Makous Walter, Carroll Joseph, Wolfing Jessica I, Lin Julianna, Christie Nathan, Williams David R
Center for Visual Science, University of Rochester, New York, NY 14627-0270, USA.
Invest Ophthalmol Vis Sci. 2006 Sep;47(9):4160-7. doi: 10.1167/iovs.05-1195.
To develop a sensitive psychophysical test for detecting visual defects such as microscotomas.
Frequency-of-seeing curves were measured with 0.75' and 7.5' spots. On each trial, from 0 to 4 stimuli were randomly presented at any of eight equally spaced loci 0.5 degrees from fixation. By correcting the aberrations of the eye, adaptive optics produced retinal images of the 0.75' spot that were 3.0 microm wide at half height, small enough to be almost entirely confined within the typical cone diameter at this eccentricity. Data were collected from a patient with deuteranopia (AOS1) whose retina, imaged with adaptive optics, suggested that approximately 30% of his cones were missing or abnormal. Patients with protanomalous trichromacy (1 subject), deuteranopia (1 subject), and trichromacy (5 subjects) served as controls (all had normal cone density and complete cone mosaics). Psychophysical results were modeled by a Monte Carlo simulation incorporating measured properties of the cone mosaic.
Frequency-of-seeing curves for AOS1 obtained with 0.75' spots showed lower asymptote, slope, and sensitivity than for controls. The 7.5' results showed that these differences were the result of the small spot size, which on some trials was confined mostly to the locus of the putatively missing cones. A two-parameter model satisfactorily described the data and was highly sensitive to the proportion of missing cones simulated.
Adaptive-optics microperimetry is a powerful psychophysical test for assessing the loss of neural elements, even in retinas that appear otherwise normal in standard clinical tests. This technique may prove useful in estimating the proportion of missing cones in different patients and in detecting other visual losses such as those associated with glaucoma.
开发一种用于检测微小暗点等视觉缺陷的灵敏心理物理学测试方法。
使用0.75'和7.5'的光斑测量视见频率曲线。在每次试验中,从0到4个刺激随机呈现在距注视点0.5度的八个等间距位置中的任何一个位置。通过校正眼睛的像差,自适应光学技术产生了0.75'光斑的视网膜图像,该图像在半高处宽3.0微米,小到几乎完全局限于该偏心度下典型视锥细胞的直径范围内。数据收集自一名患有绿色盲(AOS1)的患者,其视网膜经自适应光学成像显示,约30%的视锥细胞缺失或异常。患有红色弱(1名受试者)、绿色盲(1名受试者)和三色视觉正常(5名受试者)的患者作为对照(所有患者视锥细胞密度正常且视锥细胞镶嵌完整)。心理物理学结果通过结合视锥细胞镶嵌测量特性的蒙特卡罗模拟进行建模。
用0.75'光斑获得的AOS1视见频率曲线显示,与对照组相比,渐近线、斜率和灵敏度较低。7.5'光斑的结果表明,这些差异是光斑尺寸小的结果,在某些试验中,光斑大多局限于假定缺失视锥细胞的位置。一个双参数模型令人满意地描述了数据,并且对模拟的缺失视锥细胞比例高度敏感。
自适应光学微视野检查是一种强大的心理物理学测试方法,可用于评估神经元件的损失,即使在标准临床测试中看似正常的视网膜中也是如此。该技术可能在估计不同患者中缺失视锥细胞的比例以及检测其他视觉损失(如与青光眼相关的损失)方面证明有用。
