Vol.29 No.3 Brief Reports PDF

Retinal Dysplasia*

Mary Ellen A. Sy, MD, Romeo B. Espiritu, MD

Retinal dysplasia consists of an abnormal proliferation of developing retina, producing tubular structures with a rosette-like appearance in cross section.
1 It appears to be associated with a single pathogenetic basis: the separation of the retina during a critical stage of its differentiation from its underlying pigment epithelium.
2 We are presenting the first reported case of retinal dysplasia seen at the UP-PGH. A three-month-old female, the second of twins, born preterm at 7 months (1,400 grams) via Caesarean section, presented with bilateral leukocoria at 2 months of age. Supplemental oxygen was given for 7 days. Her development was at par with other infants her age. The patient’s twin sister had retinopathy of prematurity in both eyes (OU). Ophthalmologic examination revealed negative dazzle in OU. The right cornea measured 8 mm x 8 mm while the left cornea measured 10 mm x 10 mm. Pupils were 3 mm, slowly reactive to light with no afferent pupillary defect. Full range of ocular movements were present in OU. Intraocular pressure (IOP) was less than 4 mm Hg in the right eye (OD) and 7 in the left eye (OS). The anterior chambers in OU were shallow with posterior synechiae. A whitish mass was noted in OU with retinal vessels and hemorrhages. Gonioscopy revealed primarily open angles in OU with peripheral anterior synechiae interspersed inferiorly in OS.
The rest of the organ systems were normal. Cranial computerized tomography (CT) showed no intracranial lesions.
Ocular ultrasonography showed a right eyeball measuring 1.6 cm in anteroposterior diameter. The anterior half of the vitreous showed granular density with high narrow spikes and a midline irregular membranous density indicating detached retina. Behind the membrane was an irregularly shaped mass with spikes 50 to 70% of the anteriorly located densities. The choroid was markedly thickened (Figure 1). The left eyeball was 1.8 cm in length with findings of retinal detachment and thickened choroid. CT showed a small right globe with calcifications in the posterior globe and enlarged optic nerve, and a larger left globe with irregular thickening and increased attenuation of the inferoposterior aspect accompanied by calcifications. Differential diagnoses for leukocoria in infancy include retinopathy of prematurity (ROP), persistent hyperplastic primary vitreous (PHPV), Coats’ disease, and retinoblastoma. ROP is a proliferative retinopathy seen in premature infants weighing less than 1,500 g at birth. The younger the gestational age and the lower the birth weight, the more severe is the case. Administration of supplemental oxygen to the newborn has been implicated as a cause. It is typically a bilateral disease that affects the vitreous and peripheral retina. Even though the patient was born preterm with low birth weight, the presence of an intraocular mass and calcification ruled out this condition. PHPV is a congenital, nonhereditary malformation of the eye that is usually unilateral and not associated with systemic defects. Severe cases may present with microphthalmic eyes with shallowing of the anterior chamber and retinal detachment. The bilateral involvement in this patient and the presence of calcifications make this condition unlikely. In less severe PHPV, a membranous band extending from the posterior lens capsule to the optic disc may be present. Coats’ disease is an idiopathic condition characterized by telangiectatic and aneurysmal retinal vessels with intraretinal and subretinal exudates. It is unilateral in 80% or more of cases, 3 affecting more males (3:1 ratio). Gradual progression with increasing exudation occurs over time. Massive exudative retinal detachment can occur with cholesterol cr ystals producing characteristic echograms that were not seen in this patient. Retinoblastoma is a neuroblastic tumor that is the most common primary intraocular malignancy of childhood. The most common initial sign is leukocoria. Exophytic tumors are usually yellow-white and occur in the subretinal space with subretinal fluid accumulation and exudative retinal detachment. Calcification is a common finding in areas of necrosis of tumor cells producing echograms of extremely high reflectivity on A-scan and very bright signals on B-scan.
4 Retinoblastoma was considered in this patient because of the early presentation of bilateral leukocoria and findings on ultrasonography confirmed by CT.
The right eye was enucleated. Dissection of the globe showed a white retrolental mass occupying the anterior one half of the vitreous cavity. Microscopically, a completely dysplastic detached retina was totally separated from the choroid by eosinophilic, serous subretinal fluid and hemorrhage. There were numerous macrophages ingesting the red blood cells and cholesterol clefts in the subretinal fluid denoting an old vitreous hemorrhage. Focal retinal dysplasia includes extensive glial formation, cellular proliferation and rosette-like formation (Figure 2). The optic nerve was unremarkable.
The pathogenesis of retinal dysplasia include the following:
• resulting from hyperplastic extension of the retina into “abnormal” sites away from its pigment epithelium,
• secondary to detachment of the retina from the pigment epithelium,
• occurring in an otherwise normal location over areas devoid of pigment epithelium, and
• in situ dysplastic process with no evidence that the dysplastic retina has ever been separated from its underlying epithelium.
5 The underlying feature of each of these processes is the absence of a presumed normal histogenetic control by the pigment epithelium on the developing retina. 5 Dysplastic changes appear to be intermediate between a receptor that has developed normally and one that has followed uncontrolled, neoplastic growth. Muller fibers contribute to dysplastic rosette formation but not retinoblastoma rosette formation. Retinal dysplasia may also be associated with congenital anomalies (13%), 6 or with chromosomal abnormalities 7 like Trisomy 13, or systemic findings such as Norrie’s disease (x-linked recessive). 7 Retinal dysplasia should be considered as a differential diagnosis in patients presenting with leukocoria. The ultrasonographic and tomographic findings are helpful in the diagnosis of suspected retinal dysplasia. A thorough physical examination is needed to rule out systemic abnormalities associated with the disease. Early screening will be of help in genetic counseling of the parents.

References
1. Torczynski E, Abramson DH, Grossniklaus HE, et al. Ophthalmic pathology and intraocular tumors. In: Basic Clinical and Science Course, 1995-1996 ed. San Francisco: American Academy of Ophthalmology 1995; section 4: 95.
2. Silverstein AM. Retinal dysplasia and rosettes induced by experimental intrauterine trauma. Am J Ophthalmol 1974; 77: 51-58.
3. Haller JA. Coats’ disease. In: Ryan SJ, Schachat AP, eds. Retina, 3rd ed. St. Louis: Mosby Inc., 2001; chap 82: 1441-1448.
4. Byrne SF and Green RL. Ultrasound of the Eye and Orbit. St. Louis: Mosby Yearbook Inc., 1992; 196-204.
5. Silverstein AM, Osburn BI, Prendergast RA. The pathogenesis of retinal dysplasia. Am J Ophthalmol 1971; 72: 13-21.
6. Fulton AB, Craft JL, Howard RO, Albert DM. Human retinal dysplasia. Am J Ophthalmol 1978; 85: 690-698.
7. Godel V, Romano A, Stein R, et al. Primary retinal dysplasia transmitted as X-chromosome-linked recessive disorder. Am J Ophthalmol 1978; 86: 221-227.