MECHANICAL BEHAVIOR OF A NEW STENT WITH NEGATIVE POISSON’S RATIO: THE INFLUENCE OF GEOMETRIC PARAMETERS

IF 0.8 4区医学 Q4 BIOPHYSICS

Journal of Mechanics in Medicine and Biology Pub Date : 2024-01-25 DOI:10.1142/s0219519423501087

DONG-MEI ZHU, YAO DU, GUANG-YANG LU, CHENG-ZHAO

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引用次数: 0

Abstract

For the proposed new negative Poisson’s ratio vascular stent, the effects of stent parameters on radial resilience, axial shortening rate, and radial support stiffness were compared and analyzed based on finite element methods and orthogonal tests, considering the complete compression-grip expansion process of the stent. It was concluded that decreasing the wall width of the cell structure or increasing the length of the cell structure could improve the radial resilience performance of the stent; decreasing the number of axial cell structures, decreasing the pinch angle, and increasing the wall width of the cell structure could reduce the axial shortening rate and could improve the axial shortening performance of the stent; increasing the wall width of the cell structure, the wall thickness of the cell structure and the number of axial cell structure could improve the radial support stiffness of the stent. In Vitro tests were conducted to study the effects of compression rate, circumferential compression position, and number of axial cells on the radial support performance of the stent. The geometric parameters of vascular stents have a significant influence on the mechanical properties of stents and should be given significant consideration in the clinical selection and optimal design of stents.

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负泊松比新型支架的力学行为：几何参数的影响

对于所提出的新型负泊松比血管支架，基于有限元方法和正交试验，考虑支架完整的压缩-握持膨胀过程，比较分析了支架参数对径向回弹性、轴向缩短率和径向支撑刚度的影响。结果表明，减小细胞结构的壁宽或增加细胞结构的长度可以改善支架的径向回弹性能；减少轴向细胞结构的数量、减小夹角和增加细胞结构的壁宽可以降低轴向缩短率，改善支架的轴向缩短性能；增加细胞结构的壁宽、细胞结构的壁厚和轴向细胞结构的数量可以改善支架的径向支撑刚度。体外试验研究了压缩率、圆周压缩位置和轴向细胞数量对支架径向支撑性能的影响。血管支架的几何参数对支架的机械性能有重大影响，在临床选择和优化设计支架时应重点考虑。

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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来源期刊

Journal of Mechanics in Medicine and Biology 工程技术-工程：生物医学

CiteScore

1.20

自引率

12.50%

发文量

144

审稿时长

2.3 months

期刊介绍： This journal has as its objective the publication and dissemination of original research (even for "revolutionary concepts that contrast with existing theories" & "hypothesis") in all fields of engineering-mechanics that includes mechanisms, processes, bio-sensors and bio-devices in medicine, biology and healthcare. The journal publishes original papers in English which contribute to an understanding of biomedical engineering and science at a nano- to macro-scale or an improvement of the methods and techniques of medical, biological and clinical treatment by the application of advanced high technology. Journal''s Research Scopes/Topics Covered (but not limited to): Artificial Organs, Biomechanics of Organs. Biofluid Mechanics, Biorheology, Blood Flow Measurement Techniques, Microcirculation, Hemodynamics. Bioheat Transfer and Mass Transport, Nano Heat Transfer. Biomaterials. Biomechanics & Modeling of Cell and Molecular. Biomedical Instrumentation and BioSensors that implicate ''human mechanics'' in details. Biomedical Signal Processing Techniques that implicate ''human mechanics'' in details. Bio-Microelectromechanical Systems, Microfluidics. Bio-Nanotechnology and Clinical Application. Bird and Insect Aerodynamics. Cardiovascular/Cardiac mechanics. Cardiovascular Systems Physiology/Engineering. Cellular and Tissue Mechanics/Engineering. Computational Biomechanics/Physiological Modelling, Systems Physiology. Clinical Biomechanics. Hearing Mechanics. Human Movement and Animal Locomotion. Implant Design and Mechanics. Mathematical modeling. Mechanobiology of Diseases. Mechanics of Medical Robotics. Muscle/Neuromuscular/Musculoskeletal Mechanics and Engineering. Neural- & Neuro-Behavioral Engineering. Orthopedic Biomechanics. Reproductive and Urogynecological Mechanics. Respiratory System Engineering...