Experience in the development of a system for repeated prosthetic heart valves

Q4 Biochemistry, Genetics and Molecular Biology
E. Ovcharenko, K. Klyshnikov, A. Stasev, A. Evtushenko, I. Khalivopulo, D. V. Borisenko, T. Glushkova, A. Ivanova, I. V. Dvadtsatov, S. Krutitsky, Y. Kudryavtseva, O. Barbarash, L. Barbarash
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引用次数: 0

Abstract

The failure of heart valve bioprostheses, requiring repeated intervention to replace them, is a serious drawback that narrows the scope of such devices. The present study demonstrates the experimental investigation of a medical device designed to partially solve the problem of repeated interventions on heart valves, primarily with an emphasis on reducing the duration and trauma of such procedures due to the sutureless balloon implantation method of the «valvein- valve» method.Material and methods. The paper presents a series of in silico, in vitro and in vivo experiments to evaluate various aspects of the device under development. Numerical modeling of the final shape setting to the supporting frame of the heart valve prosthesis to select the most promising concept for prototyping was carried out in the Abaqus/CAE (Dassault Systèmes, France) based on the finite element method. The selected optimal support frame model was prototyped in the form of a series of prosthesis samples of four standard sizes for hydrodynamic studies of quantitative characteristics in vitro. The study was carried out in the Vivitro Labs unit (Vivitro Labs, Canada), imitating the physiological mode of the heart, the prostheses were examined for the mitral position. The developed prototypes of the device were supplemented with related products, an implant holder and a balloon catheter, after which the proposed method of sutureless fixation was validated in an in vitro implantation procedure on a bovine heart model and a series of in vivo (n = 3) chronic experiments on animals.Results. In the course of numerical simulation, it was shown that in Model No. 3 of the supporting frame of the prosthesis, the smallest stresses occur – with an amplitude of up to 490 MPa. For other concepts (Models No. 1 and No. 2), this indicator was significantly higher, 543 and 514 MPa, respectively. Prototypes obtained on the basis of the selected shape of the support frame demonstrated satisfactory hydrodynamic characteristics: effective hole area 190-261 mm2, regurgitation volume 6–9 ml/cycle, average transprosthetic gradient 4.4–6.4 mmHg, depending on size. The study of the technology of sutureless balloon implantation in an in vitro model of the heart and the subsequent chronic experiment on sheep confirmed the main idea of the system – the possibility of a significant reduction in the duration of repeated prosthetics. It has been shown that the time of suture implantation of the “classic” frame prosthesis of the mitral valve is 23–29 minutes, with a total access time of 41–52 minutes. When implanting the experimental device, the sutureless prosthesis itself took 4–6 minutes, access time 24–29 minutes. At the same time, one-month results of an echocardiographic study of the operation of the prosthesis demonstrated satisfactory hemodynamics.Conclusions. This work demonstrates a consistent series of tests of the system being developed for repeated heart valve replacement, which substantiates some design solutions, confirms the effectiveness and viability of the chosen approach to sutureless minimally invasive implantation.
有开发重复人工心脏瓣膜系统的经验
心脏瓣膜生物瓣膜的故障,需要反复干预才能更换,这是一个严重的缺陷,缩小了此类装置的范围。本研究展示了一种医疗器械的实验研究,该医疗器械旨在部分解决心脏瓣膜重复干预的问题,主要强调减少此类手术的持续时间和创伤,因为“瓣膜”方法的无缝合球囊植入方法。材料和方法。本文介绍了一系列的硅、体外和体内实验,以评估正在开发的设备的各个方面。基于有限元法,在Abaqus/CAE(法国达索系统)中对人工心脏瓣膜支撑架的最终形状设置进行了数值建模,以选择最有前景的原型设计概念。所选择的最佳支撑框架模型以四种标准尺寸的一系列假体样本的形式进行原型化,用于体外定量特征的流体动力学研究。这项研究是在Vivitro实验室(加拿大Vivito实验室)进行的,模拟心脏的生理模式,检查假体的二尖瓣位置。该装置的开发原型补充了相关产品、植入物支架和球囊导管,之后在牛心模型的体外植入程序和一系列动物体内(n=3)慢性实验中验证了所提出的无缝合固定方法。后果在数值模拟过程中,结果表明,在假体支撑架的3号模型中,出现的应力最小,振幅高达490 MPa。对于其他概念(1号和2号型号),该指标明显更高,分别为543和514兆帕。根据支架的选定形状获得的原型显示出令人满意的流体动力学特性:有效孔面积190-261 mm2,反流体积6-9 ml/周期,平均跨假体梯度4.4-6.4 mmHg,具体取决于尺寸。在体外心脏模型中进行的无缝合球囊植入技术研究以及随后在绵羊身上进行的慢性实验证实了该系统的主要思想——显著缩短重复假肢持续时间的可能性。研究表明,二尖瓣“经典”框架假体的缝线植入时间为23-29分钟,总进入时间为41-52分钟。当植入实验装置时,无缝合假体本身需要4-6分钟,进入时间为24-29分钟。同时,一个月的超声心动图研究结果显示,该假体的操作血流动力学令人满意。结论。这项工作证明了正在开发的用于重复心脏瓣膜置换的系统的一系列一致测试,这证实了一些设计解决方案,证实了所选无缝合微创植入方法的有效性和可行性。
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
CiteScore
0.40
自引率
0.00%
发文量
54
审稿时长
12 weeks
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