脚手架
材料科学
生物医学工程
主动脉瓣
墨水池
医学
复合材料
外科
作者
Zhang Cheng,Jiming Hao,Weiliang Shi,Ya Su,Kellen Mitchell,Weijian Hua,Weihua Jin,Serena Lee,Wen Li,Yifei Jin,Danyang Zhao
出处
期刊:Biofabrication
[IOP Publishing]
日期:2023-08-24
卷期号:15 (4): 045015-045015
被引量:2
标识
DOI:10.1088/1758-5090/aceffb
摘要
Abstract Heart valve disease has become a serious global health problem, which calls for numerous implantable prosthetic valves to fulfill the broader needs of patients. Although current three-dimensional (3D) bioprinting approaches can be used to manufacture customized valve prostheses, they still have some complications, such as limited biocompatibility, constrained structural complexity, and difficulty to make heterogeneous constructs, to name a few. To overcome these challenges, a sacrificial scaffold-assisted direct ink writing approach has been explored and proposed in this work, in which a sacrificial scaffold is printed to temporarily support sinus wall and overhanging leaflets of an aortic valve prosthesis that can be removed easily and mildly without causing any potential damages to the valve prosthesis. The bioinks, composed of alginate, gelatin, and nanoclay, used to print heterogenous valve prostheses have been designed in terms of rheological/mechanical properties and filament formability. The sacrificial ink made from Pluronic F127 has been developed by evaluating rheological behavior and gel temperature. After investigating the effects of operating conditions, complex 3D structures and homogenous/heterogenous aortic valve prostheses have been successfully printed. Lastly, numerical simulation and cycling experiments have been performed to validate the function of the printed valve prostheses as one-way valves.
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