Journal of Neuro-Ophthalmology, September 1994, Volume 14, Issue 3

The anterior visual pathways.

journal of Neuro- Ophthalmology 14( 3): 141- 154, 1994. > o 1994 Raven Press, Ltd., New York Part One Annual Review in Neuro- Ophthalmology The Anterior Visual Pathways Alfredo A. Sadun, M. D., Ph. D. and Jung Dao This review of neuro- ophthalmology of the an­terior visual pathways is one of the first of a series of reviews in the ] ournal of Neuro- Ophthalmology, which is now the official journal of the North American Neuro- Ophthalmology Society. As the first review of the anterior visual pathways, we have taken the liberty of extending the period cov­ered beyond the somewhat traditional one year. Hence, this review will cover articles from the be­ginning of 1992 through 1993. In addition, it will include a few of the most important articles that were published prior to 1992 and several articles published in early 1994 during the preparation of this manuscript. The visual system will be covered from the retina through the optic disc, the optic nerve, the optic chiasm, the optic tracts, through to the primary visual nuclei, which will include the lateral geniculate nucleus, the pretectum, the su­perior colliculus and the other minor primary visual nuclei in the mesencephalon and diencephalon. Two major topics were addressed: 1) mechanisms of axonal injury and recovery as well as the effects of corticosteroid and of surgical therapy on two com­mon optic neuropathies; and 2) the segregation of visual information into separate channels, which constitutes parallel processing of the visual system. MODULATING THE PROCESSES OF NEURONAL INJURY AND RECOVERY Neurons, whether in the eye or the brain, are susceptible to ischemic injury as a consequence of 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. a variety of insults. If blood flow is interrupted for more than several minutes, irreversible damage occurs. There have been several recent advances in our understanding of the mechanisms of hypoxic cellular injury, and with it new strategies in stroke management. Many of these issues apply also to tissue damage due to ischemia at the level of the eye and the optic pathways. Several cytotoxic amino acids including gluta-mate, N- methyl- D- aspartic acid ( NMDA) and kainic acid, stimulate neurons to permit an influx of calcium, which can lead to damage and cell death. Increased calcium leads to activation of pro­teases and phosphorylases that destroy cellular membranes, and uncouple oxidative phosphoryla­tion of the mitochondria. The cell attempts to pump out the calcium. The pumping mechanism itself leading to lactic acid or is a further intracel­lular injury. The affinity of neurotoxins for the NMDA receptor site can be blocked by certain an­tagonists. Receptor sites other than that of NMDA ( so- called non- NMDA receptor sites) can also me­diate toxic reactions initiated by glutamate and other agonists. Various strategies have been employed in at­tempts to block the NMDA receptor site so as to protect neurons from further ischemic damage. For example, dextromethorphan and MK- 801 non-competitively bind to the site, and thus act as an­tagonists to the effects of glutamate and other neu­rotoxins. Zinc and magnesium act competitively with calcium to keep the channel open, and a va­riety of calcium channel blockers such as nimo-dipine have been used to restrict the flow of cal­cium into the cells. What follows is a discussion of investigations on modulating ischemic injury in the retina, optic disc and optic nerve. 141 142 A. A. SADUN AND J. DAO Retina The article by Schumer and Podos ( 1), which appeared at the beginning of 1994, approached the subject of glaucoma from the unusual angle of ask­ing how cytotoxic agents and blocking mecha­nisms might apply at the level of the retina and optic disc in general and in glaucoma in particular. They reviewed the NMDA receptor site, its ago­nists and other cytotoxins, antagonists to the NMDA receptor site, calcium- induced damage of retinal cells and strategies of calcium channel blockage. Finally, they also reviewed recent stud­ies on nitrous oxide as an intracellular messenger, and the role of free radicals and how scavengers might be used to mitigate this damage. Unfortu­nately, the first attempts to modulate ocular blood flow with calcium channel blockers have not proven particularly successful ( 2). Similarly, the use of calcium channel blockers to prevent damage attributable to glaucoma also has not proven useful ( 3). Nonetheless, ophthalmologists now are initiat­ing studies based on what is known about the ac­tion of NMDA and nonNMDA associated neuro­toxins and transmitters as acquired from the neu­rologists and neurosurgeons. Interesting papers include the review of various NMDA receptors and their agonists and that by Albers and col­leagues describing the use of NMDA antagonists to minimize the effects of injury to neurons. A variety of excitatory amino acid neurotoxins may be released following neuronal injury from ischemia. These neurotoxins stimulate opening of Ca+ f ion channels, which permits a massive in­flux of calcium to the interior of the neurons. As mentioned previously, the rise in intracellular Ca *" + activates various lipases and prostaglandins producing irreversible membrane damage. It is interesting to note that excitoneurotoxins produce a specific pattern of cell death in the retina ( 1). It is intriguing to postulate that the pattern of cell death could be due to the differential effect of various neurotoxins on various retinal ganglion cells. Glaucoma and Alzheimer's disease are two examples of diseases due to cell specific injury in which there appears to be a predilection for the loss of one retinal ganglion cell type versus others and thus damage to one channel of information ( see later section on parallel processing). Excitatory neurotoxins such as kainic acid and NMDA will lead to the immediate death of rat ret­inal ganglion cells ( 6), but this can be modulated by pre- treatment with NMDA antagonists such as dextrophan or dextromethorphan. It has been sug­gested, therefore, that activation of NMDA recep­tors may mediate cellular damage in the retina in a variety of ischemic and degenerative diseases in­cluding glaucoma, Parkinson's Huntington's and Alzheimer's disease ( 1). Harrison ( 7) has demon­strated that certain drugs can be used clinically in the treatment of stroke to modulate the neurotoxic effects of excitatory amino acids. Calcium channel blockers would theoretically re­duce the toxic effect of such amino acids by pre­venting the great influx of calcium intracellularly. However, calcium channel blockers can also have deleterious effects such that lead to vasodilation as peripheral vasodilations and other effects on blood flow. Nitric oxide also causes vasodilation, but at a capillary level it is produced as a consequence of the stimulation of NMDA receptors; nitrous oxide, a precursor, can diffuse out of the injured cell, and exert a toxic effect on surrounding neurons ( 8,9). Verma and colleagues ( 10) have suggested that car­bon dioxide can act similarly to nitric oxide and induces a neurotoxic chain reaction. In demonstrating the presence of nitric oxide synthase in the bovine eye, Geyer and colleagues ( 11) have contributed evidence that these neuro­toxic events do probably occur at the level of the retina. In addition, free- radical scavengers have been demonstrated to protect the retina following ischemic injury ( 12,13). Such molecules may work by binding oxygen radicals induced by the in­creased intracellular calcium mediated by the NMDA receptors. Nayak and colleagues ( 14) were able to protect rabbit retinas from transient isch­emia as measured by the electroretinogram. Kashii and colleagues ( 15) ( using a model of NMDA re­ceptor mediated retinal toxicity) were able to dem­onstrate that dopamine protects against glutamate neurotoxicity in cultures of fetal rat retina. Rat ret­ina can be protected from ischemic injury from other means as well. For example, Unoki and La Vail ( 16) showed that a variety of growth factors and neurotrophic agents promote survival of the retina in adult rats in which the intraocular pres­sure was purposefully raised to induce ischemia. Moreover, it is quite likely that cells that derive from the immune system are capable also of pro­ducing survival- promoting agents, such as neuro­trophic and growth factors, that block the neuro­toxic cycles described above ( 16). As these complex cycles of ischemia ( or other injury), i. e., cellular damage, release of neurotox­ins, stimulation of NMDA receptors, and further cellular damage become better understood, the pathogenesis of a wide variety of diseases that im- / Ncuro- Ophthalmol, Vol. 14, No. ,3, 1994 ANNUAL REVIEW: THE ANTERIOR VISUAL PATHWAYS 143 pact the retina and the optic nerve will also become better understood. It may well be that disparate diseases share some elements of pathophysiology as well as the potential to be managed with similar pharmaceutical agents, the effect of which is to break the cycle of cytotoxic damage. While the major emphasis recently has been on the cytotoxic cycle, some other topic specific enigma have also been revisited. Blindness follow­ing transurethral resection of the prostrate has been described on many occasions. Blindness is usually bilateral and pupillary reflexes have more often than not been present, leading to the specu­lation that the underlying problem lies in the cor­tex ( 17). However, more cases with nonreactive pupils and asymmetrical visual loss have been de­scribed. In these instances, blindness has been as­cribed to ischemia of the optic nerves, possibly sec­ondary to electrolytic and metabolic disturbances caused by the intravesicular irrigating fluid used during surgery. Barletta and colleagues ( 17) de­scribe a patient who temporarily had no light per­ception bilaterally, with sluggish pupils, and pro­posed that the cause of this visual dysfunction was the neurotoxic effect of glycine on the retina. It is likely that neuroexcitatory mechanisms play a role in both cases. A case of neuroretinitis due to syphilis was seen in a patient with the human immunodeficiency vi­rus ( HIV). Interestingly this patient had a negative serology for syphilis ( 18), but was HIV positive on ELISA and Western blot testing. A presumptive diagnosis of syphilis was made and the patient was treated with penicillin with dramatic improve­ment in vision and in fundus findings. On the ba­sis of this clinical response and the fact that he was HIV positive, it was concluded that he had sero­negative syphilis with syphilitic neuroretinitis ( 18). This is a classic example of how patients with AIDS can fool the unwary physician by producing neg­ative serologies. Leber's congenital amaurosis is a disease that often fools the clinician, since there are often only minimal retinal or optic nerve head changes in the early course of the disease. Indeed, these patients may even have a normal ERG. A retrospective re­view over a 15- year period of 54 patients with this diagnosis showed that it was routine to have a normal initial examination, followed by the devel­opment of retinal and optic disc changes but with­out further visual loss ( 19). Two patients have been described who had se­vere periphlebitis and retinal ischemia, the under­lying etiology of which was felt to multiple sclero­sis ( 20). An intensive workup failed to find any other cause of uveitis; however, as we well know such negative workup is not uncommon in uveitis and multiple sclerosis is not such a rare disease. However, the report of a severe retinitis in a 6- year- old with cat scratch disease did seem to be a related ( 21). A 2- year- old child was described as having unilateral visual loss due to neuro- retinitis associated with chicken pox ( 22). There was some question as to whether this was acute retinal ne­crosis ( 22). Gass and colleagues ( 23) invoking the " worm" hypothesis described the use of oral thi­abendazole in four patients with diffuse unilateral subacute neuro- retinitis; all four did well. While the medication probably accelerated resolution of the visual symptoms, we know that most cases of neuro- retinitis have good long- term prognosis even untreated. Toxoplasmosis was found to be a fairly common cause of neuro- retinitis in a retro­spective review ( 24). While only two patients had chorioretinal scars typical for toxoplasmosis, all were proven to have had recent serological changes with toxoplasmosis ( 24). Two patients developed visual loss associated with the use of a monoclonal antibody to prevent rejection. An electroretinogram on one of these pa­tients led to the hypothesis that the monoclonal antibody therapy had produced direct retinal tox­icity, and perhaps an optic neuropathy as well ( 25), similar to that seen with cancer- associated ret­inopathy ( CAR). CAR may accompany certain forms of cancer, and involves antibodies against photoreceptor protein ( 28). This 23kD protein an­tigen was characterized and found to have an amino acid sequence similar to bovine recoverin ( 26). A case of cancer- associated retinopathy was described in a 68- year- old man with a 35- year his­tory of smoking ( 27). He had a rapid, unilateral loss of vision and was eventually found to have serum antibodies that reacted with retina. Cortico­steroids successfully halted his visual loss and nor­malized his antibody titers ( 27). Ten patients were described with CAR probably related to small cell carcinoma of the lungs ( 28). All ten patients had a common antibody specific for small cell carcinoma of the lung ( 28). A 68- year- old man complained of intermittent blotchy visual loss in one eye ( 29). Although his erythrocyte sedimentation rate was only 35mm/ hour, a temporal artery biopsy was positive for giant cell arteritis. Remarkably, a fluorescein an­giogram demonstrated choroidal nonperfusion, which improved after corticosteroid therapy ( 29). Subsequent report has corroborated this finding. This heuristic cases raises our level of suspicion for temporal arteritis even in patients with low eryth- / Neuro- Ophthalmol. Vol. 14, No. 3, 1994 144 A. A. SADUN AND]. DAO rocyte sedimentation rates. This report points out that ischemia can occur in a number of ocular and orbital tissues, including the choroid. In another study, patients who had sustained traumatic chorioretinal rupture with and without optic atrophy were compared ( 30). There was no correlation between the size or location of the rup­ture and the type or severity of the trauma; how­ever, not surprisingly the patients with optic atro­phy had larger afferent pupillary defects and worse vision ( 30). Optic Disc A recent review by Burde ( 31) addressed how certain anatomic characteristics of the optic nerve head might put it at risk for metabolic, vascular and mechanical injury. He described a " disc at risk," which was characterized by the absence of a small physiological cup, elevation of the disc mar­gins by a thick nerve fiber layer, anomalies of blood vessel branching and, in general, the ap­pearance of a crowded and small optic nerve head ( 31). In his analysis, Burde pointed out several fea­tures singular to the optic nerve head that may predispose it to certain types of injuries. For exam­ple, the mechanical constraints of the optic disc itself are such that relative ischemia may occur un­der ordinary circumstances producing axoplasmic swelling within the restricted space of the small canal leading to increasing compression of small blood vessels and further ischemia that in turn causes further axoplasmic swelling. This vicious circle, if unbroken, might be the pathophysiologi­cal basis for anterior ischemic optic neuropathy ( AION). Similarly patients who develop the papil-lopathy associated with insulin- dependent juve­nile diabetes mellitus have the same optic disc anatomy. Burde suggests that this papillopathy is a forme fruste of AION. He notes that often there is engorgement of the peripapillary capillary net in response to the chronic ischemia of diabetes which might be able to shunt oxygen and prevent an overt attack in the diabetic patient's " disc at risk" ( 31). Leber's hereditary optic neuropathy ( LHON) represents another metabolic disease in which the " disc at risk" is present. In this case an error in metabolism produced by mutations of mitochon­drial DNA leads to a reduction in oxidative phos­phorylation efficiency. It is intriguing that what should be a generalized impairment of energy pro­duction targets the optic disc ( at risk) in particular. However, the situation is probably not dissimilar from that described by Sadun and colleagues ( 32) in Cuban epidemic optic neuropathy ( 32,33). In Cuba, a combination of nutritional deficiencies, probably compounded by chronic exposure to tox­ins such as methanol ( found to contaminate the ubiquitous homemade rum in Cuba), might well have set the stage for an epidemic of optic neurop­athy seen in association with peripheral neurop­athy ( 34,35). In particular, folic acid deficiency in combination with formate accumulation ( from methanol metabolism) would severely reduce oxi­dative phosphorylation efficiency ( like Leber's) ( 34). Moreover, Sadun and colleagues ( 34) de­scribed fundus findings that included loss of the papillomacular bundle and swelling of the nerve fiber layer adjacent to the papillomacular bundle. In the peripapillary swollen nerve fiber layer, tiny dilated and telangiectatic blood vessels were noted, further mimicking the fundus appearance of LHON ( 34). However, patients suffering from the Cuban epidemic were otherwise clinically dis­tinct from LHON and, of course, did not show the same DNA mutations ( 36). The question therefore remains as to why patients with Cuban epidemic optic neuropathy or Lebers' hereditary optic neu­ropathy should show damage at the level of the optic disc, and most particularly injury predomi­nantly in the papillomacular bundle. Intriguingly, similar pathophysiological changes are noted also in a variety of clinical conditions and experimental models involving several toxins. For example, the optic disc appears to be an area of particular susceptibility for acute methanol neuro­toxicity. Burde ( 31) suggests that this may be be­cause this region is served by end arterioles of the posterior ciliary circulation, and hence has a lim­ited tolerance for periods of ischemia or respiratory insufficiency. Other peculiarities of the vasculature of the optic nerve head also might predispose it to a variety of vasculidities. For example, why is be­nign papillophlebitis so frequently found overly­ing the optic nerve head ( 37)? I share with a few other neuro- ophthalmologists the feeling that one feature of the disc that may put it at risk is that the retinal ganglion cell axons are forced to make a very sharp turn as they penetrate the lamina cri-bosa at the optic nerve head. Axoplasmic transport is a very energy dependent process, and it may well be that enormous energy demands are placed on the axoplasmic transport system in order to overcome the mechanical features of this sharp turn. If there is a basic defect in Redox potential, relative energy deficiency will produce axoplasmic swelling, compressing small vessels and initiating the aforementioned self- destructive cycle. In regards to LHON, a great deal of progress in / Nfunt- Ophthalmol, Vol. 14. No. 1, 1994 ANNUAL REVIEW: THE ANTERIOR VISUAL PATHWAYS 145 the genetics of the disease has been made recently. However, this is likely to be the subject of another review in these same pages. One item of general interest regarding LHON is that now that DNA testing is available, a number of patients who are diagnosed to have other optic neuropathies have turned out to have actually had LHON. For exam­ple, a case is described in which ischemic optic neuropathy was originally diagnosed in each of the two eyes of a 63- year- old patient; upon subse­quent mitochondrial DNA studies, the patient was found to have a 11778 point mutation ( 38). More often, however, LHON is mistakenly diagnosed as a metabolic or toxic optic neuropathy. It is notable that patients previously thought to have tobacco-alcohol amblyopia have often turned out to have a primary mutation for LHON. Two of 12 patients previously diagnosed to have tobacco- alcohol am­blyopia were subsequently tested and found to have the 11778 and 3460 mutations, respectively ( 39). The authors point out that, given the similar clinical characteristics of the two diseases and the possibly related pathogenesis, the diagnoses might well be confused and it is appropriate to obtain molecular genetic testing on all patients thought to have tobacco- alcohol amblyopia. How­ever, of equal interest is that LHON associated DNA mutations may render patients more suscep­tible to epigenetic factors such as tobacco and al­cohol. Perhaps we can add Cuban rum and Cuban dietary deficiencies to these epigenetic factors. Similar evidence that epigenetic factors may trig­ger an optic neuropathy in which the underlying disease is LHON comes from a case report of a nine- year- old girl in whom juvenile onset diabetes had been recently diagnosed ( 40). Over a four month period she experienced a fairly rapid loss of vision in both eyes which was clearly due to an optic neuropathy. Because there was a positive family history for LHON, blood samples were tested and found to be positive for the mitochon­drial DNA marker. Of further interest is the fact that once her hypoglycemia was stabilized, she had a fairly significant improvement in vision, and the authors concluded that her diabetes was the metabolic trigger for a premature decompensation of her LHON ( 40). Similarly, there is a report of five patients ( ages 9 to 45 years) with the 11778 mutation of LHON who suffered a loss of vision and then, over a period of months to years, had significant visual recovery ( 41). These five patients represent only 3.7% of the 136 patients with the LHON mutation who were being reviewed, so this is the exception for visual recovery and not the rule. Nonetheless, it does provide some hope for patients with LHON ( 41). Of course, it should be kept in mind that a patient with LHON may have homoplasmy ( all of their mitochondria carry the genetic defect) or heteroplasmy ( in which there is a mixture of mutated and non- mutated mitochon­dria). In the evaluation of a large series of families with the 11778 mutation, it was determined that 14% were heteroplasmic for the defect ( 42). It is interesting that heteroplasmic individuals do not differ in the clinical severity of their disease from homoplasmic patients. Apparently whether one has mitochondrial induced decompensation is an " all- or- none" phenomenon. In the same journal issue, these authors also describe identical twin brothers with the genetic makeup to develop LHON who, of course, harbored the identical ho­moplasmic DNA mutation. Nonetheless, one twin had visual losses down to the 1/ 200 level in both eyes while the other's vision remained 20/ 15 in both eyes ( 43). This description of two genetically identical individuals with extremely different symptomatology further emphasizes the impor­tance of epigenetic factors and the " all- or- none" nature of LHON. Also in the same issue, two of the authors described a maculopathy seen with the 15257 DNA mutation previously associated only with LHON ( 44). The maculopathy appeared very much like Stargardt's disease. Is it surprising that other tissues are also very susceptible to mitochon­drial insufficiency? Is it possible that this is a non­specific ocular tissue response that is specific to the 15257 mutation? In spite of our insights into the genetics of LHON and the metabolic perturbations possible, more is being learned about the association, or lack thereof, with classical epigenetic factors. Rizzo and Lessell ( 45) have revisited the issue of tobacco am­blyopia. They made the diagnosis in two patients in whom there was no other risk factor ( such as alcoholism or vitamin deficiency) ( 45). They con­cluded that if used in sufficient quantity and type ( such as 15 large cigars daily or 5 ounces of pipe tobacco per week), tobacco alone can lead to a largely reversible papillomacular bundle injury. I have also noted that a very large percentage of my patients with tobacco- alcohol amblyopia smoked cigars or pipes. It pays to remember that cigarette smoking is a rare cause of so- called tobacco ambly­opia. The concept of a disc at risk applies to other congenital optic neuropathies as well. Twenty- five patients from three pedigrees with dominant optic atrophy ( Kjer's disease) were described ( 46). As opposed to Leber's, these patients did much better in that the progression of vision began slowly and / Neuro- Ophlhalnwl. Vol. 14, No. 3. 1994 U6 A. A. SADUN AND }. DAO then stabilized and that visual acuities averaged in the 20/ 60 to 20/ 80 range ( 46). Optic nerve sheath decompressions for disc edema entered a new era with the publications of Brourman and colleagues ( 47), Sergott and col­leagues ( 48), and Corbett and colleagues ( 49). In the same issue of Archives of Ophthalmology all three groups described their success in treating the papilledema of pseudotumor cerebri by optic nerve sheath decompression. Also in this issue, Keltner ( 50) explored the mechanisms by which this operation works and recommended it in cases of pseudotumor cerebri for which medical therapy had failed. The mechanisms by which optic nerve sheath decompression might work for other diseases, however, were contested far more hotly after Ser­gott and colleagues suggested that optic nerve sheath decompression would also improve the vi­sual course in the progressive cascade form of AION ( 51). They described visual improvement in 12 of 14 eyes with the progressive form, but did not advocate surgery for the nonprogressive form of AION. Spoor and colleagues ( 52) confirmed the success of optic nerve sheath decompression for progressive AION and at about the same time Kel-man and Elman ( 53) suggested that the operation had merit for even nonprogressive forms of AION. The prevailing theory as expounded by the advo­cates of this surgery is that reducing the subarach­noid fluid pressure might gently nudge the deli­cate balance of forces in such a way as to improve local vascular perfusion and relieve the impaired axoplasmic transport ( 48). However, as Hayreh has pointed out, axoplasmic stasis is not per se a cause of visual loss ( 54). Moreover, the ischemic injury of AION occurs at the level of the lamina cribrosa, where the optic nerve head receives its blood supply from the peripapillary choroid, yet the surgery is performed several millimeters pos­terior to this, and not in any area related to the vascular supply of the peripapillary choroid ( 55). In his review of optic nerve sheath decompression for anterior ischemic optic neuropathy as well as other optic neuropathies, Sadun evaluated several possible mechanisms by which the fenestration might work and discussed the strengths and weak­nesses of several of the articles that contended that the operation was useful ( 55). A letter by Drs. McHenry and Spoor ( 56) added their experience with over 400 optic nerve sheath decompressions that they performed for anterior ischemic optic neuropathy. They contended that the procedure is most likely to work in those optic nerves in which high CSF pressure produced a subarachnoid dila­tation. Sadun ( 57) replied that there still was no adequate scientific rationale for how a change in the pressure dynamics 5 mm behind the lamina cribrosa could affect blood flow at the level of the lamina. In corroboration of the concept that optic nerve sheath decompression ( ONSD) could improve blood flow in AION, 25 patients were studied with color Doppler imaging before and after optic nerve sheath decompression ( 58). Using this methodol­ogy the authors were able to demonstrate signifi­cantly lower blood flow velocities in the central retinal artery before surgery, and a significant in­crease in blood flow velocities in both the ophthal­mic and central retinal arteries after surgery ( 58). Although they suggested that their study demon­strated that optic nerve sheath decompression im­proved blood flow to an ischemic optic nerve, it should be kept in mind that blood flow velocity is not the same thing as blood flow ( and indeed there are circumstances in which velocity may go up as resistance increases and there is thus a decrease in blood flow). The same authors found that in the 13 eyes with AION that had improved vision after optic nerve sheath decompression, there was also a concomitant improvement in blood flow velocity in the short posterior ciliary arteries; but in those eyes in which vision did not improve, color Dop­pler failed to reveal increases in blood flow veloc­ity, lending further support to color Doppler as a means of monitoring blood flow dynamics ( 58). Hayreh and Beach ( 59) discussed this paper in open forum and suggested that some of the as­sumptions made about color Doppler imaging may have been incorrect and some of the theoretical explanations for how optic nerve sheath decom­pression could improve blood flow dynamics were scientifically unfounded. Color Doppler studies were performed on 24 eyes in patients in whom there was visual loss due to pseudotumor cerebri ( 60). Improvements in blood flow parameters post decompression were documented ( 60). Several ar­ticles have questioned the use of optic nerve sheath decompression for AION for several rea­sons. Hayreh ( 54) feels that the pressure dynamics described by Sergott and colleagues ( 51) are in er­ror. Others have contended that in the natural course of nonarteritic ischemic optic neuropathy, the percentage of patients who improve is not sig­nificantly different from that of patients who have undergone optic nerve sheath decompression ( 61). Others have noted that optic nerve sheath decom­pression may not be as complication- free as ini­tially reported ( 62). Nonetheless, Sergott and his colleagues have ; Nt'uro- Ophthalmol. Vol. 14, N » . .3, 1994 ANNUAL REVIEW: THE ANTERIOR VISUAL PATHWAYS 147 maintained that optic nerve sheath decompression might improve blood flow dynamics in ischemic disease, that the operation does have great prom­ise, and that the complication rate is fairly low ( 63,64). More recently, several articles have ques­tioned the contention that optic nerve sheath de­compression improves visual function in patients with AION, and have suggested that the rate of improvement attributed to the surgery is no greater than that seen spontaneously ( 65- 68). In response to articles describing spontaneous im­provements in progressive and nonprogressive AION has come a plea from a surgeon who feels that patients should receive the benefit of the doubt and be offered optic nerve sheath decom­pression, and that the spontaneous recoveries might have had an even better outcome had the surgery been performed ( 69,70). This is unlikely, however, since patients treated with optic nerve sheath decompression may show improvements in visual acuity and in visual field ( 69,70). Vascular/ mechanical factors are at the heart of the contro­versy regarding the pathophysiology of nonar-teritic AION. Sadun ( 55), in reviewing the efficacy of optic nerve sheath decompression for AION, discussed the proposal that in at least some cases of AION, a rise in optic disc perineural pressure was involved in a vicious circle of impaired perfu­sion led to blocked axonal transport leading to in­creased pressure at the level of the lamina cribrosa. It was theorized that optic nerve sheath decom­pression might tip this delicate balance of forces and pressures in a favorable direction ( 55,63). This controversy regarding the efficacy of optic nerve sheath decompression for AION was further fu­eled by the publications of Sergott et al ( 64), McHenry and Spoor ( 65), Jablons et al ( 66), and Movasas et al ( 61). In an effort to resolve many of these questions, the NIH has funded a multi- center randomized clinical trial entitled the Ischemic Optic Neuropa­thy Decompression Trial to be conducted in 26 US clinical sites. It is hoped that this trial will at least answer the question as to whether patients who undergo optic nerve sheath decompression have a greater likelihood of visual recovery than do pa­tients whose disease is allowed to follow its natural course ( 71). Additionally, the trial should reveal the complication rates. The trial will probably not discern differences between patients with and without the progressive form of AION. However, even if this trial demonstrates efficacy for ONSD in AION, the absence of a strong scientific rationale will leave many of us feeling disconcerted ( 72- 74). A new method of performing optic nerve sheath decompression from the lateral side, without go­ing through bone, was presented ( 75). Surgery is performed through a large lateral canthotomy in­cision and the optic nerve is approached on the lateral side ( 75). Additionally, several modifica­tions of optic nerve sheath decompression have been suggested, including the use of adjunctive mitomycin and even implantation of a Molteno tube in the subarachnoid space ( 76). For patients in whom optic nerve sheath decompression has failed to relieve the disc edema associated with pseudotumor cerebri, two orbital surgeons have suggested that a secondary optic nerve sheath de­compression be performed on the other side ( 77). Since the usual first procedure is a transconjuncti­val medial approach these authors suggest follow­ing with a lateral approach, with or without re­moval of orbital bone, in those cases in which disc edema persists ( 77). Given the controversy surrounding optic nerve sheath decompression per se, it is not surprising that several letters have been exchanged regarding the use of optic nerve sheath decompression for patients with pseudotumor cerebri who show pro­gressive visual loss even in the presence of func­tioning lumboperitoneal shunts. Wall advises that lumboperitoneal shunts may function on an inter­mittent basis, and might, with revision, prevent further visual deterioration ( 78). In pseudotumor cerebri syndrome, the cause may be obstruction of the dural sinuses. Four cases have been described in which optic nerve sheath decompression led to resolution of disc edema and improvement in vi­sion in patients with dural sinus occlusion ( 79). Despite the prompt resolution of disc edema and visual field defects, it is very interesting to note that three of these four patients continued to have elevated cerebrospinal fluid pressure, suggesting that optic nerve sheath decompression has more of a local and less of a global effect. Optic nerve sheath decompression has also been suggested as a treatment in visual loss associated with other diseases. For example, Garrity and col­leagues ( 80) suggest the use of this operation to treat the papilledema that can occur following CNS infection with cryptococcus. In addition to describ­ing an initially favorable post operative clinical course, they published the autopsy findings on one patient who had had optic nerve sheath sur­gery; this showed optic nerve sheath fenestrations that were still patent ( 80). Further evidence of the patency of fenestrations following optic nerve sheath decompression was offered by Hamed and colleagues ( 81) who used neuroimaging of the op­tic nerve in two patients who had undergone optic ; Neuro- Ophthalmol. Vol. 14, No. 3, 1994 148 A. A. SADUN AND }. DAO nerve sheath decompression for pseudotumor cerebri. Both ultrasound and gadolinium MRI sug­gested that each had a cyst- like structure on the outside of the fenestration site that was contiguous with the subarachnoid space, suggestive of a glau­coma type filtering bleb ( 81). Optic nerve sheath decompression has also been suggested as a treatment for low tension glaucoma ( 82). Seven eyes of six patients with low tension glaucoma underwent optic nerve sheath decom­pression; two eyes showed some initial improve­ment but later deteriorated ( 82). This, along with the fact that the other eyes showed no improve­ment, raises the question as to the efficacy of the treatment for this ambiguous disease. Nonarteritic anterior ischemic optic neuropathy received attention outside of the arena of optic nerve sheath decompression as well. Katz and Spencer ( 83) revisited the notion that crowding of the optic nerve head is a precondition for AION, and found a small statistical correlation with hy­peropia as a risk factor ( 83). It remains unclear whether hyperopia predisposes for the develop­ment of AION, or whether myopia is protective of the development of AION. The mechanism of ischemia in acute nonarteritic AION was explored again by fluorescein angiography ( 84). While a de­lay in optic disc perfusion was noted, there was no delay in peripapillary choroidal filling ( 84). Rader and colleagues noted focal constriction of retinal arteries near the optic disc in both AION and a variety of glaucomas ( 85). Control eyes had only a 57B risk of such constriction; patients with glaucoma had a 42% risk of such constriction, and patients with nonarteritic AION had a 687c likeli­hood of such constriction ( 85). A population- based study comparing the inci­dence of AION, arteritic and nonarteritic, in the state of Missouri and Los Angeles County, Califor­nia was reported ( 86). While the incidence of AION appears to be slightly higher in Los Angeles County, the overall differences were not that great. For patients 50 or older, the annual inci­dence rate of arteritic anterior ischemic optic neu­ropathy was 0.35 per hundred thousand people and for nonarteritic AION it was 2.30 ( 86). Arteritic cases were three times more likely to occur in women than in men whereas nonarteritic cases had no sexual predilection. There was an increased incidence of nonarteritic AION among whites which is particularly interesting given that blacks had a higher incidence of strokes ( 86). While in the last couple of years the subject of nonarteritic AION has been approached from a " disc at risk" point of view which takes into ac­count mechanical as well as vascular factors ( 20,24), progress has been made also using the old fashioned concept that AION is, in some cases a form of stroke of the optic nerve. Connolly and colleagues ( 87) showed that in three patients in whom hypotension had probably caused AION, an immediate and controlled rise in blood pressure brought considerable recovery of vision ( 87). This work is of considerable interest since it: 1) empha­sizes the danger of iatrogenic hypotension; 2) pro­vides a model for treating patients in whom hy­potension has induced AION; and 3) reminds us that Hayreh ( 54,59) had previously proposed that nocturnal hypotension may be a frequent cause of AION. Slavin and Barondes ( 88) have pointed out that giant cell arteritic AION may first present with choroidal ischemia. In these cases, the first visual symptoms may not be accompanied by ischemic disc swelling. Fluorescein angiography demon­strated choroidal infarcts ( 88). A 47- year- old man experienced acute loss of vision due to giant cell arteritis. As before fluorescein angiography dem­onstrated choroidal nonperfusion ( 89), this patient had pallid swelling and blockage of a branch reti­nal arteriole. The patient was treated with high dose IV methylprednisolone therapy which may have been of benefit, as visual acuity went from light perception to 20/ 30 over a two month period ( 89). A retrospective five year review of the visual outcome in patients with giant cell arteritis seen at the Mayo Clinic revealed 245 patients of which only 14 had permanent visual loss. Two patients suffered permanent visual loss following initiation of corticosteroid therapy ( 90). Also of interest was the fact that only five patients ( 27c) showed signif­icant improvement in vision following corticoste­roid therapy. In another report, four patients were described in whom giant cell arteritis produced an ocular ischemic syndrome ( 91). In addition to the usual optic disc and retinal changes, these patients had hypotony, uveitis, and corneal edema ( 91). Visual recovery following devastating ischemia of the optic disc has been described in two differ­ent settings. The first was that of giant cell arteritis, which affected two patients and brought their vi­sion down to no light perception following central retinal artery occlusions ( CRAO) ( 92). Each re­ceived high doses of intravenous corticosteroids and, within a day each demonstrated a remarkable recovery of vision that returned essentially to base­line ( 92). Hence, " megadose IV corticosteroid ther­apy" may be useful in a variety of optic neuropa­thies ( 93,94). These two cases are also of interest as / Ncuw- Oplithalmol. Vol. 14. No. .1, 1994 ANNUAL REVIEW: THE ANTERIOR VISUAL PATHWAYS 149 a challenge to the dictum that the retina can sur­vive only ninety minutes following a central retinal artery occlusion. Visual recovery was also attained following mi-crocatheter infusion of urokinase into the ophthal­mic artery in patients with nonarteritic central ret­inal artery occlusion ( 95). However, as described in a series of 14 consecutive CRAO, patients did not have giant cells arteritis ( 94). Eleven of 14 patients were treated with urokinase; the other three pa­tients received tissue plasminogen activator. Sig­nificant improvement was noted in four of these patients and modest improvements in visual acu­ity in another five; hence 9 of 14 were significantly better than the outcomes of a control group of forty- one patients with CRAO in whom no inter­vention was attempted. Central retinal artery oc­clusions do not usually carry a good prognosis. Such a case was presented of CRAO following va­ricella infection in a child ( 96). It is likely that the varicella led to a vasculitis. Ischemia of the optic disc and surrounding tissues may also be indirectly inferred by color Doppler imaging. This new tech­nique was used to study 21 patients with high grade carotid stenosis who had ocular ischemic syndrome ( 97). Reduced central retinal artery peak systolic blood flow velocity, as well as reversal of the oph­thalmic artery flow was found in 12 eyes. Reversal of flow was found to correlate with visual acuity ( 97). Two interesting anomalies of peripapillary ves­sels were recently described. The veins of Kraupa are an anomaly found at the optic disc in which a single venous trunk branches at the margin of the disc instead of in the middle of the optic disc ( 98). Two cases are described in which fluorescein an­giograms clearly delineate these abnormal retinal veins that exit the eye at or near the optic disc margin ( 98). Another peripapillary vascular anom­aly is that of " Nettleship collaterals," which is a ring of anastomotic channels that is thought to de­velop due to chronic prelaminar obstruction of the central retinal artery ( 99). In a study of ocular pneumotonometry, it was shown that large pulse amplitude correlated with the presence of spontaneous retinal venous pulsa­tions ( 100). Furthermore, the presence of veins looping over the edge of the neural rim into a deep optic cup ( termed configuration A) was highly cor­related with the presence of retinal venous pulsa­tion, whereas a shallow or nonexistent cup was rarely seen in patients with spontaneous venous pulsation ( 100). It remains to be seen whether this relates to the concept of " disc at risk" ( 20). Nine young adults about 20 years of age had transient obscurations of vision in one eye that were indistinguishable from the amaurosis fugax usually associated with carotid or cardiac dis­ease in older patients ( 101). Thorough evaluations failed to reveal any abnormalities of embolic or atheromatous etiology. The authors concluded that this condition was distinct from that seen in older patients, was probably benign and possibly due to migrainous or other vasospasm related im­pairments of the choroidal circulation ( 101). A case was presented of a 58- year- old man with abrupt unilateral loss of vision in whom a retractile body was seen in a retinal arteriole. This provided a launching point for discussing the results of the North American Symptomatic Carotid Endarterec-tomy Trial ( 102). Papillitis and papilledema are not the only causes of a large blindspot. Acute idiopathic blind-spot enlargement has been described in which the optic nerve head may appear entirely normal, but there is an associated multiple evanescent white dot syndrome ( MEWDS). Although cases of acute idiopathic blindspot syndrome usually resolve over a period of one to three years, a recent case was described in which enlarged blindspots per­sisted for over six years due to bilateral acute idio­pathic blindspot enlargement ( 103). The presence of peripapillary atrophy suggested to the authors that the etiology of this rare syndrome may be re­lated to chronic RPE damage ( 103). Seven patients with acute idiopathic blindspot enlargement syn­drome were described as having multifocal cho­roiditis and choroidal neovascularization ( 104). We are reminded that the multiple evanescent white dot syndrome ( MEWDS) probably reflects a spec­trum of multifocal choroiditis that may or may not involve the peripapillary area. Papillophlebitis is one of several causes of an enlarged blindspot, sometimes with loss of central vision that are gen­erally benign conditions. A case of a pregnant woman in whom papillophlebitis led to an arteri­olar occlusion was described ( 105). This patient did not have eclampsia; however, because of her eye findings she underwent Cesarean section and then a three- day course of high dose corticosteroid ther­apy that led to complete resolution of findings and a return of vision to 20/ 20 ( 105). It is hard to say whether this good outcome was a consequence of the termination of the pregnancy, the corticoste­roids, or just good luck. Another patient was described in whom a slow growing presumed pigmented mass was believed to be a melanocytoma. Finally the patient had vi­sual loss and enucleation ( 106). Histopathologic examination demonstrated the presence of a pri­mary malignant melanoma ( 106). ; Neuro- Ophthalmol. Vol. U, No. 3, 2994 150 A. A. SADUN AND /. DAO Anomalies of the optic disc may sometimes be the sentinel of more generalized disease. Optic nerve head medullation ( myelinated nerve fiber layer in the peripapillary region) has been de­scribed in a mother and daughter in whom there were also musculoskeletal abnormalities ( one fin­ger per hand and lobster- claw feet), and in a ped­igree of a retinitis pigmentosa- like syndrome asso­ciated with severe degeneration of the vitreous ( 107). Because only two members of this family were identified, it was impossible to establish the mode of inheritance. A variety of disc abnormalities were described in children with cerebral malaria ( 108). The most common finding was disc edema, but in addition hemorrhages and macular edema were described. Patients with disc edema had a grim prognosis ei­ther dying or developing serious neurologic con­sequences ( 108). Two patients are described who had optic drusen accompanied by abrupt loss of visual field ( 109). The youth of these patients ( 18 and 29) and the optic disc features at the time of visual loss made the diagnosis of AION untenable. This pa­per reminds us that the two dictas relating to optic disc drusen are not absolute. These dicta are: 1) that the visual field loss is very slow and progres­sive; and 2) that central acuity is always main­tained. In the discussion following this paper, Miller ( 110) describes sudden visual field loss in a patient with optic disc drusen in whom no other clear- cut diagnosis was found. A review of 16 pa­tients with drusen seen in 26 eyes revealed that abnormalities of the pattern visual evoked re­sponse could be demonstrated even in patients without significant visual field loss ( 111). How­ever, given that there is no treatment for the visual dysfunction associated with optic disc drusen, the development of a sensitive early screening test is more of academic than clinical interest. Fifteen- year- old male identical twins and an older sister were noted to have a superior seg­mented optic disc hypoplasia with associated infe­rior visual field defects ( 112). It is of note that their mother has insulin- dependent diabetes mellitus, a metabolic abnormality when present during preg­nancy that has been shown to be associated with segmental optic nerve hypoplasia in their offspring ( 113). This and other neuro- ophthalmic complica­tions of diabetes mellitus were summarized very nicely in a review by Burde ( 113). Forty children with unilateral or bilateral optic nerve hypoplasia were retrospectively studied ( 114). The majority of these patients had an absent septum pellucidum. On the basis of the associated neuroradiological abnormalities, the authors con­struct a categorizational system for the neurologi­cal signs associated with optic nerve hypoplasia. Optic nerve aplasia probably represents a rare ex­treme of the spectrum of optic nerve hypoplasia. In a 3- year- old girl with microphthalmos the vi­sual evoked response showed a much stronger sig­nal from the ipsilateral cerebral cortex, which the authors suggest represents an anomalous connec­tion of temporal retinal fibers from the normal eye ( 115). However, insofar as there are numerous re­ciprocal excitatory and inhibitory connections be­tween the primary visual nuclei and the visual cor­tex, this physiological anomaly may reflect a dis-inhibition phenomenon instead. Two patients are described with morning glory syndrome and pituitary dwarfism ( 116) accompa­nied by a discussion of the occasional association with midline craniofacial and neurological disor­ders. Dailey and colleagues described an optic disc anomaly that resembled morning glory syndrome but was without disc glial tissue and had a peri­papillary choroidal neovascular membrane ( 117). The diagnosis of Beauvieux's syndrome is based upon the dirty grayish appearance of the optic disc on ophthalmological examination of very young infants who have bilateral amaurosis and absent pupillary reflexes. Fifteen patients are described who presented with poor vision at birth and in whom the optic nerve heads had this grayish ap­pearance ( 118). Fortunately, vision improves and the disks " normalize." Visual acuity improved in these cases to the 20/ 40 to the 20/ 200 range. This condition is thought to be due to delayed optic nerve myelination. In one patient, MRI scanning revealed other areas of the brain which had not myelinated well, and three patients had albinism. The growth, development and sizes of optic disks were studied at autopsy in 95 patients rang­ing from five months gestation to 22 years of age ( 119). It was found that 50% of the growth of the optic disc occurred by 20 weeks of gestation, 75% by birth and 95% by age one year. An important study correlated the optic area with measures of the retinal surface area and counts of retinal rods and retinal cones ( 120). There was a remarkable range in the number of receptor cells found, from 40 to 80 million rods. A linear relationship between optic disc area and the numbers of rods and cones was noted. Other investigations morphometrically analyzed the optic disc and related its area to optic nerve fiber counts ( 121). These investigators examined 72 optic nerves and, with the assistance of computer­ized image analysis, found a very strong correla- / Neuro- Ophthalmol, Vol. 14, No. 3, 3994 ANNUAL REVIEW: THE ANTERIOR VISUAL PATHWAYS 151 tion between nerve fiber count and optic disc area. Perhaps of equal importance is the fact that they found that in smaller disks there was a selective decrease in the number of smaller fibers ( 121). Patients with optic disc pits and serous macular detachments were treated with gas tamponade ( 122). While vitreo- retinal surgery helped preserve visual acuity, anatomically, the gas tamponade did not close the inner retinal layer separation or pre­clude the flow of fluid from the optic disc pit. In addition to the esoteric, were publications of the common. We were reminded that the most common form of disc anomaly is disc edema due to increased intracranial pressure ( papilledema). A case of papilledema in a 16- year- old obese girl with pseudotumor cerebri was described whose visual loss was abrupt ( 123). The authors ascribed this sudden loss to a retinal arteriole occlusion caused by compression in a crowded edematous optic disc ( 123). Disc edema due to increased intracranial pressure with normal cerebrospinal fluid constru-ents and a normal MRI is a good definition of pseu­dotumor cerebri syndrome, yet in some cases the definitive diagnosis may reveal itself later. A case is described in which such a patient went on to have moderate visual loss and optic atrophy, and only one year later was the diagnosis of malignant ependymoma of the spinal cord made ( 124). New­man ( 125) described a case of shunt failure in con­genital hydrocephalus, and Sedwick and Boghen commented on the proper workup and manage­ment of such cases. In this case, the papilledema went undetected for a long time because no one bothered to do ophthalmoscopy. This patient suf­fered devastating and permanent bilateral visual loss. It is incumbent on the treating physicians to ensure adequate follow- up. REFERENCES 1. Schumer RA, Podos SM. The nerve of glaucoma! Arch Ophthalmol 1994; 112: 37- 44. 2. Serle JB, Schmidt KG, Mittag TW, et al. Nifedipine and ocular blood flow. Invest Ophthalmol Vis Sci 1992; 33( Suppl): 1279. 3. Netland PA, Chaturvedi N, Dreyer EB. Calcium channel blockers in the management of low- tension and open-angle glaucoma. Am } Ophthalmol 1993; 115: 608- 13. 4. Steven SCF. NMDA receptors: on to molecular mecha­nisms. Nature 1992; 358: 18- 19. 5. Albers GW, Goldberg MP, Choi DW. Do NMDA antago­nists prevent neuronal injury? Yes. Arch Neurol 1992; 49: 418- 20. 6. Siliprandi R, Canella R, Carmignoto G, et al. N- methyl- D-aspartate- induced neurotoxicity in the adult rat retina. Vis Neurosci 1992; 8: 567- 73. 7. Harrison MJG. Protection against ischaemia: the bias of acute stroke therapy. Curr Opin Neurol Neurosurg 1992; 5: 33- 8. 8. Chao CC, Hu S, Molitor TW, Shaskan EG, Peterson PK. Activated microglia mediate neuronal cell injury via a ni­tric oxide mechanism. / Immunol 1992; 149: 2736^ 41. 9. Wallis RA, Panizzon K, Wasterlain CG. Inhibition of nitric oxide synthase protects against hypoxic neuronal injury. Neuroreport 1992; 3: 645- 8. 10. Verma A, Hirsch DJ, Glatt CE, et al. Carbon monoxide: aputative neural messenger. Science 1993; 34( Suppl): 826. 11. Geyer O, Podos SM, Mittag TW. Nitric oxide synthase: distribution and biochemical properties of the enzyme in the bovine eye. Invest Ophthalmol Vis Sci 1993; 34( Suppl): 826. 12. Szabo ME, Droy- Lefaix MT, Doly M, Braquet P. Ischemia-and reperfusion- induced Na + , K + , Ca2 and Mg2 + shifts in rat retina: effects of two free radical scavengers, SOD and EGB 761. Exp Eye Res 1992; 55: 39- 45. 13. Szabo ME, Droy- Lefair MT, Doly M, Braquet P, Modifica­tion of ischaemia/ reperfusion- induced ion shifts ( Na + , K + , Ca2 * and Mg2 + ) by free radical scavengers in the rat retina. Ophthalmic Res 1993; 25: 1- 9. 14. Nayak MS, Kita M, Marmor MF. Protection of rabbit retina from ischemic injury by superoxide dismutase and cata-lase. Invest Ophthalmol Vis Sci 1993; 34: 2018- 22. 15. Kashii S, Takahashi M, Mandai M, et al. Protective action of dopamine against glutamate neurotoxicity in the retina. Invest Ophthalmol Vis Sci 1994; 35: 685- 95. 16. Unoki K, LaVail MM. Protection of the rat retina from ischemic injury by brain- derived neurotrophic factor, cili­ary neurotrophic factor, and basic fibroblast growth factor. Invest Ophthalmol Vis Sci 1994; 35: 907- 15. 17. Barletta JP, Fanous MM, Hamed LM. Temporary blind­ness in the TUR syndrome. / Neuro- ophthalmol 1994; 14: 6- 8. 18. Halperin LS. Neuroretinitis due to seronegative syphilis associated with human immunodeficiency virus. / Clin Neuro- ophthalmol 1992; 12: 171- 2. 19. Heher KL, Traboulsi El, Maumenee 1H. The natural his­tory of Leber's congenital amaurosis: aged- related find­ings in 35 patients. Ophthalmology 1992; 99: 241- 5. 20. Vine AK. Severe periphlebitis, peripheral retinal ischemia, and preretinal neovascularization in patients with multi­ple sclerosis. Am / Ophthalmol 1992; 113: 28- 32. 21. Ulrich GG, Waecker NJ Jr, Meister SJ, et al. Cat scratch disease associated with neuroretinitis in a 6- year- old girl. Ophthalmology 1992; 99: 246- 9. 22. Capone A Jr, Meredith TA. Central visual loss caused by chickenpox retinitis in a 2- year- old child. Am J Ophthalmol 1992: 113: 592- 3. 23. Gass JDM, Callanan DG, Bowman CB. Oral therapy in diffuse unilateral subacute neuroretinitis. Arch Ophthalmol 1992; 110: 675- 80. 24. Fish RH, Hoskins JC, Kline LB. Toxoplasmosis neurore­tinitis. Ophthalmology 1993; 100: 1177- 82. 25. Dukar O, Barr CC. Visual loss complicating OKT3 mono­clonal antibody therapy. Am J Ophthalmol 1993; 115: 781- 5. 26. Thirkill CE, Tait RC, Tyler NK, et al. The cancer- associated retinopathy antigen is a recoverin- like protein. Invest Oph­thalmol Vis Sci 1992; 33: 2768- 72. 27. Keltner JL, Thirkill CE, Tyler NK, Roth AM. Management and monitoring of cancer- associated retinopathy. Arch Ophtlialmol 1992; 110: 48- 53. 28. Thirkill CE, Keltner JL, Tyler NK, Roth AM. Antibody reactions with retina and cancer- associated antigens in 10 patients with cancer- associated retinopathy. Arch Ophthal­mol 1993,111: 931- 7. 29. Quillen DA, Cantore WA, Schwartz SR, et al. Choroidal nonperfusion in giant cell arteritis. Am ) Ophthalmol 1993; 116: 171- 5. 30. Glazer LC, Han DP, Gottlieb MS. Choroidal rupture and optic atrophy. Br / Ophthalmol 1993; 77: 33- 5. 31. Burde RM. Optic disc risk factors for nonarteritic anterior ischemic optic neuropathy. Am ] Ophthalmol 1993; 116: 759- 64. 32. Sadun AA, Martone JF, Reyes L, DuBois L, Roman GC, / Neuro- Ophthalmol, Vol. 14, No. 3, 7994 152 A. A. SADUN AND ]. DAO Caballero B, response to Lincoff NS, Odel JG, Hirano M: " Outbreak" of Optic and Peripheral Neuropathy in Cuba? JAMA 1994; 271: 663- 4. 33. Lincoff NS, Odel JG, Hirano M. " Outbreak" of optic and peripheral neuropathy in Cuba? JAMA 1993; 270: 511- 8. 34. Sadun AA, Martone, JF, Muci- Mendoza R, et al. Epidemic optic neuropathy in Cuba: eye findings. Arch Ophthalmol 1994; 112: 691- 9. 35. Tucker K, Hedges T. Food shortages and an epidemic of optic and peripheral neuropathy in Cuba. Nutr Rev 1993; 51: 349- 57. 36. Johns D, Sadun AA. Cuban epidemic optic neuropathy: mitochondrial DNA analysis. / Neuro Opthalmol 1994, in press. 37. Vine AK. Samama MM. The role of abnormalities in the anticoagulant and fibrinolytic systems in retinal vascular occlusions. Surv Ophthalmol 1993; 37: 283- 92. 38. Borruat FX, Green WT, Graham EM, et al. Late onset Leb­er's optic neuropathy: a case confused with ischaemic op­tic neuropathy. Br / Ophthalmol 1992; 76: 571- 3. 39. Cullom ME, Heher KL, Miller NR, et al. Leber's hereditary optic neuropathy masquerading as tobacco- alcohol ambly­opia. Arch Ophthalmol 1993; 111: 1482- 5. 40. DuBois LG, Feldon SE. Evidence of a metabolic trigger for Leber's hereditary optic neuropathy a case report. / Clin Neuro- ophthalmol 1992; 12: 15- 16. 41. Stone EM, Newman NJ, Miller NR, Johns DR, et al. Visual recovery in patients with Leber's hereditary optic neurop­athy and the 11778 mutation. / Clin Neuro- ophthalmol 1992; 12: 10- 14. 42. Smith KH, Johns DR, Heher KL, Miller NR. Heteroplasmy in Leber's hereditary optic neuropathy. Arch Ophthalmol 1993; 111: 1486- 90. 43. Johns DR, Smith KH, Miller NR, et al. Identical twins who are discordant for Leber's hereditary optic neuropathy. Arch Ophthalmol 1993; 111: 1491- 4. 44. Heher KL, Johns DR. A maculopathy associated with the 15257 mitochondrial DNA mutation. Arch Ophthalmol 1993; 111: 1495- 9. 45. Rizzo JF 111, Lessell S. Tobacco amblyopia. Am j Ophthalmol 1993; 116: 84- 7. 46. Eliott D, Traboulsi EI, Maumenee IH. Visual prognosis in autosomal dominant optic atrophv ( Kjer type). Am / Oph­thalmol 1993; 115: 360- 7. 47. Brourman, ND, Spoor TC, Ramocki JM. Optic nerve sheath decompression for pseudotumor cerebri. Arch Oph­thalmol 1988; 106: 1378- 83. 48. Sergott RC, Savino PJ, Bosley TM. Modified optic nerve sheath decompression provides long- term visual improve­ment for pseudotumor cerebri. Arch Ophthalmol 1988; 106: 1384- 90. 49. Corbett JJ, Nerad JA, Tse DT, Anderson RL. Results of optic nerve sheath fenestration for pseudotumor cerebri. The lateral orbitotomy approach. Arch Ophthalmol 1988; 106: 1391- 7. 50. Keltner JL. Optic nerve sheath decompression. How does it work? Has its time come? ( editorial). Arch Ophthalmol 1988; 106: 1365- 9. 51. Sergott RC, Cohen MS, Bosley TM, Savino PJ. Optic nerve decompression may improve the progressive form of non-arteritic ischemic optic neuropathy. Arch Ophthalmol 1989; 107: 1743- 54. 52. Spoor TC, Wilkinson MJ, Ramocki JM. Optic nerve sheath decompression for the treatment of progressive nonar-teritic ischemic optic neuropathy. Am j Ophthalmol 1991; 109: 667. 53. Kelman SE, Elman MJ. Optic nerve sheath decompression for nonarteritic ischemic optic neuropathy improves mul­tiple visual function measurements. Arch Ophthalmol 1991; 109: 667- 71. 54. Hayreh SS, Beach KW. Discussion of Flaharty PM, Sergott RC, Lieb W, Bosley TM, Savino PJ. Optic nerve sheath decompression may improve blood flow in anterior isch­emic optic neuropathy. Ophthalmology 1993; 100: 303- 5. 55. Sadun AA. The efficacy of optic nerve sheath decompres­sion for anterior ischemic optic neuropathy and other op­tic neuropathies. Am / Ophthalmol 1993; 115: 384- 389. 56. McHenry JG, Spoor TC. The efficacy of optic nerve sheath decompression for anterior ischemic optic neuropathy and other optic neuropathies. Am j Ophthalmol 1993; 116: 254- 5. 57. Sadun AA. Reply to McHenry JG, Spoor TC. The efficacy of optic nerve sheath decompression for anterior ischemic optic neuropathy and other optic neuropathies. Am / Oph­thalmol 1993; 116: 255- 6. 58. Flaharty PM, Sergott RC, Lieb W, et al. Optic nerve sheath decompression may improve blood flow in anterior isch­emic optic neuropathy. Ophthalmology 1993; 100: 297- 302. 59. Hayreh SS. The role of optic nerve sheath fenestration in management of anterior ischemic optic neuropathy. Arch Ophthalmol 1990; 108: 1063- 4. 60. Mittra RA, Sergott RC, Flaharty PM, et al. Optic nerve decompression improves hemodynamic parameters in papilledema. Ophthalmology 1993; 100: 987- 97. 61. Movsas T, Kelman SE, Elman MJ, et al. The natural course of non- arteritic ischemic optic neuropathy. Invest Ophthal­mol Vis Sci 1991; 32( Suppl): 951. 62. Plotnik JL, Kosmorsky GS. Operative complications of op­tic nerve sheath decompression. Ophthalmology 1993; 100: 683- 90. 63. Flaharty PM, Sergott RC, Lieb W, et al. Optic nerve sheath decompression may improve blood flow in anterior isch­emic optic neuropathy. Ophthalmology 1993; 100: 297- 305. 64. Sergott RC, Savino PJ, Bosley TM. Optic nerve sheath de­compression: a clinical review and proposed pathophysi­ologic mechanism. Aust NZ / Ophthalmol 1990; 18: 365- 73. 65. Spoor TC, McHenry JG, Lau- Sickon L. Progressive and static nonarteritic ischemic optic neuropathy treated by optic nerve sheath decompression. Ophthalmology 1993; 100: 306- 11. 66. Jablons MM, Glaser JS, Schatz NJ, et al. Optic nerve sheath fenestration for treatment of progressive ischemic optic neuropathy: results in 26 patients Arch Ophthalmol 1993; 111: 84- 7. 67. Aiello AL, Sadun AA, Feldon SE. Spontaneous improve­ment of progressive anterior ischemic optic neuropathy: report of two cases. Arch Ophthalmol 1992; 110: 1197- 9. 68. Barrett DA, Glaser JS, Schatz NJ, Winterkorn JMS. Spon­taneous recovery of vision in progressive anterior ischemic optic neuropathy. / Clin Neuro- ophthalmol 1992; 12: 219- 25. 69. Kwitko GM. Save the optic nerve. Arch Ophthalmol 1993; 111: 300. 70. Aiello AL, Sadun AA, Feldon S. In reply to Kwitko GM. Save the optic nerve. Arch Ophthalmol 1993; 111: 300- 1. 71. Kelman SE. The ischemic optic neuropathy decompres­sion trial. Arch Ophthalmol 1993; 111: 1616- 8. ' 72. McHenry JG, Spoor TC. Optic nerve sheath fenestration for treatment of progressive ischemic optic neuropathy. Arch Ophthalmol 1993; 111: 1601. 73. Glaser JS, Jablons NM, Schat MJ, Frazier- Byrne F. In reply to McHenry, Spoor TC. Optic nerve sheath fenestration for treatment of progressive ischemic optic neuropathy. Arch Ophthalmol 1993; 111: 1601- 2. 74. Aiello AL, Sadun AA, Feldon SE. In reply to McHenry, Spoor TC. Optic nerve sheath fenestration for treatment of progressive ischemic optic neuropathy. Arch Ophthalmol 1993; 111: 1602- 3. 75. Kersten RC, Kulwin DR. Optic nerve sheath fenestration through a lateral canthotomy incision. Arch Ophthalmol 1993; 111: 870- 874. 76. Spoor TC, McHenry JG, Shin DH. Optic nerve sheath de­compression with adjunctive mitomycin and Molteno de­vice implantation. Arch Ophthalmol 1994; 112: 25- 6. 77. Anderson RL, Flaharty PM. Treatment of pseudotumor cerebri by primary and secondary optic nerve sheath de­compression. Am I Ophthalmol 1992; 113: 599- 600. / Neura- Ophtluilmol, Vol. 14, No. ^, 1994 ANNUAL REVIEW: THE ANTERIOR VISUAL PATHWAYS 153 78. Wall M. Nerve sheath decompression in patients with functioning shunts. Kelman S, Savino PJ, Elman MJ, Ser-gott RC, Bosley TM: Authors' reply. Ophthalmology 1992; 99: 480. 79. Horton JC, Seiff SR, Pitts LH, et al. Decompression of the optic nerve sheath for vision- threatening papilledema caused by dural sinus occlusion. Neurosurgery 1992; 31: 203- 12. 80. Garrity JA, Herman DC, Ime SR, et al. Optic nerve sheath decompression for visual loss in patients with acquired immunodeficiency syndrome and cryptococcal meningitis with papilledema. Am / Ophthalmol 1993; 116: 472- 8. 81. Hamed LM, Tse DT, Glaser JS, et al. Neuroimaging of the optic nerve after fenestration for management of pseudo­tumor cerebri. Arch Ophthalmol 1992; 110: 636- 9. 82. Wax MB, Barrett DA, Hart WM Jr, Custer PL. Optic nerve sheath decompression for glaucomatous optic neuropathy with normal intraocular pressure. Arch Ophthalmol 1993; 111: 1219- 28. 83. Katz B, Spencer WH. Hyperopia as a risk factor for non-arteritic anterior ischemic optic neuropathy. Am ] Ophthal­mol 1993; 116: 754- 8. 84. Arnold AC, Hepler RS. Fluorescein angiography in acute nonarteritic anterior ischemic optic neuropathy. Am j Oph­thalmol 1994; 117: 222- 30. 85. Rader J, Feuer W], Anderson DR. Peripapillary vasocon­striction in the glaucomas and in the anterior ischemic optic neuropathies. Am j Ophthalmol 1994; 117: 72- 80. 86. Johnson LN, Arnold AC. Incidence of nonarteritic and arteritic anterior ischemic optic neuropathy: population-based study in the state of Missouri and Los Angeles County, California. / Neuro- ophthalmol 1994; 14: 38- 44. 87. Connolly SE, Gordon KB, Horton JC. Salvage of vision after hypotension- induced ischemic optic neuropathy. Am I Ophthalmol 1994; 117: 235- 42. 88. Slavin ML, Barondes MJ. Visual loss caused by choroidal ischemia preceding anterior ischemic optic neuropathy in giant cell arteritis. Am / Ophthalmol 1994; 117: 81- 6. 89. Postel EA, Pollock SC. Recovery of vision in a 47- year- old man with fulminant giant cell arteritis. / Clin Neuro-ophthalmol 1993; 13: 262- 70. 90. Aiello PD, Trautmann JC, McPhee TJ, et al. Visual prog­nosis in giant cell arteritis. Ophthalmology 1993; 100: 550- 5. 91. Hamed LM, Guy JR, Moster ML, Bosley T. Giant cell ar­teritis in the ocular ischemic syndrome. Am j Ophthalmol 1992; 113: 702- 5. 92. Matzkin DC, Slamovits TL, Sachs R, Burde RM. Visual recovery in two patients after intravenous methylprednis-olone treatment of central retinal artery occlusion second­ary to giant- cell arteritis. Ophthalmology 1992; 99: 68- 71. 93. Clearkin LG, IV steroids for central retinal artery occlusion in giant- cell arteritis. Ophthalmology 1992; 99: 1482- 3. 94. Slamovits TL, Matzkin DC, Burde RM, Sachs R. Author's reply to Clearkin LG. IV steroids for central retinal artery occlusion in giant- cell arteritis. Ophthalmology 1992; 99: 1483- 4. 95. Schmidt D, Schumacher M, Wakhloo AK. Microcatheter urokinase infusion in central retinal artery occlusion. Am / Ophthalmol 1992; 113: 429- 34. 96. Cho N, Han H. Central retinal artery occlusion after vari­cella. Am I Ophthalmol 1992; 113: 591- 2. 97. Ho AC, Lieb WE, Flaharty PM, et al. Color Doppler im­aging of the ocular ischemic syndrome. Ophthalmology 1992; 99: 1453- 62. 98. Barroso L, Hoyt WF, Narahara M. Disc edge veins of Kraupa: rare exit anomalies of the retinal vein. Br ] Oph­thalmol 1992; 76: 442- 3. 99. Ragge NK, Hoyt WF. Nettleship collaterals: circumpapil-lary cilioretinal anastomoses after occlusion of the central retinal artery. Br ] Ophthalmol 1992; 76: 186- 8. 100. Hedges TR Jr, Baron EM, Hedges TR III, Sinclair SH. The retinal venous pulse, its relation to optic disc- charac­teristics and choroidal pulse. Ophthalmology 1994; 101: 542- 7. 101. O'Sullivan F, Rossor M, Elston JS. Amaurosis fugax in young people. Br ] Ophthalmol 1992; 76: 660- 2. 102. Slavin ML. Sudden visual loss with slow recovery; with comments by Wall M, Katz B. Surv Ophthalmol 1992; 37: 57- 62. 103. Cooper ML, Lesser RL. Prolonged course of bilateral acute idiopathic blind spot enlargement. / Clin Neuro- ophthalmol 1992; 12: 173- 7. 104. Callanan D, Gass JDM. Multifocal choroiditis and choroi­dal neovascularization associated with the multiple eva­nescent white dot and acute idiopathic blind spot enlarge­ment syndrome. Ophthalmology 1992; 99: 1678- 85. 105. Humayun M, Kattah J, Cupps TR, et al. Papillophlebitis and arteriolar occlusion in a pregnant woman. / Clin Neuro- ophthalmol 1992; 12: 226- 9. 106. Erzurum SA, Jampol LM, Territo C, O'Grady R. Primary malignant melanoma of the optic nerve simulating a mel-anocytoma. Arch Ophthalmol 1992; 110: 684- 6. 107. Traboulsi EI, Lim JI, Pyeritz R, Goldberg HK, Haller JA. A new syndrome of myelinated nerve fibers, vitreoretinop-athy, and skeletal malformations. Arch Ophthalmol 1993; 111: 1543- 5. 108. Lewallen S, Taylor TE, Molyneux ME, et al. Ocular fundus findings in malawian children with cerebral malaria. Oph­thalmology 1993; 100: 857- 61. 109. Moody TA, Irvine AR, Cahn PH, et al. Sudden visual field constriction associated with optic disc drusen. / Clin Neuro- ophthalmol 1993; 13: 8- 13. 110. Miller NR. Sudden visual field constriction associated with optic disc drusen. / Clin Neuro- ophthalmol 1993; 13: 14. 111. Scholl GB, Song HS, Winkler DE, Wray SH. The pattern visual evoked potential and pattern electroretinogram in drusen- associated optic neuropathy. Arch Ophthalmol 1992; 110: 75- 81. 112. Brodsky MC, Schroeder GT, Ford R. Superior segmental optic hypoplasia in identical twins. / Clin Neuro- ophthalmol 1993; 13: 152- 4. 113. Burde RM. Neuro- ophthalmic associations and complica­tions of diabetes mellitus. Am / Ophthalmol 1992; 114: 498- 501. 114. Brodsky MC, Glasier CM. Optic nerve hypoplasia: clinical significance of associated central nervous system abnor­malities on magnetic resonance imaging. Arch Ophthalmol 1993; 111: 66- 74. 115. Margo CE, Hamed LM, Fang E, Dawson WW. Optic nerve aplasia. Arch Ophthalmol 1992; 110: 1610- 13. 116. Eustis HS, Sanders MR, Zimmerman T. Morning glory syndrome in children: Association with endocrine and central nervous system anomalies. Arch Ophthalmol 1994; 112: 204- 07. 117. Dailey JR, Cantore WA, Gardner TW. Peripapillary cho­roidal neovascular membrane associated with an optic nerve coloboma. Arch Ophthalmol 1993; 111: 441- 2. 118. Pinckers A, Cruysberg JRM, Renier WO. Delayed myeli-nation of the optic nerve and pseudo optic atrophy of Beauvieux. Neuro- ophthalmol 1993; 13: 165- 70. 119. Rimmer S, Keating C, Chou T, Farb MD, et al. Growth of the human optic disc and nerve during gestation, child­hood, and early adulthood. Am } Ophthalmol 1993; 116: 748- 53. 120. Panda- Jonas S, Jonas JB, Jakobczyk M, Schneider U. Ret­inal photoreceptor count, retinal surface area, and optic / Neuro- OphthalmoI, Vol. 14, No. 3. 7994 254 A. A. SADUN AND J. DAO disc size in normal human eyes. Ophthalmology 1994; 101: 519- 23. 121. Jonas JB, Schmidt AM, Muller- Bergh JA, et al. Human optic nerve fiber count and optic disc size. Invest Ophthal­mol Vis Sri 1992; 33: 2012- 8. 122. Lincoff H, Yannuzzi L, Singerman L, et al. Improvement in visual function after displacement of the retinal eleva­tions emanating from optic pits. Arch Ophthalmol 1993; 111: 1071- 9. 123. Lam BL, Siatkowski RM, Fox GM, Glaser JS. Visual loss in pseudotumor cerebri from branch retinal artery occlusion. Am I Ophthalmol 1992; 113: 334- 6. 124. Matzkin DC, Slamovits TL, Genis I, Bello J. Disc swelling: a tall tail? Sum Ophthalmol 1992; 37: 130- 6. 125. Newman NJ with comments by Sedwick LA, Boghen DR. Bilateral visual loss and disc edema in a 15 year old girl. Surv Ophthalmol 1994; 38: 365- 70. / Neuro- Ophthalmol, Vol. 14, No. .3, 1994