Can numerical modeling help us understanding hydrops in Menière's disease? A PRISMA scoping review.

IF 2.9 3区医学 Q2 NEUROSCIENCES

Journal of Vestibular Research-Equilibrium & Orientation Pub Date : 2025-04-15 DOI:10.1177/09574271251335956

Stéphane Gargula, Dario Ebode, Antonino Maniaci, Thomas Radulesco, Giannicola Iannella, Ralph Haddad, Justin Michel

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引用次数: 0

Abstract

BackgroundThe pathophysiology of Meniere's disease (MD) is complex and intertwined with endolymphatic hydrops. Available experimental models have limitations.ObjectiveThis study aimed to analyze the impact of endolymphatic hydrops on cochleovestibular hydrodynamics through numerical simulations.MethodsA comprehensive literature review was conducted following PRISMA guidelines for Scoping Reviews. Articles were sourced in June 2024 from PubMed and Google Scholar using a combination of MESH terms related to hydrodynamics, numerical simulation, and MD. Studies involving numerical simulations of hydrops in the vestibule, cochlea, or both were included.ResultsEight studies on hydrodynamics in hydrops using numerical simulations were included. In cochlear models, hydrops affect basilar membrane mechanics, causing low-frequency hearing loss, auditory distortions, and frequency shifts. Vestibular models revealed increased static pressure in the horizontal semicircular canal, explaining abnormal vHIT findings in hydrops patients. Models also suggested chaotic fluid dynamics in dilated labyrinthine structures during caloric tests. The reviewed studies underscore the utility of numerical models in understanding the mechanics of MD; however, significant limitations were identified.ConclusionsNumerical modeling offers valuable insights into the hydrodynamic changes caused by endolymphatic hydrops in MD, but future work should address the current limitations by incorporating more accurate anatomical features and chronic progression in simulations.

查看原文本刊更多论文

数值模拟能帮助我们理解梅尼氏病中的水肿吗？PRISMA范围审查。

梅尼埃病（MD）的病理生理是复杂的，与内淋巴积液交织在一起。现有的实验模型有局限性。目的通过数值模拟分析内淋巴积液对耳蜗前庭流体力学的影响。方法按照PRISMA的范围综述指南进行全面的文献综述。文章来源于2024年6月的PubMed和谷歌Scholar，使用了与流体动力学、数值模拟和MD相关的MESH术语组合。包括前庭、耳蜗或两者中积水的数值模拟的研究。结果采用数值模拟方法进行了八项研究。在耳蜗模型中，积液影响基底膜力学，引起低频听力损失、听觉扭曲和频移。前庭模型显示水平半规管静压增加，解释了水肿患者的异常vHIT结果。模型还表明，在热量测试中，扩张迷宫结构中存在混沌流体动力学。综述的研究强调了数值模型在理解MD机制方面的效用；然而，也发现了重大的局限性。结论：数值模拟为MD内淋巴水肿引起的流体动力学变化提供了有价值的见解，但未来的工作应该通过在模拟中纳入更准确的解剖特征和慢性进展来解决当前的局限性。

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

Journal of Vestibular Research-Equilibrium & Orientation 医学-耳鼻喉科学

CiteScore

5.00

自引率

4.30%

发文量

审稿时长

>12 weeks

期刊介绍： Journal of Vestibular Research is a peer-reviewed journal that publishes experimental and observational studies, review papers, and theoretical papers based on current knowledge of the vestibular system. Subjects of the studies can include experimental animals, normal humans, and humans with vestibular or other related disorders. Study topics can include the following: Anatomy of the vestibular system, including vestibulo-ocular, vestibulo-spinal, and vestibulo-autonomic pathways Balance disorders Neurochemistry and neuropharmacology of balance, both at the systems and single neuron level Neurophysiology of balance, including the vestibular, ocular motor, autonomic, and postural control systems Psychophysics of spatial orientation Space and motion sickness Vestibular rehabilitation Vestibular-related human performance in various environments