内密外疏微孔结构膨体聚四氟乙烯管式纤维膜的制备及人工血管应用

doi:10.13475/j.fzxb.20250905201

纺织学报 ›› 2026, Vol. 47 ›› Issue (03): 1-8.doi: 10.13475/j.fzxb.20250905201

内密外疏微孔结构膨体聚四氟乙烯管式纤维膜的制备及人工血管应用

李成才¹, 朱登辉¹, 殷向², 朱海霖¹^,³, 张华鹏¹, 刘国金¹^,³, 郭玉海¹(), 刘炳荣²

¹ 浙江理工大学全省未来产业用纤维材料实验室, 浙江杭州 310018
² 江西三鑫医疗科技股份有限公司, 江西南昌 330200
³ 现代纺织技术创新中心(鉴湖实验室), 浙江绍兴 312030

收稿日期:2025-09-15 修回日期:2025-12-22 出版日期:2026-03-15 发布日期:2026-03-15
通讯作者: 郭玉海(1973—),男,研究员,博士。主要研究方向为高分子纤维材料加工成形。E-mail:gyh@zstu.edu.cn。
作者简介:李成才(1990—),男,副研究员,博士。主要研究方向为植入膨体聚四氟乙烯纤维材料和精密过滤纤维材料。
基金资助:
南昌市科技计划“揭榜挂帅”项目(洪科字〔2023〕52号-4)

Preparation of polytetrafluoroethylene tubular fiber membranes with dense inner and sparse outer pore structure and its application in artificial blood vessels

LI Chengcai¹, ZHU Denghui¹, YIN Xiang², ZHU Hailin¹^,³, ZHANG Huapeng¹, LIU Guojin¹^,³, GUO Yuhai¹(), LIU Bingrong²

¹ Provincial Laboratory of Fiber Materials for Future Industries, Zhejiang Sci-Tech University, Hangzhou, Zhejiang 310018, China
² Jiangxi Sanxin Medtec Co., Ltd., Nanchang, Jiangxi 330200, China
³ Innovation Center of Advanced Textile Technology (Jianhu Laboratory), Shaoxing, Zhejiang 312030, China

Received:2025-09-15 Revised:2025-12-22 Published:2026-03-15 Online:2026-03-15

摘要/Abstract

摘要：

为解决膨体聚四氟乙烯(ePTFE)管式纤维膜在柔韧性和纵向弹性方面的不足,通过二次定形工艺对单向拉伸法制备的ePTFE管式纤维膜进行改性,从而提升其作为人工血管的顺应性、力学性能及抗血栓能力。采用300 ℃二次加热结合水淬火处理对ePTFE膜进行结构重塑,借助扫描电镜、X射线衍射仪、拉伸测试、血管动态顺应性检测、细胞毒性实验及大型犬颈动脉置换模型系统评价其性能。结果表明:改性后的ePTFE膜形成内密外疏的微孔结构,内壁节点间距减小,外壁纤维呈波浪形排列;结晶度降低,非晶区比例增加;径向断裂强度显著提高,断裂伸长率保持稳定,且应力-应变曲线脚趾区延长,柔顺性明显改善。细胞毒性实验结果显示,细胞存活率大于90%,细胞相容性良好。动物实验结果证实,改性样品植入6个月后未见血栓形成,内皮细胞长入且组织整合良好,而未改性样品植入后短期内诱发血栓形成与炎症反应,表明该工艺可显著提升ePTFE人工血管的综合性能,具有重要的临床应用潜力。

关键词: 膨体聚四氟乙烯管式纤维膜, 内密外疏微孔结构, 人工血管, 二次定形, 顺应性, 医用纺织品

Abstract:

Objective This study aims to modify the expanded polytetrafluoroethylene (ePTFE) tubular fiber membrane prepared by unidirectional stretching through secondary heating and quenching processes, so as to address the issues of insufficient flexibility and longitudinal elasticity, thereby enhancing the compliance, mechanical properties and antithrombotic performance of artificial blood vessels and providing better materials for clinical vascular transplantation.

Method The ePTFE tubular fiber membranes were prepared by the one-way stretching method. On this basis, secondary heating (at 300 ℃) and water quenching processes were introduced to reshape the structure. The microstructure, crystallinity, mechanical properties, compliance and biocompatibility of the membranes were characterized by electron microscopy scanning, X-ray diffraction, mechanical stretching tests, dynamic vascular compliance tests and cytotoxicity experiments. The in vivo evaluation was conducted through a large dog carotid artery replacement model.

Results After secondary heating and water quenching treatment, the inner wall node spacing of the ePTFE tubular fiber membrane shortened, the pore diameter decreased, and the outer wall fibers were arranged in a wavy pattern, forming a pore structure with a denser inner layer and a sparser outer layer. The inner pore diameter was significantly smaller than the outer pore diameter. XRD analysis showed a decrease in crystallinity of the material and an increase in the proportion of amorphous regions. In terms of mechanical properties, the longitudinal strength was significantly increased (the radial fracture strength did not change much), and the elongation at break remained stable. The stress-strain curve exhibited a typical nonlinear response, and the toe region elongation indicated enhanced flexibility. Vascular compliance tests revealed that the samples after secondary heating treatment had significantly better compliance than the untreated samples, and the wavy fiber structure endowed it with the elastic deformability similar to a spring. Cell toxicity experiments indicated that the cell viability of the extract solution group was higher than 90%, with no significant cytotoxicity and good biocompatibility. Canine carotid artery replacement experiments manifested that the samples after the secondary heating treatment did not form blood clots after the implantation for 6 months. The surface was smooth and endothelial cells grew into the tube wall with well encapsulated connective tissue, and no inflammatory reaction was found, while the primary shaped samples showed blood clotting and inflammatory cell infiltration within 2-3 weeks. The performance improvement was achieved because high compliance reduced blood flow turbulence, smooth and dense inner walls inhibited platelet adhesion, and the microporous structure promoted tissue integration and vascularization.

Conclusion The secondary heating and quenching treatment can effectively optimize the structure and performance of ePTFE tubular fiber membranes, forming a dense inner and sparse outer pore structure and wave-like fiber morphology. The pore structure significantly enhances axial strength, flexibility and elasticity, making them more similar to the mechanical behavior of natural blood vessels. This material has excellent biocompatibility and antithrombotic properties. The animal experiment results, show the material has excellent tissue integration and endothelialization ability, significantly outperforming conventional primary shaped samples. Research indicates that the proposed ePTFE tubular fiber membranes have significant application potential in the field of artificial blood vessels.

Key words: expanded polytetrafluoroethylene tubular fiber membrane, dense inner and sparse outer pore structure, artificial blood vessel, secondary shaping, compliance, medical textiles

中图分类号:

Q 819

李成才, 朱登辉, 殷向, 朱海霖, 张华鹏, 刘国金, 郭玉海, 刘炳荣. 内密外疏微孔结构膨体聚四氟乙烯管式纤维膜的制备及人工血管应用[J]. 纺织学报, 2026, 47(03): 1-8.

LI Chengcai, ZHU Denghui, YIN Xiang, ZHU Hailin, ZHANG Huapeng, LIU Guojin, GUO Yuhai, LIU Bingrong. Preparation of polytetrafluoroethylene tubular fiber membranes with dense inner and sparse outer pore structure and its application in artificial blood vessels[J]. Journal of Textile Research, 2026, 47(03): 1-8.

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链接本文: http://www.fzxb.org.cn/CN/10.13475/j.fzxb.20250905201

http://www.fzxb.org.cn/CN/Y2026/V47/I03/1

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ePTFE样品	径向		纵向
ePTFE样品	断裂强度/MPa	断裂伸长率/%	断裂强度/MPa	断裂伸长率/%
一次定形	13.15±0.10	605.78±1.05	36.18±0.18	83.64±0.85
二次定形	25.75±0.11	620.34±0.80	38.06±0.21	92.22±0.73

ePTFE样品	不同压力下径向顺应性			纵向顺应性
ePTFE样品	低压 (7~12 kPa)	中压 (10.7~16.0 kPa)	高压 (14.7~20.0 kPa)	纵向顺应性
一次定形	0.11±0.01	0.11±0.01	0.12±0.01	0.51±0.01
二次定形	1.23±0.01	2.56±0.01	3.98±0.01	15.51±0.01

检测项目	检测结果	检测依据
致敏性	0%	GB/T 16886.10—2024
皮内反应	无动物皮内反应	GB/T 16886.23—2023
急性毒性	无毒性反应	GB/T 16886.11—2021
溶血率	0%(<5%代表合格)	GB/T 16886.4—2022

内密外疏微孔结构膨体聚四氟乙烯管式纤维膜的制备及人工血管应用

Preparation of polytetrafluoroethylene tubular fiber membranes with dense inner and sparse outer pore structure and its application in artificial blood vessels

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