Objective To explore the retinal and choroidal thickness of myopic patients with different diopters, and analyze the change rule and its relation with the diopter. Methods From October 2015 to June 2016, a total of 161 patients (322 eyes) with myopia and 53 normal volunteers (106 eyes) were selected from Department of Ophthalmology, West China Hospital of Sichuan University. Optical coherence tomography (OCT) examination was performed in all the subjects with Macular cube 512×128 and EDI HD-OCT model in Cirrus HD-OCT 5000 of Carl Zeiss Company from Germany, measuring the retinal and choroidal thickness in macular central fovea, and 3 and 6 mm above, below, on the nose side, and on the temporal side of macular central fovea; the data were averaged. According to the different diopters, the subjects were divided into four groups, including emmetropia group with 53 patients (106 eyes), low myopia group (equivalent diopter from –0.25 to –3.00) with 64 patients (128 eyes), moderate myopia group (equivalent diopter from –3.25 to –6.00) with 47 patients (94 eyes), and high myopia group (equivalent diopter <–6.00) with 50 patients (100 eyes). All the subjects’ best corrected visual acuities were ≥0.8. The changes of retinal and choroidal thickness in myopia patients with different diopters were compared and analyzed. Results The average retinal thickness of the patients in the emmetropia group, the low myopia group, the moderate myopia group, and the high myopia group was (242.50±29.86), (238.46±23.85), (224.52±26.01), (211.91±23.07) μm, respectively; the average choroidal thickness of the patients in the emmetropia group, the low myopia group, the moderate myopia group, and the high myopia group was (220.16±66.00), (252.39±79.56), (191.09±103.03), (121.83±92.54) μm, respectively. There was no significant difference in retinal thickness between the moderate myopia group and the high myopia group (P>0.05), while the differences in retinal thickness between the remaining groups were statistically significant (P<0.05); there was no statistically significant difference between the emmetropia group and moderate myopia group (P>0.05), while the differences in choroid thickness between the remaining groups were statistically significant (P<0.05). Conclusion In general, there are decreasing trends of the retinal thickness and choroid thickness with the increase of the diopter, which may be associated with the formation process of myopia.
ObjectiveTo construct a map of cerebral cortex thickness in Idiopathic Generalized Epilepsy (IGE) diagnosed at the first visit, using T1-weighted brain magnetic resonance imaging and advanced image analysis software. MethodsHigh-resolution three-dimensional T1 images were obtained from 27 IGE patients diagnosed at the first visit and 29 normal controls in Shouguang People's Hospital from January 1, 2022 to December 31, 2021. The location recognition calculation system of the Freesurfer software was used to calculate the values of cortical thickness in each brain region, and the cortical thickness values were transformed into a brain atlas using the image analysis software. A differential brain atlas was generated using the two-sample t-test to analyze the difference in cortical thickness between IGE patients and normal controls. Paired t-test was used for within-group comparison to explore changes of cortical thickness laterality. ResultsIn the IGE brain atlas, the brain regions with higher cortical thickness were the right left temporal pole, the right left entorhinal cortex, the head of the right anterior cingulate gyrus, the right and left insular lobe, the right and left middle temporal gyrus, the right inferior temporal gyrus, the head of the left anterior cingulate gyrus, the left tail of the anterior cingulate gyrus, the left inferior temporal gyrus, the left and right fusiform gyrus, and the left frontal pole. The areas with lower cortical thickness were the right and left paracalcaric gyrus, the right and left cuneiform lobe, the left and right lingual gyrus, the left and right posterior central gyrus, the left lateral occipital gyrus, and the right and left superior parietal gyrus. The distribution of cortical thickness of the IGE group was comparable to the cortical thickness atlas of the normal control. Compared with normal control, the areas with changes of cortical thickness in the IGE group were bilateral superior frontal gyrus, bilateral posterior central gyrus, bilateral anterior central gyri, bilateral lingual gyri, left cuneiform lobe, bilateral entorhinal cortex and temporal pole. The brain areas with laterality of cortical thickness between hemispheres in the IGE group were the tail of anterior cingulate gyrus, cuneiform lobe, inferior parietal gyrus, lateral occipital gyrus, posterior central gyrus, head of anterior cingulate gyrus, and superior marginal gyrus. Compared with normal control, the IGE group has decreased number of brain regions with laterality of cortical thickness. ConclusionThe present study revealed the distribution and laterality of cerebral cortical thickness map in early idiopathic generalized epilepsy, which provides imaging structural basis for brain research in the future.
ObjectiveTo observe and evaluate the functional-structural correlations of quick contrast sensitivity function (qCSF), quantitative color vision, best-corrected visual acuity (BCVA), and peripapillary retinal nerve fiber layer (pRNFL) thickness among different stages of diabetic retinopathy (DR). MethodsA prospective cross-sectional observational study. From November 2023 to August 2025, 135 eyes of 79 patients with type 2 diabetes diagnosed at the Endocrinology Department of Lanzhou University Second Hospital were enrolled. According to the presence and severity of DR, the eyes were divided into no DR (NDR) group (53 patients, 99 eyes), non-proliferative DR (NPDR) group (18 patients, 27 eyes), and proliferative DR (PDR) group (8 patients, 9 eyes). Forty healthy volunteers (80 eyes) were selected as the control group during the same period. All subjects underwent BCVA, qCSF, color vision, and optical coherence tomography (OCT) examinations. BCVA was measured using the international standard visual acuity chart and converted to logarithm of the minimum angle of resolution (logMAR) for statistical analysis. Contrast sensitivity (CS) was measured at spatial frequencies of 3, 6, 12, and 18 cpd using a CS test instrument; the complete qCSF was plotted using Bayesian adaptive psychophysical algorithms, and the area under the log CS function (AULCSF) was exported. The average, superior, nasal, temporal, and inferior pRNFL thicknesses were measured using OCT. Binary logistic regression analysis was performed to identify risk factors affecting different stages of DR progression; receiver operating characteristic (ROC) curve analysis was used to evaluate diagnostic efficacy. ResultsSignificant differences were found among the control, NDR, NPDR, and PDR groups in logMAR BCVA (H=41.077), AULCSF (F=48.893), CS at different spatial frequencies (F=27.528, 35.194, 49.427, 39.689), color vision (H=41.165), and inferior and temporal pRNFL thicknesses (F=6.518, 3.177; P<0.005). No significant differences were observed in superior, nasal, or average pRNFL thicknesses (F=1.828, 1.832, 0.934; P>0.05). Multivariate binary logistic regression analysis showed that AULCSF and CS at 3 and 6 cpd were independent protective factors for DR progression (P<0.05); color vision was an independent protective factor for DR progression (P<0.05); BCVA was an independent risk factor for NPDR and PDR (P<0.05), and pRNFL thickness was an independent protective factor for NPDR and PDR (P<0.05). ROC curve analysis showed that the AUC values of AULCSF and color vision in distinguishing NDR (AUC=0.701?0.850) and NPDR (AUC=0.642?0.838) were higher than those of BCVA (AUC=0.610?0.726) and pRNFL thickness (AUC=0.501?0.560). ConclusionsDuring the progression of DR, qCSF and quantitative color vision can identify neural functional abnormalities earlier than visual acuity decline and structural damage during DR progression.