3D Printing of Biodegradable Polymer Vascular Stents: A Review

Weijian Hua , Weiliang Shi , Kellen Mitchell , Lily Raymond , Ryan Coulter , Danyang Zhao , Yifei Jin
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引用次数: 10

Abstract

Biodegradable polymer vascular stents (BPVSs) have been widely used in percutaneous coronary interventions for the treatment of coronary artery diseases. The development of BPVSs is an integrated process that combines material design/selection, manufacturing, and performance characterization. Three-dimensional (3D) printing technology is a powerful tool for polymer stent fabrication. Current review studies have focused primarily on the material and structural design of polymer stents but have failed to comprehensively discuss different 3D printing approaches and stent characterization techniques. In this paper, we address these shortcomings by discussing 3D printing methods and their application in BPVSs. First, some commonly used 3D printing methods (including material extrusion, vat polymerization, and powder bed fusion) and potential 3D printing strategies (including material jetting and binder jetting) for fabricating BPVSs are discussed; furthermore, the main post-treatments are summarized. Then, techniques to characterize the morphology, mechanical properties, and biological properties of the printed BPVSs are introduced. Subsequently, representative commercial BPVSs and lab-grade BPVSs are compared. Finally, based on the limitations of stent printing and characterization processes, future perspectives are proposed, which may help develop new techniques to fabricate more customized stents and accurately evaluate their performance.

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生物可降解聚合物血管支架的3D打印研究进展
生物可降解聚合物血管支架(BPVSs)已广泛应用于经皮冠状动脉介入治疗冠状动脉疾病。bpv的开发是一个集成的过程,结合了材料设计/选择,制造和性能表征。三维(3D)打印技术是聚合物支架制造的有力工具。目前的综述研究主要集中在聚合物支架的材料和结构设计上,但未能全面讨论不同的3D打印方法和支架表征技术。在本文中,我们通过讨论3D打印方法及其在bpv中的应用来解决这些缺点。首先,讨论了一些常用的3D打印方法(包括材料挤压、还原聚合和粉末床熔融)和潜在的3D打印策略(包括材料喷射和粘结剂喷射);总结了主要的后处理方法。然后,介绍了表征打印BPVSs的形态、机械性能和生物性能的技术。随后,比较了具有代表性的商用BPVSs和实验室级BPVSs。最后,基于支架打印和表征工艺的局限性,提出了未来的展望,这可能有助于开发新技术来制造更多的定制支架并准确评估其性能。
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