10.25402/BTN.11903091.v1 Liam P. Dow Liam P. Dow Aimal H. Khankhel Aimal H. Khankhel John Abram John Abram Megan T. Valentine Megan T. Valentine Supplementary information for: 3D-printable cell crowding device enables imaging of live cells in compression: Indenter.STL Future Science Group 2020 Epithelial mechanics cell compression microscopy mechanobiology 3D printing Biochemistry and Cell Biology not elsewhere classified Biological Sciences not elsewhere classified 2020-02-26 15:43:42 Figure https://future-science-group.figshare.com/articles/figure/Supplementary_information_for_3D-printable_cell_crowding_device_enables_imaging_of_live_cells_in_compression_Indenter_STL/11903091 <div> <table> <tr> <td> <p><b>Figure S1.</b> Cell density along the axis of compression increased approximately 20%, from 14.0± 0.5 to 16.6 ± 0.9. Error bars indicate standard error of the mean. Cells were counted using the maximum intensity projections of the Hoechst channel before and after crowding</p> <p><b>Figure S2.</b> Exploded view of the assembled device, with annotation numbers as described in Tables S1 and S2. Since some regions of this device experience high localized stress during tension, the 3-D printed components included structural support features such as side ribs (1)for the base plate and gussets for the indenter (5, in inset).</p> <p>Table S1: 3-D Printed Parts </p> <p>Table S2: McMaster-Carr Parts </p> </td> </tr> </table> </div>