Ophthalmic Research Group, Life and Health Sciences, Aston University, Birmingham, United Kingdom.
Invest Ophthalmol Vis Sci. 2011 Jun 1;52(6):3689-97. doi: 10.1167/iovs.10-6805.
To quantify changes in crystalline lens curvature, thickness, equatorial diameter, surface area, and volume during accommodation using a novel two-dimensional magnetic resonance imaging (MRI) paradigm to generate a complete three-dimensional crystalline lens surface model.
Nineteen volunteers, aged 19 to 30 years, were recruited. T(2)-weighted MRIs, optimized to show fluid-filled chambers of the eye, were acquired using an eight-channel radio frequency head coil. Twenty-four oblique-axial slices of 0.8 mm thickness, with no interslice gaps, were acquired to visualize the crystalline lens. Three Maltese cross-type accommodative stimuli (at 0.17, 4.0, and 8.0 D) were presented randomly to the subjects in the MRI to examine lenticular changes with accommodation. MRIs were analyzed to generate a three-dimensional surface model.
During accommodation, mean crystalline lens thickness increased (F = 33.39, P < 0.001), whereas lens equatorial diameter (F = 24.00, P < 0.001) and surface radii both decreased (anterior surface, F = 21.78, P < 0.001; posterior surface, F = 13.81, P < 0.001). Over the same stimulus range, mean crystalline lens surface area decreased (F = 7.04, P < 0.005) with a corresponding increase in lens volume (F = 6.06, P = 0.005). These biometric changes represent a 1.82% decrease and 2.30% increase in crystalline lens surface area and volume, respectively. CONCLUSIONS; The results indicate that the capsular bag undergoes elastic deformation during accommodation, causing reduced surface area, and the observed volumetric changes oppose the theory that the lens is incompressible.
使用一种新的二维磁共振成像(MRI)范式来量化调节过程中晶状体曲率、厚度、赤道直径、表面积和体积的变化,以生成完整的三维晶状体表面模型。
招募了 19 名年龄在 19 至 30 岁的志愿者。使用八通道射频头线圈采集了优化的 T2 加权 MRI,以显示充满液体的眼球腔室。采集了 24 张 0.8 毫米厚的斜轴切片,切片之间没有间隙,以可视化晶状体。向 MRI 中的受试者随机呈现三个 Maltese 十字型调节刺激(0.17、4.0 和 8.0 D),以检查晶状体随调节的变化。对 MRI 进行分析以生成三维表面模型。
在调节过程中,晶状体平均厚度增加(F = 33.39,P < 0.001),而晶状体赤道直径(F = 24.00,P < 0.001)和表面半径均减小(前表面,F = 21.78,P < 0.001;后表面,F = 13.81,P < 0.001)。在相同的刺激范围内,晶状体表面积平均减少(F = 7.04,P < 0.005),晶状体体积相应增加(F = 6.06,P = 0.005)。这些生物测量变化分别代表晶状体表面积减少 1.82%,体积增加 2.30%。
结果表明,晶状体囊在调节过程中发生弹性变形,导致表面积减小,观察到的体积变化与晶状体不可压缩的理论相矛盾。
