C,  Koch  L,  et  al.,  2011,  Dispensing   Microorganism  Isolation  Techniques  With  Emphasis  On
               Pico  to  Nanolitre  of  a  Natural  Hydrogel  by  Laser-  Laser  Printing.  Int J Bioprint,  5:165.  DOI:10.18063/ijb.
               assisted  Bioprinting.  Biomed  Eng Online,  10:9–12.  DOI:   v5i1.165.












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