Yusupov, et al.
               with a Metal Dynamic Release Layer: A Parametric Study.   10.1007/s00339-010-6030-4.
               Int J Bioprinting, 3:42–53. DOI: 10.18063/ijb.2017.01.001.  31.  Desrus H, Chassagne B, Catros S, et al., 2016, Laser Assisted
           20.  Sorkio A, Koch L, Koivusalo L, et al., 2018, Human Stem Cell   Bioprinting using a Femtosecond Laser with and without a
               Based  Corneal  Tissue  Mimicking  Structures  Using  Laser-  Gold Transductive Layer: A Parametric Study. Proceedings
               assisted 3D Bioprinting and Functional Bioinks. Biomaterials,   Volume  9706,  Optical  Interactions  with  Tissue  and  Cells
               171:57–71. DOI: 10.1016/j.biomaterials.2018.04.034.  XXVII. DOI: 10.1117/12.2209087.
           21.  Guillemot  F,  Souquet  A,  Catros  S,  et  al.,  2010,  High-  32.  Cheptsov  VS,  Churbanova  ES,  Yusupov  VI,  et al.,  2018,
               throughput  Laser  Printing  of  Cells  and  Biomaterials  for   Laser  Printing  of  Microbial  Systems:  Effect  of Absorbing
               Tissue  Engineering.  Acta Biomater,  6:2494–2500.  DOI:   Metal Film. Lett Appl Microbiol, 67:544–549. DOI: 10.1111/
               10.1016/j.actbio.2009.09.029.                       lam.13074.
           22.  Catros S, Guillemot F, Nandakumar A, et al., 2011, Layer-  33.  Riester  D,  Budde  J,  Gach  C,  et  al.,  2016,  High  Speed
               by-Layer Tissue Microfabrication Supports Cell Proliferation   Photography of Laser Induced Forward Transfer (LIFT) of
               In Vitro and In Vivo. Tissue Eng Part C Methods, 18:62–70.   Single and Double-layered Transfer Layers for Single Cell
               DOI: 10.1089/ten.tec.2011.0382.                     Transfer. J Laser Micro Nanoeng, 11:199–203. DOI: 10.2961/
           23.  Michael S, Sorg H, Peck CT, et al., 2013, Tissue Engineered   jlmn.2016.02.0010.
               Skin  Substitutes  Created  by  Laser-Assisted  Bioprinting   34.  Zarubin VP, Zhigarkov VS, Yusupov VI, et al., 2019, Physical
               form Skin-Like Structures in the Dorsal Skin Fold Chamber   Processes Affecting the Survival of Microbiological Systems
               in  Mice.  PLoS One,  8:e57741.  DOI:  10.1371/journal.  in  Laser  Printing  of  Gel  Droplets.  Quantum Electron,
               pone.0057741.                                       49:1068–1073. DOI: 10.1070/qel17081.
           24.  Antoshin AA, Churbanov SN, Minaev NV, et al., 2019, LIFT-  35.  Tomasina  S,  Bodet  C,  Mota  T,  et  al.,  2019,  Bioprinting
               Bioprinting,  is  it  Worth  it?  Bioprinting,  15:e00052.  DOI:   Vasculature:  Materials,  Cells  and  Emergent  Techniques.
               10.1016/j.bprint.2019.e00052.                       Materials (Basel), 12:2701. DOI: 10.3390/ma12172701.
           25.  Bashkatov  AN,  Genina  EA,  Kochubey  VI,  et  al.,  2005,   36.  Young  HD,  Modi  R,  Bucaro  M,  2002,  Generation  of
               Optical Properties of Human Skin Subcutaneous and Mucous   Mesoscopic Patterns of Viable Escherichia coli by Ambient
               Tissues in the Wavelength Range from 400 to 2000 nm. J   Laser  Transfer.  Biomaterials,  23:161–166.  DOI:  10.1016/
               Phys D  Appl Physics,  38:2543–2555.  DOI:  10.1088/0022-  s0142-9612(01)00091-6.
               3727/38/15/004.                                 37.  Xiong R, Zhang Z, Huang Y, 2015, Identification of Optimal
           26.  Carvalho S, Gueiral N, Nogueira E, et al., 2017, Comparative   Printing  Conditions  for  Laser  Printing  of Alginate Tubular
               Study of the Optical Properties of Colon Mucosa and Colon   Constructs. J Manuf Process, 20:450–455. DOI: 10.1016/j.
               Precancerous Polyps between 400 and 1000 nm. Dynamics and   jmapro.2015.06.023.
               Fluctuations in Biomedical Photonics XIVXIV International   38.  Palla-Papavlu  A,  Córdoba  C,  Patrascioiu  A,  et al.,  2013,
               Society  for Optics and Photonics,  10063:100631L.  DOI:   Deposition  and  Characterization  of  Lines  Printed  through
               10.1117/12.2253023.                                 Laser-induced  Forward  Transfer.  Appl Phys  A Mater Sci
           27.  Pagès  E,  Rémy  M,  Kériquel  V,  et al.,  2015,  Creation  of   Process, 110:751–755. DOI: 10.1007/s00339-012-7279-6.
               Highly  Defined  Mesenchymal  Stem  Cell  Patterns  in Three   39.  Pescosolido L, Miatto S, Di Meo C, et al., 2010, Injectable
               Dimensions  by  Laser-Assisted  Bioprinting.  J Nanotechnol   and In Situ Gelling Hydrogels for Modified Protein Release.
               Eng Med, 6:021005. DOI: 10.1115/1.4031217.          Eur Biophys J, 39:903-9. DOI: 10.1007/s00249-009-0440-2.
           28.  Zhang  Z,  Xu  C,  Xiong  R,  et al.,  2017,  Effects  of  Living   40.  Ouyang L, Highley CB, Rodell CB, et al., 2016, 3D Printing of
               Cells  on  the  Bioink  Printability  during  Laser  Printing.   Shear-Thinning Hyaluronic Acid Hydrogels with Secondary
               Biomicrofluidics, 11:034120. DOI: 10.1063/1.4985652.  Cross-Linking. ACS Biomater Sci Eng, 2:1743–1751. DOI:
           29.  Zhang  Z,  Chai W,  Xiong  R,  et al.,  2017,  Printing-induced   10.1021/acsbiomaterials.6b00158.
               Cell Injury Evaluation during Laser Printing of 3T3 Mouse   41.  Cochis A, Bonetti L, Sorrentino R, et al., 2018, 3D Printing of
               Fibroblasts.  Biofabrication,  9:025038.  DOI:  10.1088/1758-  Thermo-responsive Methylcellulose Hydrogels for Cell-sheet
               5090/aa6ed9.                                        Engineering.  Materials  (Basel),  11:1–14.  DOI:  10.3390/
           30.  Unger  C,  Gruene  M,  Koch  L,  et  al.,  2011,  Time-resolved   ma11040579.
               Imaging  of  Hydrogel  Printing  Via  Laser-induced  Forward   42.  Ovsianikov  A,  Gruene  M,  Pflaum  M,  et al.,  2010,  Laser
               Transfer. Appl Phys A Mater Sci Process, 103:271–277. DOI:   Printing of Cells into 3D Scaffolds. Biofabrication, 2:014104.

                                       International Journal of Bioprinting (2020)–Volume 6, Issue 3        91