基于多维0/1D-3D模型的pci术后患者强化体外反搏治疗的血流动力学反应

IF 2.4 3区医学 Q3 BIOPHYSICS

Journal of biomechanics Pub Date : 2025-01-01 DOI:10.1016/j.jbiomech.2024.112487

Xuan-hao Xu , Zhi-bo Wang , Qi Zhang , Jie-ting Wang , Xue Jia , Li-ling Hao , Ling Lin , Gui-fu Wu , Shuai Tian

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引用次数: 0

摘要

体外强化反搏（EECP）在经皮冠状动脉介入治疗（PCI）后的患者康复中被广泛应用，并已证明其促进心血管功能恢复的疗效。虽然治疗效果的确切机制尚不清楚，但人们普遍认为EECP诱导的生物力学环境的改善起着关键作用。本研究旨在通过使用先进的多维0/1D-3D耦合模型对EECP期间支架内生物力学环境进行数值研究，揭示其潜在机制。生理数据，包括年龄、身高、冠状动脉造影图像和5条不同动脉的血流速度分布，临床收集了11名志愿者在休息和EECP期间的数据。这些数据有助于开发患者特异性的0/1D模型来预测冠状动脉容量流量，以及3D支架冠状动脉模型来捕获支架内详细的生物力学特征。具体而言，引入了一种浸入固体方法来解决生成三维模型计算单元的数值挑战。模拟结果显示，EECP显著改善了支架动脉内的生物力学环境，增加了时间平均壁剪切应力（静息与20 kPa vs 30 kPa: 1.39±0.4773 Pa vs 1.82±0.6856 Pa vs 1.96±0.7592 Pa, p = 0.0009），减少了相对停留时间（静息与20 kPa vs 30 kPa: 1.06±0.3926 Pa-1 vs 0.89±0.3519 Pa-1 vs 0.87±0.3764 Pa-1, p = 0.0009）

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The hemodynamic responses to enhanced external counterpulsation therapy in post-PCI patients with a multi-dimension 0/1D-3D model

Enhanced external counterpulsation (EECP) is widely utilized in rehabilitating patients after percutaneous coronary intervention (PCI) and has demonstrated efficacy in promoting cardiovascular function recovery. Although the precise mechanisms of the therapeutic effects remain elusive, it is widely postulated that the improvement of biomechanical environment induced by EECP plays a critical role. This study aimed to unravel the underlying mechanism through a numerical investigation of the in-stent biomechanical environment during EECP using an advanced multi-dimensional 0/1D-3D coupled model. Physiological data, including age, height, coronary angiography images, and blood velocity profiles of five different arteries, were clinically collected from eleven volunteers both at rest and during EECP. These data contributed the development of a patient-specific 0/1D model to predict the coronary volumetric flow and a 3D stented coronary artery model to capture the detailed in-stent biomechanical features. Specifically, an immersed solid method was introduced to address the numerical challenges of generating computational cells for the 3D model. Simulations revealed that EECP significantly improved the biomechanical environment within the stented arteries, as evidenced by increased time-averaged wall shear stress (resting vs. 20 kPa vs. 30 kPa: 1.39 ± 0.4773 Pa vs. 1.82 ± 0.6856 Pa vs. 1.96 ± 0.7592 Pa, p = 0.0009) and reduced relative residence time (resting vs. 20 kPa vs. 30 kPa: 1.06 ± 0.3926 Pa⁻¹ vs. 0.89 ± 0.3519 Pa⁻¹ vs. 0.87 ± 0.3764 Pa⁻¹, p < 0.0001). Correspondingly, low-WSS/high-RRT surfaces were obviously reduced under EECP. These findings provide deeper insights into EECP’s therapeutic mechanisms, thereby offering basis to optimize EECP protocols for enhanced clinical outcomes in post-PCI patients.

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来源期刊

Journal of biomechanics 生物-工程：生物医学

CiteScore

5.10

自引率

4.20%

发文量

345

审稿时长

1 months

期刊介绍： The Journal of Biomechanics publishes reports of original and substantial findings using the principles of mechanics to explore biological problems. Analytical, as well as experimental papers may be submitted, and the journal accepts original articles, surveys and perspective articles (usually by Editorial invitation only), book reviews and letters to the Editor. The criteria for acceptance of manuscripts include excellence, novelty, significance, clarity, conciseness and interest to the readership. Papers published in the journal may cover a wide range of topics in biomechanics, including, but not limited to: -Fundamental Topics - Biomechanics of the musculoskeletal, cardiovascular, and respiratory systems, mechanics of hard and soft tissues, biofluid mechanics, mechanics of prostheses and implant-tissue interfaces, mechanics of cells. -Cardiovascular and Respiratory Biomechanics - Mechanics of blood-flow, air-flow, mechanics of the soft tissues, flow-tissue or flow-prosthesis interactions. -Cell Biomechanics - Biomechanic analyses of cells, membranes and sub-cellular structures; the relationship of the mechanical environment to cell and tissue response. -Dental Biomechanics - Design and analysis of dental tissues and prostheses, mechanics of chewing. -Functional Tissue Engineering - The role of biomechanical factors in engineered tissue replacements and regenerative medicine. -Injury Biomechanics - Mechanics of impact and trauma, dynamics of man-machine interaction. -Molecular Biomechanics - Mechanical analyses of biomolecules. -Orthopedic Biomechanics - Mechanics of fracture and fracture fixation, mechanics of implants and implant fixation, mechanics of bones and joints, wear of natural and artificial joints. -Rehabilitation Biomechanics - Analyses of gait, mechanics of prosthetics and orthotics. -Sports Biomechanics - Mechanical analyses of sports performance.