3D printed Mg-incorporated polycaprolactone scaffolds for repairing rat skull defects

LI Xiaoye; LI Qiang; Dai Zhuo; Ding Meng; Dong Heng; Dong Qiangsheng; Bai Jing; Mou Yongbin

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3D printed Mg-incorporated polycaprolactone scaffolds for repairing rat skull defects

Author: LI Xiaoye ¹ ; LI Qiang ¹ ; DAI Zhuo ¹ ; DING Meng ¹ ; DONG Heng ¹ ; DONG Qiangsheng ² ; BAI Jing ² ; MOU Yongbin ¹
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1. Nanjing Stomatological Hospital, Affiliated Hospital of Medical School, Nanjing University
2. School of Materials Science and Engineering, Southeast University
Publication Type:Journal Article
Keywords: bone defect / skull defect / bone regeneration / bone tissue engineering / scaffolds / 3D printing / polycaprolactone / magnesium / bone volume / bone volume/total volume
From: Journal of Prevention and Treatment for Stomatological Diseases 2024;32(4):249-256
CountryChina
Language:Chinese
Abstract: Objective:To evaluate the bone repair effect of 3D-printed magnesium (Mg)-loaded polycaprolactone (PCL) scaffolds in a rat skull defect model.
Methods:PCL scaffolds mixed with Mg microparticles were prepared by using 3D printing technology, as were pure PCL scaffolds. The surface morphologies of the two scaffolds were observed by scanning electron microscopy (SEM), and the surface elemental composition was analyzed via energy dispersive spectroscopy (EDS). The physical properties of the scaffolds were characterized through contact angle measurements and an electronic universal testing machine. This study has been reviewed and approved by the Ethics Committee. A critical size defect model was established in the skull of 15 Sprague-Dawley (SD) rats, which were divided into the PCL group, PCL-Mg group, and untreated group, with 5 rats in each group. Micro-CT scanning was performed to detect and analyze skull defect healing at 4 and 8 weeks after surgery, and samples from the skull defect area and major organs of the rats were obtained for histological staining at 8 weeks after surgery.
Results:The scaffolds had a pore size of (480 ± 25) μm, a fiber diameter of (300 ± 25) μm, and a porosity of approximately 66%. The PCL-Mg scaffolds contained 1.0 At% Mg, indicating successful incorporation of Mg microparticles. The contact angle of the PCL-Mg scaffolds was 68.97° ± 1.39°, indicating improved wettability compared to that of pure PCL scaffolds. Additionally, compared with that of pure PCL scaffolds, the compressive modulus of the PCL-Mg scaffolds was (57.37 ± 8.33) MPa, demonstrating enhanced strength. The PCL-Mg group exhibited the best bone formation behavior in the skull defect area compared with the control group and PCL group at 4 and 8 weeks after surgery. Moreover, quantitative parameters, such as bone volume (BV), bone volume/total volume (BV/TV), bone surface (BS), bone surface/total volume (BS/TV), trabecular thickness (Tb.Th), trabecular number (Tb.N) and bone mineral density (BMD), of skull defects were better than those in the other groups, indicating the best bone regeneration effect. H&E, Goldner, and VG staining revealed more mineralized new bone formation in the PCL-Mg group than in the other groups, and H&E staining of the major organs revealed good biosafety of the material.
Conclusion:PCL-Mg scaffolds can promote the repair of bone defects and have clinical potential as a new scaffold material for the repair of maxillofacial bone defects.