Using Spheroids to build 3D Bioprinted Tumor Microenvironment
               Drops: Droplet-based Microfluidics for Ultrahigh-throughput   108.  Lee  K,  Kim  C,  Yang  JY,  et al., 2012, Gravity-oriented
               Biology. J Phys D Appl Phys, 46:114004.             Microfluidic Device for Uniform and Massive Cell Spheroid
               https://doi.org/10.1088/0022-3727/46/11/114004      Formation. Biomicrofluidics, 6:14114–47.
           98.  Chan HF, Zhang Y, Ho YP, et al., 2013, Rapid Formation of      https://doi.org/10.1063/1.3687409
               Multicellular  Spheroids  in  Double-emulsion  Droplets  with   109.  Fiddes LK, Luk VN, Au SH, et al., 2012, Hydrogel Discs for
               Controllable Microenvironment. Sci Rep, 3:3462.     Digital Microfluidics. Biomicrofluidics, 6:14112–211.
               https://doi.org/10.1038/srep03462                   https://doi.org/10.1063/1.3687381
           99.  Kim C, Chung S, Kim YE, et al., 2011, Generation of Core-  110.  Eydelnant IA, Li BB,  Wheeler  AR, 2014, Microgels on-
               shell Microcapsules with  Three-dimensional  Focusing   demand. Nat Commun, 5:3355.
               Device for Efficient Formation of Cell Spheroid. Lab Chip,      https://doi.org/10.1038/ncomms4355
               11:246–52.                                      111.  Aijian  AP,  Garrell  RL,  2015,  Digital  Microfluidics  for
               https://doi.org/10.1039/C0LC00036A                  Automated  Hanging Drop Cell  Spheroid  Culture.  J  Lab
           100.  Grist SM, Nasseri SS, Laplatine L, et al., 2019, Long-term   Autom, 20:283–95.
               Monitoring  in  a  Microfluidic  System  to  Study  Tumour      https://doi.org/10.1177/2211068214562002
               Spheroid Response to Chronic and Cycling Hypoxia. Sci Rep,   112.  Vadivelu  RK, Kamble  H, Shiddiky MJ,  et al., 2017,
               9:17782.                                            Microfluidic Technology for the Generation of Cell Spheroids
               https://doi.org/10.1038/s41598-019-54001-8          and Their Applications. Micromachines, 8:94.
           101.  Wang  Y, Zhao L,  Tian C,  et al., 2015, Geometrically      https://doi.org/10.3390/mi8040094
               Controlled  Preparation  of  Various Cell  Aggregates  by   113.  Moshksayan K, Kashaninejad N,  Warkiani ME,  et al.,
               Droplet-based Microfluidics. Anal Methods, 7:10040–51.  2018,  Spheroids-on-a-chip:  Recent  Advances  and  Design
               https://doi.org/10.1039/C5AY02466H                  Considerations  in  Microfluidic  Platforms  for  Spheroid
           102.  Sun Q, Tan SH, Chen Q, et al., 2018, Microfluidic Formation   Formation and Culture. Sens Actuat B Chem, 263:151–76.
               of Coculture Tumor Spheroids with Stromal Cells As a Novel      https://doi.org/10.1016/j.snb.2018.01.223
               3D Tumor Model for Drug Testing. ACS Biomater Sci Eng,   114.  Utama RH, Atapattu L, O’Mahony AP,  et al., 2020, A 3D
               4:4425–33.                                          Bioprinter  Specifically  Designed  for  the  High-Throughput
               https://doi.org/10.1021/acsbiomaterials.8b00904     Production of Matrix-Embedded  Multicellular  Spheroids.
           103.  Yazdi SR, Shadmani A, Bürgel SC, et al., Adding the “Heart”   IScience, 23:101621.
               to Hanging Drop Networks for Microphysiological  Multi-     https://doi.org/10.1016/j.isci.2020.101621
               tissue Experiments. Lab Chip, 15:4138–47.       115.  Ling K, Huang G, Liu  J,  et  al., 2015, Bioprinting-Based
               https://doi.org/10.1039/c5lc01000d                  High-Throughput Fabrication  of  Three-Dimensional  MCF-
           104.  Frey O, Misun PM, Fluri DA, et al., 2014, Reconfigurable   7 Human Breast Cancer Cellular  Spheroids.  Engineering,
               Microfluidic  Hanging  Drop  Network  for  Multi-tissue   1:269–74.
               Interaction and Analysis. Nat Commun, 5:4250.       https://doi.org/10.15302/J-ENG-2015062
               https://doi.org/10.1038/ncomms5250              116.  Vinson BT, Sklare SC, Chrisey DB, 2017, Laser-based Cell
           105.  Wu HW, Hsiao YH, Chen CC, et al., 2016, A PDMS-Based   Printing  Techniques for  Additive Biomanufacturing.  Curr
               Microfluidic  Hanging  Drop  Chip  for  Embryoid  Body   Opin Biomed Eng, 2:14–21.
               Formation. Molecules, 21:882.                       https://doi.org/10.1016/j.cobme.2017.05.005
               https://doi.org/10.3390/molecules21070882       117.  Armon N, Greenberg E,  Edri E,  et  al., 2021, Laser-Based
           106.  Dadgar N, Gonzalez-Suarez  AM, Fattahi  P,  et al., 2020,   Printing: From Liquids to Microstructures. Adv Funct Mater,
               A  Microfluidic  Platform  for  Cultivating  Ovarian  Cancer   31:2008547.
               Spheroids and Testing  their  Responses to Chemotherapies.      https://doi.org/10.1002/adfm.202008547
               Microsyst Nanoeng, 6:93.                        118.  Hakobyan  D,  Médina  C,  Dusserre  N,  et  al., 2020, Laser-
               https://doi.org/10.1038/s41378-020-00201-6          assisted  3D Bioprinting  of Exocrine  Pancreas  Spheroid
           107.  Chen  SY,  Hung  PJ,  Lee  PJ,  2011,  Microfluidic  Array  for   Models for Cancer Initiation Study. Biofabrication, 12:35001.
               Three-dimensional  Perfusion Culture  of Human Mammary      https://doi.org/10.1088/1758-5090/ab7cb8
               Epithelial Cells. Biomed Microdev, 13:753–8.    119.  Boyer  CJ,  Ballard  DH,  Barzegar  M,  et al.,  2018,  High-
               https://doi.org/10.1007/s10544-011-9545-3           throughput Scaffold-free Microtissues through 3D Printing.

           22                          International Journal of Bioprinting (2021)–Volume 7, Issue 4