Woven solutions for tissue engineering: Next-generation heart valves from fiber to function

IF 1.8 Q3 CARDIAC & CARDIOVASCULAR SYSTEMS

American heart journal plus : cardiology research and practice Pub Date : 2025-09-10 DOI:10.1016/j.ahjo.2025.100604

Cornelia Sennewald , Jasmin Pilgrim , Dilbar Aibibu , Thomas Gereke , Philipp Schegner , Chokri Cherif

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引用次数: 0

Abstract

Study objective

Cardiovascular diseases remain one of the leading causes of morbidity and mortality worldwide, yet the availability of durable, patient-specific heart valve replacements is still limited. The aim is to utilize a biomimetic, textile-based design to mimic natural tissues, thereby creating customizable solutions with improved mechanical properties and scalable production for cardiovascular applications.

Design

By leveraging advanced 3D weaving techniques, the feasibility of manufacturing anatomically adaptable and mechanically robust textile valves is demonstrated. CAD-based design workflows and functional materials such as shape memory Nitinol wires are part of this technology. The integration of form-defining geometries, multilayer structures and functional surface treatments is enabled through tailored binding design and machine adaptations.

Main outcome and results

A textile-based heart valve implant was developed using advanced 3D weaving, CAD modelling and patient-specific imaging. Integrated leaflets and an annular ring were formed directly during weaving using mold inserts and multilayer structures, eliminating post-processing. Polyester and Nitinol materials provided mechanical stability and shape-memory functionality. Simulation models and SPH analysis validated pressure behaviour and deformation under physiological conditions. Functional zones with tailored stiffness, sealing and mobility were realized through binding variation and Jacquard control. A reproducible digital workflow, from CT segmentation to weaving on modified looms, enabled scalable production of anatomically accurate, functionally optimized heart valve prostheses. Mechanical evaluations reveal favourable performance in comparison to conventional valve designs.

Conclusion

These findings highlight the potential of fiber and textile technology as a scalable, customizable clinically relevant platform for heart valve tissue engineering and future biomedical applications.

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组织工程的编织解决方案：从纤维到功能的下一代心脏瓣膜

研究目的心血管疾病仍然是世界范围内发病率和死亡率的主要原因之一，但持久的、患者特异性的心脏瓣膜置换术的可用性仍然有限。其目的是利用仿生、基于纺织品的设计来模拟自然组织，从而为心血管应用创造具有改进机械性能和可扩展生产的定制解决方案。设计通过利用先进的3D编织技术，证明了制造解剖学适应性强、机械坚固的纺织阀门的可行性。基于cad的设计工作流程和功能材料，如形状记忆镍钛诺线是该技术的一部分。通过定制的绑定设计和机器适应性，可以将定义形状的几何形状、多层结构和功能性表面处理集成在一起。主要结果：采用先进的3D编织、CAD建模和患者特异性成像技术，开发了一种基于纺织品的心脏瓣膜植入物。在织造过程中，使用模具镶件和多层结构直接形成整体单张和环形，省去了后处理。聚酯和镍钛诺材料提供了机械稳定性和形状记忆功能。仿真模型和SPH分析验证了生理条件下的压力行为和变形。通过结合变化和提花控制，实现了具有定制刚度、密封性和流动性的功能区。一个可复制的数字工作流程，从CT分割到在改进的织机上编织，使可扩展的生产解剖学上准确的、功能优化的心脏瓣膜假体成为可能。机械评估显示，与传统的阀门设计相比，它具有良好的性能。结论这些发现突出了纤维和纺织技术在心脏瓣膜组织工程和未来生物医学应用中作为可扩展、可定制的临床相关平台的潜力。

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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