Heart-on-a-chip
               To sum up, the development of heart-on-a-chip is    Scaffolds  for  Building  Cardiac  Tissue.  J  Thorac Dis,
           still in its early stage, and there are barriers to overcome   10:S2312–28.
           in  its  commercialization  and  clinical  applications.      https://doi.org/10.21037/jtd.2017.12.92
           However, it is believed that heart-on-a-chip is a promising   9.   Zhao Y, Rafatian N, Wang E, et al., 2020, Towards Chamber
           technique and has a great potential in various biomedical
           applications.                                           Specific Heart-on-a-chip for Drug Testing Applications. Adv
                                                                   Drug Deliv Rev, 165–166:60–76.
           Acknowledgments                                         https://doi.org/10.1016/j.addr.2019.12.002

               The  work  was  financially  supported  by  National   10.  Guerzoni L,  Tsukamoto  Y, Gehlen DB, et al.,  2019, A
           Natural  Science Foundation  of China  (51911530694,    Layer-by-Layer Single-Cell Coating Technique To Produce
           11902245), the Key Research and Development Program     Injectable  Beating  Mini  Heart  Tissues  via  Microfluidics.
           of Shaanxi (2021GY-294), the Zhejiang  Provincial       Biomacromolecules, 20:3746–54.
           Natural  Science  Foundation of China (LQ21E050009),      https://doi.org/10.1021/acs.biomac.9b00786
           and Beilin  District  Applied  Technology  Research  and
           Development Projects in 2020 (GX2027).              11.  Derda R, Laromaine  A, Mannoto  A,  et  al., 2009, Paper-
                                                                   supported 3D Cell Culture for Tissue-based Bioassays. Proc
           Conflict of interest                                    Natl Acad Sci U S A, 106:18457–62.
               The  authors  declare  that  they  have  no  conflict  of   12.  Lind JU, Busbee TA, Valentine AD, et al., 2017, Instrumented
           interest.                                               Cardiac  Microphysiological  Devices  via  Multimaterial
                                                                   Three-dimensional Printing. Nat Mater, 16:303.
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