Acute post-traumatic encephalocele in a child: CT and MRI features

In a patient with acute orbital trauma, visual acuity and extraocular muscle motility are the two most important ophthalmologic functions to be evaluated emergently. The assessment of these capabilities may sometimes be difficult due to the severity of the head injury, the extent of periorbital soft tissue edema, inadequate cooperation in alert patients, and a reduced level of consciousness in obtunded individuals. Consequently, computed tomography (CT) has come to play a major role in the orbital examination of acute trauma patients. In this study, in conjunction with clinical evaluation, we have sought to utilize CT to determine the various prevalences of the causes of decreased visual acuity and extraocular muscle motility resulting from orbital trauma. We retrospectively reviewed the records of all patients admitted to our emergency facility who, having suffered head trauma, underwent a CT study for diagnosis. CT examinations of the head using a multidetector scanner were performed from the base of the skull to the vertex at 5-mm intervals. Orbital CT was obtained when a routine CT of the head showed periorbital soft tissue edema and/or facial bone fractures. The orbital CT examination was performed using axial 1-mm and coronal 3-mm slices. Coronal reformation images were prepared if the patient was unable to tolerate the prone position for direct coronal imaging. The imaging findings were correlated with ophthalmologic observations. The orbit floor was the most common and the orbital roof the least common site of fracture of the bony coverings of the eye. Twenty-three patients suffered decreased visual acuity. In order of declining frequency, the causes of reduced vision consequent to trauma were retrobulbar hemorrhage, optic nerve thickening presumably secondary to edema, intraorbital emphysema, optic nerve impingement, detached retina and ruptured globe. Five patients had visual impairment without demonstratable radiographic abnormalities. The most common finding associated with diminished extraocular muscle motility was muscle impingement by fracture fragments, followed in decreasing frequency by thickened muscle due to edema or contusion, intraconal emphysema, muscle entrapment, and retrobulbar fat herniation. Six patients with decreased extraocular muscle activity had no abnormalities demonstrated on CT images. The overwhelming majority of patients with decreased visual acuity or reduced extraocular muscle motility consequent to trauma had abnormalities demonstrated by orbital CT. Hence, CT examinations should play a major role in the evaluation of the intraorbital contents in patients with orbital trauma.

The orbit may be injured directly or indirectly. Blunt and penetrating trauma occurs with equal frequency. Soft tissue swelling often obscures direct clinical evaluation of the globe, limits ocular motion, and may limit clinical assessment of vision. Plain film radiographs of the orbits and sinuses are rarely used for diagnosis in orbital trauma. Computed tomography is considered the imaging modality of choice in this circumstance, as it is deemed to be the most accurate method in detecting fractures. The protocol is based on obtaining thin-section axial scans and multiplanar reformatted images, both are useful tools to guide treatment. Orbital fractures are not considered an ophthalmologic emergency unless there is visual impairment or globe injury. Surgical repair is indicated for patients who have persistent diplopia or cosmetic concerns (enophthalmos) and generaly is not performed until swelling subsides 7-10 days after injury. Copyright © 2012 Elsevier Inc. All rights reserved.

Orbital roof fractures after blunt injury are rare. Traumatic encephaloceles in the orbital cavity are even rarer, with only 15 cases published to date. The clinical, radiological, and surgical findings of 6 cases of traumatic encephalocele treated at our institution from June 1998 to January 2000 are presented. They are also compared with previously published series. In contrast to other published cases, 5 out of 6 patients in our series were adults. The most common cause of trauma was road traffic accident. Ecchymosis and preoperative exophthalmos/proptosis were frequent. In all of our patients a coronal CT scan (3 mm increments with bone windows) was obtained. It demonstrated the extension of the orbital roof fractures and a possible encephalocele in 4 cases. Associated frontal brain contusions were seen in 5 cases. An MRI was performed in 3 patients (and only in 2 previously published cases); it showed the extension of the brain herniation into the orbital cavity. Surgical treatment via a fronto-basal approach with evacuation of the contused herniated brain tissue and orbital roof reconstruction was performed. The outcome at 6 months was good recovery in five patients with one patient still in a persistent vegetative state. Postoperatively the ocular disturbances improved in 5 cases. A review of the other published cases confirmed recovery of normal ocular function in the vast majority of the cases. Whenever orbital roof fractures associated with frontal contusions are identified in an acute brain injured patient, an orbital encephalocele should be suspected. In our opinion MRI is the investigation of choice in such patients. If the encephalocele is confirmed, a surgical approach via the subfrontal route is indicated with resection of herniated contused brain tissue, dural closure, and orbital roof reconstruction. Good results in regard to the orbital symptoms (mainly exophthalmos) can be expected.