Fabrication of an Asymmetric PCL-HAP/CS Bilayer Composite Membrane with Dual Osteogenic and Fibrogenic Functions for Guided Bone Regeneration

This project contains experimental data and figures associated with the paper <i>"Fabrication of an Asymmetric PCL-HAP/CS Bilayer Composite Membrane with Dual Osteogenic and Fibrogenic Functions for Guided Bone Regeneration"</i>(unpublished). For any additional inquiries, please direct correspondence to: <b>Email</b>: kk1097002791@gmail.comThe dataset includes:Figure 8 Dispersion of hydroxyapatite in ethanolFigure 9 Infrared spectra comparison before and after HAP modification Figure 10 XRD spectra of three kinds of filmFigure 11 Infrared spectra of three kinds of membrane materialsFigure 12A Characterization and cross sections with different membrane materialsFigure 12B Characterization and cross sections with different membrane materialsFigure 12C Characterization and cross sections with different membrane materialsFigure 12D Characterization and cross sections with different membrane materialsFigure 13A.CS Hydrophilic test figure three kinds of membrane materialsFigure 13B.PCL-HAP·CS Hydrophilic test figure three kinds of membrane materialsFigure 13C.PCL-HAP Hydrophilic test figure three kinds of membrane materialsFigure 14 Curves of three kinds of membrane DSCFigure 15 The TG curves of three kinds of membrane materialsFigure 16A Three kinds of membrane materials of two cell culture photosFigure 16B Three kinds of membrane materials of two cell culture photosFigure 16C Three kinds of membrane materials of two cell culture photosFigure 16D Three kinds of membrane materials of two cell culture photosFigure 16E Three kinds of membrane materials of two cell culture photosFigure 16F Three kinds of membrane materials of two cell culture photosFigure 17A These fluorescence images illustrate the variations in cell morphology and proliferation on different membranesFigure 17B These fluorescence images illustrate the variations in cell morphology and proliferation on different membranesFigure 17C These fluorescence images illustrate the variations in cell morphology and proliferation on different membranesFigure 17D These fluorescence images illustrate the variations in cell morphology and proliferation on different membranesFigure 17E These fluorescence images illustrate the variations in cell morphology and proliferation on different membranesFigure 17F These fluorescence images illustrate the variations in cell morphology and proliferation on different membranesFigure 18 Comparison in the adhesion of the fiber cell membrane surfaceFigure 19 Osteoblasts in the proliferation effect in comparison to the film surfaceFigure 20A Scan-based modeling images of the PCL-HAP·CS composite membrane on new bone formation in rat skull defectsFigure 20B Scan-based modeling images of the PCL-HAP·CS composite membrane on new bone formation in rat skull defectsFigure 20C Scan-based modeling images of the PCL-HAP·CS composite membrane on new bone formation in rat skull defectsFigure 20D Scan-based modeling images of the PCL-HAP·CS composite membrane on new bone formation in rat skull defectsFigure 20E Scan-based modeling images of the PCL-HAP·CS composite membrane on new bone formation in rat skull defectsFigure 20F Scan-based modeling images of the PCL-HAP·CS composite membrane on new bone formation in rat skull defects