Correspondences in the Behavior of the Electroretinogram and of the Potentials Evoked at the Visual Cortex

Electrical potentials from the eye (ERG) and from the contralateral visual cortex were recorded in response to flashes of white and of colored light of various intensities and durations. The evoked potentials were found to parallel the behavior of the ERG in several significant respects. Selective changes in the ERG brought about by increasing the light intensity and by light adaptation led to parallel selective changes in the cortical responses. The dual waves (b₁, b₂) of the ERG were found to have counterparts in two cortical waves (c₁, c₂) which, in respect to changes in light intensity and to light adaptation, behaved analogously to the two retinal components. The responses evoked at high intensity showed only the diphasic c₁-potential. As stimulus intensity was lowered the c₁-wave decreased in magnitude and a delayed c₂-component appeared. The c₂-potential increased in amplitude as light intensity of the flash was further reduced. Eventually the c₂-wave, too, decreased as stimulus reduction continued. There was no wave length specificity in regard to either the duplex b-waves or duplex cortical waves. Both appeared at all wave lengths from 454 mµ to 630 mµ. The two cortical waves evoked by brief flashes of colored light showed all the behavior to changes in stimulus intensity and to light adaptation that occurred with white light.     

Daily and circadian variation in the electroretinogram of the domestic fowl: effects of melatonin

Visual and circadian function are integrally related in birds, but the precise nature of their interaction is unknown. The present study determined whether visual sensitivity measured electroretinographically (ERG) in 7-week-old cockerels varies over the time of day, whether this rhythm persists in constant darkness (DD) and whether exogenous melatonin affects this ERG rhythmicity. ERG b-wave amplitude was rhythmic in LD and persisted in DD with peak amplitude during mid- to late afternoon in LD and mid-subjective day in DD, indicating that the ERG rhythm is endogenously generated. No daily or circadian variation in a-wave amplitude was observed, and ERG component latency and durations were not rhythmic. Intramuscular injection of 10 g/kg melatonin at ZT10 in LD significantly decreased b-wave amplitude but had no effect on a-wave. Intraocular injection of 600 pg melatonin, however, had no effect on any aspect of the ERG. These data indicate that a circadian clock regulates ocular sensitivity to light and that melatonin may mediate some or all of this effect. The level at which melatonin modulates retinal sensitivity is not known, but the present data suggest a central site rather than a direct effect of the hormone in the eye.Abbreviations DD constant darkness - ERG electroretinography - EW Edinger-Westphal nuclei - IMEL iodomelatonin - IO isthmooptic nucleus - LD light-dark cycle - SCG superior cervical ganglion - SCN suprachiasmatic nuclei - vSCN visual suprachiasmatic nucleus     

Electrophysiological organization of the eye of Aplysia

The eye of Aplysia californica was studied by electrophysiological and histological methods. It has a central spheroidal lens which is surrounded by a retina composed of several thousand receptor cells which are replete with clear vesicles, pigmented support cells, neurons which contain secretory granules, and glial cells. The thin optic nerve that connects the eye to the cerebral ganglion gives a simple "on" response of synchronized action potentials. Tonic activity occurs in the optic nerve in the dark and is dependent on previous dark adaptation. Micropipette recordings indicate that the ERG is positive (relative to a bathelectrode) on the outer surface of the eye and negative in the region of the distal segments of the receptors. Intracellular recordings show that receptor cells have resting potentials of 40–50 mv and respond to illumination with graded potentials of up to 55 mv. Dark-adapted receptors exhibit discrete bumps on the graded response to brief light flashes. Other elements in the retina that do not give large graded responses fall into two classes. One class responds to illumination with action potentials that are in synchrony with the extracellularly recorded compound optic nerve potentials. The other class is tonically active and is depolarized or hyperpolarized and inhibited upon illumination. It is apparent that complex excitatory and lateral inhibitory interactions occur among the elements of the retina.     

Electrical studies on the compound eye of Ligia occidentalis Dana (Crustacea: Isopoda)

The ERG of the compound eye in freshly collected Ligia occidentalis, in response to high intensity light flashes of ⅛ second or longer duration, begins with a negative on-effect quickly followed by an early positive deflection, rapidly returns to the baseline during illumination, and ends with a positive off-effect. As the stimulus intensity is decreased the early positivity progressively decreases and the rapid return to the baseline is replaced by a slowing decline of the negative on-effect. Responses were recorded with one active electrode subcorneally situated in the illuminated eye, the reference electrode in the dark eye. The dark-adapted eye shows a facilitation of the amplitude and rates of rise and fall of the on-effect to a brief, high intensity light stimulus. This facilitation may persist for more than 2 minutes. Following light adaptation under conditions in which the human eye loses sensitivity by a factor of almost 40,000 the Ligia eye loses sensitivity by a factor of only 3. The flicker fusion frequency of the ERG may be as high as 120/second with a corneal illumination of 15,000 foot-candles. Bleeding an otherwise intact animal very rapidly results in a decline of amplitude, change of wave form, and loss of facilitation in the ERG. When the eye is deganglionated without bleeding the animal the isolated retina responds in the same manner as the intact eye. Histological examination of the Ligia receptor layer showed that each ommatidium contains three different retinula cell types, each of which may be responsible for a different aspect of the ERG.     

Fine structure of the first optic ganglion (lamina) of the cockroach, Periplaneta americana

The structural organization of the first optic ganglion (lamina) of the cockroach (Periplaneta americana) was investigated by the use of light and electron microscopy. Each compound eye of the cockroach is composed of up to 2000 visual units (ommatidia) of the fused rhabdom type. The ommatidia themselves consist of eight receptor cells which terminate as axons in either the first or second optic ganglion. Three different short visual fibre types end in two separate strata in the lamina, and one long fibre type ends in the second optic ganglion. Monopolar second-order neurons with wide field branching patterns in the middle stratum of the first synaptic region have postsynaptic contacts with short visual fibres. Horizontal fibre elements with branching patterns at different levels of the lamina apparently form three horizontal plexuses with presynaptic and/or postsynaptic connections to first- and secondorder neurons. The lack of well-organized fibre cartridges containing a constant number of first and second order neurons in each fascicle and the presence of only unistratified wide field monopolar cells could represent, as compared to other insect orders, a primitive stage in the development of the first optic ganglion.     

CO2-induced changes in the critical fusion frequency of the fly, Sarcophaga bullata

The critical fusion frequency (CFF) for the ERG of a dipteran compound eye was measured under atmospheric conditions of low and high pCO₂. It was found that following an increase in CO₂ concentration to 80%, the CFF decreased from a mean value of 283 to 108 Hz within 60 sec and remained at this lower figure as long as the CO₂ concentration was high. Recovery to control values was observed upon removal of the CO₂. This result is compared with changes in the waveform of the single-flash ERG resulting from an identical CO₂ increase. The low CFF is associated with a single, monophasis negative wave isolated by CO₂ from the normally complex ERG. This negative wave is identified as the receptor cell component.It is suggested that two mechanisms are responsible for the frequency-dependent response characteristics of the dipteran eye. One resides at the level of the receptor cells and is responsible for the CFF recorded at 80% CO₂, while the second involves ganglionic feedback upon the receptor cells and is necessary for the maintenance of the higher CFF recorded under normal atmospheric conditions.     

Reciprocal neural influences upon the period length of the ERG circadian rhythm in the crayfish

Abstract

The relationship between left and right circadian oscillations in the ERG of the crayfishProcambarus bouvieri have been studied in intact animals and in animals with cerebral ganglion damage. Except in split‐brain preparations, the ERG oscillations of both sides were always in phase. Surgical bisection of the cerebral ganglion, also results in a shortening of the period length; this suggests that ERG circadian pacemakers normally receive a bilateral input of light stimulation. The neural connections between the eyestalks at the protocerebrum seem to have the most important role in the synchronization of the ERG oscillations of both sides.     

LIFE IN ZERO MAGNETIC FIELD. IV. INVESTIGATION OF DEVELOPMENTAL EFFECTS ON FRUITFLY VISION

The fruitfly (Drosophila melanogaster) visual system was investigated electrophysiologically in vivo after exposure to a zero magnetic field (ZMF). Electroretinographic (ERG) recording of fly eye electrical activity was performed on adult insects raised from pupae maintained for 20 hr in zero magnetic field. A flickering excitation regime was applied to excite the visual system, since in this way, a quasistable hyperpolarization component of the electroretinogram can be obtained, containing information from the neural cells, which are the most sensitive to the action of external factors during early ontogenetic stages. Results of the investigation of two D. melanogaster populations, sample and control, were statistically compared.

We found a significant statistical increase of sensitivity in neural cells from the first optic ganglion in the fly population developed from pupae exposed to ZMF.     

Heterozygous Mutation of Drosophila Opa1 Causes the Development of Multiple Organ Abnormalities in an Age-Dependent and Organ-Specific Manner

Optic Atrophy 1 (OPA1) is a ubiquitously expressed dynamin-like GTPase in the inner mitochondrial membrane. It plays important roles in mitochondrial fusion, apoptosis, reactive oxygen species (ROS) and ATP production. Mutations of OPA1 result in autosomal dominant optic atrophy (DOA). The molecular mechanisms by which link OPA1 mutations and DOA are not fully understood. Recently, we created a Drosophila model to study the pathogenesis of optic atrophy. Heterozygous mutation of Drosophila OPA1 (dOpa1) by P-element insertion results in no obvious morphological abnormalities, whereas homozygous mutation is embryonic lethal. In eye-specific somatic clones, homozygous mutation of dOpa1 causes rough (mispatterning) and glossy (decreased lens deposition) eye phenotypes in adult Drosophila. In humans, heterozygous mutations in OPA1 have been associated with mitochondrial dysfunction, which is predicted to affect multiple organs. In this study, we demonstrated that heterozygous dOpa1 mutation perturbs the visual function and an ERG profile of the Drosophila compound eye. We independently showed that antioxidants delayed the onset of mutant phenotypes in ERG and improved larval vision function in phototaxis assay. Furthermore, heterozygous dOpa1 mutation also caused decreased heart rate, increased heart arrhythmia, and poor tolerance to stress induced by electrical pacing. However, antioxidants had no effects on the dysfunctional heart of heterozygous dOpa1 mutants. Under stress, heterozygous dOpa1 mutations caused reduced escape response, suggesting abnormal function of the skeletal muscles. Our results suggest that heterozygous mutation of dOpa1 shows organ-specific pathogenesis and is associated with multiple organ abnormalities in an age-dependent and organ-specific manner.     

Studies on the electroretinogram. II. Model of an a-wave regenerator mechanism

A model is proposed to relate the regeneration of the ERGa-wave after partial light adaptation to the level of the light adaptation. The model assumes that thea-wave amplitude is a function of some reactive substance associated with ana-wave generator. The maximuma-wave amplitude occurs when the eye is fully dark adapted, and thea-wave generator initiator concentration is at a maximum. Thea-wave generator initiator concentration can be decreased by interacting with a product of the rhodopsin-light energy reaction, and increased by removal of this inhibitor. The removal of the inhibitor depends upon the isomerization of the all-trans-retinene to the 11-cis form. An excess of inhibitory material overa-wave generator initiator would cause a delay in the appearance of thea-wave until the excess inhibitory material is removed. This delay is a linear function of the logarithm of the adapting energy. The agreement of this model with the experimental ERG data is very good. Supported in whole by Public Health Service Research Grant No. NB-02522, from the National Institute of Neurological Diseases and Blindness, Bethesda, Maryland.     

Components of the ERG of the moth, Galleria mellonella

Origin of the components of the electroretinogram of the moth Galleria mellonella have been investigated. Successive recordings taken at different depths through the retina and optic ganglion indicate that the positive and maintained negative phases of the ERG originate in the retina while a phasic negative potential occurs in the ganglion, but under certain conditions may invade the retina too. There appears to be no correlation between amplitude and adaptation for the positive and slow negative phases nor will agents applied to the ganglion obliterate the positive phase. If either NaCl or Ringer solution is applied to the retina the positive phase is abolished. Isotonic KCl does not have this effect. Ringer's and NaCl applied to the ganglion do not affect the ERG. Damage to the retinal basement membrane also appears to abolish the positive phase. We interpret these effects to indicate the ion-selective permeability of the basement membrane.     

Wengen,the Sole Tumour Necrosis Factor Receptor in Drosophila,Collaborates with Moesin to Control Photoreceptor Axon Targeting during Development

Photoreceptor neurons (R cells) in the Drosophila eye define a map of visual space by connecting to targets in distinct layers of the optic lobe, with R1-6 cells connecting to the lamina (the first optic ganglion) and R7 and R8 cells connecting to the medulla (the second optic ganglion). Here, we show that Wengen (Wgn) directly binds Moesin (Moe) through a cytosolic membrane proximal domain and this interaction is important for mediating two distinct aspects of axonal targeting. First, we show that loss of wgn or moe function disrupts cell autonomous R8 axon targeting. Second, we report that wgn or moe mutants show defects in R2–R5 targeting that result from disruption of non-cell autonomous effects, which are secondary to the cell autonomous R8 phenotype. Thus, these studies reveal that the Wgn-Moe signaling cascade plays a key role in photoreceptor target field innervations through cell autonomous and non-cell autonomous mechanisms.     

Ischemic tolerance protects the rat retina from glaucomatous damage

Glaucoma is a leading cause of acquired blindness which may involve an ischemic-like insult to retinal ganglion cells and optic nerve head. We investigated the effect of a weekly application of brief ischemia pulses (ischemic conditioning) on the rat retinal damage induced by experimental glaucoma. Glaucoma was induced by weekly injections of chondroitin sulfate (CS) in the rat eye anterior chamber. Retinal ischemia was induced by increasing intraocular pressure to 120 mmHg for 5 min; this maneuver started after 6 weekly injections of vehicle or CS and was weekly repeated in one eye, while the contralateral eye was submitted to a sham procedure. Glaucoma was evaluated in terms of: i) intraocular pressure (IOP), ii) retinal function (electroretinogram (ERG)), iii) visual pathway function (visual evoked potentials, (VEPs)) iv) histology of the retina and optic nerve head. Retinal thiobarbituric acid substances levels were assessed as an index of lipid peroxidation. Ischemic conditioning significantly preserved ERG, VEPs, as well as retinal and optic nerve head structure from glaucomatous damage, without changes in IOP. Moreover, ischemia pulses abrogated the increase in lipid peroxidation induced by experimental glaucoma. These results indicate that induction of ischemic tolerance could constitute a fertile avenue for the development of new therapeutic strategies in glaucoma treatment.     

Recessive Mutations in RTN4IP1 Cause Isolated and Syndromic Optic Neuropathies

Autosomal-recessive optic neuropathies are rare blinding conditions related to retinal ganglion cell (RGC) and optic-nerve degeneration, for which only mutations in TMEM126A and ACO2 are known. In four families with early-onset recessive optic neuropathy, we identified mutations in RTN4IP1, which encodes a mitochondrial ubiquinol oxydo-reductase. RTN4IP1 is a partner of RTN4 (also known as NOGO), and its ortholog Rad8 in C. elegans is involved in UV light response. Analysis of fibroblasts from affected individuals with a RTN4IP1 mutation showed loss of the altered protein, a deficit of mitochondrial respiratory complex I and IV activities, and increased susceptibility to UV light. Silencing of RTN4IP1 altered the number and morphogenesis of mouse RGC dendrites in vitro and the eye size, neuro-retinal development, and swimming behavior in zebrafish in vivo. Altogether, these data point to a pathophysiological mechanism responsible for RGC early degeneration and optic neuropathy and linking RTN4IP1 functions to mitochondrial physiology, response to UV light, and dendrite growth during eye maturation.     

The electroretinogram in multiple sclerosis and demyelinating optic neuritis

The electroretinogram (ERG) to flashes of white light presented under photopic conditions and the pattern reversal visual evoked potentials (PR-VEPs) from both eyes were recorded from 14 patients with multiple sclerosis (MS) with monocular demyelinating optic neuritis (DON) and from 11 patients soon after presenting with monocular demyelinating optic neuritis alone. Fifteen and 10 normal subjects, matched for age and sex, were used as controls for each group of patients respectively. In the DON group of patients and controls the flicker following ERG (FF-ERG) to white flashes of light at 40 Hz was also recorded. Skin electrodes and averaging procedures were used for all the recordings. The PR-VEP elicited with stimulation of the affected eye was absent or abnormally delayed, and the amplitude of the ‘b’ wave of ERG of the affected eye was diminished in all patients. The ‘b’ wave latency, however, was similar in both affected and non-affected eyes and the controls. There was no difference in ‘a’ wave amplitude and latency between eyes of patients and normal subjects. The FF-ERG in 8 out of 10 patients with satisfactory recordings was diminished in the affected eye. These results provide neurophysiological evidence that retinal damage is not due to loss of myelin but is an early feature of demyelinating optic neuritis. This damage preferentially affects the retinal elements associated with the generation of the ‘b’ wave of the ERG, probably the glial cells of Müller.     

Development of neuronal locus specificity in Xenopus retinal ganglion cells after surgical eye transection after fusion of whole eyes

A developmental program is established in the stage 28–32 optic cup of Xenopus embryos, which specifies the permanent AP and DV reference axes for positional information in the retina, and thereby determines the pattern of spatial deployment of ganglion cell locus specificities subserving assembly of retinotopically organized connections in the tectum. This developmental program has previously proved unmodifiable in intact eye primordia submitted to a variety of rotation, transplantation, and tissue culture conditions. Here we report that the program can be modified by surgical transection of stage 32 eye primordia (with subsequent fusion of the disconnected halves to reconstitute a whole eye) and by fusion of whole stage 38 eyes, although most of the transected eyes did develop normal visuotectal projections. The remaining vertically transected eyes, and all eyes formed when a left and right stage 38 eye fused along apposed temporal edges, developed “double-nasal compound” projections to the tectum: the nasal and temporal halves of the adult retina each projected to the entire tectum, and each tectal locus was driven from two stimulus positions symmetrically disposed about the vertical meridian. The remaining horizontally transected eyes, and all eyes formed when a left and right stage 38 eye fused along apposed dorsal edges, developed “double-ventral compound” projections to the tectum: the dorsal and ventral halves of the adult retina each projected to the entire tectum, and each tectal locus was driven from two stimulus positions symmetrically disposed about the horizontal meridian. The results are considered in terms of (1) the kinds of cellular processes that could mediate the observed modifications in the original developmental program; (2) the nature and stability of the program; and (3) the general suitability of eye fragment-fusion experiments for analysis of the assembly of retinotectal connections.     

Electrophysiology and glaucoma: current status and future challenges

Visual electrophysiology allows non-invasive monitoring of the function of most processing stages along the visual pathway. Here, we consider which of the available methods provides the most information concerning glaucomatous optic nerve disease. The multifocal electroretinogram (ERG), although often employed, is less affected in glaucoma than two direct measurements of retinal ganglion cell function, namely the pattern ERG (PERG) and the photopic negative response (PhNR) of the ERG. For the PERG, longitudinal studies have been reported, suggesting that this method can be used for the early detection of glaucoma; for the PhNR, no longitudinal study is available as yet. The multifocal PERG can spatially resolve ganglion cell function but its glaucomatous reduction is typically panretinal, even with only local field changes and so, its topographic resolution is of no advantage in glaucoma. The multifocal visual evoked potential promises objective perimetry and shows sensitivity and specificity comparable with standard automated perimetry but has not been established as a routine tool to date.     

A comparison among different techniques for human ERG signals processing and classification

Feature detection in biomedical signals is crucial for deepening our knowledge about the involved physiological processes. To achieve this aim, many analytic approaches can be applied but only few are able to deal with signals whose time dependent features provide useful clinical information. Among the biomedical signals, the electroretinogram (ERG), that records the retinal response to a light flash, can improve our comprehension of the complex photoreceptoral activities.The present study is focused on the analysis of the early response of the photoreceptoral human system, known as a-wave ERG-component. This wave reflects the functional integrity of the photoreceptors, rods and cones, whose activation dynamics are not yet completely understood. Moreover, since in incipient photoreceptoral pathologies eventual anomalies in a-wave are not always detectable with a “naked eye” analysis of the traces, the possibility to discriminate pathologic from healthy traces, by means of appropriate analytical techniques, could help in clinical diagnosis.In the present paper, we discuss and compare the efficiency of various techniques of signal processing, such as Fourier analysis (FA), Principal Component Analysis (PCA), Wavelet Analysis (WA) in recognising pathological traces from the healthy ones. The investigated retinal pathologies are Achromatopsia, a cone disease and Congenital Stationary Night Blindness, affecting the photoreceptoral signal transmission. Our findings prove that both PCA and FA of conventional ERGs, don't add clinical information useful for the diagnosis of ocular pathologies, whereas the use of a more sophisticated analysis, based on the wavelet transform, provides a powerful tool for routine clinical examinations of patients.     

Cross-species axial signaling, with realignment of retinal axes, in embryonic Xenopus eyes

The locus specificities which enable retinal ganglion cells to assemble a topographic retinotectal map are patterned about a pair of (anteroposterior and dorsoventral) retinal axes set down in the early eye bud. We have transplanted a Xenopus laevis eye bud, at stage $\text{23}\text{24}$ when the retinal field is still responsive to the axial signals from the surrounding tissues, into the enucleated eye socket of a comparable stage Ambystoma maculatum embryo. Three days later, when the Xenopus eye had reached early larval stages and was no longer responsive to extraocular signals, the eye was retransplanted into the socket of the Xenopus final carrier embryo. The pattern of retinotectal connections between the eye and the carrier's optic tectum was examined by electrophysiological analysis of the visuotectal projections. The results indicated that many of the retinae had patterned locus specificities about axes derived from the salamander intermediate host. We infer that axial signaling involves fundamental cellular processes which have been highly conserved during evolution.