Anatomical Evidence for the Neural Connection from the Emotional Brain to Autonomic Innervation in the Anterior Chamber Structures of the Eye.

OBJECTIVE: Previous studies have shown that the autonomic nervous system (ANS), which can be affected by emotions, is important in the occurrence or progression of glaucoma. The autonomic innervation distributed in the anterior chamber (AC) structures might play an efferent role in the neural regulation of intraocular pressure (IOP). This study aimed to investigate the anatomic neural connection from the emotional brain to autonomic innervation in the AC. METHODS: A retrograde trans-multisynaptic pseudorabies virus encoded with an enhanced green fluorescent protein (PRV531) and non-trans-synaptic tracer FAST Dil were injected into the right eye of mice, respectively. Fluorescent localization in the emotional brain and preganglionic nuclei was studied. Five and a half days after PRV531 injection into the right AC, fluorescent signals were observed in several emotional brain regions, including the amygdala, agranular insular cortex, lateral septal nuclei, periaqueductal gray, and hypothalamus. Autonomic preganglionic nuclei, including Edinger-Westphal nucleus, superior salivatory nucleus, and intermediolateral nucleus, were labeled using PRV531. RESULTS: The sensory trigeminal nuclei were not labeled using PRV531. The fluorescence signals in the nuclei mentioned above showed bilateral distribution, primarily on the ipsilateral side. Seven days after injecting FAST Dil into the AC, we observed no FAST Dil-labeled neurons in the central nervous system. CONCLUSION: Our results indicate a neural connection from the emotional brain to autonomic innervation in the AC, which provides anatomical support for the emotional influence of IOP via the ANS.

Anatomical evidence for the efferent pathway from the hypothalamus to autonomic innervation in the anterior chamber structures of eyes.

The autonomic innervation in the anterior chamber (AC) structures might play an efferent role in neural intraocular pressure (IOP) regulation, the center of which is thought to be located in the hypothalamus. In this study, we identified the efferent pathway from the hypothalamus to the autonomic innervation in the AC structures. Retrograde trans-multisynaptic pseudorabies virus (PRV) expressing green or red fluorescent protein, PRV531 and PRV724, was injected into the right and left AC of five rats, respectively; PRV531 was injected into the right AC of another five rats, and a non-trans-synaptic tracer, FAST Dil, was injected into the right AC of five rats as a control. Fluorescence signals in autonomic ganglia,the spinal cord and the central nervous system (CNS) were observed. Seven days after FAST Dil right AC injection, FAST Dil-labeled neurons were observed in the ipsilateral autonomic ganglia, including the superior cervical ganglion, pterygopalatine ganglion, and ciliary ganglion, but not in the CNS. Four and a half days after PRV531 injection into the right AC, PRV531-labeled neurons could be observed in the ipsilateral autonomic ganglia and bilateral hypothalamus nuclei, especially in the suprachiasmatic nucleus, paraventricular nucleus, dorsomedial hypothalamus, perifornical hypothalamus and ventral mammillary nucleus. Fluorescence signals of PRV531 mainly located in the ipsilateral autonomic preganglionic nuclei (Edinger-Westphal nucleus, superior salivatory nucleus and intermediolateral nucleus), but not in sensory trigeminal nuclei. Four and a half days after PRV531 right AC injection and PRV724 left AC injection, PRV531-labeled, PRV724-labeled, and double-labeled neurons could be observed in the above mentioned bilateral hypothalamus nuclei; but few contralateral infection-involving neurons (including double-labeled neurons) could be detected in the autonomic preganglionic nuclei. Our results indicate that there exist a both crossed and uncrossed hypothalamo-pre-parasympathetic and -pre-sympathetic tracts in the efferent pathways between the bilateral hypothalamic nuclei and the autonomic innervation of the bilateral AC.

Anatomic Evidence for Information Exchange between Primary Afferent Sensory Neurons Innervating the Anterior Eye Chamber and the Dura Mater in Rat.

Purpose: Our previous studies suggested that mechanosensitive trigeminal ganglion (TG) nerve endings innervating the inner wall of the anterior eye chamber (IWAEC) might play a role in baroreception of the IOP. It has been reported that mechanosensitive TG nerve endings also innervate the dura mater. An acute IOP elevation evokes eye pain accompanied by an ipsilateral headache, suggesting that information exchange may occur between the primary afferent neurons (PANs) innervating the IWAEC and the dura mater. To verify the information exchange between PANs of the two locations, we investigated the anatomic connection between them. Methods: Non-trans-synaptic tracers, 1,1'-dilinoleyl-3,3,3',3'-tetramethylindo-carbocyanine, 4-chlorobenzenesulfonate (FAST Dil) and cholera toxin subunit-B with a 488-nm fluorescent tag (CTB-488), were applied to the dura of the anterior cranial fossa (DACF) and the anterior eye chamber (AEC) to label the PANs. A trans-synaptic tracer, GFP-expressing pseudorabies virus (PRV152), was injected into the AEC while FAST Dil was applied to the DACF to explore the connection between PANs. Fluorescent localization in the TG was studied with a confocal fluorescent microscope. Results: Nine days after rats were treated with CTB-488 in the AEC and FAST Dil on the DACF, FAST Dil-labeled (red), and CTB-488-labeled (green) TG neurons were observed in the medial part of the TG, while double-labeled neurons were absent. If PRV152 was used to substitute CTB-488, then FAST Dil (red) and PRV152 (green) double-labeled TG neurons and axons were observed 3 days later. Conclusions: Our results indicate that synapses exist between PANs of the IWAEC and the DACF, providing anatomic evidence for information exchange between them.

Platelet activation by ADP is increased in selected patients with anterior ischemic optic neuropathy or retinal vein occlusion.

To investigate whether adenosine diphosphate (ADP)-induced platelet hyperaggregability is associated with nonarteritic anterior ischemic optic neuropathy (NAION) or retinal vein occlusion (RVO). We retrospectively reviewed thrombophilia screening data of patients with NAION or RVO without a history of arterial hypertension, diabetes mellitus, hyperlipidemia, obesity, and cigarette abuse. Patients with a positive family history for thromboembolism were not excluded. Platelet aggregation (area under the curve, AUC) after induction of 0.5, 1.0, and 2.0 µmol of ADP was estimated in 25 NAION and RVO patients and compared with 25 healthy controls. We observed significantly greater platelet aggregation post 0.5 (P = 0.002) and 1.0 (P = 0.008) µmol of ADP among NAION and RVO patients compared with healthy controls. Platelet hyperaggregability was significantly more prevalent in patients than in controls (56% vs. 8%; P = 0.0006). Our results suggest that in NAION and RVO patients without a history of arterial hypertension, diabetes mellitus, hyperlipidemia, obesity, and cigarette abuse, platelets are significantly hyperreactive after induction of very low concentrations of ADP when compared with healthy individuals. This hyperreactivity is particularly evident in patients with a family history of thromboembolism.

Cannabinoids increase mechanosensitivity of trigeminal ganglion neurons innervating the inner walls of rat anterior chambers via activation of TRPA1.

Our previous study found that some trigeminal ganglion (TG) nerve endings in the inner walls of rat anterior chambers were mechanosensitive, and transient receptor potential ankyrin 1 (TRPA1) was an essential mechanosensitive channel in the membrane. To address the effect of cannabinoids on the mechanosensitive TG nerve endings in the inner walls of anterior chambers of rat eye, we investigated the effect of the (R)-(+)-WIN55, 212-2 mesylate salt (WIN), a synthetic cannabinoid on their cell bodies in vitro. Rat TG neurons innervating the inner walls of the anterior chambers were labeled by 1,1'-dilinoleyl-3,3,3',3'-tetramethylindocarbocyanine, 4-chlorobenzenesulfona (FAST DiI). Whole cell patch clamp was performed to record the currents induced by drugs and mechanical stimulation. Mechanical stimulation was applied to the neurons by buffer ejection. WIN evoked inward currents via TRPA1 activation in FAST DiI-labeled TG neurons. WIN enhanced mechanosensitive currents via TRPA1 activation in FAST DiI-labeled TG neurons. Our results indicate that cannabinoids can enhance the mechanosensitivity of TG endings in the inner walls of anterior chambers of rat eye via TRPA1 activation.

Bimatoprost Increases Mechanosensitivity of Trigeminal Ganglion Neurons Innervating the Inner Walls of Rat Anterior Chambers via Activation of TRPA1.

PURPOSE: Our previous study found that some trigeminal ganglion (TG) nerve endings in the inner walls of rat anterior chambers were mechanosensitive, and transient receptor potential ankyrin 1 (TRPA1) was an essential mechanosensitive channel in the membrane. To address the effect of bimatoprost on the mechanosensitive TG nerve endings in the inner walls of rat anterior chambers, we investigated its effect on their cell bodies in vitro. METHODS: Rat TG neurons innervating the inner walls of the anterior chambers were labeled by anterior chamber injection of 1,1'-dilinoleyl-3,3,3',3'-tetramethylindocarbocyanine, 4-chlorobenzenesulfonate (FAST DiI). Calcium imaging and whole cell patch clamp were used on neuronal cell bodies to detect the activation effect of TRPA1 channels. Whole cell patch clamp was performed to record the currents induced by drugs and mechanical stimulation. Mechanical stimulation was applied to the neurons by buffer ejection. RESULTS: Bimatoprost mimicked the effect of TRPA1 agonists, allyl isothiocyanate (AITC), and (R)-(+)-WIN55, 212-2 mesylate salt (WIN) in the TG neurons. Bimatoprost induced Ca(2+) influx in HEK293 cells stably transfected with human TRPA1, but not in untransfected cells as AITC and WIN. Moreover, bimatoprost evoked inward currents via TRPA1 activation in FAST DiI-labeled TG neurons as WIN. Bimatoprost also enhanced mechanosensitivity of FAST DiI-labeled TG neurons via TRPA1 activation. CONCLUSIONS: Our results indicate that bimatoprost is a novel agonist of TRPA1, and it can enhance mechanosensitivity of TG nerve endings in the inner walls of anterior eye chambers via TRPA1 activation in rats.

Mechanotransduction of trigeminal ganglion neurons innervating inner walls of rat anterior eye chambers.

To address mechanoreceptive roles of trigeminal ganglion (TG) nerve endings in the inner walls of rat anterior eye chambers, we investigated the mechanotransduction process and mechanosensitive (MS) channel on somata of TG neurons innervating this area in vitro. Rat TG neurons innervating inner walls of anterior chambers were labeled by anterior chamber injection of 1,1'-dilinoleyl-3,3,3',3'-tetramethylindocarbocyanine, 4-chlorobenzenesulfonate (FAST DiI). The neuronal cell bodies were voltage clamped using a whole cell patch-clamp technique, while it was deformed by ejection of bath solution to verify mechanotransduction. Immunofluorescence staining was performed on sections of TG ganglia to determine the specific MS channel proteins. Mechanical stimuli induced MS currents in 55 out of 96 FAST DiI-labeled TG neurons. The MS currents exhibited mechanical intensity-dependent and clamp voltage-dependent characteristics. Mechanical stimulation further enhanced the membrane potential and increased the frequency of action potentials. Transient receptor potential ankyrin 1 (TRPA1), TRP vanilloid 4 (TRPV4), acid-sensing ion channel (ASIC) 2 and ASIC3 channel proteins were expressed in FAST DiI-labeled TG neurons. The inhibitory effect of HC-030031, a specific inhibitor of TRPA1, on MS currents demonstrated that TRPA1 was an essential MS channel protein. Taken together, our results show that mechanical stimuli induce MS currents via MS channels such as TRPA1 to trigger mechanotransduction in TG neurons innervating inner walls of anterior chambers. Our results indicate the existence of mechanoreceptive TG nerve endings in inner walls of anterior chambers. Whether the mechanoreceptive TG nerve endings play a role in intraocular pressure sensation warrants further investigation.

Morphofunctional interactions of peripheral nerve fibers of the iris with neurons developing in the anterior chamber of the eye in rats.

Electron microscopic studies were performed on intraocular transplants of embryonic septal and hippocampal tissue developing in the anterior chamber of the eye in rats for 3-4 months. The aim of the study was to seek ultrastructural identification of peripheral nerve fibers entering transplants from the iris, and to assess their ability to establish true synaptic contacts with transplanted CNS neurons. Bundles of myelinated and unmyelinated axons surrounded by Schwann cell cytoplasm were seen within the perivascular spaces of ingrowing blood vessels. Both types of peripheral fiber were also identified in the neuropil areas of transplants. At the ultrastructural level, unmyelinated axons were found to be free of glial Schwann cell sheaths and to form typical asymmetrical synapses with the dendrites and dendritic spines of transplant neurons. These results provide evidence of the high morphofunctional plasticity of both parts (central, peripheral) of the nervous system.

[Morpho-functional interactions of the iris peripheral nervous fibers with the neurons developing in the rat anterior eye chamber].

The intraocular grafts of the septal or hippocampal embryonic tissues developing in the rat anterior eye chamber for three to four months were investigated by electron microscopy. The aim of this study was both the ultrastructural identification of the peripheral nervous fibers entering the grafts from host iris and the estimation of their capacity to establish true synaptic contacts with the central nervous system neurons of the grafts. The bundles of myelinated and unmyelinated axons, surrounded by the Schwann cell cytoplasm, were observed within the perivascular spaces of the ingrowing blood vessels. In the neuropil areas of the grafts, both types of the peripheral nervous fibers were also identified. It was demonstrated on the ultrastructural level that the unmyelinated axons lost their glial envelope of the Schwann cell and formed the typical asymmetric synapses with the dendrites and dendritic spines of the grafted neurons. The results are indicative of the high morpho-functional plasticity of both parts of the nervous system.

Nerve endings with structural characteristics of mechanoreceptors in the human scleral spur.

PURPOSE: The innervation of the scleral spur region was investigated to learn whether mechano-receptors are present in this region. METHODS: Serial tangential sections and whole-mount preparations of the scleral spur region of 18 human eyes of different ages were investigated with electronmicroscopic and immunohistochemical methods. For immunohistochemistry antibodies against neurofilament-proteins, synaptophysin, substance P (SP), calcitonin gene-related peptide (CGRP), vasoactive intestinal polypeptide (VIP), neuropeptide Y (NPY), tyrosine-hydroxylase, dopamine-beta-hydroxylase, and acetylcholinesterase were used. RESULTS: Club- or bulb-shaped nerve endings with a diameter of 5 microns to 25 microns were identified in the scleral spur region throughout the whole circumference of the eyes. The terminals derive from myelinated axons with a diameter of approximately 3 microns and stain with antibodies against neurofilament-proteins and synaptophysin but do not stain for tyrosine-hydroxylase, dopamine-beta-hydroxylase, acetylcholinesterase, NPY, VIP, SP, or CGRP. Electronmicroscopically, the endings contain abundant neurofilaments, granular and agranular vesicles of different sizes, numerous mitochondria, and lysosome-like lamellated structures. The endings are incompletely ensheathed by Schwann cells. Those areas of the cell membrane of the endings that are not covered by Schwann cells are in intimate contact with the fibrillar connective tissue elements of the scleral spur. CONCLUSION: These structural features are highly characteristic for mechanoreceptive nerve endings in other tissues of the human body. The authors therefore hypothesize that the club-or bulb-shaped nerve endings in the human scleral spur are afferent mechanoreceptors that measure stress or strain in the connective tissue elements of the scleral spur. Such changes might be induced by ciliary muscle contraction and/or by changes in intraocular pressure.

Effects of sympathetic innervation on size of myocytes in embryonic rat heart cultured in oculo.

Embryonic rat myocardium cultured in the anterior eye chamber of an adult rat increases in mass and differentiates into mature myocardium by most morphological criteria [1]. When sympathetic innervation of grafted heart tissue was prevented by superior cervical ganglionectomy (SCGx), growth of the grafts was severely compromised. The present study used morphometric methods to examine the contribution of myocyte size to the differential growth of grafts in sympathetically denervated and intact eye chambers. For this purpose, atria or ventricles from 12-day gestation rat hearts were grafted into sympathetically denervated and intact eye chambers of male host rats. Tissue was harvested after either 2 or 8 weeks in oculo. Myocyte diameter and the ratio of cytoplasmic area to nuclear area increased between 2 and 8 weeks in oculo in both atrial and ventricular grafts. In these unloaded heart grafts, estimated myocyte size did not differ between atrial and ventricular myocytes. Grafts into sympathetically innervated and denervated eye chambers did not differ in myocyte diameter or in the ratio of cytoplasmic to nuclear area, suggesting that myocyte size cannot explain the smaller mass of grafts in sympathetically denervated eye chambers. Thus, it is likely that other factors such as myocyte proliferation, myocyte survival or altered tissue composition underlie the lesser growth of grafts not innervated by sympathetic nerves.

Toxic effects of lead on neuronal development and function.

The effects of lead on the development of the nervous system are of immediate concern to human health. While it is clear that lead can affect neuronal development at levels of exposure within the range found in the environment, the particular mechanism of the disruption is not readily ascertained. Lack of knowledge of the mechanisms of lead-induced damaged hampers its treatment and prevention. The goal of our research is to develop a model system in which the effects of lead on central nervous system development can be demonstrated. The complexity of the brain hampers such investigations because often it is not clear if apparent toxic effects represents changes secondary to somatic changes, such as endocrine or hematological defects, that could alter brain development, or even transneuronal effects caused by toxicity at a distal site that deprives a brain area of a synaptic input needed for its proper development. A related problem is the redundancy of compensatory systems in the brain. Such system may disguise the severity of the initial toxic insult and themselves can cause functional disturbances. To study neuronal development in a system that minimizes such difficulties, we have grafted discrete brain regions derived from rat fetuses into the anterior chamber of the eye of adult hosts. The brain pieces continue organotypic development of the eye, but are isolated from possible secondary changes due to alterations in the development of the endocrine and other somatic systems because the adult host has these systems already fully developed. Similarly, effects mediated by connecting brain areas are minimized since the transplant is isolated in the anterior chamber of the eye.(ABSTRACT TRUNCATED AT 250 WORDS)

The innervation of the rabbit's anterior eye segment: a retrograde tracing study.

The differential innervation of the distinct elements of the anterior segment of the rabbit eye, i.e. cornea, conjunctiva, ciliary body, iris, and trabecular meshwork, was studied using horseradish peroxidase-wheatgerm agglutinin (HRP-WGA) as a tracer. HRP-WGA was injected into the anterior chamber, the conjunctiva, or the cornea, and the animals were killed after 6 to 96 hr. The HRP-WGA localization was studied at the light and electron microscopic level. Injection into the anterior chamber led to an ubiquitous spread of the tracer in all elements of the anterior segment, resulting in a consistent retrograde labelling of neurons in the trigeminal (sensory), superior cervical (sympathetic) and ciliary (parasympathetic) ganglion. Neurons in the proximal part of the pterygopalatine ganglion (parasympathetic) were labelled only when the injected tracer was present in the conjunctiva. Varying survival times after corneal injection were used to establish restricted corneal uptake. Up to 16 hr after corneal injection, HRP-WGA was limited to the cornea and led to the exclusive labelling of neurons in the trigeminal ganglion, indicating that the central cornea has an almost exclusive sensory innervation. The trigeminal sensory neurons projecting to the cornea were restricted to a small antero-medial part of the trigeminal ganglion. Electron microscopy revealed four different cell types in the trigeminal ganglion. However, distinct elements of the anterior segment did not project to specific cell types.

Re-innervation of pancreatic tissue implants in normal and in sympathetically denervated eyes of rats.

Embryonic, newborn and adult pancreatic tissue fragments were implanted into the anterior eye-chamber of rats of the same offspring to determine whether there is any difference in the pattern of their re-innervation. In another experiment the embryonic pancreatic tissue fragments were implanted into sympathetically denervated eyes of homologous rats. Newborn, adult and embryonic pancreatic tissue implants were removed under a stereo-microscope after 17, 45 and 53 days, respectively. The embryonic pancreatic tissue implants in denervated eyes were removed after 46 days. The implants were processed for electron microscopy. The embryonic, newborn and adult pancreatic tissue implants were equally well re-innervated by agranular and granular vesicle-containing nerve terminals and varicosities from the host iris. The embryonic pancreatic tissue implants were also re-innervated in sympathetically denervated eyes, most likely by parasympathetic nerves of the iris. Except for the few intrinsic nerve profiles, the re-innervating nerve fibres seemed to reach the implant stroma through the blood vessels revascularizing the implants. The re-innervation of the endocrine pancreas is more pronounced than that of the whole tissue.

Sympathetic innervation alters growth and intrinsic heart rate of fetal rat atria maturing in oculo.

The influence of sympathetic innervation on the growth and intrinsic rate of beating established by fetal rat heart was studied by culturing fetal atrial tissue in sympathetically innervated and denervated anterior eye chambers of adult Sprague-Dawley rats. One anterior eye chamber in each host rat was sympathetically denervated by removing the ipsilateral superior cervical ganglion. In oculo, atrial grafts were vascularized by blood vessels sprouting from the iris and innervated by sympathetic and parasympathetic fibers from the ground plexus of the iris. Innervation was assessed by light-activated efferent nerve stimulation to the grafts that changed their rates of beating. The norepinephrine contents of 16 atria cultured for 2.5 months in sympathetically innervated and denervated eye chambers were 5.7 +/- 1.1 ng/implant vs. 0.2 +/- 0.07 ng/implant (mean +/- SEM), indicating permanent sympathetic denervation of the anterior eye chamber and the implanted atria. By 8 weeks in oculo, atria maturing in sympathetically innervated anterior eye chambers were 86% larger than those in denervated eye chambers (2.22 +/- 0.29 vs. 1.19 +/- 0.13 mm2); the weight of innervated transplants was over 3 times that of noninnervated grafts (2.35 +/- 0.75 vs. 0.76 +/- 0.21 mg). After implanted atria had ceased growing rapidly (2.5 months in oculo), bipolar electrodes were implanted adjacent to the cornea to record impulses from atrial grafts while host rats were unanesthetized. The dark-adapted baseline heart rates of sympathetically innervated and noninnervated atria were virtually identical (289 vs. 290 bpm). Graft intrinsic heart rate was estimated by combined beta-adrenergic and muscarinic receptor blockade with atenolol (1.0 mg/kg) and methylatropine (10 micrograms/kg). Sympathetically innervated transplants had lower intrinsic heart rates than noninnervated atria (134 +/- 25 vs. 213 +/- 12 bpm). These data suggest that sympathetic innervation of the developing heart influences both growth and intrinsic rate of beating.

Survival and growth of neurons with enkephalin-like immunoreactivity in fetal brain areas grafted to the anterior chamber of the eye.

Areas of fetal rat brain and spinal cord known to contain enkephalin-like immunoreactive cell bodies and/or terminal fields were transplanted to the anterior chamber of the eye of adult rats. Enkephalin-like immunoreactive neurons survive and produce an enkephalin-like immunoreactive fiber network within grafts of spinal cord, ventral medulla oblongata, ventrolateral pons, tectum, locus coeruleus, substantia nigra and the areas containing columna fornicis and globus pallidus. Although single intraocular grafts of neocortex do not apparently contain enkephalin-like immunoreactive fibers, such grafts contain a variable amount of sparsely distributed enkephalin-like fibers when sequentially grafted in oculo with either locus coeruleus or spinal cord. Combinations of locus coeruleus and globus pallidus contained a rich enkephalin fiber network in the locus coeruleus part and a sparse innervation of the globus pallidus part. We conclude that enkephalin-like immunoreactive neurons in small areas of fetal rat brain can be successfully transplanted to the anterior chamber of the eye. They are able to survive and develop to maturity in complete isolation from the rest of the brain. In general, the enkephalin-like immunoreactive fiber density in the various single grafts approximated that of their brain counterparts in situ. Fiber formation can be reinitiated in mature enkephalin-like immunoreactive neurons by addition of new brain target areas. Thus, the technique permits establishment of isolated, defined enkephalin systems and pathways accessible to functional analysis.

Comparison of neuronal activity in septal and hippocampal grafts developing in the anterior eye chamber of the rat.

Septal and hippocampal tissue of the rat embryos (17-18 days of gestation) was transplanted into the anterior eye chamber of adult rats. Four to six months later the grafts with the piece of iris were transferred into an incubating chamber, and extracellular registration of neuronal activity was performed. Septal grafts (SG) were characterised by the presence of a greater number (70%) of spontaneously-active units, than the hippocampal grafts (HG, 41%). The level of activity in SG units was higher (mean 2.2 spikes X s-1, maximal 24 spikes X s-1), than in HG (mean 1.0 spikes X s-1, maximal 3.0 spikes X s-1). Among spontaneously active HG units, the cells with 'complex spikes' constituted the majority; in SG, besides the units with irregular single spike activity, the neurons with regular pacemaker-like and rhythmic burst (0.5-5 per s) activity were present. Stimulation of interface between iris and a graft evoked a single-spike or short burst responses in HG units. In SG, responses were tonic with gradual increase of discharge frequency or with repetitive bursts; in some cases suppression of the activity was observed. Responses of HG units followed repetitive stimulation up to 30-50 Hz and were characterized by prominent frequency potentiation. This was not observed in the SG units. These data show that embryonal nervous tissue differentiating in the anterior eye chamber develops some organotypic features of spontaneous and evoked activity similar to the activity of corresponding structures in normal conditions and in slices of adult brain.

Spinal cord grafts: an intraocular approach to enigmas of nerve growth regulation.

The possible usefulness of intraocular transplantation in studies of spinal cord growth and regeneration has been evaluated. Defined segments of fetal rat spinal cord were grafted to the anterior chamber of the eye of adult rats. Such grafts become vascularized from the host iris, grow and develop neuron types, myelinated fiber bundles, astroglial populations (as shown by GFA-immunoreactivity), and electrical activity reminiscent of such features in normal spinal cord tissue. The intraocular technique permits studies of intrinsic circuitries as well as conditions for formation of afferent and efferent connections with the host iris and with other central or peripheral tissues which can be grafted into contact with the spinal cord grafts. One example of an intrinsic system preserved in the grafts is a rich network of nerve fibers with enkephalin-like immunoreactivity. When combined with cerebral cortex, the enkephalin-positive neurons of the spinal cord graft are able to form only very limited projections to the cortex graft. Special emphasis was given the possible formation of adrenergic afferents to spinal cord grafts. No appreciable ingrowth of peripheral sympathetic nerves occurred. Locus coeruleus grafts have many organotypical electrophysiological characteristics and were able to innervate adjacent spinal cord grafts provided that the sensory innervation of the host iris was removed. Experiments such as these suggest that "negative neurotropic" factors may be present in spinal cord and possibly relate to the unique relationship between spinal ganglia and spinal cord.