原发性翼状胬肉的角膜地形图与生物力学

Corneal tomography and biomechanics in primary pterygium.

作者信息

Vanathi M, Goel Sahil, Ganger Anita, Agarwal Tushar, Dada T, Khokhar Sudarshan

机构信息

Cornea, Cataract and Refractive Services, Dr Rajendra Prasad Centre for Ophthalmic Sciences, All India Institute of Medical Sciences, New Delhi, 110029, India.

出版信息

Int Ophthalmol. 2018 Apr;38(2):663-671. doi: 10.1007/s10792-017-0514-6. Epub 2017 May 13.

DOI:10.1007/s10792-017-0514-6

PMID:28501948

Abstract

PURPOSE

To study the Scheimpflug's imaging and corneal biomechanics in primary pterygium.

METHODS

A prospective observational study of 55 patients with unilateral primary nasal pterygium was done. The normal fellow eyes of patients with pterygium were taken as controls. Clinical parameters noted included visual acuity, values of corneal curvature by doing Scheimpflug imaging, wavefront aberrations in terms of higher and lower-order aberrations and corneal hysteresis (CH) as well as corneal resistance factor (CRF) values by using ocular response analyzer.

RESULTS

Of the total 55 patients, mean age was 43.0 + 11.4 years (range: 20-72 years). Mean LogMar uncorrected visual acuity in pterygium eyes and control eyes was 0.21 + 0.20 and 0.12 + 0.15, respectively (p = 0.016). On Scheimpflug imaging the mean anterior corneal curvature values (Ka1/Ka2 D) were 41.09 + 3.38/44.33 + 2.29 in pterygium eyes, 43.13 + 1.79/43.98 + 2.17 in control eyes (p < 0.0005) and mean posterior corneal curvature (Kp1/Kp2 D) values were 6.14 + 0.39/6.53 + 0.43 in pterygium eyes and 6.13 + 0.28/6.46 + 0.47 in control eyes (p > 0.05). Analysis of corneal aberrations showed significantly higher corneal wavefront aberrations in pterygium eyes. Highest correlation of corneal astigmatism was noted with corneal area encroached by pterygium (ρ = 0.540 for LOA and 0.553 for HOA) and distance from pupillary center (ρ = 0.531 for LOA and 0.564 for HOA). Corneal biomechanical parameters including CH and CRF were found to be lower in the pterygium eyes, though not statistically significant (p value 0.60 and 0.59, respectively).

CONCLUSION

Pterygium leads to deterioration of visual performance not only by causing refractive and topographic changes but also by causing a significant increase in corneal wavefront aberrations.

摘要

目的

研究原发性翼状胬肉的眼前节分析成像及角膜生物力学特性。

方法

对55例单侧原发性鼻侧翼状胬肉患者进行前瞻性观察研究。将患翼状胬肉患者的健侧眼作为对照。记录的临床参数包括视力、通过眼前节分析成像获得的角膜曲率值、高低阶像差表示的波前像差以及使用眼反应分析仪测量的角膜滞后（CH）和角膜阻力因子（CRF）值。

结果

55例患者的平均年龄为43.0±11.4岁（范围：20 - 72岁）。翼状胬肉患眼和对照眼的平均LogMar未矫正视力分别为0.21±0.20和0.12±0.15（p = 0.016）。眼前节分析成像显示，翼状胬肉患眼角膜前表面平均曲率值（Ka1/Ka2 D）为41.09±3.38/44.33±2.29，对照眼为43.13±1.79/43.98±2.17（p < 0.0005）；翼状胬肉患眼角膜后表面平均曲率（Kp1/Kp2 D）值为6.14±0.39/6.53±0.43，对照眼为6.13±0.28/6.46±0.47（p > 0.05）。角膜像差分析显示翼状胬肉患眼的角膜波前像差显著更高。角膜散光与翼状胬肉侵犯的角膜面积相关性最高（低阶像差ρ = 0.540，高阶像差ρ = 0.553），与距瞳孔中心的距离相关性也最高（低阶像差ρ = 0.531，高阶像差ρ = 0.564）。包括CH和CRF在内的角膜生物力学参数在翼状胬肉患眼中较低，尽管差异无统计学意义（p值分别为0.60和0.59）。

结论

翼状胬肉不仅通过引起屈光和地形变化，还通过导致角膜波前像差显著增加，从而导致视觉性能下降。

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原发性翼状胬肉的角膜地形图与生物力学

Corneal tomography and biomechanics in primary pterygium.

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METHODS

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结果

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