Electrical potentials from the eye and optic nerve of Strombus: effects of electrical stimulation of the optic nerve.

1. Photic stimulation of the mature eye of Strombus can evoke in the optic nerve 'on' activity in numerous small afferent fibres and repetitive 'off' bursts of afferent impulses in a smaller number of larger fibres. 2. Synchronous invasion of the eye by electrically evoked impulses in small optic nerve fibres (apparently the 'on' afferents, antidromically activated) can evoke a burst of impulses in the larger 'off' fibres which propagate away from the eye. Invasion of the eye via one branch of optic nerve can evoke an answering burst in another branch. 3. Such electrically evoked bursts are similar to light-evoked 'off' bursts with respect to their impulse composition, their ability to be inhibited by illumination of the eye, and their susceptibility to MgCl2 anaesthesia. 4. Invasion of the eye by a train of repetitive electrically evoked impulses in the absence of photic stimulation can give rise to repetitive 'off' bursts as well as concomitant oscillatory potentials in the eye which are similar to those normally evoked by cessation of a photic stimulus. 5. The electrically evoked 'off' bursts appear to be caused by an excitatory rebound following the cessation of inhibitory synaptic input from photoreceptors which can be antidromically activated by electrical stimulation of the optic nerve. 6. The experimental results suggest that the rhythmic discharge of the 'off' fibres evoked by the cessation of a photic stimulus is mediated by the abrupt decrease of inhibitory synaptic input from the receptors.     

Surgical exposure of the optic nerve in the guinea pig.

A lateral orbitotomy approach was used to surgically expose the optic nerve in the guinea pig. This approach was excellent for experimental access to the optic nerve with minimal trauma to the eye.     

Elimination of cobalt from the frog brain introduced into the optic centres through the optic nerve.

One optic nerve in several frogs was filled with cobaltous-lysine complex, and the animals were left to survive from 1 day to 52 days. Degenerated cobalt-filled retinal fibres were phagocytosed by ependymo-glial, and microglial cells. The cobalt appeared in the ependymo-glial cells in the 4th postoperative day, and its amount was greatly reduced by the 52nd day. Within 12 days the labelled axons were replaced by cobalt-loaded microglial cells in the termination sites of optic fibres. By the end of the experimental period, the number of labelled cells increased in the periventricular layers, and decreased in places where retinal fibres had terminated. These processes were accompanied by the appearance of cobalt in the choroid plexus. It is supposed that glial cells dischargd the cobalt into brain ventricles, and the metal left the nervous tissue via the cerebrospinal fluid.     

Genetic analysis of Drosophila larval optic nerve development.

To identify genes necessary for establishing connections in the Drosophila sensory nervous system, we designed a screen for mutations affecting development of the larval visual system. The larval visual system has a simple and stereotypic morphology, can be recognized histologically by a variety of techniques, and is unnecessary for viability. Therefore, it provides an opportunity to identify genes involved in all stages of development of a simple, specific neuronal connection. By direct observation of the larval visual system in mutant embryos, we identified 24 mutations affecting its development; 13 of these are larval visual system-specific. These 13 mutations can be grouped phenotypically into five classes based on their effects on location, path or morphology of the larval visual system nerves and organs. These mutants and phenotypic classifications provide a context for further analysis of neuronal development, pathfinding and target recognition.     

Studies on the development of the eye cup and optic nerve in normal mice and in mutants with congenital optic nerve aplasia.

With the use of quantitative histological techniques, we have described, in normal mice, the formation of a system of intercellular channels within the embryonic retina and continuing without interruption into the optic stalk. The channels develop in advance of the morphological differentiation of the retinal ganglion cells and their neurites. Moreover, they appear at predictable times during gestation and are localized along the potential route to be taken by the earliest developing fibers of the optic nerve. A functional relationship may exist between the development of the channels and the subsequent outgrowth of the optic nerve from the eye. We have also examined a series of mouse embryos homozygous for the mutant gene ocular retardation (or^J), which causes optic nerve aplasia. In the or^J mutant, there is a reduction in area of these extracellular spaces and the optic nerve fails to exit from the eye. The lack of intercellular space within the mutant retina is associated with an increased number of cells which, in turn, may result from a continuing absence of normal cell death during earlier stages.     

Mass of the optic nerve, the optic chiasm and the optic tract of practical medical importance

The intraorbital, intracanalicular, and intracranial length of the optic nerve was measured. Also the length of the optic tract between chiasm and lateral geniculate body was estimated. Included are the ampulla of the optic sheaths, the course of the ophthalmic artery, and the distance of the ciliary ganglion to the lateral margin of the orbit.     

Microfibril-microvessel connections in the uvea and optic nerve of the mammalian eye.

Light- and electron-microscopic examination of arterioles, venules and capillaries of the eyes of several mammalian species has shown that the microfibrils of ocular elastic tissue attach to microvascular basement membranes throughout the uvea (iris, ciliary body, choroid) and optic nerve. Although described sporadically in prior investigations, this report shows that the connections are a common feature of the mammalian eye. The connections appear most numerous at venules and capillaries and are sparse at arterioles. The connections may provide a mechanism by which perivascular elastic tissue influences microvascular function, e.g. the control of blood pressure in them or their response to changes in intraocular pressure.     

Choroidal melanoma invading the optic nerve head

Choroidal melanoma is the most common primary intraocular tumor, however, involvement of the optic nerve is rare. This case report presents a patient with an amelanotic juxtapapillary malignant choroidal melanoma with secondary optic disc invasion. The clinical signs and symptoms, differential diagnosis, management and prognosis for survival are discussed.     

Glaucoma and optic nerve repair

Glaucoma is a leading cause of irreversible blindness worldwide and causes progressive visual impairment attributable to the dysfunction and death of retinal ganglion cells (RGCs). Progression of visual field damage is slow and typically painless. Thus, glaucoma is often diagnosed after a substantial percentage of RGCs has been damaged. To date, clinical interventions are mainly restricted to the reduction of intraocular pressure (IOP), one of the major risk factors for this disease. However, the lowering of IOP is often insufficient to halt or reverse the progress of visual loss, underlining the need for the development of alternative treatment strategies. Several lines of evidence suggest that axonal damage of RGCs occurs primary at the optic nerve head, where axons appear to be most vulnerable. Axonal injury leads to the functional loss of RGCs and subsequently induces the death of the neurons. However, the detailed molecular mechanism(s) underlying IOP-induced optic nerve injury remain poorly understood. Moreover, whether glaucoma pathophysiology is primarily axonal, glial, or vascular remains unclear. Therefore, protective strategies to prevent further axonal and subsequent soma degeneration are of great importance to limit the progression of sight loss. In addition, strategies that stimulate injured RGCs to regenerate and reconnect axons with their central targets are necessary for functional restoration. The present review provides an overview of the context of glaucoma pathogenesis and surveys recent findings regarding potential strategies for axonal regeneration of RGCs and optic nerve repair, focusing on the role of cytokines and their downstream signaling pathways.     

Enzyme histochemical changes in retinal ganglion cells and the optic nerve after goldfish optic nerve lesion. A regenerative and hypertrophic phenomena study

After sectioning of the goldfish optic nerve a number of enzyme histochemical changes are observed in the hypertrophied retinal ganglion cells and in the optic nerve. Between one and eighteen days postoperatively an increase in the amount of acid phosphatase reaction product is noted. The enhanced activity decreased to normal first in the optic nerve, followed by the optic tract and tectum. Four days postoperatively higher levels of activity were noted in the hypertrophic retinal ganglion cells for the enzymes NADH tetrazolium reductase, cytochrome oxidase, glutamate dehydrogenase and lactate dehydrogenase. The same enzymes also showed an activity increase in the lesioned optic nerve after four to ten days postoperatively, beginning at the cut and gradually spreading towards the optic tectum. Between fifteen and eighteen days the activity dropped to normal in the hypertrophic retinal ganglion cells, while in the lesioned nerve raised levels of reaction products could be seen till days thirty-five and/or forty-five. It was concluded that the degeneration of the optic pathway is marked by the increase of acid phosphatase activity, whereas the process of regeneration is characterized by an increase of NADH tetrazolium reductase, cytochrome oxidase, glutamate dehydrogenase and lactate dehydrogenase activities. The possible functional implications of these enzymes in the regenerative phenomena are discussed.     

少突胶质细胞和视神经损伤

少突胶质细胞在中枢神经系统中具有重要和广泛的生理功能。视神经损伤后,出现髓鞘脱失、少突胶质细胞死亡和髓鞘再生等病理改变,产生的髓鞘碎片能抑制视神经轴索再生。少突胶质细胞的抑制特性由特定的抑制分子介导,目前已鉴定的抑制分子主要有Nogo、髓鞘相关糖蛋白（myelin—associated glycoprotein,MAG）、少突胶质细胞髓鞘糖蛋白（oligodendrocyte myelin glycoprotein,OMgp）等,它们通过同一受体复合体传导抑制信号。阻滞抑制分子及其受体,或调整神经元的内在生长状态以克服抑制分子的抑制作用,可以促进视神经损伤后再生。本文就这方面的进展作一综述。     

Acquired pits of the optic nerve in glaucoma

An acquired pit of the optic nerve (APON) is a discrete, focal area of depression within the optic cup at the level of the lamina cribrosa. It is an under-diagnosed sign of glaucoma damage due to its subtle appearance. APONs occur more frequently unilaterally and in patients with normal-tension glaucoma (NTG). They often correspond to a deep, sharp-margined scotoma approaching or involving fixation. Given the location and progressive nature of the associated visual field defects, glaucoma patients and glaucoma suspects should be evaluated for this sign of localized optic nerve damage.     

The fine structure of the limulus optic nerve

Two complete composite photographs of the optic nerve of Limulus, made by electron microscopy, reveal the presence of neurosecretory granules in the large axons of the rudimentary eye neurons. The number of intermediate sized, (3–7 μ), of eccentric cells corresponds with the number of ommatidia as expected, but only their sheath of Schwann cells show an intimate interfolding. Based on the number of fine axons within the nerve each ommatidium has an average of 12–13 retinular cells. The diameter of their fibers is between 0.2 and 3 μ although the majority are between 1 and 1.5 μ. They are aggregated into bundles of six to seven fibers by the sheath cells although some bundles contain only two, others as many as 181 fibers. There is no indication in these studies that retinular cell axons within a bundle are associated with the same, adjacent, or other pattern of ommatidia. The photographs suggest that physiological activity in retinular cell axons might be detected most easily in the smallest bundles because they contain the fewest, but the larger retinular cell axons.     

Enzyme histochemistry of Wallerian degeneration in the immature optic nerve of rabbits.

A histochemical study was performed on the activity of several phosphatases, esterases and oxidoreductases in the immature optic nerve of rabbits undergoing Wallerian degeneration. Unilateral enucleations of the eye bulb were performed on 7 days old animals and the degenerated optic nerves were examined in rabbits, 5, 23, 63 and 173 days afterwards. The following results were obtained: 1. The reactive cells appearing in the immature optic nerve undergoing Wallerian degeneration exhibit distinctly increased activities of many hydrolytic and oxidoreductive enzymes. 2. The histoenzymic pattern of changes displayed by the reactive cells occurring in the immature, degenerating optic nerve is distinct from and bears no relation to that seen in the normally developing optic nerve. 3. The genetic formation contained in the oligodendroglial cells is not the sole factor safeguarding the transformation of immature and mature oligodendroglia into myelinating cells.     

A novel animal model of partial optic nerve transection established using an optic nerve quantitative amputator

Background

Research into retinal ganglion cell (RGC) degeneration and neuroprotection after optic nerve injury has received considerable attention and the establishment of simple and effective animal models is of critical importance for future progress.

Methodology/Principal Findings

In the present study, the optic nerves of Wistar rats were semi-transected selectively with a novel optic nerve quantitative amputator. The variation in RGC density was observed with retro-labeled fluorogold at different time points after nerve injury. The densities of surviving RGCs in the experimental eyes at different time points were 1113.69±188.83 RGC/mm² (the survival rate was 63.81% compared with the contralateral eye of the same animal) 1 week post surgery; 748.22±134.75 /mm² (46.16% survival rate) 2 weeks post surgery; 505.03±118.67 /mm² (30.52% survival rate) 4 weeks post surgery; 436.86±76.36 /mm² (24.01% survival rate) 8 weeks post surgery; and 378.20±66.74 /mm² (20.30% survival rate) 12 weeks post surgery. Simultaneously, we also measured the axonal distribution of optic nerve fibers; the latency and amplitude of pattern visual evoke potentials (P-VEP); and the variation in pupil diameter response to pupillary light reflex. All of these observations and profiles were consistent with post injury variation characteristics of the optic nerve. These results indicate that we effectively simulated the pathological process of primary and secondary injury after optic nerve injury.

Conclusions/Significance

The present quantitative transection optic nerve injury model has increased reproducibility, effectiveness and uniformity. This model is an ideal animal model to provide a foundation for researching new treatments for nerve repair after optic nerve and/or central nerve injury.