An estimation of the biomechanical properties of the continent and incontinent woman bladder via inverse finite element analysis.

IF 1.7 4区 医学 Q3 ENGINEERING, BIOMEDICAL
Maria Elisabete Teixeira da Silva, Fábio André Teixeira Pinheiro, Nuno Miguel Ferreira, Fernanda Sofia Quintela da Silva Brandão, Pedro Alexandre Lopes de Sousa Martins, Marco Paulo Lages Parente, Maria Teresa da Quinta E Costa Mascarenhas Saraiva, António Augusto Fernandes, Renato Manuel Natal Jorge
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Abstract

Stress urinary incontinence often results from pelvic support structures' weakening or damage. This dysfunction is related to direct injury of the pelvic organ's muscular, ligamentous or connective tissue structures due to aging, vaginal delivery or increase of the intra-abdominal pressure, for example, defecation or due to obesity. Mechanical changes alter the soft tissues' microstructural composition and therefore may affect their biomechanical properties. This study focuses on adapting an inverse finite element analysis to estimate the in vivo bladder's biomechanical properties of two groups of women (continent group (G1) and incontinent group (G2)). These properties were estimated based on MRI, by comparing measurement of the bladder neck's displacements during dynamic MRI acquired in Valsalva maneuver with the results from inverse analysis. For G2, the intra-abdominal pressure was adjusted after applying a 95% impairment to the supporting structures. The material parameters were estimated for the two groups using the Ogden hyperelastic constitutive model. Finite element analysis results showed that the bladder tissue of women with stress urinary incontinence have the highest stiffness (α1 = 0.202 MPa and µ1 = 7.720 MPa) approximately 47% higher when compared to continent women. According to the bladder neck's supero-inferior displacement measured in the MRI, the intra-abdominal pressure values were adjusted for the G2, presenting a difference of 20% (4.0 kPa for G1 and 5.0 kPa for G2). The knowledge of the pelvic structures' biomechanical properties, through this non-invasive methodology, can be crucial in the choice of the synthetic mesh to treat dysfunction when considering personalized options.

通过反向有限元分析估算失禁和失禁女性膀胱的生物力学特性。
压力性尿失禁通常是由于骨盆支撑结构减弱或受损造成的。这种功能障碍与骨盆器官的肌肉、韧带或结缔组织结构的直接损伤有关,其原因包括老化、阴道分娩或腹内压力增加(如排便或肥胖)。机械变化会改变软组织的微观结构组成,从而影响其生物力学特性。本研究主要通过反向有限元分析来估算两组女性(大便失禁组(G1)和小便失禁组(G2))体内膀胱的生物力学特性。这些特性是根据核磁共振成像进行估算的,方法是将在 Valsalva 动作中获得的动态核磁共振成像中的膀胱颈部位移测量值与逆向分析的结果进行比较。对于 G2,在对支撑结构施加 95% 的损伤后,对腹腔内压力进行了调整。使用奥格登超弹性结构模型估算了两组的材料参数。有限元分析结果显示,压力性尿失禁女性的膀胱组织刚度最高(α1 = 0.202 MPa,μ1 = 7.720 MPa),比持续性尿失禁女性高出约 47%。根据核磁共振成像中测得的膀胱颈上内侧位移,调整了 G2 的腹腔内压力值,结果显示两者相差 20%(G1 为 4.0 kPa,G2 为 5.0 kPa)。在考虑个性化方案时,通过这种非侵入性方法了解骨盆结构的生物力学特性对于选择合成网片治疗功能障碍至关重要。
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来源期刊
CiteScore
3.60
自引率
5.60%
发文量
122
审稿时长
6 months
期刊介绍: The Journal of Engineering in Medicine is an interdisciplinary journal encompassing all aspects of engineering in medicine. The Journal is a vital tool for maintaining an understanding of the newest techniques and research in medical engineering.
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