Axenfeld-Rieger syndrome/anomaly (ARS) is a rare genetic disorder with an autosomal dominant inheritance pattern, characterized by dysgenesis of the anterior segment of the eye. It may present with systemic anomalies (Axenfeld-Rieger syndrome) or without (Axenfeld anomaly) and may sometimes be associated with multiple congenital malformations. The estimated prevalence ranges from 1 in 50,000 to 1 in 200,000 live births, with an approximate rate of 1 in 100,000, but no epidemiological studies have been conducted to date. A clinical diagnosis of Axenfeld-Rieger syndrome requires the presence of both Axenfeld and Rieger ocular anomalies, accompanied by extraocular systemic features. Ocular manifestations include iris abnormalities, posterior embryotoxon, juvenile-onset glaucoma (a common complication), and dysgenesis of the iridocorneal angle with iridocorneal adhesions. The most commonly observed systemic anomalies include: umbilical defects; craniofacial dysmorphism; dentofacial abnormalities, such as Class III malocclusion due to maxillary hypoplasia, oligodontia, dental malformations (taurodontism, root dysplasia), microdontia, hypodontia, and anodontia; hearing impairment (partial or complete sensorineural hearing loss); and cardiac anomalies, including non-congenital heart disease and mitral valve insufficiency. Additional anomalies may include hypospadias in males, anal stenosis, endocrine disorders (notably growth retardation) secondary to pituitary dysfunction, psychomotor delay, and various neurological malformations such as Dandy-Walker malformation, mega cisterna magna, posterior fossa cysts, cerebellar vermis hypoplasia, ventriculomegaly, aprosencephaly, cerebral atrophy, microcephaly, arteriovenous malformations (AVM), and digital anomalies such as camptodactyly. Diagnosis is typically made in infancy, based on iris anomalies such as corectopia (displacement of the pupil), polycoria (multiple pupils), and iris hypoplasia. Posterior embryotoxon is frequently observed upon slit-lamp examination. Given the clinical variability, a comprehensive pediatric assessment is essential to identify systemic anomalies and distinguish Axenfeld-Rieger syndrome from the isolated Axenfeld anomaly.

Congenital eye malformations like microphthalmia-anophthalmia-coloboma (MAC), anterior segment dysgenesis (ASD), primary congenital glaucoma (PCG) and congenital cataracts (CC) are significant causes of childhood visual impairment. Phenotypic heterogeneity often complicates diagnosis. The goal of this study was to optimize the diagnostic strategy for next-generation sequencing (NGS)-based procedures, thereby aiming to identify genetic causes of congenital eye malformations. Forty patients with congenital eye malformations were included. A primary diagnostic testing (PD) of a limited number of genes was followed by multigene panel (MGP) testing, including 186 eye-related genes, and exome sequencing. Causative variants were identified in 17 patients (43%) and clinically relevant variants of uncertain significance (VUS) in 6 patients (15%). PD had a diagnostic yield (DY) of 15%, MGP of 29% and exome sequencing of 4%, leading to a cumulative DY of 43%. Diagnostic rates were highest in CC (75%), bilateral cases (46%), complex ocular phenotypes (78%), patients with extraocular manifestations (55%) and positive family history (70%). Rare and possible new genotype-phenotype correlations and candidate genes (FAT1, POGZ) could be identified. In total, eight (likely) pathogenic variants in six genes (CYP1B1, ADAMTS18, MAB21L2, NHS, MFRP, CRYBB1) were not yet reported. A stepwise genetic testing approach starting with a broad multigene panel followed by exome sequencing provides higher diagnostic yield than limited phenotype-specific testing. Comprehensive genetic diagnosis is essential for prognosis, treatment and genetic counseling, underscoring the need for routine genetic testing and interdisciplinary collaboration in managing congenital eye malformations.

The crystalline lens is an important structure in the eye that starts to develop as early as the 22nd day of gestation, with further differentiation that continues after the induction. Congenital anomalies of the lens may involve the size, shape, and position of the lens. They may sometimes be associated with anterior segment dysgenesis or persistence of the tunica vasculosa lentis and hyperplastic vitreous and hyaloid system. Manifestations of anomalies of the lens shape are usually seen in early or late childhood however may sometimes be delayed into adulthood based on the level of visual impairment or the presence or absence of any syndromic associations. While lens coloboma has more often been reported in isolation, the more commonly implicated genes include the PAX6 gene, lenticonus in particular anterior is often part of Alport syndrome with extra-ocular manifestations in the kidneys and hearing abnormalities due to mutations in the alpha 5 chain of the Type IV collagen gene. Recognition of these manifestations and obtaining a genetic diagnosis is an important step in the management. The level of visual impairment and amblyopia dictates the outcomes in patients managed either conservatively with optical correction as well as surgically where deemed necessary. This review discusses the various anomalies of the lens shape with its related genetics and the management involved in these conditions.

Aniridia is a panocular disease characterized by iris hypoplasia, accompanied by other ocular manifestations, with a high clinical variability and overlapping with different abnormalities of the anterior and posterior segment. This review focuses on the genetic features of this autosomal dominant pathology, which is caused by the haploinsufficiency of the PAX6 gene. Mutations causing premature stop codons are the most frequent among the wider mutational spectrum of PAX6, with more than 600 different mutations identified so far. Recent advances in next-generation sequencing (NGS) have increased the diagnostic yield in aniridia and contributed to elucidate new etiopathogenic mechanisms leading to PAX6 haploinsufficiency. Here, we also update good practices and recommendations to improve genetic testing and clinical management of aniridia using more cost-effective NGS analysis. Those new approaches also allow studying simultaneously both structural variants and point-mutations in PAX6 as well as other genes for differential diagnosis, simultaneously. Some patients with atypical phenotypes might present mutations in FOXC1 and PITX2, both genes causing a wide spectrum of anterior segment dysgenesis, or in ITPR1, which is responsible for a distinctive form of circumpupillary iris aplasia present in Gillespie syndrome, or other mutations in minor genes. Since aniridia can also associate extraocular anomalies, as it occurs in carriers of PAX6 and WT1 microdeletions leading to WAGR syndrome, genetic studies are crucial to assure a correct diagnosis and clinical management, besides allowing prenatal and preimplantational genetic testing in families.

A 56-year-old man with an ocular history of 20+ cut radial keratotomy (RK) in both eyes and Marfan syndrome presented with blurred vision in both eyes 2 years previously. He was intolerant of contact lenses and was correctable with spectacles for the past 10 years. His presenting photographs and corneal topographies are shown in Figures 1 and 2JOURNAL/jcrs/04.03/02158034-202102000-00022/figure1/v/2021-04-12T204757Z/r/image-tiffJOURNAL/jcrs/04.03/02158034-202102000-00022/figure2/v/2021-04-12T204757Z/r/image-tiff, respectively. His left eye had greater than 270 degrees of zonulopathy and a visually significant cataract. He underwent a planned pars plana lensectomy/vitrectomy and implantation of a scleral-fixated CZ70BD (Alcon Laboratories, Inc.) intraocular lens (IOL). He has enjoyed adequate vision in the left eye and now has a worsening cataract in his right eye. He is a practicing dentist and requested the fastest visual rehabilitation possible. His corrected distance visual acuity was 20/50 with a manifest refraction of +5.00-4.00 × 90 in the right eye and 20/25 with a manifest refraction of +1.75-2.50 × 180 in the left eye. Intraocular pressure (IOP) was measured at 16 mm Hg in both eyes, and extraocular motility, confrontational visual fields, and pupils were normal in both eyes. On slitlamp examination, he had mild ptosis in both eyes, the corneas had 20+ RK with multiple arcuate incisions at the 3- and 9-o'clock positions in both eyes, the anterior chamber (AC) was deep and quiet in both eyes, both irides had mild iridodonesis, the right lens had a 2 to 3+ nuclear sclerotic cataract with 6 clock hours of superotemporal zonulopathy that was only evident with dilation (Figure 3JOURNAL/jcrs/04.03/02158034-202102000-00022/figure3/v/2021-04-12T204757Z/r/image-tiff) and no phacodonesis. The left lens had a well-positioned CZ70BD IOL fixated at 6 and 12 o'clock without extrusion or exposure of the Gore-Tex suture. The posterior segment examination was unremarkable. What counseling would you provide for this patient in preparation for surgery? How would you plan the IOL calculations? What intraoperative techniques would you use to achieve the safest outcomes given his comorbidities?