In Vitro Investigation of the Biocompatibility of 6 Different High-Performance Resin-Based Materials for Bone Augmentation and Reconstruction.

IF 1 4区医学 Q3 SURGERY

Journal of Craniofacial Surgery Pub Date : 2025-10-08 DOI:10.1097/SCS.0000000000011898

Katharina Pippich, Luisa Flechtenmacher, Matthias Schwarz, Nils Krautkremer, Herbert Deppe, Klaus-Dietrich Wolff, Andreas M Fichter, Lucas M Ritschl

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引用次数: 0

Abstract

Introduction: Reconstructive surgery often addresses severe bone defects that impact patients' lives. While microvascular bone transfer is standard, it has drawbacks. Thus, the focus shifts to using alloplastic grafts, avoiding donor sites. This study evaluates the biocompatibility of generatively printed high-performance resins.

Materials and methods: Six printed materials were compared with titanium scaffolds: native PEEK (poly-ether-ether-ketone) and native PEKK (poly-ether-ketone-ketone) as well as the surface-modified materials MBTg (Mimicking Bone Technology) PEEK, BCP-filled PEEK, 4h-argon-etched PEKK, and So_PPSU [polyphenylsulfone with barium sulfate (BaS8O4)]. The scaffolds were CAD/CAM manufactured and individually dimensioned using Fused Layer Manufacturing. Biocompatibility was assessed through cytotoxicity, osteoblast viability, and differentiation assays. Osteoblast colonization and adhesion were examined using fluorescence and electron microscopy.

Results: All materials were noncytotoxic (P<0.05). So_PPSU exhibited the highest cell proliferation rates. MBTg PEEK, BCP-filled PEEK, and native PEKK also showed significant increases over time (P<0.05). Alkaline phosphatase activity increased for all materials, with 4h-argon-etched PEKK, MBTg PEEK, and BCP-filled PEEK showing the greatest increases. Microscopy validated these findings.

Conclusions: The tested materials were noncytotoxic, with MBTg-functionalized PEEK, 4h-argon-etched PEKK and BCP-filled PEEK showing the best biocompatibility. Furthermore, the study demonstrated the feasibility of a time-saving 3D printing process for the reproducible production of customized and functionally designed medical products.

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6种高性能树脂基骨增强重建材料的体外生物相容性研究。

骨重建手术常用于治疗影响患者生活的严重骨缺损。虽然微血管骨移植是标准的，但它有缺点。因此，重点转移到使用同种异体移植物，避免供体部位。本研究评估了生成打印高性能树脂的生物相容性。材料与方法：将六种打印材料与钛支架进行比较：原生PEEK（聚醚-醚-酮）和原生PEKK（聚醚-酮-酮）以及表面改性材料MBTg（模拟骨技术）PEEK、bcp填充PEEK、4h-氩蚀刻PEKK和So_PPSU[聚苯基砜与硫酸钡（BaS8O4）]。支架采用CAD/CAM制造，并使用熔接层制造进行单独尺寸标注。通过细胞毒性、成骨细胞活力和分化试验来评估生物相容性。荧光显微镜和电镜观察成骨细胞的定植和粘附情况。结论：所测材料均无细胞毒性，其中mbtg功能化PEEK、4h-氩蚀刻PEKK和bcp填充PEEK的生物相容性最佳。此外，该研究还证明了一种节省时间的3D打印工艺的可行性，该工艺可用于定制和功能设计的医疗产品的可重复性生产。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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来源期刊

Journal of Craniofacial Surgery 医学-外科

CiteScore

1.70

自引率

11.10%

发文量

968

审稿时长

1.5 months

期刊介绍： The Journal of Craniofacial Surgery serves as a forum of communication for all those involved in craniofacial surgery, maxillofacial surgery and pediatric plastic surgery. Coverage ranges from practical aspects of craniofacial surgery to the basic science that underlies surgical practice. The journal publishes original articles, scientific reviews, editorials and invited commentary, abstracts and selected articles from international journals, and occasional international bibliographies in craniofacial surgery.