Objective To evaluate the influence of the location of retinal vessel trunk on neuroretinal rim width of inferior and superior sectors of optic disc, and explore its role in the diagnosis of glaucomatous optic nerve lesion. Methods The photographs of ocular fundus from 459 patients with clear location of retinal vessel trunk, including large disc in 131, medium disc in 145, horizontally oval disc in 75, and small disc in 108 were evaluated. Independent-sample t test was used to compare the difference of the superior and inferior rim widths between the higher-vessel group and the lower-vessel group, and to compare the difference of superior and inferior vessel distances between the narrow-superior-rim-width group and the narrow inferior-rim-width group. Results In most of the patients, or the ones with large and small disc, the ratio of superior rim width to summation of superior and inferior rim widths in the higher-vessel group(0.467plusmn;0.051,0.445plusmn;0.040,0.508plusmn;0.056)were less than which in the lowervessel group(0.500plusmn;0.066,0.474plusmn;0.062,0.546plusmn;0.048), and the differences were significant(P=0.000, 0.045, 0.018); the ratio of superior vessel distance to summation of superior and inferior vessel distance in the narrow-superior-rim-width group(0.510plusmn;0.051,0.508plusmn;0.055,0.512plusmn;0.036)were less than which in the narrow-inferior-rim-width group(0.528plusmn;0.045,0.533plusmn;0.048,0.534plusmn;0.045), and the differences were significant(P=0.000, 0.046, 0.022). Conclusions The position of optic disc vessel trunk influences its superior and inferior rim width. The rim closer to vessel trunk position has narrower width than which comparatively far away from the position. In patients with large, medium, horizontally oval optic disc, glaucoma optic nerve lesion would be considered if the optic disc has the shape of narrower inferior rim, broader superior rim, and vessel location in the superior half of the disc. In the ones with small disc, the optic disc with the shape of narrower superior rim, broader inferior rim, and vessel location in the inferior half of the disc may suggest glaucoma optic nerve lesion. (Chin J Ocul Fundus Dis, 2007, 23: 118-121)
ObjectiveTo investigate the time relationship of the change, and diagnostic accuracy and sensitivity between retinal light threshold fluctuations (LTF) and retinal nerve fiber layer (RNFL) and ganglion cell complex(GCC) thickness on high-risk primary open-angle glaucoma (POAG). MethodsTotally 319 patients (319 eyes) with high-risk in POAG from the First Affiliated Hospital of Kunming Medical Universityand during December 2009 and December 2017, 50 healthy individuals (50 eyes) as control were collected in this longitudinal cohort study. Visual field and OCT were reviewed every 6 months on the high-risk group and every 12 months on the control group. High-risk groups inclusion criteria: vertical C/D≥0.6; early visual field defect (according to glaucoma visual field damage GSS2 quantitative grading standards, mean deviation and pattern standard deviation of central field exceeds the border as an early visual field defect); continuous repeatable results. The first field and OCT results in the absence of visual field defects and C/D≥0.6, which were conformed reliability indicators and removed learning effects as a baseline. When patients achieve POAG diagnosis criteria first time which was recorded as a turning point. And they were divided into early group meanwhile were ended of follow-up. After the last follow-up, the inspection data was segmented counted in yearly interval. The changes of LTF, thickness of RNFL and GCC during the follow-up period in the early POAG group and the control group were observed. The loss rate and change rate in each period were compared for the assessment of their trends with time. Followed by calculation of the area under receiver operating curves (AUC) to compare the predicted value of POAG and the sensitivity at 95% specificity in each period. ResultsAfter last follow-up, totally 67 patients 67 eyes (early POAG group, 37 males and 30 females) were entered the turning point. The mean follow-up of the early POAG group and the control group were 6.6 and 6.4 years. The average RNFL thickness was 79.05±8.09 μm, GCC thickness was 71.58±8.41 μm, LTF was −6.05±7.02 dB in early POAG group. The average RNFL thickness was 93.49±6.24 μm, GCC thickness was 79.72±6.32 μm, LTF was −0.31±0.58 dB in the control group. The differences of LTF and the thickness of RNFL and GCC were statistically significant (t=−5.97, −10.42, −5.60; P<0.001). The AUC of RNFL, GCC thickness and LTF increased with time in the early POAG group. The sensitivity was gradually increased at 95% specificity: 5th year before to at turning point, RNFL thickness AUC was 0.15, 0.65, 0.71, 0.77, 0.85, 0.92, and sensitivity was 20%, 56%, 61%, 65%, 70%, 76%, respectively; GCC thickness AUC was 0.12, 0.53, 0.69, 0.74, 0.82, 0.90, and sensitivity was 14%, 53%, 69%, 74%, 82%, 90%, respectively; the AUC of LTF was 0.10, 0.21, 0.33, 0.75, 0.86, 0.91, and sensitivity was 7%, 17%, 44%, 65%, 78%, 87%, respectively. ConclusionsThe earliest time of structural functional damage of POAG is at the 4th year before confirmed, simultaneous RNFL diagnosis accuracy and sensitivity are better than GCC and LTF. The earliest time of visual functional damage of POAG is at the 2th year before confirmed, simultaneous LTF diagnosis accuracy and sensitivity are better than RNFL and GCC.