Pathological consequences of inducible nitric oxide synthase expression in hippocampal slice cultures.

The generation of toxic concentrations of nitric oxide by the inducible nitric oxide synthase expressed in microglia and other brain cell types is frequently invoked as a causative factor in neurodegeneration. Experiments were carried out on slice cultures of rat hippocampus to test this hypothesis. Exposure of the slices to bacterial lipopolysaccharide plus interferon-gamma led to a time-dependent expression of functional inducible nitric oxide synthase that was found only in microglia. Microglial activation by other means, such as physical damage, was not associated with inducible nitric oxide synthase expression. Damage and cell death in slices expressing inducible nitric oxide synthase was evaluated over a period of 6 days, but none was found. Consistent with this result, cGMP measurements indicated that the average local nitric oxide concentration remained in the low nanomolar range. When the microglial population was expanded to a density three-fold above normal by applying granulocyte-macrophage colony stimulating factor, however, lipopolysaccharide plus interferon-gamma provoked neurodegeneration that could be blocked by an inducible nitric oxide synthase inhibitor. The associated nitric oxide concentration in the slices was saturating for guanylyl cyclase-coupled nitric oxide receptors, signifying at least 10 nM. It is concluded that inducible nitric oxide synthase is expressed in microglia only in response to specific stimuli involving the innate immune system, and that the resulting level of nitric oxide in intact brain tissue is normally too low to inflict damage directly. Quantities of nitric oxide sufficient to contribute directly or indirectly to pathology could be produced should the density of microglia become high enough, although caution must be exercised in extrapolating this finding to the human brain in vivo.

Infection of organotypic slice cultures from rat central nervous tissue with Trypanosoma brucei brucei.

We recently described a new procedure to grow nervous tissue as organotypic culture. The main feature of these slice cultures is to maintain a well preserved, three-dimensional organisation of the central nervous tissue. As these cultures can be kept for several weeks (up to three months), we have used this in vitro approach to study the complex interactions between host tissue and parasites during late stages of cerebral African trypanosomiasis. Light and electron microscopical studies, as well as electrophysiological recordings demonstrate that the structure and function of the nervous tissue is not severely affected even after several weeks of trypanosome infection. The presence of a large number of parasites does not seem to be deleterious to neuronal survival. Secondly, most of the trypanosomes are located around the periphery of the nervous tissue, but many of them also penetrate into the nervous parenchyma. Thirdly, trypanosomes with well-conserved morphology are found within the cytoplasm of glial cells, which in some cases were identified as astrocytes. These "intracellular parasites" seem to actively invade the target cells. Our study demonstrates that the presence of proliferating trypanosomes does not per se interfere with the neural activity of CNS tissues. Secondly, it provides, to the best of our knowledge, the first in vitro demonstration of intracellular forms of African trypanosomes.

A metallic multisite recording system designed for continuous long-term monitoring of electrophysiological activity in slice cultures.

This paper describes a flexible, metallic multielectrode array, made on kapton to fit in a recording chamber for interface-type organotypic cultures. This multisite recording system is designed for continuous multisite monitoring of electrophysiological activity in rat brain organotypic slice cultures. The system is composed of a signal conditioning set-up, which also masters electrical stimulation paradigms and a card containing the microelectrode array. The card comprises a perfusion chamber closed by a rigid and permeable membrane on which the pierced microelectrode array supporting the slice culture is placed. Once closed with a gaseous chamber, the inside of the card remained sterile and free of contamination and could be maintained inside or outside the incubator for electrophysiological analyses. Dimensions of each 28-plated gold microelectrode recording site are 50 microns x 100 microns. The design of the chambers and the card makes it possible to modify both the perfusion medium and the gaseous atmosphere in sterile conditions, allowing thus analyses of long-term effects of pharmacological compounds. Using this array one can perform stimulation and recordings of the electrical activity of the slice. Signals obtained with this reusable system exhibit a good signal-to-noise ratio. This device was tested to follow the evolution and modifications of the evoked and/or spontaneous electrical activity of the same groups of neurones during several days.

An in vitro blood-brain barrier model: cocultures between endothelial cells and organotypic brain slice cultures.

This communication describes a novel in vitro blood-brain barrier (BBB) model: organotypic slice cultures from the central nervous system were overlaid on endothelial cell monolayers grown on permeable membranes. Morphological, electrophysiological, and microdialysis approaches were carried out to characterize and validate this model. After 10 days in coculture, morphological studies reveal the presence of tight junctions. Electrophysiological recordings of neuronal activity performed on organotypic cultures with or without an endothelial cell monolayer show that amplitude of evoked responses were comparable, indicating good viability of cocultures after 2 weeks. Perfusion of known BBB permeable or nonpermeable molecules was used to test the coculture tightness in conjunction with electrophysiological or microdialysis approaches: application of glutamate (Glu), which doesn't easily cross the BBB, triggers off rhythmic activity only in control cultures, whereas epileptogenic activity was observed in both control cultures and cocultures during perfusions with picrotoxin, a molecule that can diffuse through the BBB. Finally, the microdialysis technique was used to determine the permeability of molecules coming from the perfusion chamber: L-dopa, dopamine, and Glu were employed to assess the selective permeability of the coculture model. Thus, these results indicate that the in vitro model described possesses characteristics similar to those of the BBB in situ and that cocultures of organotypic slices and endothelial cell monolayers have potential as a powerful tool for studying biochemical mechanisms regulating BBB function and drug delivery to the central nervous system.

A new extracellular multirecording system for electrophysiological studies: application to hippocampal organotypic cultures.

The present paper describes a new multirecording device which performs continuous electrophysiological studies on organotypic cultures. This device is formed by a card (Physiocard) carrying the culture which is inserted into an electronic module. Electrical activities are recorded by an array of 30 biocompatible microelectrodes which are adjusted into close contact with the upper surface of the slice culture. The microelectrode array is integrated into the card enabling electrical stimulation and recording of neurons over periods ranging from several hours to a few days outside a Faraday cage. Neuronal responses are recorded and analyzed by a dedicated electronic and acquisition chain. A perfusion chamber is contained in the card, allowing continuous perfusion in sterile conditions. Electrophysiological extracellular recordings and some drugs' effects obtained with this system in hippocampal slice cultures were identical to conventional electrophysiological set-up results with tetrodotoxin, bicuculline, kainate, dexamethasone and NBQX. The Physiocard system allows new insights for studies on nervous tissue and allows sophisticated approaches to be used quicker and more easily. It could be used for various neurophysiological studies or screening tests such as neural network mapping, nervous recovery, epilepsy, neurotoxicity or neuropharmacology.

Electrophysiological approach of the antiepileptic effect of dexamethasone on hippocampal slice culture using a multirecording system: the Physiocard.

The in vitro antiepileptic activity of the synthetic glucocorticoid dexamethasone (DEX) was tested in rat hippocampal organotypic cultures on the field potential epileptiform activity induced by picrotoxin (PTX). Spontaneous as well as evoked electrophysiological activities have been studied through the extracellular multirecording Physiocard system. PTX typically elicited seizure-like discharges (epileptiform bursts) in the hippocampus neurons. Those epileptiform bursts can be divided in two groups, one rhythmic which lasted 43+/-24s (mean+/-sd) at a frequency of 4.6+/-1.9Hz and the other arhythmic composed of population spikes, which occurred during 14.3+/-6.9min. In the presence of DEX at different concentrations, results obtained were: 1) DEX 1 microM decreased the occurrence of the two different groups of spontaneous epileptiform bursts, most of the time to zero. 2) DEX 50 microM prevented totally the occurrence of epileptiform bursts. 3) DEX 50 microM contrarily to DEX 1 microM avoided the decrease of evoked field potentials' amplitude induced by PTX 3 microM on all simultaneous recorded points. Those results suggest that synthetic glucocorticoid DEX presents an acute antiepileptic effect in a dose dependent manner on the hippocampus tissue.