State Key Laboratory of Materials Processing and Die & Mould Technology, School of Materials Science and Engineering, Huazhong University of Science and Technology, Wuhan 430074, China.
Department of Orthopedic Surgery, Tongji Hospital, Tongji Medical College, Huazhong University of Science and Technology, Wuhan 430030, China.
Acta Biomater. 2024 Nov;189:605-620. doi: 10.1016/j.actbio.2024.09.055. Epub 2024 Oct 9.
Although poly-ether-ether-ketone (PEEK) implants hold significant medical promise, their bioinert nature presents challenges in osseointegration and bone ingrowth within clinical contexts. To mitigate these challenges, the present study introduces Diamond PEEK/bioactive glass (BG) composite scaffolds, characterized by macro/micro dual-porous structures, precisely fabricated via laser powder bed fusion (LPBF) technology. The findings indicate that an increase in BG content within these scaffolds significantly augments their hydrophilicity and hydroxyapatite formation capacities. Stress-strain curve analysis demonstrates reliable load-bearing stability across all scaffold types. In vitro assessments confirmed the non-cytotoxicity of PEEK/BG samples and demonstrated improved osteogenic differentiation and mineralization with increased BG incorporation. Further, in vivo experiments illustrated that the Diamond porous structure of these scaffolds facilitated bone growth, an effect notably amplified with higher BG content. Particularly in groups with 15 wt.% and 25 wt.% BG scaffolds, new bone formation was observed not only within the macropores of the Diamond structure but also within the micropores inside the scaffold rod, suggesting an almost seamless fusion with the new bone. This demonstrates the scaffolds' effective osteointegration and bone ingrowth properties. This study conclusively established the effectiveness of Diamond-structured PEEK/BG composite scaffolds, fabricated via LPBF, in bone repair. It highlights the crucial role of BG in enhancing osteogenic potential through interaction with the macro/micro pores of the scaffold. STATEMENT OF SIGNIFICANCE: This study addresses the bioinert nature of PEEK implants by developing Diamond-structured PEEK/bioactive glass (BG) composite scaffolds by laser powder bed fusion. The dual-porous macro/microstructure enhances hydrophilicity and hydroxyapatite formation, vital for bone regeneration. By adjusting the BG content, we controlled the melt viscosity and sintering rate, leading to the formation of beneficial microscale pores. These pores resolve the issue of ineffective bioactive fillers in previous LPBF-fabricated scaffolds, enhancing the osteogenic potential of BG and inducing superior bone ingrowth and osseointegration. In vitro and in vivo analyses show enhanced osteogenic differentiation, mineralization, and bone growth, underscoring the clinical potential of these scaffolds for bone repair.
尽管聚醚醚酮(PEEK)植入物具有重要的医学应用前景,但它们的生物惰性特性在临床环境中给骨整合和骨长入带来了挑战。为了缓解这些挑战,本研究引入了 Diamond PEEK/生物活性玻璃(BG)复合支架,其具有宏观/微观双重多孔结构,通过激光粉末床熔合(LPBF)技术精确制造。研究结果表明,支架中 BG 含量的增加显著提高了其亲水性和羟基磷灰石形成能力。应力-应变曲线分析表明,所有支架类型均具有可靠的承载稳定性。体外评估证实了 PEEK/BG 样品的非细胞毒性,并表明随着 BG 含量的增加,成骨分化和矿化得到改善。此外,体内实验表明,这些支架的 Diamond 多孔结构促进了骨生长,随着 BG 含量的增加,这种作用显著增强。特别是在 BG 含量为 15wt.%和 25wt.%的支架组中,不仅在 Diamond 结构的大孔内,而且在支架棒内的微孔内都观察到新骨形成,这表明与新骨几乎无缝融合。这证明了支架的有效骨整合和骨长入特性。本研究最终证实了通过 LPBF 制造的 Diamond 结构 PEEK/BG 复合支架在骨修复中的有效性。它强调了 BG 通过与支架的宏观/微观孔相互作用增强成骨潜力的关键作用。研究意义:本研究通过激光粉末床熔合开发了 Diamond 结构 PEEK/生物活性玻璃(BG)复合支架,解决了 PEEK 植入物的生物惰性问题。双重多孔的宏观/微观结构提高了亲水性和羟基磷灰石的形成能力,这对于骨再生至关重要。通过调整 BG 含量,我们控制了熔体粘度和烧结速率,从而形成了有益的微尺度孔。这些孔解决了以前通过 LPBF 制造的支架中生物活性填料无效的问题,增强了 BG 的成骨潜力,并诱导了更好的骨长入和骨整合。体外和体内分析表明,成骨分化、矿化和骨生长得到增强,突出了这些支架在骨修复中的临床应用潜力。
