In silico tools for mechanical analysis of extra- and intra-luminal artificial urinary sphincters

IF 1.6 Q3 UROLOGY & NEPHROLOGY

BJUI compass Pub Date : 2024-12-25 DOI:10.1002/bco2.473

Gianluca Mazzucco, Paola Pirini, Chiara Giulia Fontanella, Alice Berardo, Maria Vittoria Mascolini, Ilaria Toniolo, Leonardo Marziale, Tommaso Mazzocchi, Gioia Lucarini, Nicolò Spiezia, Emanuele Luigi Carniel

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Abstract

Objectives

To analyse and compare the functionality of extraluminal and intraluminal artificial urinary sphincters (AUSs), an in silico procedure has been defined and applied. Design and reliability assessments of the AUS are typically performed using a clinical approach, which does not provide data on mechanical stimulation of urethral tissues. Mechanical stimulation may determine tissue degeneration, such as urethral atrophy or erosion, the main causes of AUS failure. In silico techniques can provide a quantitative description of stress and strain fields due to the interaction between tissues and AUS and allow investigating an extremely large number of situations, considering different configurations of AUS and urethra.

Materials and Methods

Computational investigations were carried out to evaluate the mechanical reliability of the main extraluminal and intraluminal AUS, AMS 800 and Relief. The lower urinary tract was modelled based on previous experiments. The AUS models took into account the main components that interact with biological tissues. Urethra and AUS models were coupled and used to investigate mechanical stimulation of urethral tissues.

Results

In silico simulations provide quantitative information about the mechanical stimulation of urethral tissue, such as compressive strain and stress and hydrostatic pressure, due to interaction with the AUS. Such mechanical quantities allow a comparison of reliability between extraluminal and intraluminal devices.

Conclusions

The activities define and demonstrate the effectiveness of a novel in silico approach to the design and reliability assessment of AUS devices, increasing the investigative possibilities and reducing the time, ethical and economic costs.

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腔外和腔内人工尿括约肌力学分析的硅工具。

目的：分析和比较腔外和腔内人工尿括约肌（AUSs）的功能，定义并应用了一种人工尿括约肌手术。AUS的设计和可靠性评估通常采用临床方法进行，不提供机械刺激尿道组织的数据。机械刺激可决定组织退化，如尿道萎缩或糜烂，这是AUS失败的主要原因。在硅技术可以提供一个定量的描述应力和应变场，由于组织和AUS之间的相互作用，并允许调查极其大量的情况，考虑到AUS和尿道的不同配置。材料和方法：对主要的腔外和腔内AUS、AMS 800和Relief的力学可靠性进行了计算研究。下尿路是根据以前的实验建立的。AUS模型考虑了与生物组织相互作用的主要成分。尿道和AUS模型耦合，用于研究尿道组织的机械刺激。结果：计算机模拟提供了尿道组织机械刺激的定量信息，如压缩应变、应力和静水压力，由于与AUS的相互作用。这样的机械量可以比较腔外和腔内装置之间的可靠性。结论：这些活动定义并证明了一种新颖的计算机方法对AUS设备的设计和可靠性评估的有效性，增加了调查的可能性，减少了时间、道德和经济成本。

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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