Journal of Neuro-Ophthalmology, June 2001, Volume 21, Issue 2

Neuro-Ophthalmic Manifestations of Head Trauma

OBJECTIVE: To describe the neuro-ophthalmic findings in a group of patients with head trauma. MATERIALS AND METHODS: A retrospective chart review of all patients given a diagnosis code of head trauma in the neuroophthalmology unit at Emory University between 1991 and 1999. RESULTS: A total of 326 consecutive patients were reviewed (203 [63%] men and 123 [37.0%] women). Age ranged from 2 to 86 years, with a mean of 30 years. Motor vehicle accident was the most common cause of head trauma, occurring in 195 (59.8%) patients. An abnormal neuro-ophthalmic examination was noted in 185 of 326 patients (56.7%). Loss of consciousness was not associated with any outcome, but the presence of a neuroimaging abnormality, particularly intracranial hemorrhage, was significantly associated with specific neuroophthalmic deficits. CONCLUSIONS: Head trauma causes a number of neuroophthalmic manifestations. The afferent and efferent pathways are vulnerable to traumatic injury, although the efferent system is more commonly affected. Loss of consciousness may not be a reliable predictor of specific neuro-ophthalmic outcomes, but neuroimaging abnormalities may.

Journal of'A] euro- Ophthalmology 21( 2): 112- 117, 2001. © 2001 Lippincott Williams & Wilkins, Inc., Philadelphia Neuro- Ophthalmic Manifestations of Head Trauma Gregory P. Van Stavern, MD, Valerie Biousse, MD, Michael J. Lynn, MS, Deborah J. Simon, MD, and Nancy J. Newman, MD Objective: To describe the neuro- ophthalmic findings in a group of patients with head trauma. Materials and Methods: A retrospective chart review of all patients given a diagnosis code of head trauma in the neuro-ophthalmology unit at Emory University between 1991 and 1999. Results: A total of 326 consecutive patients were reviewed ( 203 [ 63%] men and 123 [ 37.0%] women). Age ranged from 2 to 86 years, with a mean of 30 years. Motor vehicle accident was the most common cause of head trauma, occurring in 195 ( 59.8%) patients. An abnormal neuro- ophthalmic examination was noted in 185 of 326 patients ( 56.7%). Loss of conscious­ness was not associated with any outcome, but the presence of a neuroimaging abnormality, particularly intracranial hemor­rhage, was significantly associated with specific neuro-ophthalmic deficits. Conclusions: Head trauma causes a number of neuro-ophthalmic manifestations. The afferent and efferent pathways are vulnerable to traumatic injury, although the efferent system is more commonly affected. Loss of consciousness may not be a reliable predictor of specific neuro- ophthalmic outcomes, but neuroimaging abnormalities may. Key Words: Neuro- ophthalmology- Head trauma- Diplopia- Visual loss. Neuro- ophthalmic deficits may commonly follow head trauma ( 1- 13). The afferent and efferent visual sys­tems are susceptible to injury from a variety of mecha­nisms. These patients can be a diagnostic and therapeutic challenge, in large part secondary to the frequently vague nature of their visual complaints and their coexistent neurologic deficits. Although the association between head trauma and neuro- ophthalmic deficits is clear, there is as yet no definite consensus regarding the relative Manuscript received January 22, 2001; accepted April 24, 2001. Supported in part by a departmental grant ( Ophthalmology) from Research to Prevent Blindness, Inc., New York, New York, and a National Institute of Health CORE Grant P30- EY0 6360. Dr. Newman is a recipient of a Research to Prevent Blindness Lew R. Wasserman Merit Award. From the Departments of Ophthalmology ( GPVS, VB, DJS, NJN), Neurology ( VB, NJN), Neurological Surgery ( NJN), and Biostatistics ( MJL), Emory University School of Medicine, Atlanta, Georgia. Address correspondence and reprint requests to Nancy J. Newman, MD, Neuro- Ophthalmology Unit, Emory Eye Center, 1365- B Clifton Rd., Atlanta, GA 30322; e- mail: ophtnjn@ emory. edu. frequency of specific neuro- ophthalmic deficits, both af­ferent and efferent, that may accompany head trauma. In this review of all head trauma patients seen in one aca­demic neuro- ophthalmology unit during a 9- year period, we determined the relative frequency of various neuro-ophthalmic deficits incurred after head trauma and their relationship to the nature of the head injury. METHODS A retrospective chart review of all consecutive pa­tients seen between 1991 and 1999 in the neuro-ophthalmology unit at Emory University and given a diagnosis code of head trauma was performed. All pa­tients underwent a standardized neuro- ophthalmic his­tory and examination. Visual fields were tested using a Goldmann perimeter or a Humphrey automated perim­eter. Length of time from injury to examination, type of trauma sustained, extent of injuries ( including neuroim­aging, if available), and loss of consciousness were noted for each patient. For patients diagnosed with optic neu­ropathy, a distinction among mechanisms of injury ( in­direct, direct, papilledema) was made on the basis of visual acuity, visual field, and optic disc appearance. Cause of injury, sex, loss of consciousness, and the pres­ence of a neuroimaging abnormality were all evaluated as potential predictors of outcome, with outcome being defined as the presence of a neuro- ophthalmic deficit or a combination of neuro- ophthalmic deficits. All predic­tors and outcomes were categorical in nature. The asso­ciation between the predictors and outcomes was evalu­ated using a chi- squared test. In addition to univariate analyses, multivariate analyses were done using logistic regression; however, these analyses did not reveal any important associations beyond those discovered with the univariate analyses. RESULTS Three hundred and twenty- six patients were reviewed. They included 203 ( 62.3%) men and 123 ( 37.7%) women. Age ranged from 2 to 86 years, with a me­dian of 30 years. Most patients were admitted in the rehabilitation service at the time of their evaluation in our unit. The neuro- ophthalmic examination was part of a systematic evaluation obtained before their 112 NEURO- OPHTHALMIC MANIFESTATIONS OF HEAD TRAUMA 113 discharge from rehabilitation and included both symp­tomatic and asymptomatic patients. Only patients cooperative enough to perform a complete neuro- oph-thalmic examination, including formal visual field test­ing, were evaluated. The various causes of head trauma in this series are listed in Table 1. Motor vehicle accident ( MVA) was the most common cause of head trauma, occurring in 195 patients ( 59.8%). Of these, 166 were passengers or driv­ers, and the remaining patients were pedestrians struck by a moving vehicle. Falls, motorcycle accidents, and projectile injuries were less common, accounting for 31.2% of patients in total. Time from injury to examina­tion ranged from 3 days to 12 years, with a mean of 73.5 days, ± 291.8 days. One hundred and thirty patients ( 39.9%) experienced a loss of consciousness lasting from several minutes to a prolonged coma of several months' duration ( Table 2) at the time of injury. Clinically rel­evant neuroimaging findings at the time of injury were noted in 153 patients ( 46.9%) ( Table 2). We considered the following abnormalities as clinically relevant: intra­cranial hemorrhage ( ICH) ( epidural, subdural, or intra-parenchymal), basal skull fracture, and radiographically evident contusion. ICH was the most common finding, occurring in 95 patients ( 62.1%). In 70 patients ( 34.3%), neuroimaging was normal. An abnormal neuro- ophthalmic examination was found in 185 patients ( 56.7%) ( Table 3). Of the patients with abnormal neuro- ophthalmic examinations, 93 ( 50.2%) had afferent pathway deficits, and 109 patients ( 58.9%) had efferent pathway deficits. Among afferent deficits, retrochiasmal visual field defects were the most common, occurring in 47 patients ( 50.5%). Optic neu­ropathies occurred in 40 patients ( 43%) and included indirect optic nerve injury ( 27.9%) and optic nerve injury secondary to previously elevated intracranial pressure with papilledema ( 15%). Chiasmal injury and Terson syndrome were uncommon, each occurring in three patients ( 3.2%). Among efferent deficits, ocular motor cranial nerve abnormalities predominated, with 84 pa­tients ( 77.1%) having at least one ocular motor nerve palsy. Among these patients, 19 ( 22.6%) had multiple ocular motor nerve palsies. Trochlear nerve palsy was the most common deficit ( 51.2%), followed closely by oculomotor nerve palsy ( 46.4%). Twenty- four patients TABLE 1. Cause of head trauma TABLE 2. Associated findings Cause of injury Motor vehicle accident Passenger/ driver Pedestrian Fall Motorcycle accident Struck by projectile Gunshot wound to head Airplane crash Blunt injury Snowmobile accident Train crash Unknown Number (%) 195/ 326 ( 59.8) 166/ 195( 85.1) 29/ 195 ( 14.9) 58/ 326 ( 17.8) 22/ 326 ( 6.7) 22/ 326 ( 6.7) 4/ 326( 1.2) 4/ 326( 1.2) 3/ 326 (< 1) 1/ 326 (< 1) 1/ 326 (< 1) 7/ 326( 2.1) Loss of consciousness Absent Present Neuroimaging findings Significant neuroimaging abnormality Intracranial hemorrhage Skull fracture Contusion 196/ 326( 60.1%) 130/ 326 ( 39.9%) 153/ 323 ( 47.3%) 95/ 153 ( 62.1%) 37/ 153 ( 24.2%) 44/ 153 ( 28.7%) had bilateral ocular motor palsies, with bilateral trochlear nerve palsy occurring most frequently. Supranuclear ocular motor deficits were less common and included convergence insufficiency ( 16 patients, 14.7%), supra­nuclear gaze palsy ( two patients), and dorsal mid­brain syndrome ( two patients). Horner syndrome was uncommon, occurring in only three patients ( 2.7%). Central vestibular nystagmus was documented in only two patients. Cause of injury was not significantly associated with any outcome. Female sex was significantly associated with trochlear nerve palsy ( x2 = 3.80, P = 0.05) but not with any other outcome. Male sex was not significantly associated with any outcome. The presence of any neu­roimaging abnormality was significantly associated with indirect optic nerve injury ( x2 = 3.68, P = 0.05) and oculomotor nerve palsy ( x2 = 3.79, P = 0.05). The presence of an ICH was significantly associated with oculomotor nerve palsy ( x2 = 8.86, P = 0.003) and bilateral trochlear nerve palsy ( Fisher test, two- tail, P = 0.02). The presence of a basilar skull fracture was significantly associated with trochlear nerve palsy ( Fisher test, two- tail, P = 0.05). The presence of a ra­diographically evident contusion was not significantly associated with any outcome. TABLE 3. Frequency of neuro- ophthalmic deficits Deficits Any neuro- ophthalmic deficit Afferent pathway deficit Terson syndrome Optic neuropathy Indirect injury Secondary Bilateral Chiasmal injury Retrochiasmal visual field defects Efferent pathway deficit Ocular motor nerve palsy Cranial nerve III palsy Bilateral Cranial nerve IV palsy Bilateral Cranial nerve VI palsy Bilateral Multiple ocular motor nerve palsies Convergence insufficiency Supranuclear gaze palsy Dorsal midbrain syndrome Horner syndrome Central vestibular nystagmus Number (%) 185/ 326( 56.7) 93/ 185( 50.2) 3/ 93 ( 3.2) 40/ 93 ( 43.0) 26/ 93 ( 27.9) 14/ 93 ( 15.0) 13/ 40 ( 32.5) 3/ 93 ( 3.2) 47/ 93 ( 50.5) 109/ 185( 58.9) 84/ 109( 77.1) 39/ 84 ( 46.4) 3/ 39 ( 7.7) 43/ 84( 51.2) 14/ 43 ( 32.5) 21/ 84 ( 25.0) 7/ 21 ( 33.3) 19/ 84 ( 22.6) 16/ 109 ( 14.7) 2/ 109 ( 1.8) 2/ 109 ( 1.8) 3/ 109 ( 2.7) 2/ 109 ( 1.8) J Neuro- Ophthalmol, Vol. 21, No. 2, 2001 TABLE 4. Neuro- ophthalmic findings in head trauma- literature review Author Jacobi et al. ( 7) Keane ( 8) Sabales et al. ( 9) Kowal ( 10) Lepore ( 11) Mariaket al. ( 12) Moster et al. ( 13) Van Stavern et al. Author Year 1986 1989 1991 1992 1995 1997 1998 2000 Optic M/ W M = 471 W = 270 M = 125 W = 56 M = 28 W = 32 M = 7 W = 5 M = 203 W = 123 neuropathy ( indirect injury) Number of patients 741 96 181 161 60 12 46 326 Retro chiasmal VF defects Patient population Children S/ P head trauma Motorcycle/ moped acci­dent victims with N. O. abnormalities Pts referred with visual complaints after head trauma Head trauma patients referred from rehab found to have N. O. deficits Pts with diplopia and het-erodeviation after head trauma 12 head trauma pts dead within 72 hrs of injury Head trauma patients in rehabilitation Head trauma patients Cranial nerve III palsy Age range Mean ( yrs) 20.4% 1- 2 mo, 32.1% 2- 6 yrs 47.5% > 6 yrs 15- 52, 25.5 5- 74, 31 13- 38, 28.6 17- 66, 33.9 ( men) 8- 67, 30.7 ( women) 28- 85 Not provided 2- 86, 30 Cranial nerve IV palsy Time from injury to exam Not provided Not provided 3 wk-> 3 yrs, 8.5 Not provided Average 25.1 mo. 0- 72 hours Not provided 3 days-> 12 years. 73.5 days Cranial nerve VI palsy mo Most common cause of head injury MVA 338/ 741, 45.6% Motorcycle accident 94/ 96, 97.9% MVA 103/ 181,57% MVA MVA 53/ 60, 88.3% MVA 11/ 12,91.7% Not provided MVA 195/ 326, 59.8% Most common afferent deficit Not provided Traumatic optic neuropathy 16/ 96, 16.7% Functional visual field defect Optic neuropathy 26.1% Not assessed Not assessed Optic neuropathy 13.0% Retrochiasmal VF defect 47/ 93, 50.5% Convergence Statistically significant insufficiency correlations found Most common efferent deficit Cranial nerve III palsy ( 38/ 741,5.1%) Cranial nerve III palsy ( 27/ 96,28.1%) Cranial nerve IV palsy ( 24/ 60, 40%) Cranial nerve IV palsy ( 38/ 161, 24%) Cranial nerve IV palsy ( 20/ 60, 33.3%) Cranial nerve III palsy ( 6/ 12, 50%) Cranial nerve III palsy ( 15/ 46, 33%) Cranial nerve IV palsy ( 43/ 84,51.2%) Statistically significant correlations not found Jacobi et al. ( 7) Keane ( 8) Sabales et al. ( 9) Kowa ( 10) Lepore ( 11) Mariak et al. Moster et al. ( 13) Van Stavern et al. 21/ 741, 2.8% 16/ 96, 16.7% 4/ 16( 25%) bilat 14/ 181, 7.7% 42/ 161, 26.1% 24/ 42 ( 57.1%) bilat Not assessed 0/ 12 6/ 46 ( 13.0%) 26/ 93, 27.9% 18/ 741, 2.6% 4/ 96, 4.2% 20/ 64, 31.2% ( Pts with VF defects) Not assessed Not assessed Not assessed 7/ 46 ( 15.0%) 47/ 93, 50.5% 38/ 741, 15.9% 27/ 96, 28.1% 2/ 27( 7.4%) bilat 20/ 60, 33% 10/ 20 ( 50%) bilat 16/ 161, 10% 2/ 16 ( 12.5%) bilat 17/ 60, 28.3% 2/ 17 ( 11.8%) bilat 6/ 12, 50% 2/ 6 ( 33%) bilat 15/ 46, 33% 39/ 84, 46.4% 3/ 39 ( 7.7%) bilat 4/ 741, 0.6% 19/ 96, 19.8% 5/ 19( 26.3%) bilat 24/ 60, 40% 19/ 24( 79%) bilat 38/ 161, 24% 8/ 38 ( 21%) bilat 20/ 60, 33.3% 6/ 20 ( 30%) bilat 2/ 12, 17% 13/ 46, 28% 43/ 84, 51.2% 4/ 741, 0.9% 25/ 96, 26.0% 5/ 25( 20%) bilat 16/ 60, 27% 8/ 16( 50%) bilat Not provided Not provided 7/ 181, 3.9% 16/ 161, 10% 23/ 161, 14% 1/ 16 ( 6.2%) bilat 7/ 60, 11.7% 7/ 60, 11.7% 3/ 7 ( 42.8%) bilat 2/ 12, 17% Not assessed 9/ 46, 20% 21/ 84, 25.0% 0.46 16/ 109 ( 14.7%) 14/ 43 ( 32.5%) bilat 7/ 21 ( 33.3%) bilat LOC and VF defect LOC and ocular motor palsy Lack of seatbelt and neuro-ophthalmic abnormality Bilat cranial nerve palsies and cort­icospinal tract damage Avulsion of cranial nerve III and basilar skull fracture Neuroimaging abnormal and indirect optic nerve injury, Cranial nerve III palsy ICH and Cranial nerve III palsy, bilat Cranial nerve IV palsy Basilar skull fracture and Cranial nerve VI palsy Ocular motor nerve palsies & ICH, skull fracture, LOC LOC and any neuro-ophthalmic deficit Contusion and any neuro-ophthalmic deficit > 2 Abnl, abnormality; bilat, bilateral; LOC, loss of consciousness; M, men; MVA, motor vehicle accident; N. O., neuro- ophthalmic; Pts, patients; VF, visual field; W, women. NEURO- OPHTHALMIC MANIFESTATIONS OF HEAD TRAUMA 115 DISCUSSION Head trauma is common. In one survey, the incidence of traumatic head injury requiring hospitalization ranged from 109 to 322 per 100,000 people ( 4). The advent of motorized transportation has increased the clinician's ex­posure to head trauma and its complications. Indeed, MVA is the most frequent cause of head injury in the United States. Young men are most frequently affected ( 4,5), as noted in our study ( Table 4). The relationship between head trauma and neuro-ophthalmic injury has been recognized for some time. Indeed, Hutchinson's studies ( 6) in the 1880s docu­mented a clear relation between head trauma and ocular motility deficits. Surprisingly, there have been relatively few large studies assessing the frequency of specific neuro- ophthalmic deficits seen in association with head trauma ( Table 4). The relative frequency of neuro-ophthalmic deficits is highly variable, and this finding may be explained by differences in the patient popula­tion. However, a few studies reviewed patient popula­tions that were homogeneous in age or clinical charac­teristics; for example, Lepore ( 11) studied motility deficits in patients with known heterodeviations and sub­jective diplopia, thereby perhaps missing patients with only afferent, or afferent and efferent, deficits ( Table 4). Furthermore, in some reviews, certain aspects of the neuro- ophthalmic examination ( such as visual field de­fects) were not addressed. Finally, referral bias may play a role in that patients with only mild neuro- ophthalmic deficits or patients whose neurologic status renders them unable to communicate symptoms may not be referred to the neuro- ophthalmologist. It is very likely that we had such a bias, because not all patients with head trauma were evaluated by us; however, we think that our series is most likely representative of the population with se­vere head trauma. Indeed, almost all our patients were referred from the rehabilitation service, where they were admitted for at least 3 to 4 weeks. This neuro- ophthalmic evaluation was part of a routine evaluation performed before their discharge. Only 56.7% of our patients had an abnormal neuro- ophthalmic examination, suggesting that not only symptomatic patients were referred to us. Closed head injury may damage the optic nerve through a variety of mechanisms, including direct injury from a penetrating wound, indirect injury from concus-sive forces transmitted to the nerve, and disc edema from elevated intracranial pressure ( 2). Indirect optic nerve injury is the most common form of traumatic optic neu­ropathy ( TON) ( 2). The incidence of indirect TON ranges from 2.8 to 26.1% ( Table 4). This large range is most likely related to several factors: 1) TON may be difficult to diagnose in the acutely ill, head- injured pa­tient; 2) distinction between the mechanisms of TON ( direct vs. indirect injury, papilledema) requires adequate historical information and accurate and reliable visual field testing, both of which may be difficult to obtain in neurologically impaired patients; and 3) attention is often directed to efferent pathway deficits because these are more amenable to management. Our study showed a higher incidence of indirect TON than many previous studies, suggesting that TON may be underdiagnosed in the head trauma population. Although the management of indirect TON is controversial, patients with indirect TON seen within the first few hours may benefit from treatment with high- dose corticosteroids ( 1,2,14,15). Therefore, indirect TON should always be suspected in patients with severe head trauma. Traumatic chiasmal injury is uncommon and is often associated with frontal head trauma. Typical features in­clude bitemporal hemianopia ( often complete), cerebro­spinal fluid rhinorrhea, and diabetes insipidus. The mechanism of injury is unclear but may involve physical disruption of the chiasm or diffuse axonal injury ( 1). Only three of our patients had chiasmal injury, attesting to the rarity of the phenomenon. Because a relatively large proportion of neural tissue is dedicated to the primary retrochiasmal visual system, it makes intuitive sense that diffuse brain injuries should frequently damage these pathways; however, the relative frequency of traumatic retrochiasmal visual field defects is difficult to ascertain in the literature, because many studies do not specifically address this issue. This obser­vation may again reflect the difficulty in assessing visual fields in neurologically impaired patients, particularly using the automated perimetry. We were able to obtain a reliable visual field test in all our patients, using the Humphrey automated perimeter or Goldmann visual field test performed by a skilled technician in patients with cognitive disorders. More than half of our patients with afferent pathway deficits had retrochiasmal visual field defects, a much higher incidence than that reported in comparable studies. Because these visual field defects may have substantial financial and legal implications ( re­garding driving and employment), accurate visual field testing is critical in head- injured patients. Because accu­rate testing is often not possible in the immediate period after the injury and may not be possible for weeks or even months after the injury, it is important that patients be monitored at regular intervals until an accurate assess­ment can be made. The ocular motor nerves may be damaged at any point in their course from brainstem nucleus to extraocular muscle. The most likely mechanism of injury is axonal shearing resulting from differential acceleration of the skull and brain ( 2,3); however, focal lesions such as hemorrhage at the brainstem exit site ( 16) or avulsion of the nerve root ( 12) may also occur. In some cases, minor head trauma may unmask a pre- existing, otherwise un­recognized mass lesion ( 17). The trochlear nerve is the smallest and longest of the ocular motor nerves and is closely associated with the rigid tentorium, making it susceptible to traumatic injury. It is particularly susceptible to injury as it emerges from the dorsal surface of the brainstem; damage at this loca­tion often causes bilateral injury ( 1). The fourth nerve has been variably reported to be the most and least fre­quently involved ocular motor nerve after head trauma J Neuro- Ophthalmol, Vol. 21, No. 2, 2001 116 G. P. VAN STAVERN ET AL. ( Table 4) ( 1,18,19). Indeed, the diagnosis of trochlear nerve palsy may be difficult, particularly in uncoopera­tive, neurologically impaired patients. In our study, trochlear nerve palsy was the most common ocular motor nerve palsy, occurring in 51.2% of patients with ocular motor nerve palsies. A high proportion ( 32.5%) was bi­lateral, reinforcing the concept that a bilateral trochlear nerve palsy should be suspected in any patient with what appears to be a unilateral injury. Further, a certain pro­portion of posttraumatic trochlear nerve injury may rep­resent decompensation of a pre- existing congenital trochlear nerve palsy. Indeed, in one study, congenital trochlear nerve palsy was the most common cause in children ( 20). Determination of vertical fusion amplitude and examination of old photographs usually help to dis­tinguish congenital from acquired trochlear nerve palsy. Trauma is the second or third leading cause of oculo­motor nerve palsies in adults and the leading cause of acquired third nerve palsies in children ( 1,20,21). The site of injury is often difficult to localize unless other neurologic findings are present. Among our patients with ocular motor nerve palsies, oculomotor nerve injury was the second most common deficit, found in 46.4% of patients with ocular motor nerve palsies; only 7.7% were bilateral. Acquired abducens nerve palsy is the most commonly recognized ocular motor nerve palsy in any age group ( 1,19,21). This finding probably relates more to the ease of diagnosis rather than frequency of occurrence, be­cause acquired abducens nerve palsies are relatively rare in certain age groups, such as young adults ( 22). The abducens nerve has a long course and is susceptible to injury at any point; it is particularly vulnerable to the effects of elevated intracranial pressure. The abducens nerve was the least commonly affected ocular motor nerve in the previous studies ( Table 4), and this finding is in agreement with our series. Convergence insufficiency is a supranuclear motility disorder characterized by a remote near point of conver­gence, poor convergence amplitudes, and an exodevia-tion at near. Convergence insufficiency may be seen in a variety of clinical settings, but its association with head trauma has been well documented ( 3). Similar to previ­ous studies ( Table 4), convergence insufficiency was the most common supranuclear ocular motility deficit among our patients, seen in 14.7% of patients with ef­ferent deficits. Other supranuclear motility disorders ( such as supranuclear gaze palsies, skew deviation, and dorsal midbrain syndrome) are less commonly reported in association with head trauma. This finding may again reflect difficulty in diagnosing these deficits in uncoop­erative patients. In addition, some of these disorders may be relatively asymptomatic and therefore not prompt re­ferral to a neuro- ophthalmologist. Furthermore, these su­pranuclear disorders, particularly convergence insuffi­ciency, may be masked by coexistent ocular motor deficits ( 11). Knowing if specific neuro- ophthalmic deficits were more common after certain types of head injury might allow the clinician to have a higher index of suspicion for certain abnormalities when examining these patients. Loss of consciousness ( LOC) implies head injury severe enough to cause brainstem reticular formation or bi-hemispheric dysfunction through diffuse axonal injury, parenchymal contusion, or ICH. Several studies have found a correlation between LOC and particular neuro-ophthalmic deficits ( 9,23); however, LOC was not sig­nificantly associated with any outcome in our study. This finding would suggest that although LOC may be an indirect indicator of the severity of head injury, it may not be a reliable predictor of neuro- ophthalmic out­comes. The presence of a neuroimaging abnormality ( skull fracture, contusion, or ICH) would suggest a greater severity of head trauma and perhaps a more fre­quent occurrence of certain neuro- ophthalmic deficits. In our study, the presence of an ICH was significantly, and strongly, correlated to unilateral oculomotor palsy. The presence of a skull fracture was significantly, but weakly, correlated to unilateral abducens nerve palsy. The specific location and extent of the neuro­imaging abnormalities were not available in all patients; however, the information available would suggest that the presence of a neuroimaging abnormality, espe­cially ICH, should increase the index of suspicion for an ocular motor nerve injury, particularly of the oculo­motor nerve. 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