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ENGLISH ABSTRACT
基于体外光学质量测试设备的非球面人工晶状体光学性能评价
谢丽暄
廖萱
兰长骏
谭青青
潘若琳
唐玉玲
秦苏云
王艳
作者及单位信息
·
DOI: 10.3760/cma.j.cn115989-20230821-00075
Evaluation of optical performance of aspherical intraocular lens in vitro by optical bench
Xie Lixuan
Liao Xuan
Lan Changjun
Tan Qingqing
Pan Ruolin
Tang Yuling
Qin Suyun
Wang Yan
Authors Info & Affiliations
Xie Lixuan
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
Liao Xuan
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
Lan Changjun
Chengdu Eastern Aier Eye Hospital, Chengdu 610056, China
Tan Qingqing
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
Pan Ruolin
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
Tang Yuling
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
Qin Suyun
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
Wang Yan
Department of Ophthalmology, Affiliated Hospital of North Sichuan Medical College, Medical School of Ophthalmology & Optometry, North Sichuan Medical College, Nanchong 637000, China
·
DOI: 10.3760/cma.j.cn115989-20230821-00075
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摘要

目的应用体外光学质量测试设备OptiSpheric IOL R&D比较2种具有相同负球差值的非球面人工晶状体(IOL)AcrySof IQ SN60WF和Proming A1-UV的光学性能。

方法应用OptiSpheric IOL R&D设备,分别在球差为0 μm(ISO-1)和+0.28 μm(ISO-2)的模型角膜以及孔径为3.0和4.5 mm条件下对+20.0 D蓝光滤过型SN60WF和高次非球面设计的非蓝光滤过全像差补偿型A1-UV IOL进行光学性能评估。分别测量IOL居中,偏心0.3、0.5、0.7、0.9和1.1 mm,倾斜3°、5°、7°、9°和11°的调制传递函数(MTF)以及USAF 1951分辨率测试图。采用紫外可见分光光度计UV-3300测试IOL的光谱透射比。

结果与A1-UV IOL相比,SN60WF对400~500 nm波长蓝光的光谱透射比明显降低,能明显减少蓝光透过。当孔径为3.0 mm时,居中位置的SN60WF和A1-UV在100 lp/mm空间频率时ISO-1角膜测量条件下MTF值分别为0.576和0.598,ISO-2角膜测量条件下MTF值分别为0.564和0.563;当孔径为4.5 mm时,ISO-1角膜测量条件下MTF值分别为0.238和0.404,ISO-2角膜测量条件下MTF值分别为0.438和0.339。在3.0 mm孔径下,100 lp/mm空间频率时ISO-1角膜测量条件下MTF值均较ISO-2角膜测量条件下升高;在ISO-1角膜测量条件下,A1-UV相比于SN60WF展现出更优越的光学质量,而在ISO-2角膜测量条件下,2种IOL的光学质量相似。在3.0 mm孔径下,偏心0.3 mm的SN60WF和A1-UV在100 lp/mm空间频率时ISO-1角膜测量条件下MTF值分别为0.414和0.571,ISO-2角膜测量条件下MTF值分别为0.438和0.512,倾斜3°的ISO-1角膜测量条件下MTF值分别为0.522和0.597,ISO-2角膜测量条件下MTF值分别为0.532和0.531,A1-UV在2种角膜测量条件下的MTF值和USAF分辨率测试图未发生显著改变。当IOL发生相同程度偏心或倾斜时,除4.5 mm孔径ISO-1角膜测量条件以外,A1-UV各空间频率的MTF值相较于SN60WF均下降。随着孔径的增大,IOL偏心或倾斜对MTF值和USAF分辨率测试图的影响更加显著。

结论SN60WF IOL能有效滤过波长在400~500 nm范围内的蓝光。当2种IOL发生大于0.3 mm的偏心或大于3°的倾斜时,均会造成IOL的光学质量下降。A1-UV相较于SN60WF在体外抗偏心和倾斜性能方面具有一定优势。

人工晶状体;光学性能;体外;偏心;倾斜;成像质量
ABSTRACT

ObjectiveTo evaluate the optical performance of two aspheric intraocular lenses (IOL) AcrySof IQ SN60WF and Proming A1-UV with identical negative spherical aberration values, using the optical bench OptiSpheric IOL R&D through an in vitro study.

MethodsThe optical performance of + 20.0 D blue-light filtering SN60WF and monofocal high-order aspheric non blue-light filtering A1-UV IOL was evaluated through cornea models with the spherical aberration of 0 μm (ISO-1) and + 0.28 μm (ISO-2) under apertures of 3.0 mm and 4.5 mm via the optical bench OptiSpheric IOL R&D.The modulation transfer function (MTF) and USAF 1951 resolution test chart were employed to measure the IOL with centering, decentration of 0.3, 0.5, 0.7, 0.9 and 1.1 mm, as well as tilt of 3°, 5°, 7°, 9° and 11°.The spectral transmittance of IOL was measured with the UV-3300 UV-VIS spectrophotometer.

ResultsCompared with the A1-UV IOL, the spectral transmittance of SN60WF for blue light with wavelengths of 400-500 nm was significantly reduced, which effectively reduced the passage of blue light.At an aperture of 3.0 mm, the MTF values at 100 lp/mm spatial frequency for the centered SN60WF and A1-UV were 0.576 and 0.598 under ISO-1 corneal measurement conditions, 0.564 and 0.563 under ISO-2 conditions.At an aperture of 4.5 mm, the MTF values were 0.238 and 0.404 under ISO-1 corneal measurement conditions, and 0.438 and 0.339 under ISO-2 conditions.The MTF values of A1-UV and SN60WF at 3.0 mm aperture and 100 lp/mm spatial frequency under ISO-1 corneal measurement conditions were larger than those under ISO-2 corneal measurement conditions.Under ISO-1 corneal measurement conditions with a 3.0 mm aperture, A1-UV had a better optical quality compared to SN60WF, whereas under ISO-2 corneal measurement conditions, the optical quality of both IOLs was similar.Under the 3.0 mm aperture, the MTF values of SN60WF and A1-UV at a decentration of 0.3 mm and 100 lp/mm spatial frequency were 0.414 and 0.571 under ISO-1 corneal measurement conditions, 0.438 and 0.512 under ISO-2 corneal measurement conditions, respectively.The MTF values of SN60WF and A1-UV at a tilt of 3° were 0.522 and 0.597 under ISO-1 corneal measurement conditions, and 0.532 and 0.531 under ISO-2 corneal measurement conditions.The MTF values and USAF resolution test chart of A1-UV had no significant change between the two corneal measurement conditions.When subjected to equal degrees of decentration or tilting, except for the ISO-1 corneal measurement conditions at a 4.5 mm aperture, the MTF values of A1-UV showed a gradual decline across various spatial frequencies compared to SN60WF.With the increase in aperture size, the impact of IOL decentration or tilting on MTF values and USAF 1951 resolution test chart became more notable for A1-UV relative to SN60WF.

ConclusionsThe SN60WF IOL effectively filters blue light within the wavelength range of 400-500 nm.However, when both IOL experience decentration greater than 0.3 mm or tilting beyond 3°, the optical quality of the IOL will decline.A1-UV has a distinct advantage over SN60WF in terms of resistance to both decentration and tilting-induced optical performance degradation in vitro.

Lenses, intraocular;Optical performance; In vitro ;Decentration;Tilt;Optical quality
Lan Changjun, Email: mocdef.aabnisnujgnahcnal
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引用本文

谢丽暄,廖萱,兰长骏,等. 基于体外光学质量测试设备的非球面人工晶状体光学性能评价[J]. 中华实验眼科杂志,2024,42(03):240-247.

DOI:10.3760/cma.j.cn115989-20230821-00075

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近年来,人工晶状体(intraocular lens,IOL)材料和设计不断更新,同时IOL眼内位置对其光学性能的影响也值得关注 [ 1 , 2 ]。IOL的理想位置是居于囊袋内且中心与视轴重合,但由于患者眼部解剖结构、IOL特性和手术操作等因素,IOL不可避免地发生偏心和倾斜。轻微的IOL偏心和倾斜不会引起患者明显的主观不适,但一定程度的偏心和倾斜可能导致近视漂移、斜向散光、彗差等高阶像差增加、最佳矫正视力下降和视觉质量下降等 [ 1 , 2 , 3 ]。通常情况下,角膜的球差为正值且相对稳定,6.0 mm瞳孔直径下约为+0.27 μm,而晶状体的球差为负值,2个光学系统之间呈相互补偿的理想状态 [ 4 ]。然而随着年龄增长,晶状体的球差逐渐从负值变为正值,导致全眼总球差增加和视觉质量下降 [ 5 , 6 ]。目前,临床上非球面IOL应用广泛,如散光矫正型、老视矫正型IOL等,其光学性能的影响程度与非球面IOL的球差值紧密相关 [ 7 , 8 ]。本研究团队在前期临床研究中发现,植入囊袋的单焦点非球面IOL,如SN60WF和A1-UV存在不同程度的偏心和倾斜,然而其在患者视力、对比敏感度和视觉质量方面并未显示出临床意义上的差异,这说明术后轻度的IOL偏心和倾斜对患者来说是可以良好耐受的 [ 9 , 10 ]。既往关于IOL偏心和倾斜对视觉质量影响的研究大多为体内研究,容易受到个体差异、光学介质和患者主观感受的影响,具有一定的局限性,因此难以确切地评价偏心、倾斜和瞳孔大小等因素的影响 [ 11 ];另一方面,一些体外研究依赖光学设计软件,如ZEMAX、OSLO等,得到的结果可能与真实值存在一定差异 [ 12 , 13 ]。光学测试设备OptiSpheric IOL R&D能够根据不同研究目的来设置光学参数,对功能性IOL进行光学性能评估,能更客观、准确地评价IOL的光学性能 [ 7 , 8 , 14 ]。据了解,目前已有关于不同球差IOL体外光学性能比较的研究,但不同光学设计对IOL光学性能的影响尚不清楚 [ 7 , 13 , 15 ]。因此,本研究拟采用OptiSpheric IOL R&D设备比较2种具有相同负球差值但不同平台设计的非球面IOL的光学性能,旨在从光学层面为临床个性化选择IOL提供理论基础。
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兰长骏,Email: mocdef.aabnisnujgnahcnal
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谢丽暄:参与选题与研究设计、数据采集、分析/解释数据、文章撰写;廖萱、谭青青:审阅和修改论文;兰长骏:研究设计、数据分析、论文修改、对文章知识性内容作批评性审阅及定稿;潘若琳、唐玉玲、秦苏云、王艳:参与选题与研究设计、资料分析和解释

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