Objective To observe the features of the images of optical coherence tomograpy (OCT) in patients with traumatic macular hole (TMH), and detect the clinical significance of OCT. Methods Consecutive 74 patients (74 eyes) diagnosed with TMH by examinations of visual acuity, slit lamp, and direct or indirect ophthalmoscopy underwent optical coherence tomography (OCT). The analysis software of OCT was used to make the quantitative measurements of TMH. And the TMH were classified according to the morphological characteristics of the images of OCT. 50deg;color fundus photography was performed on the patients after OCT. The relationship of TMH with the average visual acuity, disease duration, average neuroepithelial thickness on the margin of hole, and the base diameter and the apex diameter of macular hole were retrospectively analyzed. Results The characterisctics of the images of 74 cases (74 eyes) of TMH were classified into 5 types: macular holes with symmetric edema of the neurosensory retina at the margin in 27 eyes (36.5%), macular holes with asymmetric edema of the neurosensory retina at the margin in 12 eyes (16.2%), macular hole with full-thickness defect of neurosensory retina without edema or detachment at the margin in 14 eyes (18.9%), macular hole with localized detachment of the neurosensory retina at the margin without edema in 17 eyes (23.0%), and macular hole with thinning neurosensory retina in 4 eyes ( 5.4%). There was no significant difference of visual acuity among different types of TMH (F=1.574, P=0.191). The visual acuity was positively related with the marginal retinal thickness (r=0.342, P=0.003), but not related to age, diameter of macular hole or the disease duration (r value was from -0.022 to -0.134,P value was from 0.863 to 0.261). The disease duration of Type IV TMH was shorter than that of other TMH types. In the patients with the disease duration over 90 days, Type I TMH was predominant. The average retinal thicknesses at the margin of the hole showed significant differences among different TMH types (F=13.921, P=0.000). Conclusions TMH could be divided into 5 types according to the characteristics of images of OCT; the clinical characteristics of different types of TMH varies.
Objective To verify the significance of the morphological changes of the macula and its relationship to visual function by using optical coherence tomography (OCT) after scleral buckling procdure. Methods The macula of retinae of 68 patients (70 eyes) with reattached retinae after scleral buckling operation for retinal detachment were examined by OCT to scan the macula through fovea vertically and horizontally. Results Among the 70 eyes, 22 eyes revealed normal macula with thickness of neurosensory retina meant (146.47±20.59)μm. In the other 48 eyes (68.60%) with abnormal macula, 19 eyes showed extensive subretinal interspace, 9 eyes showed local subretinal interspace, 8 eyes showed macula edema, 4 eyes showed thin macula, 4 eyes showed subretinal proliferation and 4 eye showed epiretinal membrane over macula. In the normal macular structure group under the OCT, the visual acuity (VA) of the operated eyes was more than 0.3 in 6 eyes 2 weeks after operation and in 14 eyes 3 mons after operation. In the macula edema group, the VA was more than 0.3 in 1 eye 2 weeks after opoeration and 2 eyes 3 mons after operation. In the subretinal interspace group, the VA was more than 0.3 in 5 eyes 2 weeks after operation and in 23 eyes 3 mons after operation. The proportions of the numbers of operated eyes with the VA more than 0.3 after 3 mons of the operation in macular normal group subretinal interspace group and other macular disease group were significantly different (χ2=18.91, P<0.01). Conclusion OCT can precisely detect the structural changes of macula after retinal reattachment and assess visual function after surgery of retinal detachment. (Chin J Ocul Fundus Dis, 2002, 18: 266-268)
Objective To observe the spectral domain optical coherence tomography (SD-OCT) features of acute Vogt-Koyanagi-Harada (VKH) eyes before and after treatment.Methods Twenty-eight patients (56 eyes) with acute VKH diagnosed by slitlamp microscopy, B mode ultrasound and fundus fluorescein angiography (FFA) were enrolled in this study. All the patients were treated with steroid after diagnosis. SD-OCT was performed in all the patients before and after treatment. The follow-up was ranged from 12 to 32 weeks with a mean of (21.30plusmn;8.53) weeks. The foveal retinal detachment height, inner and outer segments (IS/OS) of photoreceptors, and the changes in retinal structure within the vascular arcades before and after treatment were comparatively analyzed. Results OCT examination results showed that before treatment, all eyes had retinal neural epithelial detachment. The average neural epithelial detachment height in the fovea was (635.44plusmn;340.04) mu;m. Forty-three eyes (76.8%) had different types of subretinal exudates; 41 eyes (73.2%) had b granular reflection in the subretinal space. Twenty-two eyes (39.3%) had paraforveal outer nuclear layer (ONL) thickening with finger-like protrusions attached with membrane-like structure. Thirty-three eyes (58.9%) had wavy lines of the retinal pigment epithelium (RPE). After the treatment, these exudates dissolved within one week and RPE line became straight. The retina reattached after (2.33plusmn;0.82) weeks. In most patients external limiting membrane and IS/OS became intact after (5.01plusmn;6.71) weeks and (11.40plusmn;7.89) weeks respectively. However, at the end of follow-up, 46 eyes (82.1%) still had focal areas of IS/OS defect and 11 eyes (19.6%) had focal ONL thinning. Conclusions Before the treatment, the OCT features of acute VKH are serous retinal detachment at fovea, different types of subretinal exudates and wavy RPE. After the treatment, the OCT features of acute VKH are exudates dissolving, straight RPE line and early recovery of external limiting membrane.
ObjectiveTo evaluate Micron Ⅳ retinal imaging system in three mouse models of retinal diseases. MethodsMouse models of oxygen induced retinopathy (OIR) model (OIR group), N-methyl-N nitrosourea (MNU) model (MNU group) and N-methyl-D-aspartate (NMDA) model (NMDA group) were induced in 24 healthy male C57BL/6J mice. Fundus photograph, fundus fluorescein angiography (FFA) and optical coherence tomography (OCT) and electroretinogram (ERG) were used to evaluate these mice. All the imaging examinations were performed by Micron Ⅳ retinal imaging system. ResultsOIR mice showed tortuous and dilated retinal vessels in fundus photograph, neovascularization plexus and vascular leakage in FFA, and epiretinal fibrovascular tissue and tortuous expansion vascular vessels in OCT. MNU mice showed wax yellow optic disk without retinal pigmentary changes, slight thinning of retinal blood vessels in FFA, and normal structure and thickness in OCT. The a-wave amplitudes of the maximum mixed response decreased significantly, and were (15.38±4.36) μV and (13.78±5.52) μV at 2 or 3 days of modeling, respectively. NMDA mice showed a pale retina with vasospasm. ERG revealed that there was no obvious change in latency of a- and b-wave, but significantly decreased amplitude of b-wave at 12 hours and 24 hours after modeling with (72.28±7.18) μV and (65.35±9.18) μV, respectively. ConclusionMicron Ⅳ retinal imaging system is a real-time, non-invasive tool to study the retinal structure and function in animal models of retinal diseases.
Objective To observe the performance of hyperspectral non-mydriatic fundus camera prototype and its application on ocular fundus diseases. Methods The narrow band filters was inserted into the optical path of the Canon non-mydriatic retinal camera (CR-DGi). The image was converted to digital data by charge-coupled device (CCD), and then analyzed by hyperspectral data software. Twelve volunteers were examined by hyperspectral nonmydriatic fundus camera prototype to confirm the characteristic wavelength spectrums of ocular fundus diseases and the repeatability of prototype. Fifty-nine patients with ocular fundus diseases who underwent fluorescein angiography were also examined by hyperspectral non-mydriatic fundus camera prototype, to compared the images of prototype and fluorescein angiography. Results Each of the highest power of the light at the focus point and the power per unit were safe. 536, 547, 579 nm were selected as the specific retinal imaging spectrums and 608 nm as the specific choroidal imaging spectrum. The intra-observer and inter-observer reproducibility was equal or greater than 0.85. The correlation between hyperspectral non-mydriatic fundus camera prototype and fluorescein angiography in choroidal neovascularization patients were 0.782 and 0.833. Conclusions The hyperspectral nonmydriatic fundus camera prototype is safe and reliable. It shows pathological retinal and choroidal structures with specific spectrums. There are good prospects for the application in clinical diagnosis, especially for macular diseases.
Objective To investigate the characteristics and analyze the differences of choroidal neovascularization (CNV) image between exudative age-related macular degeneration (AMD) and central exudative chorioretinopathy (CEC) using optical coherence tomography (OCT). Methods Twenty-three eyes of 22 patients with exudative AMD and 20 eyes of 19 patients with CEC, which were diagnosed as CNV using fundus fluorescein angiograph (FFA) or indocyanine green angiograph ( ICGA), were examined by OCT.The size of CNV and the thickness of retinal neurosen sory layer in foveola were measured by OCT software. Results On OCT image, CNV had three main types of morphological features including simple CNV, CNV with serous retinal neurosensory layer detachment and CNV with choroidoretinal exudation. Exudative AMD mainly showed CNV with choroidoretinal exudation (56.52%) and CEC showed simple CNV (90.0%). The thickness of retinal neurosensory layer in foveola of patients with exudative AMD was thicker than that of patients with CEC and the size of CNV of patients with exudative AMD was larger than that of patients with CEC. Negative correlation was found between retinal neurosensory layer thickness in foveola and vision in both groups (gamma;=-0.521, P=0.001). Conclusions There were certain discrepancy in morphology and area in volved of CNV between exudative AMD and CEC on OCT images. (Chin J Ocul Fundus Dis, 2001,17:299-302)
Objective To investigate the neuropathogenesis of Adieprime;s pupil. Methods The neuroelectrophysiological and neuroimaging data of 42 patients with Adie's pupil (lightnear dissociation and segmental palsy of iris sphincter) were retrospectively analyzed. There were 37 patients with unilateral pupil dilation and 5 patients with bilateral pupil dilation. Cranial magnetic resonance imaging (MRI, 23 patients), Cranial CT scanning (1 patient), nerve conduction velocity (NCV, 14 patients), limb electromyogram (EMG, 5 patients), both lower extremities EMG (9 patients), visual evoked potential (VEP, 18 patients), somatosensory evoked potential (SEP, 11 patients) and electroencephalograms (EEG,5 patients) were performed on some of those patients. Results Central nervous system midline anatomic variations or minor lesions were found in 13/23 cases of MRI/CT imaging. Slowed sensory NCV and multiple sensorymotor peripheral nerve damages were evident in 6/14 cases of the NCV/EMG assay. 5/18 patients showed prolonged latency of VEP P100. 2/11 cases showed peripheral nerve damage in SEP recording, and 1/5 cases showed abnormal EEG. Conclusion Peripheral nerve damage may be an important pathogenesis of Adie's pupil, while the central nervous system damage is also involved in its pathogenesis.