Slow modulations of high-frequency activity (40-140-Hz) discriminate preictal changes in human focal epilepsy.

Recent evidence suggests that some seizures are preceded by preictal changes that start from minutes to hours before an ictal event. Nevertheless an adequate statistical evaluation in a large database of continuous multiday recordings is still missing. Here, we investigated the existence of preictal changes in long-term intracranial recordings from 53 patients with intractable partial epilepsy (in total 531 days and 558 clinical seizures). We describe a measure of brain excitability based on the slow modulation of high-frequency gamma activities (40-140 Hz) in ensembles of intracranial contacts. In prospective tests, we found that this index identified preictal changes at levels above chance in 13.2% of the patients (7/53), suggesting that results may be significant for the whole group (p < 0.05). These results provide a demonstration that preictal states can be detected prospectively from EEG data. They advance understanding of the network dynamics leading to seizure and may help develop novel seizure prediction algorithms.

Chloride-mediated inhibition of the ictogenic neurones initiating genetically-determined absence seizures.

Electroclinical investigations in human patients and experimental studies from genetic models demonstrated that spike-and-wave discharges (SWDs) associated with absence seizures have a cortical onset. In the Genetic Absence Epilepsy Rat from Strasbourg (GAERS), SWDs are initiated by the paroxysmal discharges of ictogenic pyramidal neurones located in the deep layers of the somatosensory cortex. However, the cellular and synaptic mechanisms that control the ictal discharges of seizure-initiating neurones remain unclear. Here, by the means of in vivo paired electroencephalographic (EEG) and intracellular recordings in the GAERS cortical focus, we explored the participation of the intracortical inhibitory system in the control of paroxysmal activities in ictogenic neurones. We found that their firing during EEG paroxysms was interrupted by the occurrence of hyperpolarizing synaptic events that reversed in polarity below action potential threshold. Intracellular injection of Cl(-) dramatically increased the amplitude of the paroxysmal depolarizations and the number of generated action potentials, strongly suggesting that the inhibitory synaptic potentials were mediated by GABA(A) receptors. Consistently, we showed that intracellularly recorded GABAergic interneurones fired, during seizures, shortly after (∼+8 ms) the discharge of ictogenic neurones and displayed a rhythmic bursting that coincided with the inhibitory synaptic events in neighbouring pyramidal ictogenic cells. In contrast with other forms of epilepsy, our findings suggest that paroxysmal activities in the cortical pyramidal cells initiating absence seizures are negatively controlled by a feedback Cl(-)-mediated inhibition likely resulting from the fast recurrent activation of intracortical GABAergic interneurones by the ictogenic cells themselves.

The pars reticulata of the substantia nigra: a window to basal ganglia output.

Together with the internal segment of the globus pallidus (GP(i)), the pars reticulata of the substantia nigra (SNr) provides a main output nucleus of the basal ganglia (BG) where the final stage of information processing within this system takes place. In the last decade, progress on the anatomical organization and functional properties of BG output neurons have shed some light on the mechanisms of integration taking place in these nuclei and leading to normal and pathological BG outflow. In this review focused on the SNr, after describing how the anatomical arrangement of nigral cells and their afferents determines specific input-output registers, we examine how the basic electrophysiological properties of the cells and their interaction with synaptic inputs contribute to the spatio-temporal shaping of BG output. The reported data show that the intrinsic membrane properties of the neurons subserves a tonic discharge allowing BG to gate the transmission of information to motor and cognitive systems thereby contributing to appropriate selection of behavior.

Dendritic arborizations of the rat substantia nigra pars reticulata neurons: spatial organization and relation to the lamellar compartmentation of striato-nigral projections.

The cerebral cortex provides a major source of inputs to the basal ganglia. As has been well documented, the topography of corticostriatal projections subdivides the striatum into a mosaic of functionally distinct sectors. How information flow from these striatal sectors remains segregated or not within basal ganglia output nuclei has to be established. Electrophysiologically identified neurons of the rat substantia nigra pars reticulata were labeled by juxtacellular injection of Neurobiotin, and the spatial organization of their dendritic arborizations was analyzed in relation to the projection fields of individual striatal sectors. Thirty-nine nigral neurons located in the projection territory of the distinct striatal sensorimotor sectors were reconstructed. The data show that the dendritic arborizations of nigral neurons conform to the geometry of striato-nigral projections. Like striatal projections, the arborizations formed a series of curved laminas enveloping a dorsolaterally located core. Although dendritic fields of the neurons lying in the laminae were flat, those located in the core were spherical or cylindrical, thereby conforming to the shape of the striatal projection fields. This remarkable alignment between the dendritic arborizations of nigral neurons and the projection fields from individual striatal districts supports the concept of a parallel architecture of the striato-nigral circuits. However, pars reticulata neurons usually extend part of their dendrites within adjacent striatal projection fields, thereby ensuring a continuum between channels. The extension of the dendritic arborizations within the striatal projection fields suggests that nigral neurons integrate the information that is relevant for the completion of the specific motor behavior they control.

Relationship between EEG potentials and intracellular activity of striatal and cortico-striatal neurons: an in vivo study under different anesthetics.

The functions of the basal ganglia are achieved through excitation of striatal output neurons (SONs) by converging cortical glutamergic afferents. We assessed the relationship between different patterns of activity in cortico-striatal (C-S) cells and the electrical behavior of SONs in vivo. Intracellular activities of rat C-S neurons in the orofacial motor cortex and of SONs, located in the projection field of this cortical region, were recorded under different anesthetics, which generate various temporal patterns of cortical activity. A surface electroencephalogram (EEG) of the orofacial motor cortex was simultaneously performed with intracellular recordings and EEG waves were used as correlates of a coherent synaptic activity in cortical neurons. Under barbiturate anesthesia C-S neurons showed rhythmic (5--7 Hz) supra-threshold depolarizations in phase with large amplitude EEG waves. The correlative activity of SONs was characterized by large amplitude oscillation-like synaptic depolarizations that could trigger action potentials. Under ketamine-xylazine anesthesia C-S neurons exhibited a step-like behavior consisting of depolarizing plateaus (up states), leading to multiple spike discharges, interrupted by hyperpolarizing periods (down states). The related activity of SONs was step-like membrane potential fluctuations with firing confined to the early part of the striatal up state. In C-S neurons and SONs up states coincided with slow recurrent EEG waves (approximately 1 Hz). Finally, under neurolept-analgesia an apparently disorganized EEG activity was associated with a lack of rhythmic discharge in C-S neurons. This uncorrelated activity in C-S neurons resulted in an absence of spontaneous firing as well as of large amplitude synaptic depolarizations in SONs. In the present study we demonstrate that SONs shape their input-output relationship by filtering out uncorrelated synaptic activity and that a minimal synchronization in the cortico-striatal afferents is required to produce significant synaptic depolarization in SONs.

Role of a striatal slowly inactivating potassium current in short-term facilitation of corticostriatal inputs: a computer simulation study.

Striatal output neurons (SONs) integrate glutamatergic synaptic inputs originating from the cerebral cortex. In vivo electrophysiological data have shown that a prior depolarization of SONs induced a short-term (

On the putative contribution of GABA(B) receptors to the electrical events occurring during spontaneous spike and wave discharges.

Cortical and thalamic neurones play a major role in the generation/expression of spike and wave discharges (SWDs), the main electroencephalographic (EEG) feature of absence seizures. The detailed mechanisms leading to this paroxysmal EEG activity, however, are still poorly understood. We have now made in vivo intracellular recordings from layer V cortical neurones of the facial motor cortex and from thalamocortical (TC) neurones of the ventroposteromedial and ventroposterolateral nuclei in a well established model of this disease: the Genetic Absence Epilepsy Rats from Strasbourg (GAERS). The main feature of the intracellularly recorded activity of TC neurones during spontaneous SWDs was the presence of rhythmic sequences of synaptic potentials consisting of an EPSP closely followed by 2-6 IPSPs. These rhythmic sequences were superimposed on a small tonic hyperpolarization that lasted for the whole duration of the SWD and was still present at potentials close to -85 mV. The rhythmic IPSPs, on the other hand, had a reversal potential of -68 mV, and always appeared as depolarizing events when recording with KCl-filled electrodes at -55 mV. Low frequency electrical stimulation of the corresponding cortical area evoked in TC neurones a short and a long lasting IPSP, whose waveforms were reminiscent of a GABA(A) and a GABA(B) IPSP, respectively. The main feature of the intracellular activity recorded in cortical neurones during spontaneous SWDs was the presence of rhythmic depolarizations. Their frequency was similar to the one of SWDs in the EEG, and was not affected by DC injection. The amplitude of the rhythmic depolarizations, however, increased following steady hyperpolarization of the neurone by DC injection. An increase in the apparent input resistance of cortical neurones was observed during SWDs compared to the inter-SWDs periods. Low frequency electrical stimulation of the contralateral striatum evoked in cortical neurones a short and a long lasting IPSP, whose waveforms were reminiscent of a GABA(A) and a GABA(B) IPSP, respectively. Our data indicate that there are no rhythmic GABA(B) IPSPs and low threshold Ca2+ potentials in GAERS TC neurones during SWDs, but rhythmic sequences of EPSP/IPSPs superimposed on a tonic hyperpolarization that might represent a long lasting GABA(B) IPSP. Further experiments are required to clarify the nature of the voltage waveform and the increase in input resistance observed in cortical neurones during spontaneous SWDs in GAERS.

In vivo induction of striatal long-term potentiation by low-frequency stimulation of the cerebral cortex.

Both long-term depression and long-term potentiation have been described at corticostriatal synapses. These long-lasting changes in synaptic strength were classically induced by high-frequency (100 Hz) electrical stimulations of cortical afferents. The purpose of the present study was to test the ability of corticostriatal connections to express use-dependent modifications after cortical stimulation applied at the frequency of synchronization of corticostriatal inputs observed in our in vivo preparation, i.e. the barbiturate-anesthetized rat. For this study we used an identified monosynaptic corticostriatal pathway, between the orofacial motor cortex and its target region in the striatum. Intracellular recording of striatal output neurons showed spontaneous large-amplitude oscillation-like depolarizations exhibiting a strong periodicity with a narrow frequency band at 5 Hz. Using the focal electroencephalogram of the cortical region projecting to the recorded cells, we found that membrane potential oscillations in striatal neurons were in phase with episodes of spontaneous cortical spindle waves. To determine directly the pattern of activity of corticostriatal neurons, we performed intracellular recordings of electrophysiologically identified corticostriatal neurons simultaneously with the corresponding surface electroencephalogram. We found that corticostriatal cells (n = 7) exhibited periods of spontaneous 5-Hz discharges in phase with the cortical spindle waves. Therefore, we have tested the effect of repetitive cortical stimulations at this low frequency (5 Hz, 500-1000 pulses) on the corticostriatal synaptic efficacy. In 62% of cases (eight of 13 neurons tested), this conditioning was able to produce long-term potentiation in the corticostriatal synaptic efficacy. The mean increase of excitatory postsynaptic potential amplitude ranged from 13.3% to 172% (mean = 67.3%, n = 8). These results provide additional support for physiological long-term potentiation at corticostriatal connections. Furthermore, this study demonstrates that corticostriatal long-term potentiation can be induced by synchronization at low frequency of cortical afferents. Our data support the concept that the striatal output neuron may operate as a coincidence detector of converging cortical information.

Intracellular recordings in thalamic neurones during spontaneous spike and wave discharges in rats with absence epilepsy.

1. In vivo extracellular and intracellular recordings were performed from thalamocortical (TC) neurones in a genetic model of absence epilepsy (genetic absence epilepsy rats from Strasbourg) during spontaneous spike and wave discharges (SWDs). 2. Extracellularly recorded single units (n = 14) fired either a single action potential or a high frequency burst of up to three action potentials, concomitantly with the spike component of the spike-wave complex. 3. Three main events characterized the intracellular activity of twenty-six out of twenty-eight TC neurones during SWDs: a small amplitude tonic hyperpolarization that was present throughout the SWD, rhythmic sequences of EPSP/IPSPs occurring concomitantly with the spike-wave complexes, and a small tonic depolarization at the end of the SWD. The rhythmic IPSPs, but not the tonic hyperpolarization, were mediated by activation of GABAA receptors since they reversed in polarity at -68 mV and appeared as depolarizing events when recording with KCl-filled electrodes. 4. The intracellular activity of the remaining two TC neurones consisted of rhythmic low threshold Ca2+ potentials, with a few EPSP/IPSP sequences present at the start of the SWD. 5. These results obtained in a well-established genetic model of absence epilepsy do not support the hypothesis that the intracellular activity of TC neurones during SWDs involves rhythmic sequences of GABAB IPSPs and low threshold Ca2+ potentials.

In vivo activity-dependent plasticity at cortico-striatal connections: evidence for physiological long-term potentiation.

The purpose of the present study was to investigate in vivo the activity-dependent plasticity of glutamatergic cortico-striatal synapses. Electrical stimuli were applied in the facial motor cortex and intracellular recordings were performed in the ipsilateral striatal projection field of this cortical area. Recorded cells exhibited the typical intrinsic membrane properties of striatal output neurons and were identified morphologically as medium spiny type I neurons. Subthreshold cortical tetanization produced either short-term posttetanic potentiation or short-term depression of cortically-evoked excitatory postsynaptic potentials. When coupled with a postsynaptic depolarization leading the membrane potential to a suprathreshold level, the tetanus induced long-term potentiation (LTP) of cortico-striatal synaptic transmission. Induction of striatal LTP was prevented by intracellular injection of a calcium chelator suggesting that this synaptic plasticity involves an increase of postsynaptic free calcium concentration. Contrasting with previous in vitro studies our findings demonstrate that LTP constitutes the normal form of use-dependent plasticity at cortico-striatal synapses. Since excitation of striatal neurons produces a disinhibition of premotor networks, LTP at excitatory striatal inputs should favor the initiation of movements and therefore could be critical for the functions of basal ganglia in motor learning.

The lamellar organization of the rat substantia nigra pars reticulata: segregated patterns of striatal afferents and relationship to the topography of corticostriatal projections.

The striatonigral pathway provides one of the most direct routes for information flow through the basal ganglia system. Via this pathway information from sensory, motor and associative areas of the cerebral cortex are routed to a variety of thalamocortical and brainstem networks involved in the organization of motor behaviour. In a previous analysis of the rat substantia nigra pars reticulata we have shown that the nigral cells which project to thalamus, tectum and tegmentum are topographically ordered along a series of curved laminae. Extending these observations, the present study examined how striatal regions related to particular areas of the cerebral cortex innervate the lamellar keyboard of nigral output neurons. For this purpose, small microiontophoretic injections of wheat germ agglutinin conjugated to horseradish peroxidase were performed in the striatum and the distribution of retrogradely-labelled cells in the cerebral cortex and anterogradely-labelled axons in the substantia nigra were conjointly examined. The results indicate that with the exception of the striatal region related to the allocortex, all the various components of the striatal functional mosaic are represented in the substantia nigra pars reticulata. This representation is organized under the form of longitudinal bands which compose a series of curved laminae enveloping a core located dorsolaterally in the substantia nigra. The striatal mapping in substantia nigra pars reticulata is such that the projections of the auditory and visual compartments are confined to the most ventral lamina. More dorsally, an ordered representation of the body is achieved by the nigral lamination. The oral and perioral body parts are centred on the dorsolateral core and the more distal parts of the face and limbs are progressively set out in more peripheral laminae. In the region affiliated to the prefrontal cortex, the dorsal cingulate district innervate a ventromedial lamina, the prelimbic/insular district lie dorsal to it. Projections from lateral orbital and insular compartments extend laterally along the dorsal margin of the pars reticulata. Since the "onion-like" distribution of striatal inputs is precisely the form observed in the distribution of nigral efferent neurons, the present observations favour the view that the nigral lamination underlies formation of specific input-output channels of processing. Evidence is considered that these channels are specialized for particular classes of movements or behaviours and integrate the various information relevant to the completion of these movements or behaviours.

Long-term potentiation of glycinergic inhibitory synaptic transmission.

1. Tetanizing protocols were used to test whether glycinergic inhibition undergoes long-term plasticity in vivo. For this purpose we studied the inhibition evoked disynaptically in the teleost Mauthner (M) cell by stimulation of the posterior branch of the contralateral VIIIth nerve. The advantage of this experimental design is that the inhibition, which is mediated by identified second-order commissural interneurons, is not contaminated by parallel excitation. 2. The VIIIth-nerve-evoked inhibitory postsynaptic potentials (IPSPs), which are generated at the level of the soma, are depolarizing in Cl(-)-loaded M cells. After VIIIth nerve tetanization, these IPSPs exhibited potentiation lasting > 30 min in 23 of 31 cells. The maximum enhancement measured 5-10 min after the onset of the tetanization averaged 100 +/- 19% (mean +/- SE). In contrast, the non-"tetanized" collateral IPSP induced by antidromic stimulation of the M axon did not increase significantly suggesting synaptic specificity of the potentiation. 3. Single-electrode voltage-clamp studies of Cl(-)-loaded M cells indicated that this plasticity is due to an increased synaptic conductance that occurs without obvious modifications of the kinetics or voltage dependence of the inhibitory postsynaptic currents. 4. The synaptic conductance and its changes during potentiation were quantified by measuring the inhibitory shunt of the antidromic spike while recording with potassium-acetate-filled electrodes. For this purpose the ratio, r', of the inhibitory to resting membrane conductances, was calculated using the expression (V/V')--1, where V and V' are the amplitudes of the control and the test antidromic spikes, respectively. This ratio was called fractional conductance. Measured at the peak of the expected VIIIth-nerve-evoked IPSP, r' increased by 114 +/- 18% (n = 46). Again the collateral inhibitory conductance was not modified. 5. Because there are two synapses in the inhibitory pathway, it became important to determine whether modifications of the second-order inhibitory junctions contribute to the overall potentiation. Several experimental procedures were used for this purpose. 6. The input-output relationship at the inhibitory synapses was determined by comparing the size of the presynaptic volley and r'. The former was recorded intra- or extracellularly as a monophasic positive potential, the so-called extrinsic hyperpolarizing potential, which increases in parallel with the strength of VIIIth nerve stimulation. In 12 experiments where the presynaptic volley was unaffected by the tetanization, suggesting lack of involvement of the first relay, r' nevertheless increased in amplitude by 79 +/- 14%.(ABSTRACT TRUNCATED AT 400 WORDS)

"Latent" inhibitory connections become functional during activity-dependent plasticity.

Simultaneous pre- and postsynaptic recordings from identified glycinergic inhibitory interneurons and the Mauthner cell showed that 25% of the afferents produced no or extremely small postsynaptic responses. Morphological determination of the number of contacts made by these cells on the Mauthner cell revealed a connectivity similar to that of functional neurons which always produce clear inhibitory postsynaptic potentials, suggesting that most of the endings, made by weak interneurons are silent. Intraaxonal injection of 4-aminopyridine or Ca2+ greatly enhanced transmission at functional connections but did not modify those which were ineffective. However, after eighth nerve tetanic stimuli, transmission at the weak connections was unmasked or enhanced for prolonged periods and was twice as likely to be potentiated, with a 6-fold greater mean enhancement than the potent ones. This result provides additional support for long-term potentiation of inhibitory synapses. Furthermore, weakly functional junctions represent a "reserve" pool which can be critical for the expression of plasticity within a network, and, consequently, for setting the threshold of reflex activities such as the escape reaction mediated by the Mauthner cell.

Synchronous bursting in a subset of interneurons inhibitory to the goldfish Mauthner cell: synaptic mediation and plasticity.

1. Presynaptic activity in the inhibitory network impinging on the Mauthner (M-) cell was investigated in the goldfish medulla in vivo using extra- and intracellular recordings. The inhibitory presynaptic volley elicited by stimulation of the contralateral vestibular nerve consisted of multiple successive peaks at high frequency (up to 1,000 Hz). Less pronounced multicomponent responses were recorded after antidromic activation of the M-cell. Such high-frequency "oscillatory" field potentials also occurred spontaneously. 2. In intracellular recordings, a subset of inhibitory interneurons showed evoked and spontaneous burst discharge. Burst action potentials were correlated with the peaks in the extracellular volley, suggesting that repetitive firing of these cells is synchronized. Nonbursting cells, on the other hand, fired single action potentials in response to vestibular stimuli and were not activated via the M-cell collateral network. 3. Bursting cells were determined morphologically to be part of the feedback inhibitory circuit. Their responses to stimulation of the contralateral vestibular nerve thus suggest the existence of a crossed excitatory pathway to these interneurons. 4. Vestibular-evoked excitatory postsynaptic potentials (EPSPs) in bursting interneurons had a short latency of 0.781 +/- 0.08 ms (mean +/- SD, n = 18) but reached threshold at 2.25 +/- 1 ms (n = 21). These characteristics are suggestive of a chemically mediated EPSP. Indeed, the evoked synchronous repetitive activity of these cells was prevented by superfusion with excitatory amino-acid receptor antagonists. 5. Bursting neurons showed several characteristics that differentiate them from nonbursting cells, including brief action potentials, plateau responses, and intense spontaneous subthreshold activity. 6. With extracellular recordings, tetanization of contralateral vestibular primary afferents evoked a long-lasting potentiation of oscillatory population responses in 11 of 27 cases. Furthermore in three experiments, the frequency of occurrence of spontaneous bursts was enhanced and a similar facilitation was detected at the intracellular level. 7. We conclude that a subset of interneurons in this inhibitory network is capable of repetitive discharges and that evoked as well as spontaneous firing in this population is synchronized. Although electrical coupling between interneurons may mediate synchronization and intrinsic membrane properties may promote burst activity, our data suggest strongly that repetitive firing requires chemically mediated transmission. Furthermore they indicate that the mechanisms underlying evoked as well as spontaneous bursting in this population show activity-dependent plasticity.

Synaptic noise and multiquantal release at dendritic synapses.

1. The quantal nature of inhibitory synaptic noise recorded intracellularly from the lateral dendrite of the goldfish Mauthner cell was studied, using new detection and measurement procedures that eliminate operator intervention. In addition, we employed an analytical algorithm, not previously applied to this problem, which treats composite amplitude distributions as mixtures of gaussians of unknown separations and variances. 2. As in the soma of this neuron, the dendritic inhibitory noise is quantal, with the exception that in the dendrite multiple equally spaced classes may persist in the presence of tetrodotoxin (TTX), an observation that may be correlated with the finding that the inhibitory afferents at this level often contain more than one release site. The validity of the analysis was confirmed by superfusing with saline containing low calcium and high magnesium, which reduces composite histograms that are gaussian mixtures to a single class, equal in amplitude to that of the first component detected in the control. 3. These results suggest that spontaneous exocytotic events may be synchronized at adjacent active zones within single terminals and that lowering the probability of release by reducing calcium may then be a more effective method for isolating single miniature events than is TTX.