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Show Journal of Neuro- Ophthalmology 14( 4): 234- 249, 2994. © 1994 Raven Press, Ltd., New York Part Two Annual Review in Neuro- Ophthalmology The Anterior Visual Pathways Alfredo A. Sadun, M. D., Ph. D., and Jung Dao Optic Nerve The optic nerve has always been the focus of a great deal of attention in neuro- ophthalmology. In the last two years there have been several articles presenting results of the Optic Neuritis Treatment Trial ( ONTT). About 450 patients at 15 centers were randomized to one of the three groups to receive oral prednisone, intravenously administered methylprednisolone followed by oral prednisone, or placebo ( 126,127). In a landmark study, published in the New England Journal of Medicine, it was found that at 6 months follow- up, intravenous methylprednisolone followed by oral prednisone led to a better recovery of vision in patients with optic neuritis than did placebo or oral prednisone ( 126). Even more remarkably, it was discovered that oral prednisone alone increased the risk of new episodes of optic neuritis, so its use should be discouraged ( 88,128). At 1 year follow- up, the difference between placebo- treated patients and those on intravenous methylprednisolone had vanished ( 129). Hence the only value for intravenous treatment would have been to hasten visual recovery ( the rate of improvement was faster for patients receiving intravenous treatment, but the overall improvement was not greater). Most of the patients entering the Optic Neuritis Treatment Trial had their baseline visual fields carefully studied ( 130). Central or centrocecal scotomas were found in only about 8% of the eyes of patients with optic neuritis as demonstrated on the From the Department of Ophthalmology, Doheny Eye Institute, University of Southern California School of Medicine, Los Angeles, California, U. S. A. Address correspondence and reprint requests to Dr. Alfredo A. Sadun, Estelle Doheny Eye Institute, 1450 San Pablo Street, Los Angeles, CA 90033, U. S. A. Humphrey visual fields analyzer. Approximately 48% had diffuse visual field loss and 20% had nerve- fiber bundle- type defects. Of further interest was the fact that the fellow uninvolved eye in over two- thirds of the cases had minimal visual field defects as well ( 130,131). In rebuttal, Pollack ( 132) criticized these findings largely because the visual fields were done using Humphrey automated perimetry. Pollack ( 132) argued that properly performed visual fields would have greater diagnostic value and demonstrated more defects. Keltner and colleagues ( 133) responded to this criticism that automated visual fields are now the " gold standard" and therefore, for practical considerations, the visual field test most likely to occur in common usage. In addition to visual field defects, the fellow eyes of patients with optic neuritis demonstrated color vision abnormalities in 22%, and contrast sensitivity defects in 15%. Only 14% had more than one line of decreased visual acuity ( 134). The ONTT also demonstrated that routine diagnostic studies, including ANA testing, were generally not helpful ( 135). It has been suggested that steroids are particularly likely to be beneficial when given to patients with extremely severe visual loss due to optic neuritis. It has been hypothesized that steroids might reduce the extreme edema that accompanies demy elination reducing relative ischemia. As mentioned previously, this issue was addressed directly by the Optic Neuritis Treatment Trial, and it was found that prednisone treatment did not reduce the number of poor outcomes ( 136). In general, the early ONTT reports led to the following conclusions: 1. Diagnostic studies, including magnetic resonance imaging ( MRI), are not necessary. 234 ANTERIOR VISUAL PATHWAYS 235 2. Oral prednisone was definitely contraindi-cated. 3. Intravenous methylprednisolone followed by oral prednisone was probably of slight value ( 126- 128,135,137). Additionally, in an editorial that followed the New England Journal of Medicine article, Lessell ( 138) addressed the association between optic neuritis and multiple sclerosis. Noting that most patients with optic neuritis have the same high- intensity signals on MRI as do multiple sclerosis patients, and that the clinical characteristics of optic neuritis whether associated or not associated with multiple sclerosis are the same, he concluded that optic neuritis is simply an attack of multiple sclerosis, and the results of the Optic Neuritis Treatment Trial might thus be extrapolated to issues of management for multiple sclerosis ( 138). Most recently, another article looking at a longer term follow- up of patients in the ONTT presented bombshell findings. The patients treated with intravenous methylprednisolone for optic neuritis had a reduced incidence of multiple sclerosis of more than 50%(!) ( 139). At 2 years follow- up it was found that symptoms of definite multiple sclerosis in patients who presented with optic neuritis could be reduced from approximately 17% to less than 8% by the administration of intravenous methylprednisolone. The huge protective effect of intravenous methylprednisolone also led to a reassessment of the value of MRI scans ( 137,140). It is now believed that if an MRI shows two or more unidentified bright objects ( plaques) 3- mm in diameter, the patient is likely to develop multiple sclerosis, or at least have a recurrence of optic neuritis. Thus this cohort should receive intravenous methylprednisolone, since this treatment would be given not for its effect on visual outcome, but rather to " slow down" the development of multiple sclerosis ( 139). In an editorial reviewing these data and the recommendations made by the Optic Neuritis Treatment Trial group, Savino ( 141) concluded that 1. high- dose intravenous corticosteroid side effects are minimal; 2. visual deficits in the fellow eye are common; 3. the standard extensive workup for patients with optic neuritis is unnecessary except for brain MRIs to assess the patient's risk for multiple sclerosis; 4. corticosteroids speed up the recovery but have no influence on final visual income; 5. severity of initial visual loss is a predictor of final visual income; and 6. he personally would now perform brain MRIs on all patients with optic neuritis, and when the MRI was suggestive of multiple sclerosis, he would encourage treatment with intravenous methylprednisolone regardless of the patient's visual status. The downside of treatment with intravenous methylprednisolone has been addressed as well ( 142). Major side effects ( depression and acute pancreatitis) were rare and easily reversed ( 142). Further follow- up data from the ONTT study is awaited with great interest. Further surprises may await us. At this junction my take- home message is, in cases of acute optic neuritis, do an MRI and, if positive, give intravenous methylprednisolone. I present this to the patient as a window of opportunity to reduce or slow down the development of multiple sclerosis. Why such high doses of methylprednisolone protect against multiple sclerosis remains a question for future research. An odd new treatment for multiple sclerosis has also been proposed recently. A medicinal plant, Ruta graveolens, is ascribed to contain potassium channel blockers ( 143). Nine patients with acute optic neuritis were treated with a single dose extracted from this plant, and in 5 of the 9 patients the scotoma became smaller for a period of 24 to 48 hours. While it is interesting to theorize why blocking potassium might be advantageous in a demyelinative state, the lack of control subjects and other methodological problems makes it very hard to analyze this paper ( 143). In the meantime, work is continuing on an optic neuritis model in the guinea pig ( 144). Endogenous hydrogen peroxide produced a breakdown of the blood- brain barrier in the optic nerve of guinea pigs sensitized for experimental allergic encephalitis ( 144). Such hydrogen peroxide might derive from a variety of inflammatory cells seen around blood vessels in the optic nerve during episodes of optic neuritis. Celesia and colleagues ( 145) presented contrast sensitivity gratings to patients with multiple sclerosis and to controls and then analyzed the visual evoked responses by fast Fourier transform. They found that one- third of their multiple sclerosis patients showed abnormalities at all spatial frequencies tested, and more than half had abnormalities to at least one spatial frequency. These findings corroborate the fact that many patients with multiple sclerosis have had subclinical attacks of optic neuritis. In another study, 104 patients with multiple sclerosis and normal visual acuity had measures of visual acuity, visual evoked response ( 8), / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 236 A. A. SADUN AND J. DAO contrast sensitivity functions, brightness sense testing, and color vision testing ( 146). In their study group, 22% had a previous history of acute optic neuritis, but this group was distinguishable from the larger group only by contrast sensitivity testing. In general, most patients had normal visual acuities, normal contrast sensitivities and normal color vision ( 146). In the same issue of Neuro-ophthalmology is a description of 60 eyes of 50 patients with optic neuritis who had been treated with high doses of methylprednisolone in a protocol quite similar to that used in the Optic Neuritis Treatment Trial ( 147). This study, done in France, found dramatic improvement in vision in 56 of 60 eyes, and normalization of visual fields in a kinetic pattern that they described as " progressive centripetal amelioration" ( 147). From Japan came a review of 14 patients with idiopathic optic neuritis in whom visual acuities were between no light perception and counting fingers ( 148). Despite having been selected for such poor vision, about three- quarters of them showed improvement of visual acuity to 20/ 40 or better; however, in about one- quarter of the eyes, the visual acuity remained below 20/ 200 ( 148). Also from Japan came a description of a 3- year- old child with bilateral optic neuritis ( papillitis) documented both clinically and with MRI ( 149). Not surprisingly, her vision recovered with corticosteroids. A case of bilateral visual loss and optic disk swelling in a 9- year- old child diagnosed to be optic neuritis ( papillitis) provided the basis for a review of the management of optic neuritis in children ( 150). Optic neuritis has also been described to be associated with familial Mediterranean fever ( 151), which is a poorly understood inherited disorder characterized by recurrent fevers. Two young patients of Sephardic background, with an 8- to 10- year history of familial Mediterranean fever, developed painless blurring of vision in the setting of normal neuroradiological studies ( 151). In both cases visual acuities returned to normal and, since both patients were in their twenties, one must wonder whether this represents isolated optic neuritis of an idiopathic or multiple sclerosis-associated nature that, by happenstance, was seen with familial Mediterranean fever. Optic neuritis in combination with parainfectious encephalitis was reported in two children in whom there was also increased signal in the thalamus on T2- MRI ( 152). Biopsy of the thalamic lesions demonstrated chronic perivascular inflammation with activated microglia in a nodular formation. Both patients improved following steroid administration ( 152), but in both cases initial attempts at tapering the corticosteroids led to relapses. Long- term corticosteroid use resulted in good final visual acuity. A 20- year- old black patient whose initial workup was normal was diagnosed as having bilateral retrobulbar neuritis ( 153). Attempts at tapering corticosteroids led to relapses of optic neuritis. Such a finding requires a complete systemic evaluation to exclude a collagen vascular diathesis and sarcoidosis. Further workup demonstrated elevations of angiotensin- converting enzyme and erythrocyte sedimentation rate, leading to a diagnosis of sarcoidosis ( 153). A 52- year- old black man with sickle cell SS disease had a sudden loss of vision in one eye and an amaurotic pupil. His examination and workup were entirely normal until 2 months later, when optic atrophy developed. The diagnosis is of posterior ischemic optic neuropathy secondary to sickle cell disease. This is largely a diagnosis of exclusion ( 154). A 40- year- old patient is described with progressive loss of vision over 1 month to light perception and in whom disk edema was noted ( 155). Workup was otherwise negative and she was put on corticosteroids, which led to prompt return of her vision to 20/ 40 within the next 2 weeks. However, 4 months later her vision again decreased and further neuroimaging demonstrated a lesion compatible with sarcoidosis in the temporal fossa ( 155). Such cases serve as regular reminders that steroid- responsive optic neuritis may have a specific etiology, and, when patients show reexacerbation of symptoms on steroid taper, further workup is mandated. Retrobulbar optic neuropathy may occur as an indirect consequence of Wegner's granulomatosis ( 156), that is, compression or vasculitis. In the absence of any orbital disease, a 55- year- old woman developed bilateral severe optic neuropathies with small focal lesions seen on MRI in the posterior optic nerves ( 156). These findings probably represent a local vasculitis. Although nasopharyngeal carcinomas often lead to ocular symptoms, it is rare that such patients present initially with visual loss. However, cases have been described in which profound visual loss was the initial presentation of nasopharyngeal carcinoma, as the tumor had extended to the optic canal, producing isolated optic neuropathy ( 157). Radiation therapy failed to lead to any visual recovery, but may have delayed the onset of ophthalmoplegias. Visual recovery from radiation- induced optic neuropathy has been attributed to the use of hy- / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 ANTERIOR VISUAL PATHWAYS 237 perbaric oxygen therapy ( 158). Hyperbaric oxygen therapy was given to a 45- year- old woman who suffered severe visual field loss bilaterally followed by the visual acuity going to no light perception in one eye, 1.5 years after receiving 5,000 cGy of radiation therapy. Within 2 weeks of the initiation of hyperbaric oxygen therapy, the temporal hemi-anopia cleared in the less affected eye and light perception returned to the more severely affected eye. Repeat MRI studies showed decreased swelling and less gadolinium enhancement in the optic nerves ( 158). Two cases are reported in which embolization of the internal maxillary artery was required to control severe epistaxis ( 159). Unfortunately, in both cases the ophthalmic artery was occluded. A case of a 67- year- old man who underwent bilateral neck dissection that resulted in bilateral posterior ischemic optic neuropathy was described ( 160). Histopathologic analysis revealed infarction of the orbital portions of both optic nerves, which led to the hypothesis that postoperative hypotension had caused the problem ( 160). In addition to hypotension, anemia associated with surgery may be a significant risk factor for the development of posterior ischemic optic neuropathy ( 161). Amiodarone, a medication given for cardiac arrhythmia, may have contributed to a bilateral progressive optic neuropathy seen in a 62- year- old woman ( 162). However, features of ischemia in this case may have complicated the picture ( 162). It is well known that ethambutol, like a number of other antibiotics, can produce an optic neuropathy. This neuropathy is felt to be reversible if caught early. This belief is addressed in a series of seven consecutive patients receiving this drug ( 163). Of the seven patients, three developed severe optic atrophy even after discontinuation of the drug at first visual symptoms, and only three recovered vision to the 20/ 200 or better level. The authors concluded that, given the poor reversibility of vision loss following ethambutol optic neuropathy, this drug should be used rarely as a first-line antituberculous medication ( 163). Additionally, the authors suggested that visual evoked potentials are valuable in the detection and monitoring of the optic neuropathy associated with ethambutol ocular toxicity. I find electrophysiologic tests to rarely be more sensitive than an in-office clinical assessment. Similarly, a Japanese study of familial optic atrophy found that elec-troretinograms were of no assistance ( 164). They described two unrelated young adults who developed bilateral optic atrophy with deterioration in vision. Whereas dark adaptometry was abnormal, electroretinograms were entirely normal, raising the possibility of a newly described congenital disorder ( 164). Also from Japan is a case report of a huge glioma that involved the right optic nerve and chiasm of a 6- month- old girl for whom proptosis was the presenting symptom. She underwent craniotomy for resection of the lesion, and the histology confirmed the clinical diagnosis of a pilocystic astrocytoma, grade I ( 165). While initially her visual acuity was judged to be no light perception and light perception, respectively, by 18 months of age she had a visual acuity of 20/ 60 in the better eye and has done well subsequently ( 165). The authors were able to monitor this recovery with visual evoked potentials; however, I am concerned that difficulties in assessing visual acuities at this early age, and the natural maturation of the visual system may have confounded their interpretations. Dutton ( 166) has authored a comprehensive review of gliomas of the anterior visual pathway. In his very extensive review of the literature he concludes that this intrinsic optic nerve tumor occurs primarily in the first decade of life when it may grow rapidly, but then generally falls into a phase of stability. Hence the long- term prognosis is really not so bad, although there is an overall mortality rate of about 5%. Generally, conservative management is recommended, but in cases of complete blindness and pain or severe proptosis, surgical resection may be indicated ( 166). Four young children with neurofibromatosis type I, in whom original neuroimaging studies were negative but in whom gliomas of the anterior visual pathways eventually cropped up, have been described ( 167). While the authors did not suggest that this shows that these type of tumors can be acquired later in childhood, they do point out that initial negative neuroimaging should not be the basis for telling parents that their children will not develop visual problems in the future ( 167). In the case of neurofibromatosis type II, a 34- year- old woman presented with hearing loss and bilateral optic neuropathies ( 168). Computed tomography ( CT) scanning demonstrated what appeared to be bilateral optic nerve sheath meningiomas in addition to the expected bilateral acoustic neuromas ( 168). Meningiomas of the optic nerve sheath are also reviewed by Dutton ( 169), who discusses the various modalities of therapy, including conservative follow- up, surgical resection, and radiation. Optic nerve sheath meningiomas are also reviewed from a neuroimaging point of view ( 170). In 13 patients MRI sometimes proved advantageous over CT scanning in characterizing optic / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 238 A. A. SADUN AND J. DAO nerve sheath meningiomas in the orbit, canal, or intracranially ( 170). A new method for delivering precise radiation therapy for unilateral optic nerve sheath meningiomas has also been described ( 171). A 66- year- old man had an initial diagnosis of normal pressure glaucoma but was subsequently found to have an optic neuropathy due to compression from a meningioma ( 172). This confusion was due to the nasal step seen on his visual fields and the classical cupping and loss of optic disk rim seen on funduscopy. We are reminded that patients with low tension ( normal pressure) glaucoma should undergo neuro- ophthalmological workup. This article is followed by a remarkable editorial by J. L. Smith ( 173). He allows us to eavesdrop on some of the reviewers' comments on this paper, such as that this patient did not, by the criteria of Trobe ( 1980), meet the definition of glaucoma. Because of this serious objection, the paper was submitted to a glaucoma expert who agreed that the compressive lesion did, indeed, closely mimic normal tension glaucoma ( 173). Further clues that this was not glaucoma may have been that ( a) the nasal field defect was inferior ( not superior, as usual), and ( b) the patient reported blurred vision each morning ( 173). Gaze- induced amaurosis is a well- known phenomenon usually reflecting intermittent compression from an orbital mass. A case of gaze- induced amaurosis was described in which color Doppler imaging demonstrated a decrease in flow through the central retinal artery corresponding to those times and ocular position at which the patient could not see ( 174). The mass was an orbital varix, which was subsequently removed, after which the patient no longer noted any visual dysfunction and color Doppler imaging showed normal flow through the central retinal artery ( 174). A metastatic lesion to the optic nerve was described by Mansour and colleagues ( 175) in a 41- year- patient with a 2- week history of progressive visual loss. It was unusual in that no other cranial nerves were involved and there was no other evidence of an orbital process. A paraneoplastic syndrome producing an optic neuropathy was also described in a patient who, in addition to having progressive bilateral loss of vision, was noted to have ataxia and downbeat nystagmus ( 176). Although MRI of the brain was normal, the cerebrospinal fluid protein was found to be elevated. Ultimately, the diagnosis of small cell carcinoma was made on biopsy of a pulmonary lymph node. These cells were strongly positive for neuron- specific enolase, which is also found in astrocytes, possibly leading to this cross- specificity ( 176). Horton and colleagues ( 177) described MRI of the optic nerve in a case of acute myelocytic leukemia. This was in a 58- year- old man who complained of visual loss in one eye and in whom fundus examination showed disk edema and central retinal artery occlusion. On MRI, a bright signal filled a very extended subarachnoid space, indicating leukemic infiltrate ( 177). A lymphomatous infiltrate of the optic nerve was described in a 21- year- old man who had a diagnosis of Hodgkin's disease for 3 years ( 178). He presented with visual loss and disk edema, and on MRI scannings showed diffuse enlargement of the optic nerve. Combined radiation therapy and corticosteroids resolved the disk edema and led to a marked improvement in visual acuity ( 178). An 84- year- old patient presented with severe visual loss and pro-ptosis and was found to have a small cell malignant lymphoma ( 179). Local radiation therapy led to resolution of both proptosis and improvement in vision to 20/ 40 ( 179). A 40- year- old patient with progressive loss of vision was found by biopsy to have a plasma cell granuloma ( 180). Corticosteroid therapy led to tumor shrinkage and visual improvement ( 180). From Belgium came a description of a sphenoid sinus mucocele that did not cause the usual proptosis; rather, the patient developed sudden total blindness in one eye and then, over the next 5 days, in the other eye ( 181). Following surgery there was some recovery of vision in the second eye. From Japan came two papers describing new psychophysical measures of optic nerve function. Contrast sensitivity testing was done using both stationary and motion ( drifting vertical stripes) paradigms, and was found to be a sensitive measure of the impairments associated with optic neuritis and other optic neuropathies ( 182). Temporal modulation transfer functions of vision in patients with optic neuritis were also investigated ( 182). In patients with optic neuritis, an abnormality could best be detected by estimating the first and second harmonic components ( 183). The quantified relative afferent pupillary defect was correlated to visual fields measured by both static and kinetic perimetry in 137 patients with a variety of optic neuropathies ( 184). In some categories of optic neuropathy the correlation was strong, but in other categories, such as optic neuritis, the correlation was poor ( 184). Cryptococcal meningitis is becoming more common, largely because of the increase in AIDS. Sudden bilateral visual loss is a frequent occurrence with cryptococcal meningitis ( 185). A postmortem histopathologic study of the visual pathways from / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 ANTERIOR VISUAL PATHWAYS 239 such a patient with cryptococcal meningitis revealed focal areas of necrosis scattered throughout both optic nerves, as well as heavy infiltration of the meninges by the fungus ( 185). In a clinical study of 80 AIDS patients with cryptococcus infections, it was found that 33% had papilledema, 9% had visual loss, and 9% had a sixth nerve palsy ( 186). The presence of papilledema did not correlate with longevity in these patients. However, it is not always possible to characterize the nature of the optic neuropathies seen in HIV- positive men ( 187). Two HIV- positive patients were described as having bilateral optic neuropathies that could not be characterized. One patient received AZT and the other steroids, and both did well ( 187). While it is impossible to be sure as to what was the etiology of the visual loss or even if the treatment were related to the resolution of the problem, this paper is useful in reminding us that the prognosis is not uniformly dismal in HIV- positive patients who have an optic neuropathy. In the same journal issue was a description of an HIV- positive man who had subacute syphilitic meningitis that led to bilateral optic neuritis ( 188). Periocular corticosteroid injections may have helped salvage his vision. In a review of 78 asymptomatic HIV positive men ( 156 eyes) in which there was no retinitis, defects of color vision, and contrast sensitivity suggested a subclinical primary optic neuropathy ( 189). This was corroborated by a histopathological study in which optic nerves from patients with AIDS but with no retinitis were examined with a variety of special stains ( 190). A diffuse loss of axons was noted. Morphometry indicated that the pattern of axonal dropout was not limited to one fiber type. Histologic studies of 66 postmortem optic nerves from normal human subjects revealed that mast cells, frequently found in other ocular elements, could also be found scattered about in the meninges of almost all of these specimens ( 191). It is interesting to speculate that these mast cells might mediate certain inflammatory conditions of the optic nerve, perhaps by the release of hydrogen peroxide as described in an experimental model above ( 144). Histopathologic studies of the optic nerves during autopsy may provide us with useful information on other general issues. For example, Budenz and colleagues ( 192) looked at the optic nerves from 13 infants who died from acute intracranial injuries due to either blunt trauma or violent shaking. Optic nerve sheath hemorrhages were found in all 13 cases, but not in 6 other infants who died from sudden infant death syndrome. Metastatic lesions of the optic nerve are often found at the level of the optic canal. In reviewing five patients with metastatic prostrate cancer, Kattah and colleagues ( 193) demonstrated compressive optic neuropathies clinically ( on the basis of MRIs) and later his-topathologically. These metastases were found in the epidural and subperiosteal spaces near the optic canal. The existence of metastases in this closed space probably explains why the visual loss was remarkably acute ( one to several days) ( 193). Radiotherapy and pulse intravenous methylprednis-olone was somewhat helpful in these cases. The reader is encouraged to appreciate the characteristic pattern of bone hypertrophy and deformity that is seen on MRI with optic nerve compression in the optic canal. The optic canal is also a subject of interest in cases of posttraumatic visual loss due to optic nerve injury. In a follow- up of their classic 1990 paper ( 194), Levin, Joseph, Rizzo, and Lessell ( 195) present further retrospective analysis of 31 cases in which transethmoidal decompression of the optic canal was performed in patients in whom head trauma led to visual loss. Interestingly, they found that younger patients showed markedly better improvement in vision than did patients 40 or older. This seemed to be the most important variable ( as compared with preoperative visual acuity, delay to surgery, or the presence of fractures), and hence should certainly be incorporated into the long-awaited randomized trial for optic canal decompression for traumatic optic neuropathy. Girard and colleagues ( 196) also used a transethmoidal approach for canal decompression but extended this surgery into the sphenoid sinus in decompressing optic nerves following indirect trauma. In 8 of 11 patients ( including 4 patients with no light perception) they were able to document marked improvement in vision following surgery ( 196). Although they had no control group, they felt that their results compared favorably to those in the literature, in which spontaneous improvement of optic neuropathy following blunt head trauma is usually in the 33% range ( 197). Optic Chiasm Closed head injury can lead to a traumatic chiasmal syndrome. Although such injury is uncommon, and not readily visible on neuroimaging, it needs to be considered particularly when the visual field is suggestive ( 198). In one report, excellent MRIs demonstrated swelling of the optic chiasm with a hemorrhage that dissected up into the / Neuro- Ophthalmol, Vol. 14, No. 4> 1994 240 A. A. SADUN AND J. DAO hypothalamus of a 17- year- old who suffered blunt head trauma ( 198). Bitemporal hemianopsias as well as evidence of diabetes insipidus triggered the appropriate workup in this case. Neetens ( 199) has published a review of a traumatic bitemporal hemi-anopia. He described how trauma to the forehead region may produce a type of splitting of the optic chiasm with the result of an immediate loss of vision, possible seesaw nystagmus, and sometimes hypothalamic symptoms. There is an excellent section describing the three mechanisms by which such damage can occur to the optic chiasm ( shearing, contre- coupe, and stretching separation) ( 199). Another case report describes a 42- year- old man who suddenly awoke with unilateral visual loss with visual fields suggesting a junctional scotoma ( 200). Neuroimaging demonstrated a hemorrhage associated with a cavernous hemangioma ( 200). A case is described also of a 21- year-old women with progressive visual loss and what appeared to be a glioma or meningioma at the junction of the optic nerve and chiasm ( 201). The MRI showed this to be an annular enhancing lesion and surgical excision demonstrated this to be a choristoma ( 201). Three cases are described of children, ages 4 through 8, who had presumed chiasmal gliomas ( based on MR imaging) ( 202). Without any medical or surgical intervention, all three showed improvement in visual function ( 202). Another case described is that of a 43- year-old pregnant woman who, in her third trimester, developed visual loss that was found to be secondary to several aneurysms in the area of the optic chiasm ( 203). In this case care had to be taken to not endanger the fetus with workup or aneurysmal clipping. Two patients are described in whom chiasmal compression occurred following transphenoidal resection due to excessive packing of fat during surgery ( 204). In one case the excessive fat was removed, and the patient showed prompt recovery of vision. In the other, no attempt was made to remove this excess fat and the visual loss persisted ( 204). Another case is that of a patient in whom a pituitary macroadenoma was followed by serial magnetic resonance imaging scans to the point of spontaneous involution ( 205). This led to an empty sella syndrome, and documented the long-suspected relationship between empty sellar syndrome and infarction of a pituitary adenoma ( 205). In cases of optic chiasm dysfunction, the appropriate visual field test and interpretation often points to the appropriate neuroimaging. Martin- Boglind ( 206) described the use of visual fields and computer- assisted interpretations in over 300 patients, about half of whom had known chiasmal or perichiasmal lesions. There was approximately a 30% false negative rate, with only a 1% false positive rate, suggesting that this technique is useful, but not of sufficient reliability to forego the usual neuroimaging in suspicious cases. Chiasmal and perichiasmal lesions can mimic low- tension glaucoma. In a review of 62 patients with " classical signs of low tension glaucoma," neuroimaging demonstrated that 90% had pathology of the intracavernous carotid arteries ( 207). Even more remarkably, about half of these patients had asymmetry of the optic nerve head cups, which corresponded to the side of greater carotid artery involvement ( 207). Most neuro- ophthalmolo-gists are aware that dolichoectasias of the carotids may produce binasal field defects that sometimes look like glaucoma. The Optic Tracts and Primary Visual Nuclei Few clinical studies have explored the role of ophthalmologic disease at the level of the primary visual nuclei. The lateral geniculate nucleus is the major primary nucleus, and the destination of most of the retinal ganglion cell fibers. In a histopathologic study of the lateral geniculate nucleus, it was found that patients with glaucoma showed more losses in the magnocellular layers ( I and II) than in the parvocellular layers ( III- IV) ( 208). This is further corroboration of the hypotheses, described by Quigley and others ( 303), that glaucoma may have a preferential effect on the magnocellular system and hence that appropriate screening tests should be performed that target the psychophysical functions of this system. Further histopathologic work on the lateral geniculate nucleus in humans was done on a human brain obtained from an individual who had been noted to have strabismic amblyopia ( 100). Significant shrinkage of cells was found in both lateral geniculate nuclei corresponding to those layers innervated by the amblyopic eye. This was true for both magnocellular and parvocellular layers, but was more prominent in the ipsilateral lateral geniculate nucleus ( 209). Interestingly, this corresponds closely to findings from the monkey model of strabismic amblyopia and suggests that structural changes occur at the lateral geniculate nucleus, which is more than a mere relay station to the visual cortex. Remarkably, there was a report that levodopa administration can improve visual acuities and reduce the size of scotomas in human amblyopia ( 210). These authors extended their psychophysical measures of the effect of levodopa / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 ANTERIOR VISUAL PATHWAYS 241 in a double- masked crossover study and showed that over two- thirds of the patients improved significantly after 1 week of such therapy. It is unclear why the patients got better, why their improvement persisted after discontinuation of therapy, or at what anatomic site this may have had an effect. Three patients are described in whom arteriovenous malformations caused damage to the optic radiations ( 211). The band atrophy noted in the contralateral optic nerve suggested retrograde transsynaptic degeneration across the lateral geniculate nucleus. However, high quality neuroim-aging revealed that the deep venous drainage from each arteriovenous malformation would directly involve the lateral geniculate nucleus, and hence damage the optic tract directly, not requiring transsynaptic degeneration as a mechanism ( 211). The contribution of another primary visual nucleus was described in a report from Austria of a patient in whom a hemorrhage that damaged the right superior colliculus and right pulvinar of the thalamus ( as demonstrated by MRI) led to disassociated unilateral convergence paralysis ( 212). Both the superior colliculus and the pulvinar are known, on the basis of animal experimental models, to control ocular motility ( see section to follow on anatomical pathways. PARALLEL PROCESSING IN THE ANTERIOR VISUAL SYSTEM Parallel processing refers to separate channels through which information can be independently processed. Vision scientists have considered parallel processing in the visual system of a variety of animals for many years. Yet, ophthalmologists have tended to see the human visual system as serial processing. Many textbooks, even in n e u r ophthalmology, emphasize that visual information proceeds from the retina to the lateral geniculate nucleus only to " relay" to the visual cortex via the optic radiations. Light, entering the eye, is transduced into electrochemical signals by rods and cones that then input into bipolar, amacrine, and horizontal cells connecting to the retinal ganglion cells. Bishop ( 213) first suggested in 1933 that there are three types of retinal ganglion cells with different elec-trophysical properties and conduction velocities. Different morphological schemes of classifying retinal ganglion cells were variably proposed leading to Polyak's ( 214) classification of four types of primate retinal ganglion cells. In 1966, Enroth- Cugell and Robson ( 215) described X and Y cell types and in 1974 Boycott and Wassle ( 216) provided corresponding morphologic classes of retinal ganglion cells in the cat. More recently, these anatomic and physiological classes of retinal ganglion cells were described in the primate retina ( 217). Most generally, the anterior visual pathways of primates can be considered to be composed of three distinct parallel pathways of retinofugal projections to subcortical primary visual nuclei ( 218,219). About 80% of all retinal ganglion cells are of moderate size and have color- opponent physiologic responses and project to the parvicellular layers of the dorsal lateral geniculate nucleus; these cells are often referred to as the P ( or P- beta) ganglion cells. Interruption of this P pathway leads to deficiencies in color vision, visual acuity, and contrast sensitivity at high spatial and low temporal frequencies ( 220). In contrast, the M pathway seems to be primarily involved with color ignorant large cells that mediate information of high temporal and low spatial frequency contrast sensitivity, and probably motion ( 221). The retinal ganglion cells of the M cell pathway have large visual field areas, fast conduction speeds and project to the two magnocellular layers of the retinal ganglion dorsal lateral geniculate nucleus; these cells have also been called alpha cells. A third ( gamma) class of cells is less well understood and probably projects mainly to the superior colliculus, the pretectum and other brainstem primary visual nuclei ( 218,219). In the last few years there has been a great emphasis on the segregation of the M and P pathways ( 222). Human psychophysical and developmental studies have demonstrated the great significance of this segregation. For example, it has been proposed that a human neonate's vision is entirely subcortical and only begins to have cortical elements at about two months postnatally. Thereafter, the M and P cell pathways may underlie further visual development ( 223). The implication is that the basic behavior of a neonate relies only upon the rapid detection of objects in peripheral field such as might be processed by the superior colliculus and other primary visual nuclei of the brainstem that receive input from the primitive gamma class of retinal ganglion cells. Thereafter, cortical integration of spatial representation systems for color and form take place, suggesting involvement of the P cell system. Finally, the M cell system contributions of relative position, motion, and depth come in. Hence it is suggested that human development goes from gamma class ganglion cells to the P cell system to the M cell system ( 223). At the level of the visual cortex, the anatomic segregation of the M and P pathways remains / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 242 A. A. SADUN AND J. DAO largely complete even to the extent that there remains separation of axon terminal arboration fields and dendritic fields ( 221). This anatomic segregation begins, of course, in the retina with evidence that there is a distinction between the topography of the M and P cell ganglion cells. M cells, identified by neurofibrillar staining, probably constitute 6% to 10% of the retinal ganglion cells except for the nasal horizontal meridian where they represent up to 20% of the retinal ganglion cells ( 218). This is interesting because this nasal horizontal meridian is represented by the monocular visual field of the cortex. Most of the other retinal ganglion cells ( about 80%) are P ganglion cells, which are concentrated in the fovea but remain the dominant cell form across most of the rest of the retina as well ( 220). The consequence of selective damage to M or P cell ganglion cells have been measured psycho-physically in man and monkey as well. Selective destruction of P cells by a neurotoxicant led to decreases in visual acuity in all areas of the visual field ( 220). However, there was preservation of contrast sensitivity, vernier acuity, and even shape discrimination despite this chemoablation. Similar studies have revealed that M and P ganglion cells show a clear difference in their contrast sensitivity, particularly at low luminances; M cells are up to 10 times more sensitive to light than P cells ( 224). While some have proposed that this reflected an inherent linkage between rod vision and the M cell pathways, more recent studies have shown that scotopic visual acuity at all eccentricities is better than could be supported by a mosaic of pure M cells ( 225). Hence this simplified viewpoint can not be substantiated. There seems to be a marked similarity between morphologic and functional characteristics of the M type ganglion cell in the primate and the Y type retinal ganglion cell in the cat. For example, in primates, the temporal frequency response of M retinal ganglion cells is modified by increasing contrast, and increasing the contrast modifies the temporal frequency response of Y retinal ganglion cells in the cat ( 226). In contradistinction, P retinal ganglion cells in monkey and human gave a sustained response to increasing contrast. However, there are some who feel that P ganglion cells are not that similar to the cat X cells and instead should be regarded as a primate specialization not found in the retinae of lower mammals ( 226). It has also been found that, in monkey, there is a distinct pattern of electrotonic cellular coupling between M cells to each other and to amacrine cells; P ganglion cells however show no evidence of such coupling ( 227). Such M ganglion cell coupling may serve as a mechanism for increasing the luminance contrast sensitivity as well as variably maintaining large receptive fields. While there may be relatively poor contrast sensitivity with P ganglion cells, this is in part compensated by the great number of P ganglion cells in the retina. Recent studies have also validated Livingstone's proposal that color and motion may be processed in partially separate pathways with the P cell system mediating the former and the M cells system the latter ( 228,229). Livingstone and Hubel ( 222) proposed and more recently Merrigan and Maunsell ( 221) have shown that stereopsis, motion, and figure/ ground discrimination were probably M cell functions, whereas visual acuity and color vision were primarily P pathway mediated. While this might be an oversimplification of a highly complex set of systems, it at least sets the stage for understanding the segregation of two or more systems at both subcortical and cortical levels. However, at the subcortical level there are a number of other parallel pathways. Animal experiments in a variety of vertebrates suggest that there are retinal ganglion cell projections to at least five and probably eight or more primary visual nuclei. Retinofugal fibers have been clearly established to project to 1. the superior colliculus ( optic tectum); 2. the pretectum; 3. the lateral geniculate nuclei ( in most animals there is a separate projection to either the dorsal lateral geniculate nucleus or the ventral lateral geniculate nucleus); 4. the accessory optic system; and 5. the suprachiasmatic nucleus of the hypothalamus ( 230). Projections to other nuclei of the hypothalamus have also been described in humans as well as in animals ( 231). Similarly, projections to the human accessory optic system have also been recently demonstrated ( 232). More recent studies have yielded insights into the development of these retinofugal pathways to the primary visual nuclei. It might be said that there is a paradigm of dendritic remodeling as a general mechanism for mammalian retinal ganglion cell development by which extensive regression of the dendritic tree occurs after birth ( 233); axonal elongation is followed by branching of collaterals with final or elaboration of collaterals based upon the " correctness" of their connection ( 234); and electrophysiological restructuring of retinofugal projections can occur due to variations / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 ANTERIOR VISUAL PATHWAYS 243 of sodium- mediated action potentials ( 235). While these studies were done on rats, hamsters, and cats respectively, it was demonstrated in monkey that there is an order in which the retinal ganglion cells develop beginning with axons of small caliber and followed successively by medium size and finally large retinal ganglion cells with large fibers ( 219). This is particularly interesting, given that the smallest class of cells contribute pathways to the hypothalamus and midbrain, which might be considered more " primitive." Further evidence in the cat reveals development by fiber type ( chrono-topy), which might contribute to the morphologic differentiation of these different retinal ganglion cell types ( 236- 239). Both retinotopic and chrono-topic arrangements can be discerned not only at the level of each primary visual nucleus, but in the decussation patterns of fibers at the optic chiasm. While some feel that retinotopy ( preservation of the visual map) is maintained all along the fiber pathway until it hits its target visual nucleus, more recent studies have shown that HRP- labeled axon profiles emanating from a cluster of cat retinal ganglion cells became quite scattered in the distal optic nerve ( 240). These studies have been repeated in monkey as well ( 241). Indeed, retinotopy as measured by the number of fascicles is actually lost as the fibers progress from the retrobulbar optic nerve to the optic nerve near the optic chiasm ( 242). Moreover, fibers deriving from the temporal retina develop at a different time than those that derive from the nasal retina ( 243). Hence retinotopy or fiber arrangement must be maintained or restructured by more than simple mechanical and physical relations. How then do fibers know whether to decussate at the chiasm or not? One possibility is that each of the two paths of each retina ( retinal ganglion cells from the nasal half of the retina of each eye versus the temporal half) carry a different molecular trophic factor, which provides a lateralization signal at the level of the optic chiasm ( 244,245). Setting aside the problem of whether to decussate at the optic chiasm, the retinofugal axons deriving from retinal ganglion cells must reorganize themselves and reestablish retinotopy at the level of the optic tract. This appears to occur suddenly at the optic chiasm/ tract junction and may also reflect some type of trophic molecular message ( 246). Substrates that might mediate such signals have been suggested in studies that attempt to regulate growth cone behavior of retinal ganglion cells grown in vitro ( 247). For example, extracts obtained from a suspension of cells from the anterior superior colliculus promoted the growth of retinal ganglion cells that derive from the temporal but not nasal retina ( 247). Hence it seems likely that at least each half of the retina contributes retinal ganglion cells whose axons respond to a different molecular gradient in a trophic fashion. Each gradient could establish an axis and indeed this has been demonstrated to exist in the optic chiasm of the ferret ( 248). Retinal ganglion cell axons, which appear dispersed in the most posterior portions of the optic nerve, segregate sharply as they reach the ferret optic chiasm, such that fibers that derive from the dorsal retina immediately migrate caudo-medially, and those from the ventral retina rostro-laterally ( 248). Within the optic tracts, the largest fibers tend to run on the surface and the smallest at the core; this mirrors the arrangement of the optic nerves as well ( 249). This fiber arrangement described in the monkey probably explains why lesions of the optic tract in humans produce such incongruous visual field defects. This arrangement of smaller axons centrally and larger axons more superficially may also reflect the chronotopic arrangement since small caliber retinal ganglion cells send off their axons first, while larger axons undergo axogenesis later ( 219). Another element that may help control chronotopicy may be the changing glial environment along the optic pathways and particularly the optic tracts ( 250). The best understood primary visual nucleus remains the lateral geniculate nucleus. In the cat, retinotopically ordered retinofugal fibers project to the ventral and dorsal lateral geniculate nuclei; but only the dorsal lateral geniculate nuclei project to the visual cortex. Ventral lateral geniculate nucleus cells project to the pretectum and superior colliculus and probably other brainstem nuclei as well. Recent work has furthered this understanding of lateral geniculate nucleus function with emphasis that it is more than a relay of monocular retinal information. In the dorsal lateral geniculate nucleus it has been shown that each neuron may be contacted by over 10 retinofugal axons and that each retinofugal fiber probably contacts more than 20 neurons in the lateral geniculate nucleus ( 251). Both M- and P- type retinal ganglion cells project to the dorsal lateral geniculate nucleus ( layers 1 and 2 for M cells and layers 3 and 5 for P cells). The third and smallest retinal ganglion cell type ( which we might regard as gamma or W- like) also projects to the dorsal lateral geniculate nucleus in primates ( 252). Recent updates on the circuitry of the lateral geniculate nucleus have confirmed and advanced the point first made by Guillery in 1971 in both cat and monkey that there is minimal binocular overlap between contralateral and ipsilateral projec- / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 244 A. A. SADUN AND J. DAO tions to the lateral geniculate nucleus and that cells in each lamina fire only in response to incoming retinal signals ( 253,254). In contradistinction, the ventral lateral geniculate nucleus, as described in the tree shrew, receives input from the retina, cortex, pretectum, and superior colliculus ( 255). Two subdivisions of the ventral lateral geniculate nucleus probably mediate visuosensory and visuomotor functions separately; a third ventral lateral geniculate nucleus region projects to the suprachiasmatic nucleus of the hypothalamus, an important area for light en-trainment and synchronization of the circadian rhythm ( 256). In this sense, it can be seen that the lateral geniculate nucleus, if regarded as a cortical relay in rodents and cats, must also be regarded as a relay to brainstem visual nuclei. Despite the emphasis on the segregation of the M and P pathways, selective damage to one or the other pathway by ablation of the corresponding layers in the dorsal lateral geniculate nucleus in monkeys did not significantly affect the accuracy of ocular saccades to stationary or moving targets ( 257). Similarly, it was shown that either the M or P pathway alone was capable of relaying sufficient information about target motion to generate functionally effective smooth pursuit eye movements. In most mammals retinotopically ordered fibers project to the superficial gray layer of the superior colliculus with most of the contribution coming from the contralateral retina ( 258). In the monkey, unlike the rodent, most of the cells of the superior colliculus receive binocular information while establishing a retinotopic map of the contralateral visual field ( 259- 261). Specificity of connections and the role of chronotopy and position based hues, as well as neuronal activity and chemical gradients, have been explored through a variety of studies in rodents and other mammals ( 262- 267). In many ways, the patterning of retinotectal connections in rodents has been the model upon which specificity studies have been performed to determine how multiple cues work together to guide the sculpting of retinotopy. The striking neurochemical architecture of the superior colliculus as well as its absence of sulci has made it ideal for such study ( 266). While the superficial layer of the superior colliculus appears to be visuosensory in function, the deeper layer is probably multisensory and certainly has some premotor functions. Between the two layers is an interlaminar zone with connections that may be different in different mammalian species ( 268- 270). In this zone as well as in the deeper layers of the superior colliculus, neuronal activity has been observed in the initiation of a saccade as compared to that responsible for specifying the horizontal and vertical amplitude of each saccade ( 271). The accessory optic system in the mesencephalon is comprised of thin fasiculi and associated nuclei arranged differently in different vertebrates. The three or more clusters of cells that constitute the accessory optic system probably receive large-diameter retinofugal axons that are crucial for coordinating head and eye movements in order to maintain a stable gaze ( 230). Recent studies have established the nature of the GABAnergic circuits in the accessory optic system and the receptive field properties in mammals, including monkey ( 272,273). The histologic appearance of the three accessory optic system nuclei in humans is not significantly different from those of monkey ( 232). The retinofugal input to the pretectum has been well known in man because of its clinical significance for the pupillary reflex. It would be better to describe the pretectum as a complex of cell clusters rather than a single nucleus, all of which mediate the pupillary light reflex by relaying light information to the Edinger- Westphal nucleus. One of the pretectal nuclear subdivisions is the nucleus of the optic tract, which receives bilateral input and subserves optokinetic nystagmus ( 274,275). There is also evidence that the nucleus of the optic tract also helps along with the accessory optic system for gaze stabilization and control of visual-vestibular interaction ( 276). While the predominance of retinal ganglion cell input to the nucleus of the optic tract is from small cells ( perhaps W- like cells), some medium and some large caliber axons also terminate in the nucleus of the optic tract ( 277). Direct retinal input has been demonstrated to the suprachiasmatic, the supraoptic, and the paraventricular nuclei of the hypothalamus in man ( 231). The suprachiasmatic nucleus in particular ( but probably all three of these hypothalamic nuclei) helps subserve the light entrainment and synchronization of the circadian rhythm. In some animals, further visual input can be traced to the suprachiasmatic nucleus from subdivisions of the lateral geniculate nucleus ( 278- 280). Most of the neurons of the suprachiasmatic nucleus are GABA producing, and there is good evidence that GABA should be considered the principal neurotransmitter of the circadian system ( 281). The suprachiasmatic nucleus and other hypothalamic nuclei can be considered as " biologic clocks" that use visual input as entrainment diurnal rhythm. The output of the suprachiasmatic nucleus may contribute to the " biological calendar," / Neuro- Ophthalmol, Vol. 14, No. 4, 1994 ANTERIOR VISUAL PATHWAYS 245 which expresses seasonal cycles and even milestones of development. For example, the volume of a human suprachiasmatic nucleus, and the number of vasopressin- immunoreactive neurons contained within it, fluctuate rhythmically over the year with values that begin twice as high in the autumn as in the summer ( 282). Indirect inputs between the suprachiasmatic nucleus and the pineal may help regulate the timing of developmental milestones such as the onset of menarche. The pulvinar complex is found in the lateral aspect of the thalamus, and lies above and somewhat medial to the lateral geniculate nucleus; it too has been shown to receive retinofugal projections in cat, monkey, and humans, respectively ( 283- 286). The function of the pulvinar remains poorly understood but probably relates indirectly to the control of eye movements by identifying the most salient visual objects ( 287,288). The concept of parallel pathways has, especially in the last few years, proven to be a powerful paradigm for understanding the organization of the visual system and, by consequence several interesting clinical features, especially in regard to methods of visual assessment for patients with visual dysfunction. While it is somewhat simplified, it is useful to think of the M and P cell pathways as anatomically and functionally distinct and as channels for different psychophysical features. The third or small cell pathways can be considered as a primitive system that projects to various brainstem nuclei that mediate unconscious visual information useful to the control of eye movements and the light entrainment of circadian rhythms. Certain diseases may selectively impair one pathway pver the other. For example, it has been demonstrated in Alzheimer's disease there is a predilection for involvement of the M pathway ( 289). Similarly, Quigley and his colleagues ( 290) have described greater losses of fibers in the M pathway in chronic glaucoma. This has been anatomically corroborated by electrophysiologic studies ( 291,292) and histopathologic studies of the lateral geniculate nucleus ( 293,294). On the other side of the coin are diseases like optic neuritis, which may have predominant effects on the P cell pathway. For example, optic neuritis patients who have recovered to normal visual acuity and full fields may still have impairments of foveal critical flicker frequency, a psychophysical test of visual temporal resolution ( 295). This may be because temporal resolution is higher in the M than in the P cell pathway. Similarly, Regan has shown that a patient with multiple sclerosis and optic neuritis seemed to have impairments of recognition of motion- defined shapes, which are rendered visible by a shift in velocity ( 296). Once again, this suggests the selective impairment of P pathway retinal ganglion cell axons. However, using the simplified scheme of M and P cell circuitry to explain every clinical syndrome may be stretching things. For example, several authors have suggested that developmental dyslexia is caused by selective lesions to the M cell pathway and consequently selective injury to the magnocel-lular layers ( I and II) of the lateral geniculate nucleus ( 297- 300). Not withstanding their histopathologic and psychophysical studies, the clinical implications remain highly speculative, and there is the danger that special forms of " treatment" will be offered for profit in exploitation of these theories and of the patients with dyslexia ( 301). The medical community must remain wary of inappropriate application of preliminary scientific studies for justification of unproven treatment strategies. Blindsight is the ability of some apparently blind patients to react to visual stimuli even when they are totally unaware of conscious vision due to damage along the geniculate/ visual cortex pathway. It has been traditionally hypothesized that such abilities might be due to an alternate subcortical pathway ( i. e., superior colliculus). However, reexamination of this issue suggests that, at least in some patients, an isolated tiny island of residual vision not disclosed by conventional visual field examination, is responsible for providing sufficient visual information for accurate responses but insufficient for conscious awareness of vision ( 302). Notwithstanding these " reality checks," there can be no question that the existence of parallel pathways provides important clinical insights, namely, that there is much more to vision than visual acuity and many more inputs to the brain than those simply relayed through the P- cell lateral geniculate nucleus. It is quite likely that in the next decade advances in diagnosis and management of diseases will be made with a better understanding of these multiple and sometimes separate channels of visual information. REFERENCES 126. Beck RW, Cleary PA, Anderson MM Jr, et al. A randomized, controlled trial of corticosteroids in the treatment of acute optic neuritis. 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