Biomechanical Evaluation of Eustachian Tube Dysfunction

咽鼓管功能障碍的生物力学评估

• 批准号: 7433239
• 负责人: SAMIR N GHADIALI
• 金额: $ 3.18万
• 依托单位: LEHIGH UNIVERSITY
• 依托单位国家: 美国
• 财政年份: 2006
• 资助国家: 美国
• 起止时间: 2006-07-01 至 2008-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7433239
• 关键词: Accounting; Address; Adhesions; Adhesives; Adult; Affect; Age; Age-Years; Anatomy; Animal Experiments; Anti-Inflammatory Agents; Antibiotics; Biomechanics; Child; Chronic; Cleft Palate; Clinical; Clinical Treatment; Closure; Complex; Computational Technique; Computer Simulation; Condition; Data; Depth; Development; Disease; Ear Diseases; Effectiveness; Elements; Etiology; Eustachian Tube; Evaluation; Functional disorder; Future; Gases; Glycoproteins; Goals; Hand; Healthcare Systems; Infant; Inflammation; Inflammatory; Irritants; Knowledge; Lead; Liquid substance; Mechanics; Modeling; Morphology; Mucous Membrane; Muscle; Nasal cavity; Nature; Numbers; Operative Surgical Procedures; Otitis Media; Otitis Media with Effusion; Outcome; Pathology; Patients; Pharmacologic Substance; Physiological; Population; Property; Range; Relative (related person); Research; Research Personnel; Research Proposals; Rheology; Samil; Simulate; Standards of Weights and Measures; Structure; Structure-Activity Relationship; Surface Tension; Techniques; Testing; Therapeutic; Tissues; Translating; Tube; Update; Validation; Variant; Viscosity; base; clinically relevant; concept; cost; ear infection; expectation; improved; innovation; middle ear; multi-scale modeling; novel; pathogen; physical property; pressure; programs; simulation; soft tissue; surfactant; three-dimensional modeling; two-dimensional; Accounting; Address; Adhesions; Adhesives; Adult; Affect; Age; Age-Years; Anatomy; Animal Experiments; Anti-Inflammatory Agents; Antibiotics; Biomechanics; Child; Chronic; Cleft Palate; Clinical; Clinical Treatment; Closure; Complex; Computational Technique; Computer Simulation; Condition; Data; Depth; Development; Disease; Ear Diseases; Effectiveness; Elements; Etiology; Eustachian Tube; Evaluation; Functional disorder; Future; Gases; Glycoproteins; Goals; Hand; Healthcare Systems; Infant; Inflammation; Inflammatory; Irritants; Knowledge; Lead; Liquid substance; Mechanics; Modeling; Morphology; Mucous Membrane; Muscle; Nasal cavity; Nature; Numbers; Operative Surgical Procedures; Otitis Media; Otitis Media with Effusion; Outcome; Pathology; Patients; Pharmacologic Substance; Physiological; Population; Property; Range; Relative (related person); Research; Research Personnel; Research Proposals; Rheology; Samil; Simulate; Standards of Weights and Measures; Structure; Structure-Activity Relationship; Surface Tension; Techniques; Testing; Therapeutic; Tissues; Translating; Tube; Update; Validation; Variant; Viscosity; base; clinically relevant; concept; cost; ear infection; expectation; improved; innovation; middle ear; multi-scale modeling; novel; pathogen; physical property; pressure; programs; simulation; soft tissue; surfactant; three-dimensional modeling; two-dimensional

DESCRIPTION (provided by applicant): Otitis media (OM) is one of the most prevalent diseases in children and cost the US healthcare system an estimated $5 billion dollars annually. Although the primary etiology responsible for the persistence of OM conditions is a dysfunctional Eustachian tube (ET), standard treatment therapies for OM do not address the underlying biomechanical and structural abnormalities responsible for ET dysfunction. Recently, several clinical therapies which target specific mechanical and/or physical properties have been suggested to improve ET function. However, the relative effectiveness of these therapies in patient populations with different structural pathologies is not known. Therefore, the goal of this research program is to develop an in- depth understanding of how various biomechanical and biophysical properties influence ET function in different OM prone patient populations. Due to the large number of physical properties, and the complex interactions among these properties, we will elucidate the mechanisms responsible for ET dysfunction using a sophisticated multi-scale computational approach. First, established computational modeling techniques will be used to investigate how the pathological anatomy of ET tissues influences opening phenomena in various OM prone populations. Second, fluid-structure interactions and multi-scale phenomena will be incorporated into the tissue deformation models in order to investigate how various clinically relevant properties (i.e. surface tension and mucosal adhesion forces) influence ET opening. Several sensitivity analyses will be performed to identify which biomechanical or biophysical properties have the greatest impact on ET function in different patient populations. In addition, the computational models will be used to estimate changes in ET function during various pathological conditions. As a result, this research will identify the biomechanical and biophysical mechanisms responsible for ET dysfunction. This information is vital to the development of novel treatment therapies that seek to restore normal ET function in patients with OM.

描述（由申请人提供）：耳炎媒体（OM）是儿童中最普遍的疾病之一，估计每年损失50亿美元的医疗保健系统。尽管负责OM条件持续性的主要病因是功能障碍的Eustachian Tube（ET），但OM的标准治疗疗法并未解决负责ET功能障碍的基本生物力学和结构异常。最近，已经提出了一些针对特定机械和/或物理特性的临床疗法以提高ET功能。但是，这些疗法在具有不同结构病理的患者群体中的相对有效性尚不清楚。因此，该研究计划的目的是对各种生物力学和生物物理特性如何影响不同OM容易发生的患者人群的功能有深入的了解。由于物理特性大量以及这些特性之间的复杂相互作用，我们将使用复杂的多规模计算方法来阐明负责ET功能障碍的机制。首先，已建立的计算建模技术将用于研究ET组织的病理解剖学如何影响各种OM俯卧种群的开放现象。其次，将将流体结构相互作用和多尺度现象纳入组织变形模型，以研究各种临床相关的特性（即表面张力和粘膜粘附力）如何影响ET开放。将进行几种灵敏度分析，以确定哪些生物力学或生物物理特性对不同患者人群的ET功能具有最大的影响。此外，计算模型将用于估计各种病理条件下ET功能的变化。结果，这项研究将确定导致ET功能障碍的生物力学和生物物理机制。该信息对于寻求恢复OM患者正常功能的新型治疗疗法的开发至关重要。