Sphenoid dysplasia in neurofibromatosis type 1: a new technique for repair

Sphenoid dysplasia in patients with neurofibromatosis type 1: Clinical features and imaging findings including cerebrospinal fluid alterations

INTRODUCTION

Neurofibromatosis Type 1 (NF-1) is a genetic disorder that occurs in 1:2500-3000 live births and may involve multiple organs. An uncommon but well-known phenomena is sphenoid dysplasia, which appears in 3-11% of the patients, and may result in significant lowering of the orbit. Understanding the cause and development of this process might predict its course and its treatment.

METHODS

The records of 29 patients with PNF in the head and neck region were searched for location of the PNF and type of surgery. Photographs were studied for facial disturbances, including vertical dystopia, hypertelorism, ptosis, exophthalmos and enophthalmos. MR and CT scans were studied for the presence of PNF, aspect of the sphenoid bone, alteration in the CSF circulation, and other tumour involvement.

RESULTS

Fourteen of 29 patients with PNF in the head and neck presented with sphenoid dysplasia. All 14 patients had their PNF located in the periorbital region. Increased locoregional CSF collections were seen in almost all of these patients. Besides glioma of the optical nerve or hamartomas in the cerebrum and cerebellum, there were no other tumours found. Surgical treatment varies from simple excision to excessive debulking of the PNF, reconstruction of the orbit and even enucleation.

CONCLUSION

Although sphenoid dysplasia is uncommon in NF-1 patients, early recognition is important to prevent facial disfigurement and vision loss. Clinicians should be aware that abnormalities in the periorbital region and especially vertical dystopia might be the first sign of sphenoid dysplasia. Performing a CT or black-bone MR scan would be the next step to confirm or exclude sphenoid dysplasia and abnormal CSF dynamics.

Craniofacial bone alterations in patients with neurofibromatosis type 1

Osseous manifestations of neurofibromatosis 1 (NF-1) occur in a minority of the affected subjects but may be because of significant clinical impairment. Typically, they involve the long bones, commonly the tibia and the fibula, the vertebrae, and the sphenoid wing. The pathogenesis of NF-1 focal osseous lesions and its possible relationships with other osseous NF-1 anomalies leading to short stature are still unknown, though it is likely that they depend on a common mechanism acting in a specific subgroup of NF-1 patients. Indeed, NF-1 gene product, neurofibromin, is expressed in all the cells that participate to bone growth: osteoblasts, osteoclasts, chondrocytes, fibroblasts, and vascular endothelial cells. Absent or low content of neurofibromin may be responsible for the osseous manifestations associated to NF-1. Among the focal NF-1 osseous anomalies, the agenesis of the sphenoid wing is of a particular interest to the neurosurgeon because of its progressive course that can be counteracted only by a surgical intervention. The sphenoid wing agenesis is regarded as a dysplasia, which is a primary bone pathology. However, its clinical progression is related to a variety of causes, commonly the development of an intraorbital plexiform neurofibroma or the extracranial protrusion of temporal lobe parenchyma and its coverings. Thus, the cranial bone defect resulting by the primary bone dysplasia is progressively accentuated by the orbit remodeling caused by the necessity of accommodating the mass effect exerted by the growing tumor or the progression of the herniated intracranial content. The aim of this paper is to review the neurosurgical and craniofacial surgical modalities to prevent the further progression of the disease by "reconstructing" the normal relationship of the orbit and the skull.

Clinical, radiological features and surgical strategies for 23 NF1 patients with intraorbital meningoencephalocele

Intraorbital meningoencephalocele is a rare manifestation of neurofibromatosis type 1 (NF1) caused by secondary changes in sphenoid dysplasia, and it seriously affects patients' vision and facial appearance. We retrospectively analyzed the clinical data of 23 patients with NF1 and intraorbital meningoencephalocele, summarized the surgical strategies employed, and evaluated their clinical efficacy in order to better understand its management in clinical practice, establish a reasonable surgical strategy, and assess prognosis. Before surgery, 22 patients had unilateral pulsatile exophthalmos, 18 patients had significant visual impairment, and 13 patients had ptosis associated with an orbital plexiform neurofibroma (PNF). All 23 patients underwent microsurgical craniotomy with skull base reconstruction using a soft titanium mesh. One month after surgery, the degree of exophthalmos in the 22 (95.65%) patients was significantly reduced compared with before surgery (P < 0.001), and ocular pulsation had subsided. The visual acuity did not decrease significantly (P = 0.298) compared with before surgery. Eleven (47.83%) patients received phase-II eyelid PNF resection and/or oculoplastic surgery, and the degree of ptosis was significantly reduced (P < 0.001). There was no recurrence of pulsatile exophthalmos, displacement of titanium mesh, decreased visual acuity, or increased degree of ptosis noted during follow-up. The best strategy is to reconstruct the skull base under microscopy to relieve pulsating exophthalmos and preserve existing visual function. In cases of ptosis caused by an eyelid PNF, surgical resection should be performed as soon as possible to remove the tumor, and/or oculoplastic surgery should be performed to improve the cosmetic outcome.

Novel Three-Dimensional Morphometry to Reassess Orbit Deformities Associated With Orbital-Periorbital Plexiform Neurofibroma

BACKGROUND

Orbit deformities are usually found in neurofibromatosis type 1 patients, especially those with orbital-periorbital plexiform neurofibroma (OPPN). Unfortunately, current morphometry is complicated and, in some cases, cannot be performed on the deformed orbit due to the destruction of landmarks. Herein, we present a novel 3-dimensional (3D) morphometry for these orbital measurements.

METHODS

We retrospectively reviewed 29 patients with OPPN, and another 29 disseminated cutaneous neurofibroma patients served as controls. All patients had undergone craniofacial computed tomography and 3D reconstruction. New morphometry was used to measure the area of the orbital rim (OR) and superior orbital fissure (SOF).

RESULTS

For the 29 patients with OPPN, the area of the OR at the affected side was 14.18 ± 3.50 cm, while the OR at the nonaffected side was 12.32 ± 1.38 cm. In addition, the area of the SOF at the affected side was 5.37 ± 5.75 cm, while that at the nonaffected side was 1.27 ± 1.03 cm. The OR and SOF at the affected side are more likely to become enlarged compared with those at the nonaffected side. Among the 29 patients with OPPN, the novel morphometry could be performed in 19 cases (65.5%) that cannot be measured by previous morphometry.

CONCLUSION

The novel morphometry is convenient and reproducible, which optimizes its application in pathologic cases, especially those involving deformed orbits.

Neuroimaging findings of extensive sphenoethmoidal dysplasia in NF1

Whereas isolated sphenoid wing dysplasia (SWD) is a well-known clinical feature in neurofibromatosis 1 (NF1), extensive cranial defects involving multiple bones have been rarely reported in this disorder. In this report, we describe the clinical course of a 20-year-old male with NF1 and an extensive cranial bone dysplasia. The large sphenoethmoidal defect was associated with transethmoidal and orbital cephalocele as well as inferolateral herniation of the frontal lobe. In spite of the large defect, the individual did not have any symptoms or complications resulting from the osteopathy. We review the current knowledge of the pathogenesis and management of cranial bone dysplasia in NF1.