Erwin-J. Speckmann

A portable chamber for long-distance transport of surviving human brain slice preparations

Incubation chambers for surviving brain slice preparations are in most cases designed to be stationary. For investigations on human brain tissue resected for the treatment of brain tumor or epilepsy, portable incubation chambers are needed in addition to stationary ones to allow transport of the slices between laboratories and hospitals located far from each other. For such purposes, interface chambers have been in use. In view of the ongoing discussion of the merits of interface versus submerged baths, here we describe an alternative chamber as a lightweight, easy to assemble portable bath of the submersion type for transport of surviving brain slice preparations over considerable distances. The chamber has been used in a variety of investigations on human brain slices. These slice preparation showed bioelectric properties comparable to those reported in investigations by other laboratories using stationary incubation chambers in cases where portable ones were not needed.

Heat shock protein-27 is upregulated in the temporal cortex of patients with epilepsy.

Summary:  Purpose: Heat shock protein‐27 (HSP‐27) belongs to the group of small heat shock proteins that become induced in response to various pathologic conditions. HSP‐27 has been shown to protect cells and subcellular structures, particularly mitochondria, and serves as a carrier for estradiol. It is a reliable marker for tissues affected by oxidative stress. Oxidative stress and related cellular defence mechanisms are currently thought to play a major role during experimentally induced epileptic neuropathology. We addressed the question whether HSP‐27 becomes induced in the neocortex resected from patients with pharmacoresistant epilepsy.

Multireceptor analysis in human neocortex reveals complex alterations of receptor ligand binding in focal epilepsies

Purpose:  A disturbed balance between excitatory and inhibitory neurotransmission underlies epileptic activity, although reports concerning neurotransmitter systems involved remain controversial.

Continuous measurement of pentylenetetrazol concentration by a liquid ion exchanger microelectrode

A double-barrelled microelectrode is described, which permits the continuous measurement of the concentration of the epileptogenic agent pentylenetetrazol (PTZ). The electrode is based on the liquid potassium exchanger (Corning No. 477 317) and enables measurements of PTZ concentration in physiological salines down to 1 mM. The electromotive behaviour of the liquid membrane against PTZ cannot directly be described by the Nicolsky-Eisenman formalism. It is suggested that specific interactions of the PTZ molecule with the Corning ligand are involved in the potential generating mechanisms.

Microcutting of living brain slices by a pulsed ultrafine water jet which allows simultaneous electrophysiological recordings (micromingotome)

Up to now microsurgical dissections in living nervous tissue (e.g. in slices or cell cultures) are performed either by micro-scalpels or by laser beams. As an alternative technique, a device for cutting with an ultrafine pulsed water jet was developed to allow precise, visually controled dissections in neuronal circuits even during electrophysiological recordings. Water is ejected by pressure (20-30 bar) from patch pipettes with tip diameters of 10-12 microm. By means of a piezo-element the pipette and the water jet are forced to oscillate vertically with a frequency of 200-400 Hz with an adjustable amplitude. These oscillations facilitate the transsection of neuronal connections even in thick slice preparations. Best results were obtained when the tip of the pipette was about 500 microm above the surface of the submerged slice tissue. This micromingotome offers the following advantages: (i) histological studies show that the water jet cleans the cutting surface, thus avoiding debris and its uncontrolable effects on cells underneath; (ii) the arrangement enables ongoing electrophysiological recordings from hippocampal slices during the cutting procedure and thus facilitates studies of the functions of neuronal connections; (iii) the device allows even disconnection in cultured nervous tissue overgrowing polyamid grids with 50 microm wide meshes.

Optical monitoring of PO2 changes and simultaneous recording of bioelectric activity in human and animal brain slices

For investigations of hypoxic effects in nervous tissue, brain slices are often used as a model system. This provides the advantage that parameters of the micromilieu, e.g. pH and temperature can easily be controlled and measurements of different data, e.g. bioelectric potentials, ion activities etc. can be performed. It is of special importance that the PO2 the slice preparation is exposed to is equally controlled under these conditions. Therefore, a PO2 monitoring system is needed which provides representative values for the tissue environment. This requirement is fulfilled by an optical PO2 sensing method based on phosphorescence quenching as a function of PO2. Here, the application of this method as adapted for use in in vitro models is described and compared to the polarographic oxygen-sensing method. Both the optical and polarographic methods are comparable regarding accuracy and response time of measurements. Furthermore, both the optical method and electrophysiological measurements can be combined. Lastly, under experimental conditions, neither the phosphorescent dye Palladium-meso-tetra-4-carboxyphenyl-porphine nor the illumination necessary for excitation of the dye influence bioelectric activity of neuronal tissue in vitro. In conclusion, the optical PO2 sensing method presented here provides a tool for reliable and continuous monitoring of PO2 in the immediate environment of brain slice preparations.

Cutting of living hippocampal slices by a highly pressurised water jet (macromingotome).

Living brain slices are usually cut with razor blades, which compress a ca. 50-microm-thick layer of tissue. This results in cell debris and lesioned cells which, e.g. form diffusion barriers between the bath and living neurons underneath, thereby prolonging response times of neurons to drugs in the bath saline and impeding the experimental access to intact neurons. To avoid such drawbacks, a macromingotome was developed which cuts nervous tissue with water jets. Physiological saline under pressures of 100-1800 bar was ejected through nozzles of 35-100 microm to cut 300-500-microm-thick hippocampal slices. Systematic variations of pressure and nozzle diameter revealed best results at 400-600 bar and with nozzle diameters of 60-80 microm. Under these conditions, intact CA1- and CA3-neurons as well as granule cells were detected with infrared microscopy at less than 10 microm underneath the surface of the slice. Superficial neurons with intact fine structures were also seen when the slices were studied by light-microscopy. Intra- and extracellular recordings from superficial neurons showed normal membrane- and full action potentials and the development of stable epileptiform discharges in 0 Mg(2+)-saline. These results indicate that the macromingotome offers an alternative way of cutting slices which may facilitate electrophysiological/neuropharmacological or fluorometric studies on superficial neurons.

Seizure Semiology, Neurotransmitter Receptors and Cellular-stress Responses in Pentylenetetrazole Models of Epilepsy

Ongoing research has elucidated a large variety of genes, proteins and enzyme products that are affected in epilepsy. Despite the pharmacological advances achieved by the development of antiepileptic drugs, numerous patients become pharmacoresistant. Therefore, animal models addressing these complex interactions among compensatory gene-expression cascades and consecutive molecular mechanisms are still a necessity for research-based gene and pharmacotherapy. In this article, we focus on pentylenetetrazole models to study the consequences of tonic–clonic seizures. We address two complex and closely linked aspects: alterations in neurotransmission and oxidative-stress responses. Reviewing just these two aspects highlights the need for a more standardised use of animal models and methods to allow a better integration of data from different lines of research. The latter will be most applicable for the understanding of complex disease-related interactions of gene networks, proteins and enzyme products and timely, research-based development of future therapeutic options.

Fast, quantitative in situ hybridization of rare mRNAs using 14C-standards and phosphorus imaging.

The use of radiolabelled probes for in situ hybridization (ISH) bears the advantage of high sensitivity and quantifiability. The crucial disadvantages are laborious hybridization protocols, exposition of hybridized sections to film for up to several weeks and the time consuming need to prepare tissue standards with relatively short-lived isotopes like (33)P or (35)S for each experiment. The quantification of rare mRNAs like those encoding for subunits of neurotransmitter receptors is therefore a challenge in ISH. Here, we describe a method for fast, quantitative in situ hybridization (qISH) of mRNAs using (33)P-labelled oligonucleotides together with (14)C-polymer standards (Microscales, Amersham Biosciences) and a phosphorus imaging system (BAS 5000 BioImage Analyzer, Raytest-Fuji). It enables a complete analysis of rare mRNAs by ISH. The preparation of short-lived (33)P-standards for each experiment was replaced by co-exposition and calibration of long-lived (14)C-standards together with (33)P-labelled brain paste standards. The use of a phosphorus imaging system allowed a reduction of exposition time following hybridization from several weeks to a few hours or days. We used this approach as an example for applications to quantify the expression of GluR1 and GluR2 subunit mRNAs of the alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) receptor in the hippocampus of untreated rats, and after intraperitoneal application of the organo-arsenic compound dimethyl arsenic acid.