The update of the cognition of fundus diseases is inseparable from the rapid development of fundus multimodal imaging. Especially in recent years, the application of wide and ultra-wide fundus photography, ultra-wide fundus fluorescein angiography, indocyanine green angiography, fundus autofluorescence and optical coherence tomography angiography contribute to observe the peripheral retinopathy more directly. The application of adaptive optics and fluorescence lifetime imaging ophthalmoscopy contribute to have a further understanding of fundus diseases at the cellular and metabolic level. Multimodal imageing reflect the pathological characteristics of the diseases from different angles and levels. At the same time, the digitization and intelligence of fundus images are also developing rapidly. However, there are some problems that the ophthalmologists needs to consider further, such as the correctly understanding the use of multimodal imaging, the application of artificial intelligence, and how to sum up from the images.
ObjectiveTo observe the imaging features of optical coherence tomography (OCT) in peripheral retinal abnormalities of high myopia (HM). MethodsA retrospective series of case studies were conducted. From March 2019 to March 2021, 38 cases (50 eyes) in high myopia with peripheral retinal abnormalities who were confirmed to Henan Eye Hospital were enrolled in the study. There were 21 eyes in 17 males and 29 eyes in 21 females, age was 39.58±15.29 years, diopter was (-9.10±2.44) D. All patients underwent wide-angle fundus photography and OCT examination. According to wide-angle fundus photography and OCT, HM with peripheral retinal abnormalities were classified into white-without-pressure, black-without-pressure, lattice degeneration, peripheral pigmented degeneration, retinoschisis and retinal holes. OCT imaging features of peripheral abnormalities in high myopia was observed. ResultsIn 50 eyes, 65 peripheral retinal abnormalities were observed by OCT. In 6 white-without-pressure, intense hyperreflectivity was shown at the level of the ellipsoid zone that abruptly transitions to relative hyporeflectivity at the dark border of the lesion. In 16 black-without-pressure, reflectivity of the ellipsoid zone decreased. In 10 sites of lattice degeneration, cystoid degeneration, local thinning, retinal tear at the posterior edge and boundary of the lesion was shown, whcih may be accompanied by local vitreous condensation and traction. In 4 peripheral pigmented degeneration, retinal interlayer hyperreflectivity was shown. In 12 retinoschisis, neuroepith-elial separation was connected by vertical bridge or columnar light bands, of which 3 were accompanied with localized retinal detachment and 2 with splitting-related retinal vascular abnormalities. In 17 retinal holes, full layer of neuroepithelium lost, that 12 zones were accompanied with retinal detachment with vitreous adhesion or traction. ConclusionOCT manifestations of peripheral retinal abnormalities in HM varies.
ObjectiveTo identify the causative gene and observe the phenotypic characteristics of a family with isolated microphthalmia-anophthalmia-coloboma (MAC). MethodsA retrospective clinical study. One patient (proband) and 3 family members of a family with MAC visited the Henan Eye Hospital from May 2019 to May 2022 were included in the study. The patient's medical history and family history were inquired in detail, and the best corrected visual acuity (BCVA), slit lamp microscope, fundus photography, optical coherence tomography (OCT), ophthalmological B mode ultrasound and axial length (AL) measurement were performed. The peripheral venous blood of the proband, his parents and brother was collected for Trio whole-exome sequencing and pathogenic gene screening. Fluorescence quantitative Polymerase chain reaction was used to verify the suspicious variations. The clinical features of the patient's ocular and systemic also were observed. ResultsThe proband, male, was 3 years old at the first visit. The horizontal pendular nystagmus was detected in both eyes. Vertical elliptical microcornea and keyhole-shaped iris colobomas were detected in both eyes. The objective refraction at first visit (3 years old) was -4.00 DS/-0.50 DC×105° (OD) and -3.50 DS/-1.25 DC×80° (OS). Refraction and BCVA at 6 years old: -6.50 DS/-2.00 DC×110°→0.05 (OD) and -6.00 DS/-1.50 DC×80°→0.2 (OS). The AL at 4 years and 10 months old was 24.62 mm (OD) and 23.92 mm (OS), respectively. The AL at 5 years and 7 months old was 25.24 mm (OD) and 24.36 mm (OS), respectively. Ultrasonography shows tissue defects in both eyes. Fundus photography showed the inferior choroidal coloboma involving optic disc. OCT showed the optic disc in both eyes was abnormal with colobomas around, and the retinal neurosensory layer in colobomas area was disordered and thin; the retinoschisis was visible in the left eye. The proband's parents and siblings have normal phenotypes. Whole exome sequencing reveals a denovo heterozygous deletion of YAP1 gene: YAP1, chr11: 10280247-102100671, NM_ 001130145, loss 1 (EXON: 6-9). The results of bioinformatics analysis were pathogenic variants. Parents and siblings were of the wild type. ConclusionsLoss of heterozygosity in exons 6-9 of YAP1 gene is the pathogenic variation in this family. It can cause abnormal development of anterior segment, chorioretinal colobomas, deepening of axial myopia, even severe macular colobomas and retinoschisis.