Purpose To investigate the association between the macular volume and thickness, as assessed by optical coherence tomography (OCT), with refraction state and axial length (AL) in children. Methods A total of 100 normal children whose right eyes were randomly selected were divided into five groups due to their refraction, comprising hyperopia, emmetropia, low myopia, moderate myopia, high myopia. The AL of the eyes was measured by IOL mas ter measuring machine. Then the macular volume and thickness were measured by OCT. Results Children with high myopia have smaller macular volume and thinner parafoveal retinal thickness (especially out-ring macular). The minimum thickness and average thickness of the fovea were not significantly different among the five groups. The macular volume ,total average macular thickness and quadrant-specific macular thickness(except the nasal inner quadrants) were positively associated with refraction and negatively associated with AL, while t here were no correlation between minimum foveal thickness, the average foveal th ickness and refraction or AL. Conclusions In Chinese children, increasing axial length was associated with reduced macular volume and thickness (except the foveal region and the nasal inner quadrant). (Chin J Ocul Fundus Dis,2008,24:114-117)
Objective lt;brgt;To investigate the morphological features of choroidal neovascularization (CNV) in central exudative chorioretinopathy (CEC) using optical coherence tomography(OCT). lt;brgt; lt;brgt;Methods lt;brgt;OCT and fundus fluorescein angiography (FFA) were performed in 41 cases (43 eyes) of CEC,and the course of CEC disease was from 1 week to 10 months. Twenty-seven of 43 eyes were also examined by indocyanine green angiography (ICGA). lt;brgt; lt;brgt;Results lt;brgt;OCT images revealed 5 kinds of morphological features of CEC: well-defined CNV(41.86 %),poorly-defined CNV(30.23 %),hemorrhagic pigment epithelium detachment (PED)(16.28 %), CNV companied with serous (6.98 %) or hemorrhagic neurosensory retina detachment (4.65 %). CNV mainly showed well-defined and poorly-defined CNV (72.09 %).In those eyes that could clear define the CNV boundary,there were 12 eyes on FFA examination and 20 eyes on ICGA examination which defined the boundary from retinal horizontal plane, while there were 23 eyes on OCT examination which defined the boundary from retinal vertical section. Classic CNV on FFA consistently presented with well-defined boundaries on OCT, whereas non-classic CNV had a variable cross-sectional appearance. lt;brgt; lt;brgt;Conclusions lt;brgt;The OCT morphological features of CNV in CEC is mainly well-defined CNV and poorly-defined CNV; OCT examination can precisely observe the retinal and choriocapillaries pathological anatomy of CEC from retinal vertical section, in making the CEC diagnosis as an important complementary examination of FFA and ICGA which observe the focus from retinal horizontal plane. lt;brgt; lt;brgt;(Chin J Ocul Fundus Dis, 2002, 18: 121-124)
ObjectiveTo use flash electroretinogram (F-ERG) and optical coherence tomography (OCT) to examine patients with primary retinitis pigmentosa (RP), and analyze the specificity of the disease on F-ERG and OCT. MethodsThirty-seven patients (74 eyes) diagnosed with primary retinitis pigmentosa in the Department of Ophthalmology, West China Hospital between September 2013 to October 2014 and 38 normal volunteers (76 eyes) were included in this study. F-ERG and OCT examinations were performed on all the patients. Then, we analyzed the differences between the two groups of subjects. ResultsFor RP patients undergoing P-ERG examination with the dark adaptation of 0.01 ERG, the latency of b wave was (73.24±6.42) ms and the amplitude of b wave was (22.87±22.48) μV; when dark adaptation of 3.0 ERG was adopted, the latency of a wave was (24.57±6.30) ms, the amplitude of a wave was (35.45±25.54) μV, the latency of b wave was (48.19±8.18) ms, and the amplitude of b wave was (119.47±50.89) μV; with the light adaptation of 3.0 ERG, the latency of a wave was (21.01±4.86) ms, the amplitude of a wave was (12.59±13.43) μV, the latency of b wave was (38.43±5.00) ms, and the amplitude of b wave was (27.19±38.12) μV. For normal volunteers undergoing F-ERG examination with the dark adaptation of 0.01 ERG, the latency of b wave was (72.63±3.49) ms and the amplitude of b wave was (86.36±21.57) μV; when the dark adaptation was 3.0 ERG, the latency of a wave was (22.88±1.62) ms, the amplitude of a wave was (210.74±43.57) μV, the latency of b wave was (42.59±2.60) ms, and the amplitude of b wave was (398.29±62.42) μV; when the light adaptation of 3.0 ERG was adopted, the latency of a wave was (16.61±0.87) ms, the amplitude of a wave was (54.26±19.64) μV, the latency of b wave was (33.29±1.11) ms, and the amplitude of b wave was (176.98±63.44) μV. There were no significant differences between the two groups when dark adaptation ERG was 0.01 (P=0.48), but for other adaptations, there were significant differences in the latency and amplitude of a and b wave between the two groups (P<0.05). The results of OCT showed that the retinal thickness of the RP patients with a range of 1 mm diameter centered on macular center concave was (218.66±74.14) mm, 3 mm diameter was (275.03±47.85) mm, and 6 mm diameter was (247.37±46.44) mm. For normal volunteers, OCT showed that the retinal thickness with a 1 mm range centered on macular center concave was (250.38±15.79) mm, 3 mm was (323.64±17.26) mm, and 6 mm was (283.44±12.50) mm. The differences between the two groups were statistically significant for each range (P<0.01). ConclusionFor patients with RP, F-ERG shows latency delay and amplitude decrease for each response, while OCT displays a thinning thickness of macular fovea. Therefore, F-ERG and OCT can not only effectively evaluate the functions of macular and the surrounding retina, but can also be used as an effective method for the diagnosis of RP.