High frequency stimulation or elevated K+ depresses neuronal activity in the rat entopeduncular nucleus.

High frequency stimulation (HFS) is applied to many brain regions to treat a variety of neurological disorders/diseases, yet the mechanism(s) underlying its effects remains unclear. While some studies showed that HFS inhibits the stimulated nucleus, others report excitation. In this in vitro study, we stimulated the rat globus pallidus interna (entopeduncular nucleus, EP), a commonly stimulated area for Parkinson's disease, to investigate the effect of HFS-induced elevation of extracellular potassium (K(+)(e)) on rat EP neuronal activity. Whole-cell patch-clamp recordings and [K(+)](e) measurements were obtained in rat EP brain slices before, during and after HFS. After HFS (150 Hz, 10 s), [K(+)](e) increased from 2.5-9.6+/-1.4 mM, the resting membrane potential of EP neurons depolarized by 11.1+/-2.5 mV, spiking activity was significantly depressed, and input resistance decreased by 25+/-6%. The GABA(A) receptor blocker, gabazine, did not prevent these effects. The bath perfusion of 6 or 10 mM K(+), with or without synaptic blockers, mimicked the HFS-mediated effects: inhibition of spike activity, a 20+/-9% decrease in input resistance and a 17.4+/-3.0 mV depolarization. This depolarization exceeded predicted values of elevated [K(+)](e) on the resting membrane potential. A depolarization block did not fully account for the K(+)-induced inhibition of EP neuronal activity. Taken together, our results show that HFS-induced elevation of [K(+)](e) decreased EP neuronal activity by the activation of an ion conductance resulting in membrane depolarization, independent of synaptic involvement. These findings could explain the inhibitory effects of HFS on neurons of the stimulated nucleus.

[Opsoclonus-myoclonus syndrome in children].

To study clinical peculiarities of parainfectious opsoclonus-myoclonus syndrome (OMS) in children and to elaborate approaches to its pharmacotherapeutic correction, 20 children, including 12 girls and 8 boys, have been examined using neurological, neurophysiological, immunological and virological methods along with magnetic resonance tomography (MRT). Age-at-disease-onset was from 8 months to 3 years old. The development of neurological symptoms was related to a virus infection (55% of cases) or vaccination (15%). Marked disease seasonality (autumn, spring) was observed. In some cases, a possible role of infectious factor in the disease development was confirmed by virological and immunological studies. OMS was featured by the absence of specific brain MRT changes and low frequency of significant abnormalities of cerebrospinal fluid. A positive experience of the use of hormonal therapy and immunomodulators is presented.

Model of frequent, recurrent, and spontaneous seizures in the intact mouse hippocampus.

This study presents a model of chronic, recurrent, spontaneous seizures in the intact isolated hippocampal preparation from mice aged P8-P25. Field activity from the CA1 pyramidal cell layer was recorded and recurrent, spontaneous seizure-like events (SLEs) were observed in the presence of low Mg2+ (0.25 mM) artificial cerebrospinal fluid (ACSF). Hippocampi also showed interictal epileptiform discharges (IEDs) of 0.9-4.2 Hz occurring between seizures. No age-specific differences were found in SLE occurrence (2 SLEs per 10 min, on average), duration, and corresponding frequencies. After long exposure to low Mg2+ ACSF (>3 h), SLEs were completely reversible within minutes with the application of normal (2 mM Mg2+) ACSF. The AMPA antagonist, CNQX, blocked all epileptiform activity, whereas the NMDA antagonist, APV, did not. The gamma-aminobutyric acid (GABA)A antagonist, bicuculline, attenuated and fragmented SLEs, implicating interneurons in SLE generation. The L-type Ca2+ blocker, nifedipine, enhanced epileptiform activity. Analysis of dual site recordings along the septotemporal hippocampus demonstrated that epileptiform activity began first in the temporal pole of the hippocampus, as illustrated by disconnection experiments. Once an SLE had been established, however, the septal hippocampus was sometimes seen to lead the epileptiform activity. The whole hippocampus with intact local circuitry, treated with low Mg2+, provides a realistic model of recurrent spontaneous seizures, which may be used, in normal and genetically modified mice, to study the dynamics of seizures and seizure evolution, as well as the mechanisms of action of anti-epileptic drugs and other therapeutic modalities.

Studies of the structure of glutamate receptor ion channels and the mechanisms of their blockade by organic cations.

The structural determinants for blockade of the AMPA and NMDA subtypes of glutamate receptors were studied by analysis of structural-functional relationships in a series of mono- and dicationic compounds. The results showed that the hydrophobic and nucleophilic components of the blocker binding sites are located close to each other in the channel of the NMDA receptor, while they are spatially distant in the channel of the AMPA receptor. Molecular mechanical methods were used to construct models of these channels satisfying these topographic criteria and providing adequate descriptions of the binding of the channel blockers. According to the models, binding of blockers to the NMDA channel occurs in the selective filter of the channel (the N/Q/R site). The nucleophilic region of the AMPA channel is formed by the oxygen atoms of glycine residues in position +2 relative to the selective filter. Identification of the major relationships between the molecular structure of the ion channels of these glutamate receptor subtypes and their blockade by organic cations allows the further synthesis of AMPA and NMDA channel blockers with specified levels of activity and selectivity to be directed.

Calcium signaling components of oscillating invertebrate neurons in vitro.

We have studied the Ca(2+) dynamics of bursting-spiking neurons in the lobster stomatogastric ganglion. Neurons in this ganglion undergo spontaneous oscillations in membrane voltage with a period of 1-10 s in situ. We found that neurons isolated from the ganglion and filled with the fluorescent calcium indicator Fluo-4 show simultaneous changes of membrane potential and cytoplasmic Ca(2+) concentration ([Ca(2+)](I)). These Ca(2+) signals are highly heterogeneous both in terms of amplitude and time constants. They showed variable spatial distributions with the soma exhibiting low and slow signals, and a region in the process with large and fast signals. Ca(2+) transients in the processes are dependent on external Ca(2+) and can be blocked by Co(2+), but not other, more specific Ca(2+) current blockers. Rather, nifedipine a known Ca(2+) current blocker, affects the distribution of the Ca(2+) signal, which suggests a specific localization of Ca(2+) channels. Although the signal is not absolutely dependent on action potentials, it is greatly reduced when action potentials are blocked by tetrodotoxin. Termination of the signal depends only slightly on Ca(2+) buffering mechanisms such as mitochondria, Ca(2+)/Na(+) and Ca(2+)/H(+) exchangers. We also demonstrate the presence of caffeine-sensitive internal stores in stomatogastric ganglion cells. The store distribution is different but overlaps with the voltage-dependent distribution. The maximal caffeine-activated Ca(2+) signal is in the soma and it is smaller in the processes. Unlike the voltage-activated Ca(2+) signal this signal is not blocked by Co(2+). Nevertheless, the two types of signal interact during caffeine application. This unique spatial separation of two Ca(2+) sources may have important functional implication.

Structural characteristics of ionotropic glutamate receptors as identified by channel blockade.

The channels of four types of ionotropic glutamate receptor (NMDA receptors and Ca-permeable AMPA receptors of rat brain neurons, and cation-selective receptors from mollusk neurons and insect postsynaptic muscle membranes) and two subtypes of nicotinic cholinoreceptor (from frog neuromuscular junctions and cat sympathetic ganglia) were studied. The structural characteristics of channels determining their susceptibility to blockade by organic mono- and dications were identified. These studies used homologous series of adamantane and phenylcyclohexyl derivatives. These experiments showed that the receptors studied here could be divided into two groups. The first group included the AMPA receptor and the mollusk and insect receptors. These were characterized by the lack of effect on the part of monocations and a strong relationship between the activity of dications and the distance between nitrogen atoms. The second group included the NMDA receptor and both subtypes of the nicotinic cholinoreceptor (muscular and neuronal). Here, conversely, the activity of monocations and dications, regardless of their lengths, were essentially identical. A model for the binding sites of blockers in channels is proposed, which takes these observations into account.

[Structure of glutamate receptor ion channels and mechanisms of their blockade by organic cations]. / Issledovanie stroeniia ionnykh kanalov retseptorov glutamata i mekhanizmov ikh blokady organicheskimi kationami.

Structural determinants of blocking the glutamate receptors of AMPA and NMDA subtypes, were studied. Close location of hydrophobic and ammonium groups is necessary for affective blocking of the NMDA receptor channels, whereas blockers of the AMPA receptor channels have a distance of about 10 angstroms between these two groups. Models of the channels meeting these topographic data have been devised using a molecular mechanics approach. The accomplished studies revealed molecular basis of channel blockade of the NMDA and AMPA receptors. This may allow designing predictable new blocking compounds with a desired selectivity.

[Structural characteristics of ionotropic glutamate receptors revealed by channel blockade]. / Strukturnye osobennosti ionotropnykh glutamatnykh retseptorov, vyiavliaemye blokadoi kanalov.

The topography of the channel binding site in glutamate receptors (AMPA and NMDA types of rat brain neurons, receptors of molluscan neurons and insect muscle), and in two subtypes of nicotinic cholinoreceptors (in frog muscle and cat sympathetic ganglion), has been investigated by comparison of the blocking effects of mono- and dicationic derivatives of adamantane and phenylcyclohexyl. The channels studied can be divided into two groups. The first one includes AMPA receptor and glutamate receptors of mollusc and insect, and is characterised by the absence of activity of monocationic drugs and the strong dependence of dicationic once on the internitrogen distance in the drug molecule. The second group includes NMDA receptor and both nicotinic cholinoreceptors. Contrary, here the blocking potency of monocations and dications are practically equal irrespective of molecule length. The data obtained suggest that hydrophobic and nucleophilic components of the binding site are located close to each other in the channels of the NMDA receptor type but are separated by approximately 10 A in the AMPA receptor channel.

Voltage-dependent block of native AMPA receptor channels by dicationic compounds.

1. The kinetics of open channel block of GluR2-containing and GluR2-lacking AMPA receptors (AMPAR) by dicationic compounds (IEM-1460, IEM-1754, and IEM-1925) have been studied in rat hippocampal neurones using whole-cell patch clamp recording and concentration-jump techniques. Neurones were isolated from hippocampal slices by vibrodissociation. 2. The dicationic compounds were approximately 100 - 200 times more potent as blockers of GluR2-lacking AMPAR than as blockers of GluR2-containing AMPAR. The subunit specificity of channel block is determined by the blocking rate constant of a dicationic compound, whereas differences in unblocking rate constants account for differences in potency. 3. Hyperpolarization may decrease the block produced by IEM-1460 and IEM-1754 block due to the voltage-dependence of the unblocking rate constants for these compounds. This suggests that dicationic compounds permeate the AMPAR channel at negative membrane potentials. The effect was particularly apparent for GluR2-lacking AMPAR. These findings indicate that the presence of GluR2-subunit(s) in AMPAR hinders the binding of the cationic compounds and their permeation through the channel. 4. The most potent compound tested was IEM-1925. The presence of a phenylcyclohexyl moiety instead of an adamantane moiety, as in IEM-1460 and IEM1754, is probably responsible for the higher potency of IEM-1925. Dicationic compounds are important not only as pharmacological tools, but also as templates for the synthesis of new selective AMPAR blockers which may be potential therapeutic agents.

The open channel blocking drug, IEM-1460, reveals functionally distinct alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate receptors in rat brain neurons.

The properties of alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptors were examined in various cell types isolated from young rat hippocampus, striatum and cerebellum using patch-clamp and fast application techniques. A dicationic adamantane derivative, IEM-1460, reversibly inhibited kainate-induced currents. In the presence of 100 microM IEM-1460, kainate currents in striatal giant cholinergic interneurons and hippocampal non-pyramidal neurons were inhibited by 95% and 81%, respectively, at Vh = - 70 mV. Striatal GABAergic principal cells, hippocampal pyramidal neurons and cerebellar Purkinje cells had low sensitivity to IEM-1460 (inhibition by 4-15%). Analysis of averaged data from the cell types studied revealed a highly significant positive correlation (r= 0.93, P < 0.01) between percentage inhibition by 100 microM IEM-1460 and relative calcium permeability of AMPA receptors, P(Ca)/P(Na). Also, within each brain structure, the sensitivity of IEM-1460 block was lower the stronger the outward rectification of kainate currents. Some hippocampal neurons exhibited intermediate sensitivity to IEM-1460. Kainate currents were suppressed by 40% in the presence of 100 microM IEM-1460. Meanwhile, AMPA receptors in this cell type had low calcium permeability (P(Ca)/P(Na) = 0.13) and demonstrated outwardly rectifying kainate currents. The interrelation of different properties of AMPA receptors considering their assembly is discussed. The data obtained suggest that IEM-1460 may be a convenient and promising marker of native AMPA receptor assembly: it selectively inhibits Ca(2+)-permeable, GluR2-lacking AMPA receptors.

Characterization of AMPA receptor populations in rat brain cells by the use of subunit-specific open channel blocking drug, IEM-1460.

Dicationic adamantane derivative, IEM-1460, which selectively blocks GluR2-lacking, Ca2+-permeable alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionate (AMPA) receptors, was used to characterize the distribution of AMPA receptors among populations of rat brain cells. IEM-1460 inhibited kainate-induced inward currents (at -80 mV) in a dose-dependent manner. IEM-1460 concentrations producing 50% inhibition of kainate-induced current amplitude (IC50) varied greatly depending on the cell type studied. Striatal giant cholinergic interneurons and putative Bergmann glial cells isolated from the cerebellum were found to be highly sensitive to IEM-1460 block (IC50=2.6 microM), indicating the expression of GluR2-lacking AMPA receptor subtype. Among hippocampal and cortical non-pyramidal neurons, there were cell-to-cell differences in the pattern of AMPA receptor subtype expression. Some cells which are known to express AMPA receptors lacking GluR2 subunit exhibited high sensitivity of IEM-1460 block (IC50 about 1 microM) but in the others, the part of AMPA receptor population seemed to be represented by GluR2-having receptor subtype. The latter subtype was mainly expressed by pyramidal neurons isolated from hippocampus (IC50=1102 microM) and sensorimotor cortex (IC50=357 microM) which showed low affinity for IEM-1460 block. In conclusion, IEM-1460 can be utilized as an indicator of the distribution of AMPA receptor subtypes among populations of rat brain cells, and pharmacological detection of the absence of GluR2 subunit in AMPA receptor assembly can provide useful information for the interpretation of physiological events.

Selective block of AMPA/kainate receptors of hippocampal interneurons as a new approach to the investigation of inhibitory system.

Effects of open channel blockers of AMPA/kainate receptors have been examined using whole cell recordings and kainate application in the neurons freshly isolated by vibrodissociation from the rat hippocampal slice preparation. Although the hippocampal neurons differed little in the voltage-current relations and sensitivity to kainate, a prominent difference was found in their susceptibility to the blocking action of adamantane derivatives studied. The pyramidal neurons had low sensitivity to the open channel blockers but the neurons which might be assigned most probably to the group of inhibitory interneurons proved to be highly sensitive. A group of neurons of intermediate sensitivity have also been found. The ability of the same blocking drugs to depress the excitatory inputs in the inhibitory interneurons has been demonstrated in the experiments on the hippocampal slice preparation. Enhancement of the field spike and excitatory postsynaptic potential amplitude was observed in the presence of adamantane derivatives. An additional treatment of the preparation with a GABA receptor antagonist, bicuculline, did not potentiate this effect. In conclusion, the observed difference in the pharmacological properties of inhibitory interneurons may be effectively used for detailed analysis of the brain synaptic transmission.

Block of open channels of recombinant AMPA receptors and native AMPA/kainate receptors by adamantane derivatives.

1. The effects of two adamantane derivatives, 1-trimethylammonio-5-(1-adamantane-methyl-ammoniopentane dibromide) (IEM-1460) and 1-ammonio-5-(1-adamantane-methylammoniopentane dibromide) (IEM-1754) on kainate-induced currents were studied in Xenopus oocytes expressing recombinant ionotropic glutamate receptors and in freshly isolated neurones from rat hippocampal slices. 2. The adamantane derivatives caused use- and voltage-dependent block of open channels of recombinant AMPA receptors. This antagonism was dependent on receptor subunit composition; channels gated by recombinant, homomeric GluR1 and GluR3 receptors exhibited a higher sensitivity to block than those gated by receptors containing edited GluR2 subunits. In the former cases, IEM-1460 had an IC50 of 1.6 microM at a holding potential (Vh) of -80 mV and IEM-1754 was 3.8 times less potent than IEM-1460. In contrast, 100 microM IEM-1460 inhibited responses to 100 microM kainate of receptors containing edited GluR2 subunits by only 7.8 +/- 2.4% (n = 5 oocytes at a Vh of -80 mV. 3. Native AMPA/kainate receptors in isolated hippocampal cells were inhibited by adamantane derivatives in a use- and voltage-dependent manner. This antagonism was dependent on cell type: pyramidal neurones were less sensitive to IEM-1460 (IC50 = 1617 microM at Vh = -80 mV) than interneurones (IC50 = 1.6 microM at Vh = -80 mV). IEM-1460 and IEM-1754 were equipotent when applied to pyramidal neurones, but IEM-1754 was less potent (approximately 3 times) than IEM-1460 when applied to interneurones. 4. It is concluded that the presence of the edited GluR2 subunit in recombinant AMPA receptors and native AMPA/kainate receptors inhibits channel block by organic cations and that adamantane derivatives are potentially valuable tools for identifying classes of AMPA/kainate receptors and their roles in synaptic transmission.

[The effect of divalent cations on the kinetics of the activation and blockade of the nicotinic cholinoreceptor ion channel in rat skeletal muscle]. / Vliianie dvukhvalentnykh kationov na kinetiku aktivatsii i blokady ionnogo kanala nikotinovogo kholinoretseptora skeletnoi myshtsy krysy.

The influence of alkaline earth metal ions calcium and magnesium on the conductance and on the kinetics of activation and atropine-induced blockade of nicotinic cholinoreceptor ion channels in cultured rat skeletal muscle were studied using patch-clamp technique. In physiological concentrations these cations influence both conductance and kinetics of blockade, but have no significant effect on the kinetics parameters of activation. The data suggest that physiological cations modulate the generation of postsynaptic potentials in the normal condition as well as in the presence of blocking drugs.

[The clinical masks of foreign bodies in the bronchi]. / Klinicheskie maski inorodnykh tel bronkhov.

Three cases of foreign bodies in the bronchi, aspiration of which has gone unnoticed for the patients, are considered. In view of great diagnostic difficulties of related inflammation in atelectasis-affected sites of the lungs encountered in such cases, the study of the disease history and bronchological examination seem essential and should be detailed and comprehensive. This is especially true in torpid and atypical course of pneumonia, signs of aspiration and bronchial obstruction.

[A single calcium channel with anomalous rectification in mollusk neurons]. / Odinochnyi kalievyi kanal s anomal'nym vypriamlenium v neironakh molliuska.

The patch clamp technique was used to examine the properties of an inward-rectifying potassium channel in the cell membrane of freshwater mollusc Planorbarius corneus neurons. Inward currents of single channels were observed at potentials more negative than potassium equilibrium potential (EK), when microelectrode contained potassium ions (50 mmol/l) and potassium channel blockers: tetraethylammonium, barium or cesium ions (10-20 mmol/l). The conductance of the single channel was equal to 81 +/- 12 pS at 50 mmol/l potassium ion concentration in the patch electrode. At potentials more positive than EK the conductance sharply decreased to 0 pS. The times of the open state of the closed one of the channel and probability of the open state existing for the ionic channel were estimated with various constant potentials. It was revealed that the channel openings were grouped in bursts. The lifetime of the open state and burst duration decreased with hypopolarization of the patch.

[Comparative research on synaptic transmission in the sympathetic ganglia of rabbits and frogs during acetylcholinesterase inhibition]. / Sravnitel'noe issledovanie sinapticheskoi peredachi v simpaticheskikh gangliiakh krolika i liagushki v usloviiakh ingibirovaniia atsetilkholinésterazy.

Organophosphorus inhibitor of acetylcholinesterase (AChE) armin (1 x 10(-6) M) induced a variety of pre- and postsynaptic effects resulting from the AChE inhibition and subsequent accumulation of acetylcholine (ACh) in the synaptic cleft. The intensity of postsynaptic effects (level of neuron depolarization, degree of action potential depression) was shown to be different in the ganglia of frog and rabbit. This could be explained by differences in the total amount of ACh released in response to nerve stimulation as well as at rest. Both muscarinic and nicotinic cholinoreceptors were involved in the process of sustained depolarization of the neurons in the rabbit superior cervical ganglion after AChE inhibition. In frog ganglion neurons the nicotinic receptors did not participate in depolarization evidently due to their fast desensitization. The activation of presynaptic muscarinic receptors resulted in decrease of ACh released by nerve stimulation seems to weaken depolarization and blockade of synaptic transmission in sympathetic ganglia treated by AChE inhibitors.