Pulsatile Proptosis and Sphenoid Wing Dysplasia with no Evidence of Neurofibromatosis Type 1: A Case Report and Review of the Literature
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Case Report
P: 304-308
October 2024

Pulsatile Proptosis and Sphenoid Wing Dysplasia with no Evidence of Neurofibromatosis Type 1: A Case Report and Review of the Literature

Turk J Ophthalmol 2024;54(5):304-308
1. Bismil State Hospital, Clinic of Ophthalmology, Diyarbakır, Türkiye
2. Manisa Celal Bayar University Faculty of Medicine, Department of Ophthalmology, Manisa, Türkiye
No information available.
No information available
Received Date: 29.04.2024
Accepted Date: 13.08.2024
Online Date: 25.10.2024
Publish Date: 25.10.2024
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Abstract

In this study, we aimed to present a rare case of pulsatile proptosis due to sphenoid wing dysplasia without the features of neurofibromatosis type 1 (NF1). A 17-year-old male patient presented with swelling in the superotemporal region of the right eye. Physical examination revealed facial asymmetry with a pulsatile, ill-defined, soft lesion with in the superotemporal region of the right orbit associated with pulsatile proptosis, downward dystopia, and hypotropia. Computer tomography imaging to establish a differential diagnosis showed temporal lobe herniation secondary to sphenoid wing dysplasia. The patient was assessed for NF1, which is most commonly associated with sphenoid wing dysplasia, but no evidence supporting the diagnosis was found. Patients presenting with proptosis should be carefully examined for pulsation and murmurs, and a trauma history should be investigated. Radiological imaging should be used to facilitate the differential diagnosis, and the current clinical condition should be managed with a multidisciplinary approach.

Keywords:
Dystopia, exophthalmos, neurofibromatosis type 1, pulsatile proptosis, sphenoid wing dysplasia

Introduction

Proptosis is defined as one or both eyes bulging forward.1 It can result from different conditions such as infectious, inflammatory, vascular, and neoplastic conditions. Differential diagnosis is critical since it may risk vision and even life.

Encephalocele is one of the causes of proptosis. Encephaloceles are acquired or congenital herniations of meninges and brain parenchyma through a structural cranial bone defect. Traumatic intraorbital encephalocele, though rare, is the most common type and arises from orbital roof fractures caused by blunt trauma. Congenital cases are often linked with sphenoid dysplasia, which is most frequently associated with neurofibromatosis type 1 (NF1).2, 3 Sphenoid dysplasia-related encephaloceles cause ocular symptoms such as dystopia, strabismus, and optic disc pressure. NF1 is a hereditary neurocutaneous disorder. Instances of sphenoid dysplasia occurring without associated NF1 features are rare.4

The aim of this article is to present a rare case of non-NF1-related pulsatile proptosis and review of literature.

Case Report

A 17-year-old male patient presented to the eye clinic with a pulsating lesion in the superotemporal region of the right orbit persisting for 5 years. Macroscopic examination revealed facial asymmetry with a pulsatile, ill-defined, soft lesion in the superotemporal region of the right orbit, and no audible bruit was detected.

The patient exhibited downward dystopia, 10 prism diopters of hypotropia in primary position, and proptosis of the right eye (Figure 1). Eye movements were restricted upward in the right eye but free in other directions. Suppression was observed in the Worth 4-dot test and Schober’s test.

On examination, the patient’s direct and consensual light reflexes were normal, bilateral visual acuity was 20/20 and intraocular pressures were within normal limits. Anterior segment and fundus examination findings were normal (Figure 2). Optical coherence tomography, retinal nerve fiber layer analysis, and visual field examination revealed no pathology.

In contrast-free orbital computer tomography, the right greater wing of the sphenoid bone appeared dysplastic (Figure 3). There was a distinct extra-axial cerebrospinal fluid space in the right temporal fossa, and herniation of the temporal lobe into the orbit markedly displaced the superior oblique muscle. The patient was evaluated for NF1, but there were no findings that satisfied the diagnostic criteria other than sphenoid wing dysplasia. The patient also had no family history of NF1. The family was referred for genetic counseling and no specific feature was identified.

Consultations with the plastic and reconstructive surgery and neurosurgery departments were sought for the patient. Orbital roof reconstruction was recommended by the neurosurgery team. However, the patient declined surgical treatment. He is currently continuing follow-up in the strabismus unit.

Discussion

In this report, we present a rare instance in which a patient presented with pulsatile proptosis and diagnosed with sphenoid wing dysplasia despite having no clinical evidence of NF1.

Proptosis refers to the forward protrusion of one or both eyes from the orbit. This condition arises due to an increase in the contents within the fixed anatomical structure of the bony orbit.5 The reflection of cerebrospinal fluid pulsations into the orbit due to a defect in the orbital roof is termed pulsatile proptosis. Pulsatile proptosis is observed in conditions such as carotid-cavernous fistula, arteriovenous malformation, and encephalocele secondary to sphenoid wing dysplasia or orbital roof fracture.6, 7 A differential diagnosis can be made through physical examination, anamnesis (including trauma history, chemosis, epibulbar venous congestion, and the absence of a bruit), and radiological imaging. Our patient had pulsatile proptosis but no trauma history, chemosis, epibulbar venous congestion, or bruit.

Sphenoid wing dysplasia is characterized by hypoplasia or total absence of the greater or lesser wing of the sphenoid bone. It leads to the expansion of the orbit and middle cranial fossa, causing herniation of the temporal lobe into the orbit.4 Pulsatile proptosis is observed as a result. Although it can be seen as an isolated deformity, it most commonly occurs in association with NF1.

Sphenoid wing dysplasia is one of the major diagnostic criteria for NF1, and is considered a pathognomonic finding for the disease. Between 5% and 12% of NF1 patients have signs of sphenoid wing dysplasia.4 NF1 is an autosomal dominant inherited disorder that arises from a mutation of a gene of chromosome 17q11.2.8 NF1 diagnostic criteria include: >6 cafe-au-lait macules, >2 neurofibromas, freckling in axillary or inguinal regions, optic pathway glioma, >2 iris Lisch nodules or choroid abnormalities, distinctive osseous lesion (such as sphenoid dysplasia, pseudoarthrosis of a long bone), presence of a heterozygous pathogenic NF1 variant. NF1 is characterized by the presence of two or more of the diagnostic criteria.9 In our patient, there were no findings that satisfied the diagnostic criteria other than sphenoid wing dysplasia, and there was no family history of NF1.

Upon reviewing the literature, we found that only 5 patients with sphenoid wing dysplasia did not have evidence of NF1. Among these, one patient was diagnosed with myofibroma, another with craniofacial fibrous dysplasia, and the other three patients had isolated bone defects, similar to our case.4, 10, 11 Table 1 summarizes case reports of sphenoid wing dysplasia in the literature.4, 10-32

In the literature, there are publications reporting orbital roof reconstruction with a titanium mesh and/or bone graft in the treatment, although they are limited in number. Surgeries performed early after diagnosis have been shown to have a more successful visual prognosis.10, 12

In conclusion, history of trauma should not be overlooked in the differential diagnosis of pulsatile lesions around the orbit, and radiological imaging should be utilized to aid diagnosis. Additionally, findings related to NF1, which are closely linked to the patient’s symptoms, should be thoroughly examined, and genetic counseling should be provided to the patient.

Ethics

Informed Consent: Obtained.

Authorship Contributions

Surgical and Medical Practices: S.S.İ, M.E., Concept: S.S.İ, M.E., Design: M.A., H.M., Data Collection or Processing: Y.D.A., Analysis or Interpretation: M.A., H.M., Literature Search: Y.D.A., M.E., Writing: Y.D.A., M.E.

Conflict of Interest: No conflict of interest was declared by the authors.

Financial Disclosure: The authors declared that this study received no financial support.

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