Interplay between multifocal optics and accommodation: implications for myopia progression

多焦点光学器件与调节之间的相互作用：对近视进展的影响

基本信息

批准号：
10637313
负责人：
Susana Marcos
金额：
$ 53.7万
依托单位：
UNIVERSITY OF ROCHESTER
依托单位国家：
美国
项目类别：
财政年份：
2023
资助国家：
美国
起止时间：
2023-07-01 至 2028-04-30
项目状态：
未结题

来源：
https://reporter.nih.gov/project-details/10637313
关键词：
Address Affect Asian Blindness Cataract Child Clinical Clinical Trials Compensation Contact Lenses Crystalline Lens Custom Data Diameter Effectiveness Engineering Eye Eye diseases Eyeglasses Failure Focal Adhesions Future Glaucoma Goals Grant Growth Health Image Individual Intervention Knowledge Length Light Link Location Macular degeneration Maps Measurement Methods Monitor Myopia Operative Surgical Procedures Optics Outcome Pattern Peripheral Physiological Population Presbyopia Psychophysics Pupil Refractive Errors Relaxation Reporting Retina Retinal Detachment Role Schools Signal Transduction Societies Technology Testing Traction Vision Visual Visual Acuity Work adaptive optics design experimental study high risk improved innovation lens novel operation personalized strategies response retinal imaging simulation success visual optics young adult

项目摘要

ABSTRACT Myopia is a refractive error type of eye disorder where light is focused in front of the retina, requiring optical corrections to recover the resulting loss in visual acuity. It is a broadly significant health condition: it is estimated that by 2050 50% of the world population will be myopic. Moreover, even if myopia is compensated with spectacles, contact lenses or surgery, high myopia is linked to a higher risk of retinal detachment, glaucoma, and cataract. Strategies to halt the progression of myopia are therefore an urgent need. Myopia arises from a mismatch between ocular axial length and optical power, but the signals that prompt excessive eye growth are not well understood. Among various strategies developed for myopia control, the use of multifocal contact lenses (MCL) is gaining significant traction. A generalized working principle behind MCL design is that induced myopic defocus in the peripheral retina is protective for foveal axial growth. Initial clinical trials report encouraging reduction of myopia progression in children fitted with MCLs (generally, center-distance and high add powers) however they are still far from the desired effectiveness. Unlike MCL for presbyopia, MCLs for myopia control are prescribed on subjects that can accommodate. However, we currently do not have a good understanding of how accommodation interacts with MCLs in determining retinal image quality. This is a critical gap in knowledge as accommodation affects the very central feature of MCL design — the degree and the sign of retinal defocus. For example, depending on MCL design and individual physiological parameters, some subjects could rely on the near zones of the MCL for near vision, potentially exposing the retina to hyperopic defocus and triggering eye growth. We, a diverse team of optical engineers, physicists and neuroscientists will make use of adaptive optics simulation technologies and psychophysical paradigms to map non-invasively MCL lens patterns onto the subject’s pupil and systematically address key outstanding questions on the interplay between MCL design, accommodation, image quality and visual function with MCLs in young myopes. The group has previously developed adaptive optics technologies to test presbyopia corrections, novel methods based on wavefront sensing to quantify the accommodative response, IOL designs for presbyopia and psychophysical paradigms suited for young subjects. We are now using these capabilities, expanded to binocular simulation and testing, to understand factors underlying accommodative and binocular mechanisms of MCL-based interventions to slow down myopia. The long-term goal is to develop a mechanistic understanding that can help guide the design and personalization of MCL myopia control interventions. We plan to 1) determine the accommodative response with multifocal patterns in young myopes and emmetropes, 2) quantify the effects of various multifocal designs on foveal visual function and 3) test the role of accommodative response on the outcome success in children that have been clinically treated with multifocal contact lenses

抽象的近视是一种屈光不正类型的眼睛疾病，光线聚焦在视网膜前面，需要光学矫正以恢复由此造成的视力损失：据估计，这是一种广泛重要的健康状况。到2050年，世界上50%的人口将患有近视，而且，即使近视得到了补偿。眼镜、隐形眼镜或手术，高度近视与视网膜脱离、青光眼、因此，迫切需要采取措施来阻止近视的发展。眼轴长度和光焦度不匹配，但促使眼睛过度生长的信号是在控制近视的各种策略中，多焦点隐形眼镜的使用尚不为人所知。 (MCL) 正在获得显着的关注 MCL 设计背后的一个普遍工作原理是诱发近视。周边视网膜的散焦对中心凹轴生长有保护作用，初步临床试验报告令人鼓舞。减少佩戴 MCL 的儿童的近视进展（通常是中心距和高附加度数）然而，与控制老花眼的 MCL 不同，MCL 控制近视的效果还很远。规定了可以容纳的科目，但是我们目前还没有很好的了解。调节如何与 MCL 相互作用来确定视网膜图像质量这是一个关键的知识空白。因为调节影响 MCL 设计的核心特征——视网膜散焦的程度和迹象。例如，根据 MCL 设计和个人生理参数，一些受试者可以依赖 MCL 的近区用于近视力，可能使视网膜暴露于远视散焦并触发我们是一个由光学工程师、物理学家和神经科学家组成的多元化团队，将利用自适应技术。光学模拟技术和心理物理学范式将非侵入性 MCL 镜片图案映射到受试者的学生并系统地解决有关 MCL 设计之间相互作用的关键悬而未决的问题，该小组之前曾研究过 MCL 对年轻近视患者的调节、图像质量和视觉功能的影响。开发了自适应光学技术来测试老花眼矫正，基于波前的新颖方法用于量化调节反应的传感、老花眼人工晶状体设计和心理物理学范式适合年轻受试者，我们现在正在使用这些功能，并将其扩展到双目模拟和测试。了解基于 MCL 的干预措施的调节和双眼机制的潜在因素，以减缓长期目标是形成一种机制理解，以帮助指导设计和 MCL 近视控制干预措施的个性化我们计划 1) 确定调节反应。年轻近视眼和正视眼患者的多焦点模式，2) 量化各种多焦点设计的效果中央凹视觉功能和 3) 测试调节反应对儿童成功结果的作用已接受多焦点隐形眼镜临床治疗的