Hippocampal slices from kindled rats show an increased sensitivity for induction of epileptiform activity by changes in extracellular ion concentrations

The ability of increases in extracellular potassium ([K+]o) and/or decreases in extracellular calcium ([Ca2+]o) to induce epileptiform activity in hippocampal slices was studied by systematically varying [K+]o and [Ca2+]o. Slices prepared from kindled rats, both 1 week and 1 month after the last kindled seizure, showed an increased sensitivity to perturbations of both ions. Stimulus-locked epileptiform discharges occurred with small displacements of [K+]o and/or [Ca2+]o. The ionic threshold for spontaneous epileptiform discharges was not significantly affected. This long-lasting change in sensitivity to the ionic environment produced by the kindling process had important implications for epileptogenesis in chronically epileptic tissue.     

Increasing extracellular potassium results in subthalamic neuron activity resembling that seen in a 6-hydroxydopamine lesion

Abnormal neuronal activity in the subthalamic nucleus (STN) plays a crucial role in the pathophysiology of Parkinson's disease (PD). Although altered extracellular potassium concentration ([K+]o) and sensitivity to [K+]o modulates neuronal activity, little is known about the potassium balance in the healthy and diseased STN. In vivo measurements of [K+]o using ion-selective electrodes demonstrated a twofold increase in the decay time constant of lesion-induced [K+]o transients in the STN of adult Wistar rats with a unilateral 6-hydroxydopamine (6-OHDA) median forebrain bundle lesion, employed as a model of PD, compared with nonlesioned rats. Various [K+]o concentrations (1.5-12.5 mM) were applied to in vitro slice preparations of three experimental groups of STN slices from nonlesioned control rats, ipsilateral hemispheres, and contralateral hemispheres of lesioned rats. The majority of STN neurons of nonlesioned rats and in slices contralateral to the lesion fired spontaneously, predominantly in a regular pattern, whereas those in slices ipsilateral to the lesion fired more irregularly or even in bursts. Experimentally increased [K+]o led to an increase in the number of spontaneously firing neurons and action potential firing rates in all groups. This was accompanied by a decrease in the amplitude of post spike afterhyperpolarization (AHP) and the amplitude and duration of the posttrain AHP. Lesion effects in ipsilateral neurons at physiological [K+]o resembled the effects of elevated [K+]o in nonlesioned rats. Our data suggest that changed potassium sensitivity due to conductivity alterations and delayed clearance may be critical for shaping STN activity in parkinsonian states.     

Cesium induces spontaneous epileptiform activity without changing extracellular potassium regulation in rat hippocampus

Cesium has been widely used to study the roles of the hyperpolarization-activated (I(h)) and inwardly rectifying potassium (K(IR)) channels in many neuronal and nonneuronal cell types. Recently, extracellular application of cesium has been shown to produce epileptiform activity in brain slices, but the mechanisms for this are not known. It has been proposed that cesium blocks the K(IR) in glia, resulting in an abnormal accumulation of potassium in the extracellular space and inducing epileptiform activity. This hypothesis has been tested in hippocampal slices and cultured hippocampal neurons using potassium-sensitive microelectrodes. In the present study, application of cesium produced spontaneous epileptiform discharges at physiological extracellular potassium concentration ([K(+)](o)) in the CA1 and CA3 regions of hippocampal slices. This epileptiform activity was not mimicked by increasing the [K(+)](o). The epileptiform discharges induced by cesium were not blocked by the N-methyl-D- aspartate (NMDA) receptor antagonist AP-5, but were blocked by the non-NMDA receptor antagonist CNQX. In the dentate gyrus, cesium induced the appearance of spontaneous nonsynaptic field bursts in 0 added calcium and 3 mM potassium. Moreover, cesium increased the frequency of field bursts already present. In contrast, ZD-7288, a specific I(h) blocker, did not cause spontaneous epileptiform activity in CA1 and CA3, nor did it affect the field bursts in the dentate gyrus, suggesting that cesium induced epileptiform activity is not directly related to blockade of the I(h). When potassium-sensitive microelectrodes were used to measure [K(+)](o), there was no significant increase in [K(+)](o) in CA1 and CA3 after cesium application. In the dentate gyrus, cesium did not change the baseline level of [K(+)](o) or the rate of [K(+)](o) clearance after the field bursts. In cultured hippocampal neurons, which have a large and relatively unrestricted extracellular space, cesium also produced cellular burst activity without significantly changing the resting membrane potential, which might indicate an increase in [K(+)](o). Our results suggest that cesium causes epileptiform activity by a mechanism unrelated to an alteration in [K(+)](o) regulation.     

Role of extracellular space in hyperosmotic suppression of potassium-induced electrographic seizures

1. Focal electrographic seizures arose in the CA1 region of rat hippocampal slices bathed in elevated (8.5 mM) external potassium [( K+]o). High [K+]o also induced spontaneous interictal bursts that originated in area CA3 and propagated to CA1. To examine the contribution to electrographic seizure initiation of excitatory mechanisms that are influenced by extracellular volume, we studied the effect of hyperosmotic expansion of interstitial volume on seizure occurrence, interictal bursts, and excitatory synaptic transmission. The tissue electrical resistance was also measured leading up to and during seizures. 2. Media made 5-30 mosmol/kg hyperosmotic by addition of agents restricted to the extracellular space (mannitol, sucrose, raffinose, L-glucose, dextran) rapidly and reversibly abolished [K+]o-induced spontaneous CA1 seizures in 86% of slices tested. However, similar increases in osmolality effected by agents that access the intracellular compartment (D-glucose, glycerol) did not influence electrographic seizure occurrence. Hyperosmotic changes with plasma membrane impermeable compounds, but not permeable compounds, produced significant concentration-dependent decreases (1-10%) in the electrical resistance of CA1 stratum pyramidale. Because tissue resistance is proportional to extracellular volume, these results suggest that hyperosmotic suppression of electrographic seizures is associated with expansion of the extracellular space in hippocampal slices. 3. Measurement of electrical resistance of the CA1 stratum pyramidale during spreading depression and electrographic seizure revealed an increase in tissue resistance to 122% and 108% of control, respectively. Furthermore, a slight (approximately 2%) but significant increase in electrical resistance gradually occurred over the 20 s immediately preceding seizure generation. The observed increase in tissue resistance suggests extracellular space is decreased during these events. 4. Hyperosmolality did not alter CA3 interictal burst frequency. However, burst intensity, estimated from the total length of the burst waveform, was significantly reduced in both the CA3 (83% control) and CA1 region (67% control) when osmotic changes were imposed by plasma membrane impermeant compounds. Additionally, media made hypoosmotic by removal of 7.5 mM NaCl reversibly increased burst intensity. 5. High [K+]o potentiated excitatory synaptic transmission and excitatory postsynaptic potential (EPSP) spike coupling.(ABSTRACT TRUNCATED AT 400 WORDS)     

Activity-evoked increases in extracellular potassium modulate presynaptic excitability in the CA1 region of the hippocampus

1. The effects of stimulus-evoked potassium release on the excitability of presynaptic axons were studied in the rat hippocampal slice preparation. Extracellular stimulation and recording in the stratum radiatum of CA1 yielded a characteristic field potential corresponding to the compound action potential of nonmyelinated afferents and subsequent postsynaptic activation of pyramidal cells. 2. Repetitive stimulation (1 s; 2-100 Hz) produced biphasic changes in the excitability of the afferents. Initial responses showed increased conduction velocity and variably increased amplitude; subsequent responses showed progressively decreasing conduction velocity and amplitude tending toward conduction block. Decreases in excitability were maximal at the end of stimulation and were more pronounced with higher stimulation frequencies. 3. When synaptic transmission was abolished with superfusate containing elevated [Mg2+] (6 mM) and decreased [Ca2+] (0.25 mM), kynurenic acid (1 mM), or adenosine (100 microM), the ability of the fibers to follow repetitive stimulation was enhanced, as indicated by a reduction in amplitude decrement of the presynaptic volley. The decrease in conduction velocity at the end of stimulation was less than half that obtained with intact postsynaptic activity. 4. Concomitant with changes in the excitability of CA1 afferents, the concentration of extracellular potassium ( [K+]o) increased up to 7 mM, as recorded in the stratum radiatum with potassium ion-sensitive microelectrodes. When postsynaptic activity was blocked, activity-evoked rises in [K+]o were reduced to less than 25% of their former value. This suggests that activity-evoked increases in [K+]o derive predominantly from postsynaptic elements. 5. Superfusion of solutions containing elevated [K+] produced biphasic changes in the excitability of CA1 afferents that were qualitatively similar to those produced by repetitive stimulation. Elevated [K+]o below 6 mM produced increased excitability, whereas [K+]o above 6 mM yielded decreased excitability. 6. These results demonstrate that in the CA1 region of the hippocampus, significant rises in [K+]o occur with activity and derive predominantly from postsynaptic elements. The conduction properties of CA1 afferents are sensitive to the level of [K+]o, whether altered artificially or by activity. These effects may constitute a mechanism of postsynaptic modulation of presynaptic conduction operating within a broad range of afferent firing frequencies in the hippocampus.     

Regional and species differences in vascular reactivity to extracellular potassium

In-vitro vasoreactivity to extracellular potassium (Ko+) was tested in isolated human pial and mesenteric arteries as well as basilar and mesenteric arteries from rabbits and rats. Contractions were induced by stepwise increases in [K+]o and were measured isometrically with a force-displacement transducer, in small-volume organ baths. Significant differences between species as well as between regions were found. The threshold of [K+]o for eliciting contraction in human cerebral arteries in hyperosmotic solutions was 10 mM, in rabbit cerebral arteries 17 mM and in rat cerebral arteries 27 mM. The threshold concentration for contraction in mesenteric arteries was significantly higher compared to cerebral arteries in humans and rabbits, but lower in rats: 20 mM in humans, 26 mM in rabbits and 25 mM in rats. In all species the contractile amplitudes were significantly higher in both cerebral and mesenteric arteries when [K+]o was increased under isotonic conditions in the buffer solution than when hyperosomolality was created. This difference increased with increasing hyperosmolality. In hyperosmotic solutions, the EC50 for [K+]o was lower in cerebral and mesenteric arteries from man than in vessels from rabbit and rat. When the solutions were isotonic, this pattern was seen only in mesenteric arteries. It is concluded that significant species and regional differences in vascular responses to [K+]o exist. Considering that [K+]o is increased in cerebral ischaemia, the observed significantly lower threshold for K+-induced contractions in human cerebral arteries may be of importance, especially in human cerebral ischaemic events.     

KCNQ/Kv7 channel regulation of hippocampal gamma-frequency firing in the absence of synaptic transmission

Synchronous neuronal firing can be induced in hippocampal slices in the absence of synaptic transmission by lowering extracellular Ca2+ and raising extracellular K+. However, the ionic mechanisms underlying this nonsynaptic synchronous firing are not well understood. In this study we have investigated the role of KCNQ/Kv7 channels in regulating this form of nonsynaptic bursting activity. Incubation of rat hippocampal slices in reduced (<0.2 mM) [Ca2+]o and increased (6.3 mM) [K+]o, blocked synaptic transmission, increased neuronal firing, and led to the development of spontaneous periodic nonsynaptic epileptiform activity. This activity was recorded extracellularly as large (4.7 +/- 1.9 mV) depolarizing envelopes with superimposed high-frequency synchronous population spikes. These intraburst population spikes initially occurred at a high frequency (about 120 Hz), which decayed throughout the burst stabilizing in the gamma-frequency band (30-80 Hz). Further increasing [K+]o resulted in an increase in the interburst frequency without altering the intraburst population spike frequency. Application of retigabine (10 microM), a Kv7 channel modulator, completely abolished the bursts, in an XE-991-sensitive manner. Furthermore, application of the Kv7 channel blockers, linopirdine (10 microM) or XE-991 (10 microM) alone, abolished the gamma frequency, but not the higher-frequency population spike firing observed during low Ca2+/high K+ bursts. These data suggest that Kv7 channels are likely to play a role in the regulation of synchronous population firing activity.     

Role of Na-K pump potassium regulation and IPSPs in seizures and spreading depression in immature rabbit hippocampal slices

1. Using the immature (8-12 days postnatal) rabbit hippocampal slice preparation, we investigated regional extracellular potassium concentration [( K+]o) changes that occur during spontaneous and evoked spreading depression (SD) episodes. We report here a difference between the CA1 and CA3 cell populations in the immature hippocampus with regard to 1) resting [K+]o, 2) magnitude of the [K+]o change during seizurelike events and SDs, and 3) susceptibility to SD episodes. Experiments were also performed to elucidate the roles that the Na-K pump and synaptic inhibition play in controlling SD onset, duration, and recovery. We demonstrated a major role for potassium regulation by the Na-K pump and a lesser modulatory role for inhibitory postsynaptic potentials (IPSPs) in preventing SD in the CA3 region. 2. Simultaneous intra- and extracellular recordings were made in the CA1 and CA3 regions of the immature rabbit hippocampus during spontaneous or evoked SD, while potassium ion-sensitive microelectrodes (K-ISMs) monitored changes in [K+]o. The CA1 region had 1) a higher frequency of spontaneous SD episodes than CA3, 2) a lower threshold to potassium-triggered SD, 3) a longer duration SD episode, and 4) smaller post-SD membrane potential and [K+]o undershoots (below the original resting membrane potential and resting [K+]o). 3. During the onset of a SD episode in the CA1 region, the local [K+]o rose either before or at the same time as the membrane potential depolarization. 4. In the CA3 region, spontaneous ictallike events consisting of tonic cell depolarization with repetitive activity followed by clonic afterdischarges were more likely to occur than SD episodes. During these ictallike episodes, [K+]o rose above the 10- to 12-mM ceiling level reported for adult CNS tissue during seizures. Increases in [K+]o evoked by repetitive stimulation were regulated at a lower level in CA3 (average [K+]o rise to 11.4 mM) than in CA1 (average [K+]o rise to 18.3 mM). 5. In CA3, bath application of 10 microM bicuculline or 3.4 mM penicillin did not change the frequency of spontaneously occurring SDs or the SD response threshold to local pressure ejection of 2 M KCl. However, blockade of IPSPs did lead to lower thresholds for SD or seizurelike episodes elicited by stimulation of the mossy fibers. 6. A single application of ouabain (10 microM) to CA3 by local pressure ejection caused a slow rise in local [K+]o measured with K-ISMs. The ouabain treatment also increased the frequency of spontaneous postsynaptic potential activity and decreased the amplitude and duration of CA3 pyramidal cell afterhyperpolarizations (AHPs).(ABSTRACT TRUNCATED AT 400 WORDS)     

NADH fluorescence and [K+]o changes during hippocampal electrical stimulation.

1. Short (2 s) trains of stimuli were applied to the dorsal hippocampal surface of cats, producing an increase in [K+]o and a decrease in NADH fluorescence (the latter being indicative of an increase in tissue oxygen utilization). 2. The [K+]o rose rapidly during stimulation (delta[K+]o values from 1 to 6 mM) with larger stimulus currents producing larger changes. The time course of the poststimulus decline of [K+]o was an exponential decay function, with T 1/2 values varying from 1.3 to 6.9s, and independent of the magnitude of the delta[K+]o. Consistent undershoots of [K+]o occurred following stimuli causing less than 1 mM change in [K+]o. 3. The maximum depression of fluorescence and the time integral of the fluorescence changes following each stimulus train were both highly correlated with the total increase of [K+]o occurring during the stimulus train. 4. Application of several stimulus trains in close succession resulted in more rapid potassium reuptake following the later trains and an unusually large undershoot after the last train. Concomitantly, there was a progressive decrease in the fluorescence level. 5. When afterdischarges were induced by prolonged (less than 2 s) stimulation, larger and more sustained increases in [K+]o and decreases of fluorescence were observed, and there was some indication that afterdischarges were followed by accelerated reuptake of extracellular potassium.     

Nonsynaptic epileptogenesis in the mammalian hippocampus in vitro. II. Role of extracellular potassium

The role of extracellular K+ (K+o) in nonsynaptic epileptogenesis induced in the CA1 area of rat hippocampal slices by lowering [Ca2]o was studied with K+-selective microelectrodes (KSMs). Extracellular field potentials and [K+]o were recorded simultaneously with 1-2 KSMs in the CA1 stratum pyramidale. In slices perfused with an oxygenated standard physiological solution (containing 2 mM Ca2+), base-line [K+]o was stable for several hours. The washout of Ca2+o was accompanied by a gradual tonic rise of [K+]o. Spontaneous and stimulus-evoked maximal seizurelike events (SLEs) appeared when [K+]o was approximately 0.5 mM above the initial 5 mM base line. These changes were reversible in normal medium. When K+o was pressure ejected in the CA1 stratum pyramidale of spontaneously active slices, a local rise in [K+]o of approximately 0.5 mM was necessary to trigger a SLE. A similar apparent [K+]o "threshold" was associated with SLEs evoked by electrical stimulation. Increasing [K+] in the perfusing solution by small increments (1 mM) markedly enhanced SLEs frequency and velocity of spread and decreased the period of absolute refractoriness that succeeded each paroxysm. Similar changes occurred during periods of transient hypoxia. Small [K+] decreases in the perfusate had the converse effects. Spontaneous SLEs were associated with phasic increases in [K+]o. In simultaneous [K+]o recordings from two layers, these transients were largest (up to 3.5 mM above base line) and rose more steeply at the stratum pyramidale. Toward the outer dendritic layers they became smaller, slower in time course, and delayed in onset. We conclude that the main source for these [K+]o transients are the hippocampal pyramidal cell bodies, which discharge intensely during a SLE, and that excess K+o is spatially dispersed around the discharge zone of the paroxysm. [K+]o continued to rise, though at a slower rate, throughout the course of a SLE. Following SLE termination, [K+]o decayed slowly to base line. The invasion of a CA1 region by a propagating SLE was preceded quite often by a slow rise in [K+]o. A sudden transition to a steeply rising [K+]o marked the explosive recruitment of this region into the discharge zone of the spreading paroxysm. The total (tonic and phasic) increase in [K+]o during SLEs did not surpass a maximal level of approximately 9 mM, which was the ceiling level of [K+]o in low [Ca2+]o. However, when spreading depression occurred, [K+]o rose up to 30-40 mM for several minutes. Spreading depression rarely appeared spontaneously despite the recurrence of SLEs, but could be provoked by repetitive electrical stimulation.(ABSTRACT TRUNCATED AT 400 WORDS)     

Significance of extracellular potassium in central respiratory control studied in the isolated brainstem-spinal cord preparation of the neonatal rat

The significance of extracellular potassium in central respiratory control was investigated using the isolated brainstem-spinal cord preparation of the neonatal rat. Depth profiles of extracellular potassium activity ([K+])ECF in the medulla were measured with ion-sensitive microelectrodes. Although [K+]ECF increased with depth in medullary tissue during control (4 mM) and low (1 mM) potassium concentration ([K+])CSF superfusion, this gradient disappeared with higher [K+]CSF. With low [K+]CSF (1 mM), respiratory CO2 responsiveness was abolished, and increased with high [K+]CSF (8 mM). Respiratory frequency (fR) was diminished at low [K+]CSF (1 mM), and increased with elevated [K+]CSF (8 and 16 mM); with yet higher [K+]CSF (32 mM) apnea occurred after a transient increase in fR. Perforated patch recording revealed that high [K+]ECF decreased membrane resistance, depolarized membrane potential, and increased firing frequency in most of the recorded medullary neurons. High [K+]ECF also increased excitatory and inhibitory post-synaptic potentials of medullary neurons and augmented the functional connectivity among neurons. It is concluded that [K+]ECF is of importance in the maintenance of respiratory rhythm and central chemosensitivity.     

Activity-dependent changes in extracellular potassium and excitability in turtle olfactory nerve

The excitability properties of turtle olfactory nerve (o.n.) were studied in vitro using potassium-sensitive microelectrodes (KSM), a modified sucrose gap chamber, and a standard nerve chamber to measure conduction velocity. A pronounced supernormal period (SNP), as indicated by increased conduction velocity of the o.n. fiber volley, lasting up to several seconds, was observed following a single stimulus. The compound action potential recorded in the sucrose gap chamber showed a prolonged depolarization with a similar time course to the SNP. When stimulation intensity was submaximal the response amplitude, and the extracellular potassium concentration [K+]o, continuously increased during repetitive stimulation. In contrast, when supramaximal stimuli were applied, the amplitude of the o.n. fiber volley was reduced during a high-frequency stimulus train for all responses after the initial one even though latency was maximally reduced, i.e., during supernormal conduction. Superfusion with various levels of K+ elicited changes in the excitability of the o.n. fibers. Small increases in [K+]o above the resting concentration of 2.6 mM led to an increase in resting excitability, whereas larger increases resulted in decreased excitability and conduction block. The SNP was eliminated when extracellular potassium was elevated between 3 and 4 mM above resting levels. Microstimulation of a small bundle of o.n. fibers led to an increase in [K+]o along the bundle but also around adjacent nonactivated fibers. The excitability of these neighboring nonactivated fibers was increased, further indicating the importance of activity-dependent changes in [K+]o in modulating axonal excitability. These results demonstrate the importance of activity-dependent increases in extracellular potassium in modulating nonmyelinated o.n. fiber excitability. They also indicate that increases in [K+]o and an associated membrane depolarization contribute to the increased excitability observed during fiber recruitment and the supernormal period.     

An N-methyl-D-aspartate receptor-independent excitatory action of partial reduction of extracellular [Mg2+] in CA1-region of rat hippocampal slices

Partial reduction of [Mg2+]o from 2 to 1 mM markedly enhanced neuronal responses evoked by Schaffer collateral-commissural fiber stimulation in the CA1-region of rat hippocampal slices. The amplitude of extracellular population potentials recorded in the CA1-pyramidal cell layer and maximum dV/dt of extracellular population EPSP's recorded in the CA1-pyramidal apical dendritic layer were both increased. However, unlike findings from slices where Mg2+ was completely removed from the bathing medium, there was no spontaneous or evoked epileptiform activity, and the N-methyl-D-aspartate (NMDA) receptor antagonist 2-amino-5-phosphonovalerate (2-APV) did not antagonize the enhancement of evoked responses. These results indicate that, in addition to the participation of NMDA receptors in the epileptiform activity observed when Mg2+ is completely removed from the bathing medium, there is also an NMDA receptor-independent excitatory action of partial reduction of [Mg2+]o in hippocampal slices.     

Potassium and calcium concentrations in interstitial fluid of hippocampal formation during paroxysmal responses

The concentration of potassium ([K+]o) and of calcium ([Ca2+]o) in interstitial fluid of the hippocampal formation of rats anesthetized with urethan was recorded with double-barreled ion-selective microelectrodes. The ipsilateral angular bundle was stimulated with trains of repetitive pulses. [K+]o increased during angular bundle stimulation in both dendritic and cell body layers of the fascia dentata. When stimulation was frequent and intense enough to provoke intercurrent paroxysmal discharge (IPaD), [K+]o in the granule cell body layer rose much above the level it attained during previous, nonparoxysmal activation. No similar excess increase of [K+]o related to paroxysmal firing was observed in the dendritic layer. It is concluded that tonic paroxysmal discharge of the granule cells is associated with an outflow of K ions from the cell somata, but not the dendrites. Extracellular sustained potential (SP) shifts and responses of [K+]o associated with paroxysmal firing showed no consistent correlation in fascia dentata. It is concluded that paroxysmal SP shifts in fascia dentata (unlike in spinal cord and cerebral neocortex) are dominated by the extracellular currents generated by granule cells, not by neuroglia. In the postparoxysmal phase, however, a small residual SP shift was observed in both soma and dendrite layers, which had characteristics compatible with its being generated by glial cells. Responses of [Ca2+]o varied from rat to rat. During nonparoxysmal excitation [Ca2+]o increased, decreased, or remained unchanged. During paroxysmal firing [Ca2+]o always decreased in the granule cell body layer, but the magnitude of the response varied greatly. In the dendritic layer a similar but smaller decrease was observed in some but not all cases. Probable reasons for the unpredictability of the responses of [Ca2+]o are discussed. The responses of [Ca2+]o recorded in fascia dentata of urethan-anesthetized rats that have previously been kindled were not detectably different from those of control animals. Le?o's spreading depression (LD) was associated with large increase of [K+]o, decrease of [Ca2+ )o, and intense negative SP shift in both dendritic and cell body layers of fascia dentata, as well as in CA1 zone of hippocampus. It is concluded that LD in hippocampal formation is associated with more widespread depolarization of pyramidal and granule cells than in cerebral neocortex and cerebellar cortex where changes of [K+]o are limited to the more superficial layers.     

Different responses of CA1 and CA3 regions to hypoxia in rat hippocampal slice

1. To study the effects of brief periods of hypoxia on cellular functions in the rat hippocampal slice, extracellular and intracellular recordings were made from pyramidal neurons, and interstitial potassium activity ([K+]o) was measured in the pyramidal cell layers. Slices were perfused in an interface chamber at 36-37 degrees C with medium containing 8.5 mM [K+]o. Hypoxia was induced by switching the overflow gas from O2-CO2 to N2-CO2. 2. Brief periods of hypoxia (5-60 s) produced electrographic seizures with typical tonic and clonic components in 53% of 293 slices that generated spontaneous interictal bursts. Hypoxia-induced seizures were usually initiated in and restricted to the Ca1 region; only 2.5% of these slices generated seizures in CA3. In contrast to the CA1 region, the CA3 region could undergo spreading depression during hypoxia. The probability of seizure generation in CA1 was increased with increasing duration of hypoxia and was greatly reduced by lowering the bath temperature a few degrees. 3. [K+]o gradually increased in the CA1 and CA3 cell layers during the 20 s leading up to an hypoxia-induced seizure. [K+]o rose to approximately 9.8 mM (from a base line of 8.5 mM) in CA1 just before a seizure and to 11.4 mM during the seizure. After hypoxia, [K+]o reached a higher level in CA1 than in CA3, regardless of whether 1 microM tetrodotoxin was present to eliminate differences in cell firing in the two regions. CA1 pyramidal cells and glia gradually depolarized by several millivolts during and after hypoxia; no initial hyperpolarizing phase was detected. 4. Burst input from CA3 was necessary for hypoxia-induced seizures. The frequency and intensity of spontaneous burst-firing in CA3 remained steady in the period leading up to a CA1 seizure episode. In contrast, the intensity of synaptically driven bursts in CA1 grew markedly just before seizure onset. N-methyl-D-aspartate (NMDA) receptors participated in the crescendo of increasingly synchronous activity in CA1, because the competitive NMDA receptor antagonist, D-2-amino-5-phosphonovaleric acid (D-APV, 30 microM), stereoselectively reduced seizure intensity. 5. Hypoxia-induced seizures were followed by a depressant phase, which was manifested most prominently by a prolonged (up to several minutes) reduction in the frequency and intensity of burst-firing in the CA3 region, hyperpolarization of CA1 neurons, and undershoot of [K+]o. In normal (3.5 mM) [K+]o, synaptically driven population spikes in CA1 were only reduced in amplitude by hypoxia; hypoxia did not induce seizures in 3.5 mM [K+]o.(ABSTRACT TRUNCATED AT 400 WORDS)     

Sodium pump activity, not glial spatial buffering, clears potassium after epileptiform activity induced in the dentate gyrus

A number of mechanisms have been proposed to play a role in the regulation of activity-dependent variations in extracellular potassium concentration ([K(+)](o)). We tested possible regulatory mechanisms for [K(+)](o) during spontaneous recurrent epileptiform activity induced in the dentate gyrus of hippocampal slices from adult rats by perfusion with 8 mM potassium and 0-added calcium medium in an interface chamber. Local application of tetrodotoxin blocked local [K(+)](o) changes, suggesting that potassium is released and taken up locally. Perfusion with barium or cesium, blockers of the inward rectifying potassium channel, did not alter the baseline [K(+)](o), the ceiling level of [K(+)](o) reached during the burst, or the rate of [K(+)](o) recovery after termination of the bursts. Decreasing gap junctional conductance did not change the baseline [K(+)](o) or the half-time of recovery of the [K(+)](o) after the bursts but did cause a decrease in the ceiling level of [K(+)](o). Perfusion with furosemide, which will block cation/chloride cotransporters, or perfusion with low chloride did not change the baseline [K(+)](o) or the half-time of recovery of the [K(+)](o) after the bursts but did increase the ceiling level of [K(+)](o). Bath or local application of ouabain, a Na(+)/K(+)-ATPase inhibitor, increased the baseline [K(+)](o), slowed the rate of [K(+)](o) recovery, and induced spreading depression. These findings suggest that potassium redistribution by glia only plays a minor role in the regulation of [K(+)](o) in this model. The major regulator of [K(+)](o) in this model appears to be uptake via a Na(+)/K(+)-ATPase, most likely neuronal.     

K+]o clearance in cortex: a new analytical model.

1. It has been suggested that passive diffusion is the principal mechanism of the clearance of locally elevated extracellular potassium, K+o, in the cerebral cortex. This concept was based on the assumption that elevated K+ could be modeled as a point source. In the present study, the functional role of passive diffusion was reevaluated in the anesthetized cat cortex following local electrical stimulation. 2. The initial spatial distribution of extracellular potassium activity, [K+]o, elevated by monopolar stimulation, could be modeled by a two-dimensional Gaussian function at and below the 500-micron cortical depth. Azimuthal symmetry around the stimulating electrode was assumed and cylindrical spatial coordinates were used. 3. The observed clearance of transiently elevated [K+]o as a function of space and time was much more rapid than that predicted by an analytical model consisting of the homogeneous diffusion equation whose initial condition was the Gaussian spatial distribution of [K+]o at the onset of the clearance process. 4. It is concluded that passive diffusion does not significantly contribute to the rapid clearance of locally elevated extracellular potassium in the cortex. Active uptake of potassium by cortical cells should be more seriously considered as being primarily responsible for the potassium clearance.     

Effect of kindling on potassium-induced electrographic seizures in vitro

The properties of high [K+]o-induced spontaneous bursting and electrographic seizures in hippocampal slices prepared from rats subjected to kindling from either the lateral entorhinal cortex or the angular bundle were compared to those in control slices. Kindling enhanced the frequency of K+-induced burst-firing in the CA3 region and the duration of triggered bursts in the dentate gyrus, as previously reported. However, kindling had no influence on the characteristics or occurrence of electrographic seizures in the CA1 region of slices bathed in elevated [K+]o. In addition, the development of electrographic seizures in slices from control animals did not require a preconditioning period of burst input from the CA3 region.     

马桑内酯致痫大鼠海马神经细胞外Na~ 、K~ 活度的变化

目的和方法 :应用Na 、K 选择性微电极检测马桑内酯致痫大鼠海马及海马脑片神经细胞外Na 、K 活度的改变。结果 :海马内注射马桑内酯 (5 μL ,5× 10 -4 mol/L)致痫大鼠 30s、1min和 2min后 ,海马神经细胞外Na 活度分别低于对照组 2 7 7mmol/L、5 0 3mmol/L和 5 7 8mmol/L ,而K 活度则分别高于对照组 2 3mmol/L、2 4mmol/L和 2 9mmol/L(P <0 0 1)。 3min后 ,K 活度基本恢复至对照水平 ,而Na 活度仍持续低于对照水平 (P <0 0 1)。海马脑片的实验结果与在体实验相似。结论 :海马神经细胞处于癫痫状态时 ,存在Na 内流、K 外流现象。     

Epileptiform activity induced by changes in extracellular potassium in hippocampus

Using extra- and intracellular recording techniques, we investigated the induction and frequency modulation of spontaneous epileptiform activity produced by changes in the concentration of extracellular potassium ([K+]o). This paper describes a quantitative relationship between [K+]o and the frequency of spontaneously occurring epileptiform events. Recordings were made from the CA3 subfield of the rat in vitro hippocampal slice preparation. Intracellular microelectrodes were filled with 2 M Cs2SO4 and connected to a 3-kHz, time-share, single-electrode current- and voltage-clamp device. The frequency of spontaneous epileptiform (interictal) discharges was determined from extracellular recordings as a function of [K+]o. Current- and voltage-clamp techniques were used to characterize the intracellular correlate of these epileptiform events. The frequency of bicuculline-induced spontaneous epileptiform discharges was dependent on [K+]o. Below 4 mM [K+]o, spontaneous discharges occurred sporadically in the presence of 10 microM bicuculline. Increasing [K+]o from 5 to 10 mM caused a fivefold increase in the rate of spontaneous discharges. Spontaneous epileptiform discharges also occurred in the absence of bicuculline when [K+]o was increased above 6.5 mM. The rate of these discharges was dependent on [K+]o in much the same way as the discharges induced by bicuculline. For any given [K+]o concentration greater than 6.5 mM, however, the resultant discharge rate was faster than that obtained when bicuculline was present in the bathing solution. Simultaneous intra- and extracellular recordings revealed that the spontaneous high-[K+]o-induced interictal discharge was accompanied by a large depolarization of the membrane potential that appeared similar to the paroxysmal depolarizing shift (PDS) seen with other convulsants. The intracellularly recorded event fulfilled the criteria for a synaptically mediated PDS. The waveform of the PDS was complex and dependent on the membrane potential. When the membrane potential was held at 0 mV, spontaneously occurring hyperpolarizing potentials were noted during the inter-PDS interval. These events were blocked by picrotoxin or bicuculline and were probably spontaneous inhibitory postsynaptic potentials. The complexity of the PDS waveform suggested that more than one synaptic conductance was involved in the generation of the PDS. The mean measured reversal potential of the depolarizing phase was -10.7 mV. Voltage-clamp techniques were used to measure the conductance underlying the depolarizing phase of the high-[K+]o-induced PDS. The mean measured conductance was 51.5 nS, with a reversal potential of -7.9 mV.(ABSTRACT TRUNCATED AT 400 WORDS)