Noninvasive 3D Microscopic Studies of Corneal Elasticity and Collagen Structure

角膜弹性和胶原蛋白结构的无创 3D 显微镜研究

• 批准号: 7691722
• 负责人: TIBOR JUHASZ
• 金额: $ 30.68万
• 依托单位: UNIVERSITY OF CALIFORNIA-IRVINE
• 依托单位国家: 美国
• 财政年份: 2008
• 资助国家: 美国
• 起止时间: 2008-09-30 至 2012-08-31
• 项目状态: 已结题
• 来源: https://reporter.nih.gov/project-details/7691722
• 关键词: 3-Dimensional; Acoustic Microscopy; Acoustics; Address; Affect; Astigmatism; Behavior; Biomechanics; Blindness; Cadaver; Cataract Extraction; Clinical; Clinical Data; Collagen; Cornea; Corneal Diseases; Data; Dependence; Development; Diagnosis; Disease; Disease Progression; Elasticity; Elements; Eye; Fourier Transform; Human; Human Characteristics; Image; Individual; Keratoconus; Keratoplasty; Knowledge; Lasers; Lead; Left; Life; Maps; Measurement; Measures; Mechanics; Methods; Microscope; Microscopic; Microscopy; Modality; Modeling; Movement; Operative Surgical Procedures; Optics; Oryctolagus cuniculus; Outcome; Pathological Dilatation; Pattern; Physiologic pulse; Play; Postoperative Period; Procedures; Property; Radiation; Resolution; Risk; Role; Spatial Distribution; Structure; Techniques; Technology; Testing; Therapeutic; Tissues; Transplantation; Variant; Vision; Visual; base; corneal surgery; improved; in vivo; instrument; novel; novel diagnostics; prevent; public health relevance; regional difference; research study; second harmonic; submicron; theories; tool

DESCRIPTION (provided by applicant): Corneal biomechanics plays an important role in determining the eye's structural integrity, optical power and the overall quality of vision. Common conditions that manifest abnormal corneal biomechanics, such as keratoconus and post-LASIK ectasia affect millions of people and often necessitate corneal transplantation. Corneal biomechanics also plays an increasingly recognized role in the post-operative results of therapeutic and refractive corneal surgery procedures, affecting the predictability, quality and stability of final visual outcomes. A critical limitation to increasing our understanding of how corneal biomechanics controls corneal stability and refraction is the lack of non-invasive technologies that microscopically measure the corneal structure and local biomechanical properties, such as corneal elasticity within the 3D space. We hypothesize that by measuring the movement of a femtosecond laser generated cavitation bubble as it interacts with an acoustic radiation force, we can determine local values for an individual cornea's Young's modulus, without altering its structure and function. We also hypothesize that the inhomogeneous elastic properties of the cornea are strongly influenced by the microstructural organization of collagen lamellae, and that corneas with abnormal biomechanics also may be associated with an abnormal organization of corneal lamellae. Finally, we hypothesize that based on the elasticity and microstructural data for a particular cornea, a specific finite element model (FEM) can be constructed that accurately describes and predicts its biomechanical behavior. To test our hypothesis we plan to develop a bubble-based, acoustic radiation force elastic microscope (ARFEM) and show that it can be used noninvasively to develop a high resolution 3D corneal elasticity map. We will then correlate local variations in corneal elasticity with the microstructure observed by femtosecond laser based second harmonic imaging microscopy (SHIM). We will also investigate biomechanically disordered corneas with both, ARFEM and SHIM, and correlate their elasticity maps with microstructural observations. We will construct a FEM based on the measured ARFEM and SHIM data and show that this model accurately predicts biomechanical behavior for a particular cornea. Finally we will demonstrate in a live rabbit model, that both, ARFEM and SHIM can be performed safely in vivo without tissue damage or harmful effects to the eye. The successful completion of this project will provide experimental evidence that corneal elasticity maps and microstructure can be measured in vivo noninvasively. It will also provide support for the theory that corneal elasticity is influenced by the collagen microstructure, and that the biomechanical behavior of a cornea characterized by ARFEM and SHIM can be accurately predicted by individualized finite element modeling. The results of this project will increase our understanding of corneal biomechanics and its dependence on collagen microstructure and may provide the basis for a novel tool that could be helpful in diagnosing, preventing or treating increasingly common corneal diseases such as keratoconus and post-LASIK ectasia. PUBLIC HEALTH RELEVANCE: We introduce novel noninvasive methods to define spatial distribution of elastic properties and collagen microstructure of individual corneas. The correlation of these functional and structural measurements in healthy eyes will be compared with those that either have common corneal disorders (such as keratoconus and post-LASIK ectasia), or are at risk for them. The results of this project will improve our understanding of corneal biomechanics and its dependence on the collagen microstructure, providing a basis for novel diagnostic instruments and eventual therapeutic modalities for the millions of people that are at risk for severe visual loss from these conditions.

描述(申请人提供)：角膜生物力学在决定眼睛的结构完整性、光学能力和整体视觉质量方面发挥着重要作用。常见的角膜生物力学异常情况，如圆锥角膜和LASIK术后扩张症，影响着数以百万计的人，通常需要进行角膜移植。角膜生物力学也在治疗性和屈光性角膜手术的术后结果中发挥着越来越重要的作用，影响最终视觉结果的可预测性、质量和稳定性。提高我们对角膜生物力学如何控制角膜稳定性和屈光度的理解的一个关键限制是缺乏非侵入性技术来显微镜测量角膜结构和局部生物力学特性，如3D空间内的角膜弹性。我们假设，通过测量飞秒激光产生的空化气泡与声辐射力相互作用时的运动，我们可以确定单个角膜的杨氏模量值，而不会改变其结构和功能。我们还假设，角膜的非均匀弹性特性强烈地受到胶原板的微结构组织的影响，而生物力学异常的角膜也可能与角膜板层的异常组织有关。最后，我们假设，基于特定角膜的弹性和微观结构数据，可以构建特定的有限元模型，以准确地描述和预测其生物力学行为。为了验证我们的假设，我们计划开发一种基于气泡的声辐射力弹性显微镜(ARfem)，并证明它可以非侵入性地用于开发高分辨率3D角膜弹性图。然后，我们将把角膜弹性的局部变化与飞秒激光二次谐波成像显微镜(SHIM)观察到的微结构相关联。我们还将用ARFE和SHIM研究生物力学紊乱的角膜，并将它们的弹性图与显微结构观察相关联。我们将根据测量的ARFE和Shim数据构建一个有限元模型，并表明该模型可以准确地预测特定角膜的生物力学行为。最后，我们将在活体兔子模型中演示，ARFE和SHIM都可以在体内安全地执行，而不会对组织造成损害或对眼睛造成有害影响。该项目的成功完成将为角膜弹性图和微结构的在体非侵入性测量提供实验证据。这也为角膜弹性受胶原微结构影响的理论提供了支持，并且可以通过个体化的有限元模型准确地预测以ARFE和Shim为特征的角膜的生物力学行为。该项目的结果将增加我们对角膜生物力学及其对胶原微结构的依赖的了解，并可能为新的工具提供基础，该工具可能有助于诊断、预防或治疗日益常见的角膜疾病，如圆锥角膜和LASIK术后扩张。公共卫生相关性：我们引入了新的非侵入性方法来定义个体角膜弹性特性和胶原微结构的空间分布。健康眼睛的这些功能和结构测量的相关性将与那些患有常见角膜疾病(如圆锥角膜和LASIK术后扩张症)或有风险的患者进行比较。该项目的结果将提高我们对角膜生物力学及其对胶原微结构的依赖的了解，为数百万因这些疾病而面临严重视力丧失风险的人提供新的诊断工具和最终的治疗方式。