Ophthalmic Aspects Of Orbital Injury

Screening Criteria for Detecting Severe Ocular Injuries in the Setting of Orbital Fractures

PURPOSE

Define incidence of severe ocular trauma in orbital fracture patients and determine if ocular signs and symptoms are useful predictors of severe ocular injuries.

METHODS

Retrospective chart review was performed on all patients with orbital fractures between April 1, 2013, and December 31, 2014. Patients were included if they had radiographic evidence of acute fracture of at least one orbital wall and were evaluated by the Ophthalmology service. Demographics, concurrent injury data, and symptoms and signs of ocular trauma were collected. Concurrent ocular injuries were grouped by severity. Predictive signs or symptoms for severe ocular trauma were identified by stepwise logistic regression analysis. The threshold point for predictive signs and symptoms was detected by a receiver operating characteristic (ROC).

RESULTS

Five-hundred-twelve patients were included. The most common mechanisms of injury were assault (39%), fall (25%), and motor vehicle accident (21%). The incidence of any concurrent ocular trauma was 75% (383/512), with 14% (70/512) being severe. Four signs and symptoms were predictors of severity: blurred vision (P < 0.0001), pain with eye movements (P < 0.0001), visual acuity worse than 20/40 in the ipsilateral eye (P < 0.001), and restricted motility (P < 0.001). The presence of 2 or more of these signs or symptoms was predictive of severe ocular trauma with high sensitivity (91%) and specificity (86%).

CONCLUSIONS

In cooperative patients with acute orbital wall fractures, the presence of 2 or more signs or symptoms is predictive of severe ocular trauma and necessitates the need for urgent ophthalmic consultation.Severe ocular injury associated with orbital wall fracture is more likely in patients with 2 or more ophthalmic signs or symptoms.

Is specialized ophthalmologic evaluation necessary after orbital fractures? A prospective 64-case study

INTRODUCTION AND OBJECTIVE

The objective of this study was to determine whether there is a need for ophthalmologists to perform a specialized assessment after the occurrence of orbital fractures.

MATERIALS AND METHODS

Sixty-three patients (64 orbits) diagnosed with orbital fractures were evaluated preoperatively (up to 24 h after the trauma) and in 90-day postoperative period.

RESULTS

Eight injuries required either specialized clinical or surgical ophthalmologic intervention. Of these patients, four required emergency eye surgery: two patients with corneal lacerations had lesions larger than 2 mm. Two patients had extensive ocular lesions after multiple traumas with uveal exposure and without light perception. Another four patients (iridodialysis associated with lens subluxation, anterior uveitis, direct lesion on the optic nerve, and chorioretinitis sclopetaria) received conservative management.

CONCLUSION

This study concluded that a specialized ophthalmologic examination as soon as possible is important, particularly in cases in which the signs and symptoms of severity are associated. The non-ophthalmologist surgeon must have the basic medical knowledge required to provide basic primary ophthalmologic care and to discern the severity of the injury.

Traumatic Orbital Apex Syndrome: An Uncommon Sequela of Facial Trauma

Orbital apex syndrome (OAS) is a rare ocular complication following craniomaxillofacial trauma. This traumatic syndrome is a combination of features seen in both superior orbital fissure syndrome and traumatic orbital neuropathy due to nerve impingement. Due in part to the rarity of this disorder, the optimal treatment of traumatic OAS has yet to be determined. We present a case in which traumatic OAS was caused by direct compression due to a displaced fracture segment from the superior orbit. The patient was successfully treated with a combination of emergent decompression and urgent reconstruction suggesting that this may be an effective strategy in OAS resulting from direct nerve compression as a result of craniomaxillofacial fracture.

Longitudinal relationship between traumatic brain injury and the risk of incident optic neuropathy: A 10-year follow-up nationally representative Taiwan survey

Accumulating evidences had shown that traumatic brain injury was associated with visual impairment or vision loss. However, there were a limited number of empirical studies regarding the longitudinal relationship between traumatic brain injury and incident optic neuropathy. We studied a cohort from the Taiwanese National Health Insurance data comprising 553918 participants with traumatic brain injury and optic neuropathy-free in the case group and 1107836 individuals without traumatic brain injury in the control group from 1st January 2000. After the index date until the end of 2010, Cox proportional hazards analysis was used to compare the risk of incident optic neuropathy. During the follow-up period, case group was more likely to develop incident optic neuropathy (0.24%) than the control group (0.11%). Multivariate Cox regression analysis demonstrated that the case group had a 3-fold increased risk of optic neuropathy (HR = 3.017, 95% CI = 2.767-3.289, p < 0.001). After stratification by demographic information, traumatic brain injury remained a significant factor for incident optic neuropathy. Our study provided evidence of the increased risk of incident optic neuropathy after traumatic brain injury during a 10-year follow-up period. Patients with traumatic brain injury required periodic and thorough eye examinations for incident optic neuropathy to prevent potentially irreversible vision loss.

Successful delayed treatment of the traumatic orbital apex syndrome by nasal endoscopic decompression surgery

To report a patient with traumatic orbital apex syndrome, who fully recovered visual and extraocular function following surgery. A 34-year-old male presented with visual and extraocular function disorders in his right eye following traffic accident, who was referred to our hospital 5 weeks after accident. The patient underwent endoscopic optic nerve and orbital apex decompression with topical and systemic application of nerve growth factor and steroids after a failed trial of mega-dose intravenous corticosteroids. Visual acuity improved to 20/20 at 3 weeks after surgery, and the right eye globe moved in most directions at 1 year, which remained stable at 3 years. Surgical decompression should be considered even when symptoms have been present for over a month.

Successful Treatment of the Traumatic Orbital Apex Syndrome due to Direct Bone Compression

Orbital apex syndrome is an uncommon but severe ocular complication of craniomaxillofacial fracture. The optimal treatment strategy for this very rare traumatic syndrome has not been well established. We present a case in which traumatic orbital apex syndrome was caused by direct compression from the displaced fracture segments. Visual and extraocular function both improved quickly after emergency decompression surgery. This case suggests that managing the direct type of traumatic orbital apex syndrome with craniomaxillofacial fracture with a combination of urgent reduction of impinging bone and decompression of affected nerves is an effective strategy.

Posttraumatic superior ophthalmic vein thrombosis in a 2 years old

Superior ophthalmic vein thrombosis (SOVT) usually results from inflammatory, infectious, or malignant causes. This case describes a 2-year-old boy with severe prolapsing chemosis and proptosis due to thrombosis of the right superior ophthalmic vein resulting from midfacial and right orbital fractures 1 week after the initial trauma. Magnetic resonance imaging and internal carotid artery angiogram are essential in the diagnosis of SOVT. The literature on issues surrounding this case was reviewed with emphasis on the diagnostic evaluation, differential diagnoses, and management of posttraumatic SOVT.

Optic nerve monitoring

Orbital and anterior skull base surgery is generally performed close to the prechiasmatic visual pathway, and clear strategies for detecting and handling visual pathway damage are essential. To overcome the common problem of a missed clinical examination because of an uncooperative or unresponsive patient, flash visual evoked potentials and electroretinograms should be used. These electrophysiologic examination techniques can provide evidence of intact, pathologic, or absent conductivity of the visual pathway when clinical assessment is not feasible. Visual evoked potentials and electroretinograms are thus essential diagnostic procedures not only for primary diagnosis but also for intraoperative evaluation. A decision for or against treatment of a visual pathway injury has to be made as fast as possible due to the enormous importance of the time elapsed with such injuries; this can be achieved additionally using multislice spiral computed tomography. The first-line conservative treatment of choice for such injuries is megadose methylprednisolone therapy. Surgery is used to decompress the orbital compartment by exposure of the intracanalicular part of the optic nerve in the case of optic canal compression. Modern craniomaxillofacial surgery requires detailed consideration of the diagnosis and treatment of traumatic visual pathway damage with the ultimate goal of preserving visual acuity.

Concomitant cranial and ocular combat injuries during Operation Iraqi Freedom

BACKGROUND

Concomitant cranial and ocular injuries were frequently seen in combat casualties during Operation Iraqi Freedom. The incidence of these injuries is reported along with an interventional case series.

METHODS

A retrospective review was conducted of all surgical patients treated by U.S. Army neurosurgeons and ophthalmologists in Iraq from December 2005 to April 2006.

RESULTS

Out of 104 patients with cranial trauma and 158 patients with ocular trauma, 34 had both cranial and ocular injuries (32.7 and 21.5% of patients with cranial and ocular injuries, respectively). Neurosurgical procedures included exploratory craniotomy, decompressive craniectomy, and frontal sinus surgery. Ophthalmologic surgical procedures included globe exploration, open globe repair, primary enucleation, orbital fracture repair, lateral canthotomy and cantholysis, and repair of lid and periocular lacerations. Patients with cranial trauma had a higher incidence of orbital fracture, orbital compartment syndrome, and multiple ocular injuries compared with patients without cranial trauma (odds ratio 6.4, 3.9, and 3.3, respectively).

CONCLUSION

A strong association exists between cranial and ocular trauma in combat casualties treated during Operation Iraqi Freedom. Combat health support personnel should maintain a high level of suspicion for one of these injuries when the other is present. Co-locating neurosurgeons and ophthalmologists in support of combat operations facilitates the optimal treatment of patients with these combined injuries.

[Posttraumatic amaurosis after complex frontobasal fracture. Differential diagnosis and therapy]

BACKGROUND

Whether surgical nerve decompression is indicated for the treatment of posttraumatic reduced vision with optic nerve compression in the bony canal has been a subject of controversy for decades. On balance, the recent literature suggests that this procedure is indeed indicated, as a supplement to high-dosed cortisone therapy. The risk of surgery-related side effects is usually rated low in the literature.

CASE REPORT

We report on a woman patient in whom craniocerebral trauma involved a fracture of the left optic canal with unilateral loss of vision. In the decompression operation, intraoperative symptoms gave rise to the suspicion of an arteriovenous fistula, which had not been revealed by computer tomography and which was seen as sufficient grounds for discontinuing the procedure. In addition to a carotid artery-sinus cavernosus fistula (CCF Barrow type A), subsequent angiography revealed a dissected aneurysm at the branching of the occluded ophthalmic artery.

DISCUSSION AND CONCLUSIONS

In decisions on whether surgical relief of pressure on the optic canal is indicated after trauma-related visual loss, the possibility of secondary lesions near the tip of the orbita and the optic canal must be taken into account. These are not always revealed by computer tomography. The indications should be critically weighed up in each individual case, with additional imaging examinations, such as MR-angiography, CT-angiography, or conventional angiography, performed as needed. The options and indications for imaging are discussed. The procedure can by no means be rated as "minimally invasive", as is postulated by some authors.

[Single and temporally displaced second nerve lesions in an animal model and their clinical significance]

BACKGROUND

Surgical optic decompression after trauma has been discussed controversially. The surgical trauma is supposed to produce an additional nerve lesion with the danger of complete loss of vision. Alternatively, conservative high dose cortisone therapy has been recommended.

METHODS

The functional and morphological consequences of a lesion after calibrated optic compression in one or two sessions were examined in an animal model using 29 Wistar rats.

RESULTS

Depending on the duration and intensity of the lesion, we observed a linear decline in the number of neurons in the RGC (retinal ganglion cell) layer as well as an increasing reactivity to GFAP (glial fibrillary acidic protein) as an indication of central gliosis of astrocytes; however, this was independent on whether optic compression was performed in one or two sessions.

CONCLUSIONS

To reduce secondary damage to the visual nerve and the central visual system that might increase with a persisting lesion, the indication for surgical relief of an eye affected by afference should be considered liberally, especially in view of the low morbidity of rhinosurgical intervention.

Prevalence of significant intraocular sequelae in blunt orbital trauma

The purpose of this study was to describe the prevalence of significant intraocular sequelae (SIOS) and its correlation with the severity of blunt orbital trauma. Four hundred ten consecutive patients presenting to the ED who had sustained blunt orbital trauma were studied. The severity of orbital trauma was graded and SIOS was determined by the presence of an intraocular injury as listed in Table 2. The presence of SIOS was noted in 14 (41.2%) mild, 22 (59.5%) moderate, and 20 (29.4%) severe orbital trauma. In the severe group, the presence of SIOS was detected in 8 (23.5%) blowout fractures and in 12 (35.3%) non-blowout fractures. In view of the high rates of ocular complications among mild and moderate orbital injuries, such patients should have prompt ophthalmic follow up. The relatively low prevalence of SIOS in patients with severe orbital trauma could suggest a protective mechanism in this type of injury.

Ocular and periocular injuries from orbital fractures

BACKGROUND

Orbital fractures are associated with ocular and periocular injuries. The role of the ophthalmologist in the evaluation and management of facial trauma, including orbital fractures, has not been clearly defined. The purpose of this study is to identify and characterize ocular and periocular injuries associated with orbital fractures to define the role of the ophthalmologist in the management of facial trauma.

STUDY DESIGN

Retrospective case review.

RESULTS

Three hundred sixty-five patients with orbital fractures who were evaluated by an ophthalmologist as part of their initial trauma evaluation were studied. The majority of the patients with orbital fractures (74%) did not have associated ocular or periocular injuries. Twenty-three of 104 (22%) ocular injuries in 23 of 95 (24%) patients required immediate intervention by an ophthalmologist.

CONCLUSIONS

Facial trauma and orbital fractures are associated with significant ocular and periocular injuries, the minority of which require immediate evaluation and treatment by an ophthalmologist. These results differ from those previously reported.

Orbital fractures in children

PURPOSE

To describe the demographics, etiologic factors, clinical presentations, and outcomes of orbital fractures in children.

METHODS

This was a retrospective case series of 96 consecutive patients under 18 years of age with orbital fractures presenting to the Massachusetts Eye and Ear Infirmary, including both hospitalized and nonhospitalized patients.

RESULTS

Orbital fractures in children were most frequently the result of sports, assault, or motor vehicle accident. The majority of patients did not require hospitalization and were treated as outpatients. The medial wall and floor of the orbit were the most frequent locations of fracture. Approximately half of the patients in this series required surgery, most often for entrapment. There were no cases of persistent diplopia in patients in whom surgery was performed or was not indicated. Associated ocular injuries were observed in half of the patients.

CONCLUSIONS

In this series of hospitalized and nonhospitalized patients, orbital fractures in children had a location pattern similar to that most frequently observed in adult patients (floor and medial wall). Orbital fractures in children frequently require surgery. The high prevalence of ocular injury in children with orbital fractures emphasizes the need for a comprehensive ophthalmic evaluation.

Eye injuries in patients with major trauma

BACKGROUND

A study was performed to determine the type and frequency of ocular injuries in patients with major trauma.

METHODS

All patients with ocular and adnexal injuries (n = 178) among 1,119 patients admitted with major trauma (Injury Severity Score >15) to the Royal Prince Alfred Hospital from July 1990 to December 1997 were analyzed.

RESULTS

Sixteen percent of the major trauma cohort had ocular or orbital trauma. Fifty-five percent of patients with injuries involving the face had ocular or orbital injuries. A range of ocular injuries was seen. Analysis of the major trauma cohort showed that motor vehicle drivers, orbital and base of skull fractures, eyelid lacerations, and superficial eye injuries were strongly associated with vision-threatening injury.

CONCLUSION

Patients with major trauma and facial injuries have a high risk of vision-threatening injury. Patients with orbital fractures, base of skull fracture, eyelid lacerations, and superficial eye injuries should be assessed by an ophthalmologist as part of the early management of their trauma to determine whether an ocular injury is present.

Endoscopic optic nerve decompression: the Graz experience

Recommendations for management of traumatic injuries to the optic nerve in the literature include expectant management, medical therapy, surgical treatment, and medical therapy combined with surgical decompression. Traditional surgical approaches to optic nerve decompression (OND) are a neurosurgical or craniotomy approach, extranasal transethmoidal approach, transorbital approach, transantral approach, and intranasal microscopic approach. Recent advances in instrumentation and surgical techniques have made an endoscopic approach to OND possible. Since 1991 endonasal endoscopic decompression of the optic nerve has been the surgical approach of choice in patients requiring OND in the authors' hospital. The endoscopic method offers many advantages over the traditional approaches. Decreased morbidity, preservation of olfaction, rapid recovery time, more acceptable cosmetic results with no external scars, no risk of injury to the developing teeth in children, and less operative stress in a patient who may have multisystem trauma are only some of the benefits associated with the endoscopic OND. The authors' technique of endonasal endoscopic approach to OND, medical management, and indications for surgery and the results in 22 patients undergoing this procedure are discussed.

Assessment of ocular trauma associated with head and neck injuries

We reviewed the real and potential ocular problems in all head and neck injuries at a tertiary care and regional trauma center from April of 1994 to March of 1995. Through a retrospective study, 127 charts were reviewed, specifically looking at the mechanism of injury, types of injury, whether there was any ocular trauma noted in the chart, and whether there was a consultation to the ophthalmology department. Forty-one of these patients were seen by an ophthalmologist as the initial consultant for ocular and orbital injuries recognized by the emergency staff. In the 86 remaining patients, signs of potential ocular injury were recorded in the chart in 62 (72%) of these patients, yet an ophthalmology consultation was requested for only 23 of them (37%). This survey reveals the lack of awareness in a regional trauma center of certain ocular and periocular signs that may be indicative of more serious ocular injuries. It is the purpose of this article to highlight these concerns to the various health professionals involved with head and neck trauma patients in the hope that the patients will, in the end, benefit from a more thorough and complete assessment of the potential ocular and periocular injuries.

Frontal basilar trauma: classification and treatment

We report our experience with 14 consecutive cases of frontal basilar trauma occurring in children and adolescents aged 18 months to 18 years (mean 9.5 years). Brain parenchymal injury resulting in functional deficit occurred in 5 patients (36 percent), 2 patients suffered bilateral blindness, and 1 suffered unilateral loss of vision. A classification system and treatment algorithm based on the clinical fracture pattern seen by computed tomography are introduced. Type I, central, is confined to the upper nasoethmoidal complex, central frontal bone, and medial third of the superior orbital rims. Type II, unilateral, involves the entire supraorbital rim and the upper lateral orbital wall, extending into the squamosa of the temporal bone and ipsilateral frontal bone. Type III, bilateral, involves fractures of the upper nasal ethmoidal complex, bilateral supraorbital and upper lateral orbital wall fractures, and bilateral frontal bone fractures. This classification was utilized to plan elective orbital and cranial osteotomies, similar to those used for frontal orbital advancement at the time of acute fracture repair. Frontal orbital osteotomies were used to access the anterior cranial fossa, orbital apices, and nasofrontal ducts and to obtain an intact bony template for side-table reassembly of the fracture fragments. There was no significant operative morbidity, one late cerebrospinal fluid leak, and no infections. Reoperation was necessary in four patients (29 percent) for aesthetic indications.

Surgical techniques in orbital roof fractures: early treatment and results

Repositioning of fractured fragments, stabilization with miniplates and reconstruction using autologous bone are commonly used techniques in the treatment of fractures of the orbital roof. Between 1988 and 1993, 101 patients were operated upon transcranially in the Department of Neurosurgery of the Landesnervenklinik Salzburg, for fractures of the orbital roof. The method, the timing and the results of treatments are presented. It can be demonstrated that even in severely injured patients the results were good in 79.2% (80 patients).

Associated injuries in facial fractures: review of 839 patients

Patients with facial trauma may have associated injuries requiring immediate or specialised attention. This paper reports the incidence and nature of significant associated neurosurgical, ocular, spinal, torso and extremity injuries in facial fracture patients treated by the Department of Plastic and Reconstructive Surgery from June 1989 to June 1992. Of 839 patients treated during the period, 95 patients (11.3%) sustained significant concomitant injuries outside the facial skeleton. There were 45 (5.4%) patients with associated neurosurgical injuries, 33 (3.9%) with ocular injuries, 8 (0.9%) with spinal injuries, 16 (1.9%) with injuries of the torso, and 62 (7.4%) with injuries of the extremities. The spectrum of the injuries is presented. Most neurosurgical injuries are a result of focal impact and the intervention required is related mainly to local fracture management and the repair of dural tears. The risk of significant ocular injury is highest when the fracture involves the orbit. Injuries of the spine, torso (chest, abdomen, pelvis), and limbs were seen mainly in road trauma patients.