Interaction of penicillin and pentobarbital with inhibitory synaptic mechanisms in neocortex

Differential modulation of repetitive firing and synchronous network activity in neocortical interneurons by inhibition of A-type K(+) channels and Ih

GABAergic interneurons provide the main source of inhibition in the neocortex and are important in regulating neocortical network activity. In the presence 4-aminopyridine (4-AP), CNQX, and D-APV, large amplitude GABAA-receptor mediated depolarizing responses were observed in the neocortex. GABAergic networks are comprised of several types of interneurons, each with its own protein expression pattern, firing properties, and inhibitory role in network activity. Voltage-gated ion channels, especially A-type K(+) channels, differentially regulate passive membrane properties, action potential (AP) waveform, and repetitive firing properties in interneurons depending on their composition and localization. HCN channels are known modulators of pyramidal cell intrinsic excitability and excitatory network activity. Little information is available regarding how HCN channels functionally modulate excitability of individual interneurons and inhibitory networks. In this study, we examined the effect of 4-AP on intrinsic excitability of fast-spiking basket cells (FS-BCs) and Martinotti cells (MCs). 4-AP increased the duration of APs in both FS-BCs and MCs. The repetitive firing properties of MCs were differentially affected compared to FS-BCs. We also examined the effect of Ih inhibition on synchronous GABAergic depolarizations and synaptic integration of depolarizing IPSPs. ZD 7288 enhanced the amplitude and area of evoked GABAergic responses in both cell types. Similarly, the frequency and area of spontaneous GABAergic depolarizations in both FS-BCs and MCs were increased in presence of ZD 7288. Synaptic integration of IPSPs in MCs was significantly enhanced, but remained unaltered in FS-BCs. These results indicate that 4-AP differentially alters the firing properties of interneurons, suggesting MCs and FS-BCs may have unique roles in GABAergic network synchronization. Enhancement of GABAergic network synchronization by ZD 7288 suggests that HCN channels attenuate inhibitory network activity.

MicroPET imaging of noxious thermal stimuli in the conscious rat brain

Small animal positron emission tomography (microPET) has been utilized in the investigation of nociception. However, a possible drawback from previous studies is the reduced activation pattern due to the application of anesthesia. The purpose of the present study was to demonstrate a potential means of avoiding anesthesia during stimulation, as well as minimizing the confounding anesthetic effect. Sodium pentobarbital and ketamine were first evaluated to determine their effect on microPET images in the current study. [(18)F]-Fluorodeoxyglucose ((18)F-FDG) was an appropriate radiotracer to reveal activated regions in rat brains. Pentobarbital anesthesia significantly reduced (18)F-FDG uptake in neural tissues, blurrier to lower contrast; therefore, ketamine was used to anesthetize animals during microPET. After the rats were anesthetized and secured in a laboratory-made stereotaxic frame, a simple, noninvasive stereotaxic technique was used to position their heads in the microPET scanner and to roughly conform the images in the stereotaxic atlas. For functional imaging, conscious rats were restrained in cages with minimal ambient noise; short repetitive thermal stimuli were applied to each rat's tail subsequently. The rats were adequately anesthetized with ketamine following 30 min of scanning without stimulation. An activation index (AI) was calculated from microPET data to quantify the local metabolic activity changes according to the normalized (18)F-FDG dosage. The average AI indicated a side-to-side difference for all innocuous stimulations in the thalamus. However, such side-to-side difference was only observed for noxious heat and cold stimulations in primary somatosensory cortex (SI), secondary somatosensory cortex (SII), and agranular insular cortex (AIC). The present study demonstrated the feasibility of the microPET technique to image metabolic functions of the conscious rat brain, offering better rationale and protocol designs for future pain studies.

Barbiturate activation and modulation of GABA(A) receptors in neocortex

We determined if anesthetic and anti-epileptic barbiturates inhibit neurons by different mechanisms. Current- and voltage-clamp recordings were made from somatosensory neurons of neocortex and some thalamocortical neurons in coronal brain slices of rats. We compared effects of pentobarbital, amobarbital, and phenobarbital on inhibitory postsynaptic currents (IPSCs) mediated by gamma-aminobutyric acid (GABA), input conductance, and evoked action potential firing. In neocortex, pentobarbital (EC(50)=41 microM) and amobarbital (EC(50)=103 microM) increased the decay time constant of GABA(A)ergic IPSCs. At higher concentrations, pentobarbital and amobarbital shunted firing by increasing input conductance through agonism at GABA(A) receptors. At anti-epileptic concentrations, phenobarbital increased the IPSC decay time constant (EC(50)=144 microM), and shunted firing by agonism at GABA(A) receptors (EC(50)=133 microM). In thalamocortical neurons, similar concentrations of phenobarbital had negligible effects on GABA(A)ergic IPSCs, conductance, and firing. In contrast to their thalamic actions, barbiturates inhibit neocortical neurons mostly through GABA receptors. Neocortical enhancement of inhibition by pentobarbital and amobarbital, combined with actions on thalamocortical neurons, may contribute to redundant mechanisms of anesthesia. The ability of phenobarbital at anti-epileptic concentrations to inhibit neocortical firing by direct activation and modulation of GABA(A) receptors relates to its specialized therapeutic effects.

Pentobarbital modulates intrinsic and GABA-receptor conductances in thalamocortical inhibition

We investigated interactions of an anesthetic barbiturate, pentobarbital, with non-ligand gated channels and identified inhibitory synaptic transmission in thalamic neurons. Using whole cell voltage-clamp, current-clamp and single channel recording techniques in rat ventrobasal neurons of slices and dispersed preparations, we determined the mechanisms of pentobarbital actions on ionic currents and inhibitory postsynaptic currents (IPSCs), mediated by aminobutyric acid (GABA). We investigated pentobarbital effects on intrinsic currents using hyperpolarizing voltage commands from rest and tetrodotoxin blockade of action potentials. At concentrations near 8 microM, pentobarbital increased input conductance and induced net outward current, I(PB), at potentials near action potential threshold. The reversal potential of I(PB) was -75 mV, implicating K+ and other ions. Cs+ (3 mM) which inhibits both K+ currents and inward rectifier (Ih), completely blocked IPB, whereas the selective Ih blocker, ZD-7288 (25 microM), or Ba2+ (2 mM) which suppresses only K+ currents, reduced IPB. Pentobarbital inhibited the Ih, consistent with a ZD-7288-induced shift in reversal potential for IPB toward K+ equilibrium potential. Pentobarbital increased the inward K+ rectifier, IKir, and leak current, Ileak. We determined the susceptibility of IPSCs, evoked by reticular stimulation, to antagonism by bicuculline, picrotoxinin and 2-hydroxysaclofen and identified their receptor subclass components. At EC50 = 53 microM, pentobarbital increased the duration of IPSCs. The prolonged IPSC duration during pentobarbital was attributable to enhanced open probability of GABAA channels, because combined with GABA, pentobarbital application increased mean channel open time without affecting channel conductance. At concentrations up to 100 microM, pentobarbital did not directly activate GABAA receptors. The concentration-response relationships for pentobarbital effects on the intrinsic currents and IPSCs overlapped, implying multiple sites of action and possible redundancy in anesthetic mechanisms. This is the first study to show that an i.v. anesthetic modulates the intrinsic currents, Ih, IKir, and Ileak, as well as IPSC time course in the same neurons. These effects likely underlie inhibition in thalamocortical neurons during pentobarbital anesthesia.

Chloride accumulation and depletion during GABA(A) receptor activation in neocortex

The response of neocortical neurons to GABA is strongly influenced by the intracellular chloride concentration. We tested the hypothesis that activation of GABA(A) receptors can result in either depletion or accumulation of intracellular chloride. The measured reversal potentials of currents evoked by exogenously applied or synaptically released GABA were not significantly different. During GABA responses, voltage steps to the reversal potential revealed prominent tail-like currents. The polarity of these currents was opposite to that of the GABA-evoked currents, consistent with either accumulation or depletion of intracellular chloride. These results demonstrate that currents evoked by exogenously applied and synaptically released GABA share similar ionic dependencies. Current fluxes during GABA(A) receptor activation can be sufficiently large to change the intracellular chloride concentration.

Potassium-coupled chloride cotransport controls intracellular chloride in rat neocortical pyramidal neurons

Chloride (Cl(-)) homeostasis is critical for many cell functions including cell signaling and volume regulation. The action of GABA at GABA(A) receptors is primarily determined by the concentration of intracellular Cl(-). Developmental regulation of intracellular Cl(-) results in a depolarizing response to GABA in immature neocortical neurons and a hyperpolarizing or shunting response in mature neocortical neurons. One protein that participates in Cl(-) homeostasis is the neuron-specific K(+)-Cl(-) cotransporter (KCC2). Thermodynamic considerations predict that in the physiological ranges of intracellular Cl(-) and extracellular K(+) concentrations, KCC2 can act to either extrude or accumulate Cl(-). To test this hypothesis, we examined KCC2 function in pyramidal cells from rat neocortical slices in mature (18-28 d postnatal) and immature (3-6 d postnatal) rats. Intracellular Cl(-) concentration was estimated from the reversal potential of whole-cell currents evoked by local application of exogenous GABA. Both increasing and decreasing the extracellular K(+) concentration resulted in a concomitant change in intracellular Cl(-) concentration in neurons from mature rats. KCC2 inhibition by furosemide caused a change in the intracellular Cl(-) concentration that depended on the concentration of pipette Cl(-); in recordings with low pipette Cl(-), furosemide lowered intracellular Cl(-), whereas in recordings with elevated pipette Cl(-), furosemide raised intracellular Cl(-). In neurons from neonatal rats, manipulation of extracellular K(+) had no effect on intracellular Cl(-) concentration, consistent with the minimal KCC2 mRNA levels observed in neocortical neurons from immature animals. These data demonstrate a physiologically relevant and developmentally regulated role for KCC2 in Cl(-) homeostasis via both Cl(-) extrusion and accumulation.

Zinc and zolpidem modulate mIPSCs in rat neocortical pyramidal neurons

Pharmacological modulation of gamma-aminobutyric acid-A (GABAA) receptors can provide important information on the types of subunits composing these receptors. In recombinant studies, zinc more potently inhibits alphabeta subunits compared with the alphabetagamma combination, whereas modulation by nanomolar concentrations of the benzodiazepine type 1-selective agonist zolpidem is conferred by the alpha1betagamma2 subunit combination. We examined four properties of miniature inhibitory postsynaptic currents (mIPSCs) from identified necortical pyramidal cells in rat brain slices: decay time constant, peak amplitude, rate of rise, and interevent interval. Exposure to 50 microM zinc reduced the decay time constant, peak amplitude, and rate of rise with no effect on interevent interval. Zolpidem enhanced mIPSCs in a concentration-dependent manner. Both 20 and 100 nM zolpidem increased the decay time constants of mIPSCs. In some cells, both peak amplitude and rate of rise were also enhanced. All cells treated with zinc were also responsive to zolpidem. These results show that neocortical pyramidal cells have a population of GABAA receptors sensitive to both zinc and zolpidem.

Ethanol selectively enhances the hyperpolarizing component of neocortical neuronal responses to locally applied GABA

Local application of GABA to rat cerebral cortical neurons in brain slices elicited biphasic responses mediated via GABAA receptors. The fast component of the response, which was most apparent with somatic application of GABA, was hyperpolarizing at the normal resting membrane potential (GABAh response). The slower component could be elicited by GABA application to nearly all regions of the cell, and was depolarizing at the resting membrane potential (GABAd response). The reversal potential of evoked IPSCs recorded with whole-cell patch electrodes (-68 mV) was comparable to the reversal potential of the GABAh response (-69 mV), and was significantly different from the reversal potential of the GABAd response (-56 mV). The GABAd response was more sensitive to enhancement by pentobarbital and more readily antagonized by both bicuculline and picrotoxin than the GABAh response. Recording in bicarbonate-free buffer changed the reversal potential of the GABAd response significantly, but had no effect on the GABAh response. In contrast, superfusion with ethanol significantly enhanced the GABAh response, while having no effect on the GABAd component. Although a localized collapse of the Cl- gradient, which has been proposed to underlie the GABAd response, could explain the greater sensitivity of the GABAd response to pentobarbital and the GABAA antagonists, this could not account for the greater sensitivity of the GABAh response to ethanol. Differences in GABAA receptor subunit composition may result in the expression of dendritic and somatic GABAA receptors that have different kinetics, reversal potentials, and sensitivity to pharmacological agents, including ethanol.

GABAA mediated afterdepolarization in pyramidal neurons from rat neocortex

We report a novel slow afterdepolarization (sADP) in layer V pyramidal neurons when brain slices from somatosensory cortex are perfused with gamma-aminobutyric acid (GABA). Whole cell recordings were made from visually identified neurons in slices from 3- to 5-wk-old rats. The firing of action potentials at 100 Hz for 1 s, evoked by a train of brief current pulses, typically is followed by a slow afterhyperpolarization (sAHP). When GABA (1 mM) was applied to the perfusate, the sAHP was replaced by a sADP of approximately 18 mV in amplitude, which on average lasted for 26 s. The sADP was not evoked or terminated as an all-or-none event: it grew in amplitude and duration as the number of evoked action potentials was increased; and when the sADP was interrupted with hyperpolarizing current steps, its amplitude and duration were graded in a time- and voltage-dependent manner. The sADP did not depend on Ca2+ entry into the cell: it could be evoked when bath Ca2+ was replaced by Mn2+ or in neurons dialyzed with 20 mM bis-(o-aminophenoxy)-N,N,N',N'-tetraacetic acid. We hypothesized that the sADP was generated predominantly in the dendrites because it was associated with the firing of small-amplitude action potentials that continued after the somatic membrane potential was repolarized to -70 mV by steady current injection. We tested this hypothesis by evoking the sADP in neurons with surgically amputated apical dendrites. In those neurons, the average duration of the sADP was 78% shorter than in neurons with an intact apical dendrite and there were no associated small action potentials. The sADP also was evoked by muscimol, but not by baclofen, and was blocked by bicuculline or picrotoxin but not by CGP 35348, indicating that it is mediated through the activation of GABAA receptors. Our results suggest that intense activity in the presence of GABA results in a long-lasting enhancement of excitability in the apical dendrite that in turn could lead to amplification of distal excitatory synaptic potentials.

Propofol inhibits epileptiform activity in rat hippocampal slices

Propofol (2,6 di-isopropylphenol) is an intravenous general anesthetic used widely in neuroanesthesia, as a sedative in intensive care units, and has successfully aborted refractory status epilepticus. We investigated the effects of propofol on epileptiform activity in rat hippocampal slices. Interictal epileptiform activity was produced by bath applying one of the following: picrotoxin (PTX; 10 and 50 microM), bicucculine methiodide (BMI; 10 and 50 microM), 4-aminopyridine (4-AP; 50 microM), 8.5 mM [K+]o or 0 [Mg2+]o artificial cerebrospinal fluid. Propofol was then added in increasing concentrations and the effect on the rate of extracellular field epileptiform discharges was measured. Ictal-like discharges (> 2 Hz for > 2 s) were produced by 7.5 mM [K+]o and pilocarpine (10 microM). Propofol (30 micrograms/ml, 168 microM) completely abolished discharges induced by 8.5 mM [K+]o and at 60 micrograms/ml (337 mM) completely suppressed discharges induced by 4-AP and 0 [Mg2+]o. Propofol was less effective in reducing discharges produced by GABAA/Cl- receptor complex antagonists. Propofol at a concentration of 300 micrograms/ml (1.7 mM) was needed to reduce BMI-induced (50 microM) discharges by 77% and only reduced PTX-induced (50 microM) discharges by 20%. Ictal-like discharges produced by pilocarpine were disrupted by low concentrations of propofol (3-10 micrograms/ml, 16.9-56.2 microM) and the duration of the ictal-like discharge period was significantly reduced. We found that propofol has significant in vitro antiepileptic effects. Additionally, propofol was less effective against GABAA antagonists suggesting that the GABAA receptor complex is the site of its action.

Changes in the strength of recurrent inhibition in cobalt-induced epilepsy

Changes in the strength of recurrent inhibition in the feline cortex in cobalt (CoCl2)-induced epilepsy were observed. The strength of inhibition was analyzed in terms of paired-pulse depression of the amplitude of somatosensory evoked potentials (SEPs) elicited by stimulation of the ventral posterolateral (VPL) thalamic nucleus. An enhancement in recurrent inhibition was observed shortly after CoCl2 application. The size of the amplitude of cortical evoked potentials (EPs) elicited by VPL stimulation increased simultaneously. The reduction of inhibition that appeared later was associated with afterdischarges (ADs) evoked by VPL stimulation. These ADs frequently extended to epileptic discharges. These results suggest that the reduction in recurrent inhibition induced by CoCl2 application plays an important role in the spread of seizure activity.

Afterpotentials following penicillin-induced paroxysmal depolarizations in rat hippocampal CA1 pyramidal cells in vitro

Epileptic discharges were induced by superfusion of rat hippocampal slices with penicillin. Under these conditions the neurons generated paroxysmal depolarization shifts (PDS) after electrical stimulation of Schaffer collaterals. The PDS were followed by large afterhyperpolarizations lasting about 2 s. The mechanisms causing these afterhyperpolarizations were studied in CA1 pyramidal cells. A late component of the afterhyperpolarizations, which determined their overall duration, was blocked by intracellular application of EGTA and reduced by superfusion with 8-Br-cAMP. In the same neurons these drugs had a comparable effect on afterhyperpolarizations following depolarizing current injections; it was therefore concluded that the late component of the PDS afterhyperpolarizations was caused by a slow Ca2(+)-activated K+ current. An initial fast component of PDS afterhyperpolarizations, which peaked about 60 ms after PDS onset, was reduced by EGTA but not affected by 8-Br-cAMP suggesting that the fast Ca2(+)-activated K+ current also contributed to the PDS afterhyperpolarizations. Superfusion of the slice with the gamma-aminobutyric acid B receptor (GABAB) antagonists phaclofen or 5-aminovalerate reduced the amplitude of the afterhyperpolarizations during the first 1000 ms but did not affect the late Ca2(+)-dependent component, indicating that a GABAB-mediated K+ inhibitory postsynaptic potential (IPSP) contributed to the PDS afterhyperpolarization. Intracellular injection of Cl- revealed that an early part of the afterhyperpolarizations lasting about 500 ms was Cl(-)-dependent. This component was blocked by superfusion of the slices with bicuculline, suggesting that a GABAA-mediated Cl- IPSP contributed to the PDS afterhyperpolarization.(ABSTRACT TRUNCATED AT 250 WORDS)

Alterations in the microenvironment during spreading depression associated with epileptiform activity in the immature neocortex

Local changes in extracellular ion concentrations were measured with ion-sensitive microelectrodes in slices of mature (greater than 40 days of age) or immature (16-30 days of age) rat neocortex maintained in vitro. Repetitive stimulation resulted in increases in extracellular potassium ([K+]o) to levels of 8.85 +/- 2.1 mM in slices from adult animals and 12.77 +/- 1.8 mM in slices from immature animals. During exposure to picrotoxin, maximum levels were 11.3 +/- 2.6 and 14.8 +/- 2.5 mM in the mature and immature groups, respectively. Picrotoxin (50 microM) induced spontaneous bursts of repetitive spiking, followed by a slow, negative field potential, associated with spreading depression (SD), in slices from immature animals. [K+]o levels increased to 10.2 +/- 3.9 mM during repetitive spike discharges and reached 30.3 +/- 18.5 mM during SDs. Variations in the size of the extracellular space (ES) were examined during SD. The ES was found to reversibly decrease by 39 +/- 4.5%. Clusters of repetitive spikes were associated with 0.1-0.2 mM decreases in [Ca2+]o, whereas 1.12 +/- 0.06 mM decreases were observed during SDs. Decreases in [Na+]o and [Cl-]o of 56 +/- 10 mM and 41 +/- 9 mM, respectively, were observed during SDs suggesting that a net transmembrane movement of water occurred during SDs. These results indicate that changes in [K+]o associated with epileptiform activity in the immature nervous system are quantitatively different from those observed in the mature brain. These large increases in [K+]o may contribute to the prolonged nature of epileptiform discharges in the developing nervous system.

Long-term potentiation in frontal cortex: role of NMDA-modulated polysynaptic excitatory pathways

The present study examined the role of N-methyl-D-aspartic acid (NMDA) receptors in synaptic plasticity in regular-spiking cells of rat frontal cortex. Intracortical stimulation, at levels subthreshold for elicitation of action potentials, evoked a late excitatory postsynaptic potential (EPSP) in layer II-III neurons that was sensitive to the selective NMDA antagonist D-2-amino-5-phosphonovaleric acid (APV). This late EPSP showed marked short-term frequency-dependent depression, suggesting that it is polysynaptic in origin. Polysynaptic late EPSPs were selectively enhanced following high-frequency stimulation. This sustained increase in synaptic efficacy, or long-term potentiation, was expressed in regular spiking cells and appeared to result from activation of NMDA receptors on excitatory interneurons. These data demonstrate the existence of an NMDA-modulated polysynaptic circuit in the neocortex which displays several types of use-dependent plasticity.

Two inhibitory postsynaptic potentials, and GABAA and GABAB receptor-mediated responses in neocortex of rat and cat

1. Pyramidal neurones from layers II and III of the rat primary somatosensory cortex and cat primary visual cortex were studied in vitro. Inhibitory postsynaptic potentials (IPSPs) and responses to exogenously applied gamma-aminobutyric acid (GABA) and its analogue baclofen were characterized. The results from rats and cats were very similar. 2. Single electrical stimuli to deep cortical layers evoked a sequence of PSPs in the resting neurone: (a) an initial, brief excitation (EPSP), (b) a short-latency, fast inhibition (the f-IPSP) and (c) a long-latency, more prolonged inhibition (the l-IPSP). The f-IPSP was accompanied by a large conductance increase (about 70-90 nS) and reversed polarity at -75 mV; the l-IPSP displayed a relatively small conductance increase (about 10-20 nS) and reversed at greater than -90 mV. 3. Focal application of GABA near the soma evoked a triphasic response when measured near the threshold voltage for action potentials: (a) the GABAhf (hyperpolarizing, fast) phase was very brief and was generated by a large conductance increase with a reversal potential of -78 mV, (b) the GABAd (depolarizing) phase also had a high conductance but reversed at -51 mV, (c) the GABAhl (hyperpolarizing, long-lasting) phase had a relatively low conductance and reversed at -70 mV. The GABAhf response was specifically localized to the soma, whereas the apical or basilar dendrites generated predominantly GABAd responses. 4. Baclofen, a selective GABAB receptor agonist, caused a small (about 2 mV), slow hyperpolarization of the resting potential, which reversed at -90 mV. Saturating baclofen doses increased membrane conductance by a maximum of about 12 nS. Baclofen depressed the amplitude and conductance of PSPs; when baclofen was focally applied near the soma. IPSPs were selectively depressed. 5. The GABAA receptor antagonists bicuculline methiodide or picrotoxin (10 microM) greatly depressed f-IPSPs, but either enhanced or did not affect l-IPSPs. Concomitantly, GABAhf and GABAd responses were antagonized, leaving a more prominent GABAhl response that reversed polarity at a more negative level of -87 mV. Baclofen responses were unaffected by bicuculline and picrotoxin. Extracellular barium abolished the baclofen response, and shifted the reversal potentials of the GABAd and GABAhl responses in the positive direction; the GABAhf response was unaffected. 6. Both focal GABA and f-IPSPs strongly depressed the intrinsic excitability of pyramidal neurones. Each greatly increased spike threshold and abolished or vastly reduced the capacity of the cells to fire repetitively during intense stimuli.(ABSTRACT TRUNCATED AT 400 WORDS)

Sensory modulation of hippocampal transmission. II. Evidence for a cholinergic locus of inhibition in the Schaffer-CA1 synapse

The present work studied the neurotransmitter mediating the depressive effect of sensory stimulation on the Schaffer-CA1 transmission. Field responses of the CA1 region evoked by ipsilateral CA3 stimuli were recorded in paralyzed, locally anesthetized rats following the same experimental paradigm as in the previous work. The tissue zone under recording was perfused in vivo by an implanted hollow fiber (brain dialysis device) with either Krebs-Ringer bicarbonate (KRB), or KRB with penicillin, atropine, acetylcholine or eserine. Results were the following: (1) atropine increased the field excitatory postsynaptic potential (EPSP) amplitude in a dose-dependent manner and totally abolished the modulatory action of sensory stimulation; (2) both the field EPSP and the modulatory action of sensory stimulation remained unaltered during the blockade of GABAergic activity by penicillin; (3) acetylcholine as well as eserine induced a great diminution of both field EPSP and population spike amplitudes, without altering the effect of sensory stimulation; (4) penicillin and atropine induced multiple population spikes, reversing the effect of sensory stimulation and increasing the cell excitability. These results demonstrate that the sensory modulation of information transfer through the Schaffer-CA1 synapse is mediated by a muscarinic cholinergic mechanism. The dose-dependent increase in the field EPSP by muscarinic blockade is evidence for the existence of a cholinergic presynaptic inhibition on the Schaffer collateral terminals.

Extracellular K+ and Ca2+ changes during epileptiform discharges in the immature rat neocortex

Picrotoxin-induced epileptiform activity was examined in neocortical slices prepared from 8- to 15-day-old rats. This activity consisted of spontaneous bursts of 3-5 discharges that resembled interictal spikes and were interspersed with ictal-like paroxysms lasting 10-30 s. Measurements of extracellular potassium ([K+]o) and calcium ([Ca2+]o) were made during these spontaneous epileptiform events, using ion-sensitive electrodes. Individual interictal spikes were associated with [Ca2+]o decreases of 0.1-0.2 mM, whereas sustained ictal-like discharges were accompanied by decreases of 0.3-0.4 mM. Measurement of [K+]o showed that individual interictal spikes were associated with increases in [K+]o up to 12 mM, whereas increases to more than 20 mM accompanied long-lasting ictal-like discharges. Maximum increases in [K+]o were observed ca. 600 microns below the pial surface. [K+]o increases were followed by undershoots of the resting [K+]o level. The unusually high [K+]o levels associated with epileptiform discharges in the immature neocortex suggest that disturbances in [K+]o regulation may contribute to the generation of the picrotoxin-induced, spontaneous, prolonged ictal-like discharges observed in the 8- to 15-day age group.

Inhibitory potentials in neurons of the deep layers of the in vitro neocortical slice

Neocortical neurons in slices of the rat sensorimotor region maintained in vitro generate postsynaptic potentials (PSPs) in response to focal extracellular stimulation. These PSPs are mainly depolarizing at the resting membrane potential (Vm) but a sequence of depolarizing-hyperpolarizing potentials is often disclosed by depolarizing the Vm. The stimulus-induced hyperpolarization can last up to 1000 ms and show two components: the early one (peak latency 10-20 ms), is inverted by diffusion of Cl- into the cell; the late one is diminished by augmenting [K+]o. The membrane conductance is increased throughout the stimulus-induced hyperpolarization, mainly during the first 10-60 ms. A decrease in excitability results from both the hyperpolarizing trend and the conductance increase. The latter is more effective in decreasing depolarizing than hyperpolarizing pulses of current injected intracellularly.