Nickel–titanium alloy porous scaffolds based on a dominant cellular structure manufactured by laser powder bed fusion have satisfactory osteogenic efficacy

IF 8.7 1区 医学 Q1 ENGINEERING, BIOMEDICAL
Jiaming Lin , An Yan , Anfei Huang , Qinglian Tang , Jinchang Lu , Huaiyuan Xu , Yufeng Huang , Tianqi Luo , Zhihao Chen , Anyu Zeng , Xiaojun Zhu , Chao Yang , Jin Wang
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Abstract

Nickel–titanium (NiTi) alloy is a widely utilized medical shape memory alloy (SMA) known for its excellent shape memory effect and superelasticity. Here, laser powder bed fusion (LPBF) technology was employed to fabricate a porous NiTi alloy scaffold featuring a topologically optimized dominant cellular structure that demonstrates favorable physical and superior biological properties. Utilizing a porous structure topology optimization method informed by the stress state of human bones, two types of cellular structures—compression and torsion—were designed, and porous scaffolds were produced via LPBF. The physical properties of the porous NiTi alloy scaffolds were evaluated to confirm their biocompatibility, while their osteogenic efficacy was investigated through both in vivo and in vitro experiments, with comparisons made against a traditional octahedral unit cell structure. NiTi alloy porous scaffolds can be nearly net-shaped via LPBF and exhibit favorable physical properties, including a low elastic modulus, high hydrophilicity, a specific linear expansion rate, as well as superelastic and shape memory effects. These scaffolds demonstrate excellent biocompatibility, support in vitro osteogenesis, and possess significant in vivo bone ingrowth capabilities. When compared to titanium alloys, NiTi alloys show comparable osteogenic properties in vitro but superior bone ingrowth properties in vivo. Additionally, among octahedral-type, torsion-type, and topologically optimized compression-type porous scaffolds, the latter demonstrates enhanced bone ingrowth properties. LPBF technology is effective for manufacturing porous NiTi alloy scaffolds with fine pore structures and excellent mechanical properties. The scaffolds based on topologically optimized dominant cellular structures facilitate satisfactory and efficient bone formation.

Abstract Image

通过激光粉末床融合技术制造的基于优势细胞结构的镍钛合金多孔支架具有令人满意的成骨功效
镍钛(NiTi)合金是一种广泛应用的医用形状记忆合金(SMA),以其出色的形状记忆效果和超弹性而著称。本文采用激光粉末床熔融(LPBF)技术制造了一种多孔镍钛合金支架,这种支架具有拓扑优化的主导细胞结构,具有良好的物理和生物特性。根据人体骨骼的应力状态,利用多孔结构拓扑优化方法,设计了两种细胞结构--压缩和扭转,并通过 LPBF 制备了多孔支架。对多孔镍钛合金支架的物理性质进行了评估,以确认其生物相容性,同时通过体内和体外实验研究了其成骨功效,并与传统的八面体单胞结构进行了比较。镍钛合金多孔支架可通过 LPBF 几乎呈网状,并表现出良好的物理特性,包括低弹性模量、高亲水性、特定线膨胀率以及超弹性和形状记忆效应。这些支架具有良好的生物相容性,支持体外成骨,并具有显著的体内骨生长能力。与钛合金相比,镍钛合金的体外成骨性能相当,但体内骨生长性能更优。此外,在八面体型、扭转型和拓扑优化压缩型多孔支架中,后者具有更强的骨生长特性。LPBF 技术可有效制造具有细孔结构和优异机械性能的多孔镍钛合金支架。基于拓扑优化的优势细胞结构的支架可促进令人满意的高效骨形成。
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来源期刊
CiteScore
8.30
自引率
4.90%
发文量
303
审稿时长
30 days
期刊介绍: Materials Today Bio is a multidisciplinary journal that specializes in the intersection between biology and materials science, chemistry, physics, engineering, and medicine. It covers various aspects such as the design and assembly of new structures, their interaction with biological systems, functionalization, bioimaging, therapies, and diagnostics in healthcare. The journal aims to showcase the most significant advancements and discoveries in this field. As part of the Materials Today family, Materials Today Bio provides rigorous peer review, quick decision-making, and high visibility for authors. It is indexed in Scopus, PubMed Central, Emerging Sources, Citation Index (ESCI), and Directory of Open Access Journals (DOAJ).
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