Institut des Neurosciences, Département de Neurochimie-Anatomie, CNRS UMR 7624, Université Pierre et Marie Curie, 9 quai Saint-Bernard, F-75005 Paris, France
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Abstract |
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Introduction |
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The low excitability of SONs led to the assumption that they filter out weak, uncorrelated synaptic inputs and that significant synaptic depolarizations, i.e. those leading to action potential discharges, are driven by synchronized activity in many converging cortico-striatal afferents (Nisenbaum et al., 1994; Nisenbaum and Wilson, 1995
; Wilson, 1995
; Charpier et al., 1999a
). A direct validation of this hypothesis requires experimental procedures by which intracellular activity of SONs can be recorded under different levels of synchrony in their cortico-striatal afferents. Up to now such a comparative study has not been performed. Therefore, we have here studied the relationship between the voltage behavior of SONs and the temporal structure of activity in their cortical afferents under different types of anesthesia (barbiturate, ketaminexylazine and neuroleptanalgesia), which generate different patterns of cortical activity (Steriade et al., 1993a
; Contreras et al., 1997a
; Steriade, 1997
; Pinault et al., 1998
; Charpier et al., 1999b
). In separate experiments we performed intracellular recordings of cortico-striatal (C-S) neurons in the orofacial motor cortex and of SONs located in the projection field of this cortical area. To assess the link between different levels of cortical synchrony and the electrical events in SONs and C-S neurons, in each experiment intracellular activities were recorded simultaneously with surface electroencephalograms (EEG) of the orofacial motor cortex. Since an EEG is an averaging of cortical field potentials, which reflects correlated synaptic potentials in the related cortical cells (Klee et al., 1965
; Creutzfeld et al., 1966
; Contreras and Steriade, 1995
), EEG waves were used as an indicator of synchronized activity in the cerebral cortex.
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Materials and Methods |
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Animal Preparation and Surgery
Experiments were performed in vivo on 29 adult male SpragueDawley rats (Charles River, France) weighing 240300 g.
In a first set of experiments (n = 13 rats) animals were anesthetized using sodium pentobarbital (66 mg/kg i.p.; Sanofi, Libourne, France). Barbiturate anesthesia was maintained throughout the experiment with additional doses of pentobarbital (20 mg/kg i.p.) every hour.
In a second set of experiments (n = 6 rats) rats were first deeply anesthetized with a mixture of ketamine (90 mg/kg i.p. Imalgène; Rhône Mérieux, France) and xylazine (10 mg/kg i.p.; Sigma, France). Deep anesthesia was maintained by supplementary doses of ketamine (50 mg/kg i.m.) administrated hourly.
In a last series of experiments (n = 10 rats) the animals were initially anesthetized with sodium pentobarbital (40 mg/kg i.p.) and ketamine (100 mg/kg i.m.). Once the surgical procedures had been completed (see below), neurolept-analgesia (Flecknell, 1996) was obtained by injections of fentanyl (3 mg/kg i.p.; Janssen, France) and haloperidol (1 mg/kg i.p. Haldol; Janssen, France), which were repeated every 2030 min (Pinault et al., 1998
; Charpier et al., 1999b
).
EEG was continuously monitored to assess the depth of anesthesia and additional doses of anesthetics were given to maintain a constant pattern of EEG waves that was characteristic of the type of anesthesia. In addition, the heart rate was monitored throughout the experiments.
After initial anesthesia a cannula was inserted into the trachea and the animal was placed in a stereotaxic frame. Wounds and pressure points were infiltrated with lignocaine (2%), repeated every 2 h. To obtain long-lasting stable intracellular recordings rats were immobilized with gallamine triethiodide (40 mg i.m. Flaxedil every 2 h; Specia, Paris, France) and artificially ventilated. Body temperature was maintained (36.537.5°C) with a homeothermic blanket. At the end of the experiments the animals were killed with an overdose of pentobarbital (200 mg/kg i.p.).
Recordings and Stimulations
EEG Recordings
Silver bipolar electrodes of low resistance (60 k) were placed on the dura to record a focal EEG of the orofacial motor cortex (Neafsey et al., 1986
). Tip separation (11.5 mm) of the surface EEG electrodes was sufficiently wide to allow intracellular recordings of C-S neurons (see below) between EEG electrodes.
Intracellular Recordings
Intracellular recordings were performed using glass micropipettes filled with 2 M potassium acetate (5070 M). Measurements of membrane input resistance (Rin) and time constant (
) were based on the linear electrical cable theory applied to an idealized isopotential neuron (Rall, 1969
). In practice, Rin was assessed by measurement of the mean (n
10) membrane potential change at the end of hyperpolarizing current pulses of weak intensity (0.4 nA, 200 ms duration, every 1.25 s) applied through the recording electrode and
was the time taken for the membrane potential to reach 63% of its final value. The resting membrane potential (Vm) values were corrected according to the tip potential recorded extracellularly immediately after loss of the intracellular recording.
Striatal neurons were recorded within the projection field of the contralateral orofacial motor cortex (Deniau et al., 1996). Stereotaxic coordinates for striatal recordings were as follows: 9 mm anterior to the inter-aural line, 3.54 mm lateral to the midline and 35.6 mm ventral to the brain surface. To assess the relationship between SONs activity and cortical field potentials, intracellular recordings of SONs were combined with the focal surface EEG of the related orofacial motor cortex (Fig. 1A
).
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Intracellular recordings were obtained under current-clamp conditions using the active bridge mode of an Axoclamp-2B amplifier (Axon Instruments, Foster City, CA). Data were stored on-line on a DTR-1404 digital tape recorder (Biologic, Claix, France) and were then digitized with a sampling rate of 20 kHz (intracellular signals) or 300 Hz (EEG) for off-line analysis. To perform spectral analysis of EEG potentials, fast Fourier transforms were applied using Spike 2 (CED Software; Cambridge Electronic Design, Cambridge, UK). Cross-correlograms between subthreshold intracellular activities and EEG waveforms (down-sampling at 300 Hz for both signals) were calculated using Spike 2. The amplitude of action potentials (APs) was calculated as the potential difference between their voltage threshold, evident as an abrupt increase in slope depolarization, and the peak of the spike waveform. Numerical values are given as means ± SD. Statistical significance was assessed by performing appropriate statistical tests, a one way analysis of variance (ANOVA), a MannWhitney rank sum test or a Levene median test. In some measurements the normality of distributions was tested using the KolmogorovSmirnov test and a GaussianLaplace fit was performed. Simple linear regression was done with a confidence interval of 95%.
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Results |
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Data were obtained from 35 C-S neurons and 22 SONs. In this neuronal sample both types of cells had a Vm < 55 mV, APs with a rise time < 700 µs and an amplitude > 50 mV.
Electrophysiological Identification of SONs and C-S Neurons
SONs
Whatever the anesthesia, neurons recorded within the striatum (Fig. 1A) could be identified as SONs using the distinctive electrophysiological features of these cells (Jiang and North, 1991
; Nisenbaum et al., 1994
; Nisenbaum and Wilson, 1995
; Charpier et al., 1999a
; Mahon et al., 2000
): (i) a low Vm (
72 mV) (Fig. 1
B1B3); (ii) a low apparent input resistance at rest (<40 M
); (iii) the presence of a slow ramp-like membrane depolarization in response to intracellular injection of a positive threshold current pulse (Fig. 1B1B3
). This classical delayed excitation, which leads to a long latency to spike discharge, is due to a voltage-dependent slowly inactivating potassium current available around 60 mV (Nisenbaum et al., 1994
; Gabel and Nisenbaum, 1998
). However, because in vivo intracellular recordings often exhibited continuous synaptic noise, the application of positive current pulses could coincide with spontaneous synaptic depolarizing potentials and consequently lead to earlier firing (Fig. 1B1
, top trace). As shown by the pooled data presented in Table 1
, basic electrical membrane properties of SONs (Vm, Rin, AP amplitude and rise time) were not significantly different under barbiturate, ketaminexylazine and neuroleptic analgesia. In addition, the voltage-dependent intrinsic properties of SONs at potentials close to the firing threshold were not affected by the different anesthetics used (Fig. 1
B1B3).
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C-S neurons were reliably identified by their antidromic activation from the contralateral striatum (Fig. 2A). Electrical stimulation of the contralateral striatum allowed us to avoid any antidromic activation of passing corticofugal axons (Wilson, 1987
; Cowan and Wilson, 1994
). The criteria used for identification of antidromic action potentials were: (i) the constant latency of the antidromic response despite imposed changes of membrane potential (Fig. 2
B1); (ii) collision of the antidromic spikes with spontaneously occurring orthodromic APs (Fig. 2
B2, top traces); (iii) the all or none property of the evoked spikes when the stimulation was just below threshold for antidromic activation (Fig. 2
B2, lower trace). In most cases (25 of 35 C-S cells) antidromic activation was followed by a short latency mixed inhibitory synaptic potential (Fig. 2
B2, top and bottom traces). The depth of intracellular recordings (12002600 µm from the cortical surface) indicated that the recorded C-S neurons were presumably located in the deep part of layer III and in layer V. This is consistent with previous findings obtained from intracellular labeling of crossed C-S neurons (Cowan and Wilson, 1994
). Antidromic latencies, which ranged between 3.3 and 24 ms (mean = 7.3 ± 4.1 ms) with two preferred modes at 36 and 79 ms (Fig. 2C
), were not related to the depth of recording (Fig. 2D
). To assess the conduction velocity of C-S neurons we approximated the course of the axons as straight line segments from the soma to the striatum. The mean estimated conduction velocity was 1.48 ± 0.62 m/s (from 0.36 to 2.71 m/s, n = 35).
As for SONs, comparison of the basic membrane properties of the cortical neurons under the three conditions of anesthesia did not show any significant differences (Table 2). For instance, as demonstrated in Figure 3A
, AP properties were not significantly modified (see Table 2
). Moreover, C-S neurons displayed similar voltage changes in response to intracellular negative current pulses (Fig. 3B
) and a post-inhibitory rebound of excitability, reminiscent of a low threshold activated calcium potential, was observed in all tested cells (n = 29 C-S neurons). An important result was that the firing pattern of C-S neurons was mainly driven by the background synaptic activity rather than by their intrinsic membrane properties. As illustrated by the C-S neuron shown in Figure 3C
(barbiturate anesthesia), while the directly induced firing pattern was stereotypical during epochs of reduced synaptic activity (Fig. 3
C1), it varied as the number of spontaneous synaptic events increased (Fig. 3
C2).
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Barbiturate Anesthesia
In a first series of experiments intracellular activity of SONs (n = 10) and surface EEG were recorded under barbiturate anesthesia. As previously reported (van Luijtelaar, 1997; Charpier et al., 1999a
), rat EEG under this anesthetic exhibited spontaneous recurrent spindles consisting of sequences of large amplitude waves (upper traces in Figs 4
A1,B1 and 5A
) that occurred with a frequency range of 57 Hz (Fig. 4
A2). Simultaneously, SONs displayed grouped rhythmic depolarizing post-synaptic potentials clearly correlated with the negative EEG waves (Fig. 4
A1,B1). Two mains arguments attest that these membrane potential fluctuations represent excitatory post-synaptic potentials (EPSPs): (i) the frequency of oscillations was voltageindependent, indicating their synaptic origin (Charpier et al., 1999a
); (ii) these spontaneous oscillations exhibited the same sensitivity to changes in membrane potential as glutamergic cortically evoked synaptic potentials (Kita, 1996
; Charpier et al., 1999a
). While these EPSPs remained mostly sub-threshold for spike discharge (Fig. 4
A1), firing could occur with the largest EPSPs, which were systematically coincident with large amplitude EEG spindle waves (Fig. 4
B1).
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While the mean firing rate of SONs under barbiturate anesthesia was weak (<1 Hz) [see also Charpier and Deniau and Charpier et al. (Charpier and Deniau, 1997; Charpier et al., 1999a
)], we were able to assess in five active SONs the timing of their spiking relative to the same zero-time reference as for sub-threshold events. As illustrated in Figure 4
B1,B2, spike discharge in SONs mostly temporally followed the peak of the corresponding EEG wave. However, collision of the oscillation- like striatal depolarization with small synaptic events could lead to earlier AP firing (Fig. 4
B2, arrow in inset). It is important to note that such a decrease in the firing latency of SONs was also observed following temporal summation of a small spontaneous EPSP with a depolarizing current pulse (see Fig. 1B
, top trace). AP latencies resulting from such complex synaptic potentials were not included in the Gaussian distribution (P = 0.8, KolmogorovSmirnov test) of SON firing probability (Fig. 4
B3).
Similar to the activity of SONs, C-S neurons (n = 19) under barbiturate anesthesia exhibited large spontaneous membrane depolarizations that occurred in phase with the EEG spindle waves (Fig. 5A). However, in contrast to SONs, most C-S neurons (14 of 19 cells), which had a more depolarized resting potential (Table 1
versus Table 2
), were spontaneously active with a mean firing frequency of 1.6 ± 1.26 Hz (0.264.6 Hz, n = 14). APs in C-S neurons were triggered at the peak of the largest synaptic depolarizations, which were systematically associated with large amplitude negative EEG waves (Fig. 5A
). To assess the temporal relationship between firing of C-S neurons and epochs of cortical synchronization, we measured, as for SONs, the timing of individual AP in C-S neurons relative to the reliable and consistent zero-time reference, i.e. the peak of negative EEG waves (Fig. 5B
). As illustrated by the typical example of firing probability density shown in Figure 5C
, C-S neuron spikes mostly preceded the peak of the corresponding cortical waves. For the studied C-S neurons (n = 6) and SONs (n = 5) we found that the probability density of firing in both cell types could be fitted to a normal function. As shown in Figure 6
, the mean value of the pooled distributions was 11.4 ± 15.3 ms (empty bars) for C-S neurons and +13.9 ± 12.2 ms (filled bars) for SONs. This temporal dispersion of cortical and striatal firing was statistically different (P < 0.01, Levene median test). Therefore, the mean spike timing of SONs was delayed by ~25 ms compared with that of C-S neurons. We also noticed that the slope of membrane depolarization leading to firing was slower in SONs than in C-S neurons (Fig. 6
, inset).
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SONs (n = 7) recorded under ketaminexylazine anesthesia exhibited a spontaneous activity different to that observed under barbiturate anesthesia. They displayed step-like membrane potential fluctuations consisting of recurrent sustained depolarizing plateaus (up states) interrupted by hyperpolarizing periods (down states) (Fig. 7A, lower trace). This type of activity is classically observed in rats anesthetized with a combination of urethane and ketaminexylazine (Wilson and Kawaguchi, 1996
; Stern et al., 1997
, 1998
). As in the experiments under barbiturate anesthesia, SONs were mostly silent, while one or two APs could be triggered during periods of membrane depolarization (Fig. 7A,C,E
). We found that the alternation of up and down states was correlated with a slow rhythm of EEG potentials (Fig. 7A
). This cortical oscillation had a frequency near 1 Hz (Fig. 7B
) and exhibited faster waves in each cycle. This is similar to the slow cortical oscillations present in cats under ketaminexylazine anesthesia (Steriade, 1993a,b; Contreras and Steriade, 1995
).
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In C-S neurons (n = 6) we observed a step-like behavior of membrane potential similar to that observed in SONs and most of the up states were supra-threshold for spike discharge (Fig. 8A). As shown by the superimposed records in Figure 8B
, the onset of C-S neuron up states was precisely timed with the early positive wave of the slow EEG potentials (see also Fig. 8D
). The up state duration in C-S neurons (Fig. 8C
) ranged between 120 and 1097 ms, with a mean value of 436 ± 199.5 ms (n = 144 up states), and was significantly longer (P < 0.0001, MannWhitney rank sum test) than that calculated for SONs (Fig. 7D
). As for SONs, we measured the latency of AP discharges in C-S neurons with respect to onset of the up state (Fig. 8D
). We found that the probability of AP discharge in C-S cells was greatest during the first 200 ms of the up state (AP 1,
t = 86 ± 107 ms, from 0 to 536 ms, n = 131 APs), then the probability of firing decreased progressively throughout the up state (AP 2,
t = 183 ± 158 ms, from 16 to 776 ms, n = 79 APs). The later APs spread out at the end of the up state (APs 36,
t = 339 ± 216 ms, from 51 to 938.5 ms, n = 85 APs). An example of the temporal distribution of spikes during successive up states in a single C-S cell is shown in Figure 8E
.
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A striking feature of SONs recorded under neurolept-analgesia (fentanylhaloperidol) (n = 5) was the presence of small amplitude, temporally disorganized synaptic potentials (Fig. 9A, bottom trace) and the absence of spontaneous APs. This intracellular activity was associated with an apparently irregular EEG, composed of a mixture of waves (Fig. 9A
, top trace). In contrast to the two previous anesthesias, the EEG did not show a clear rhythmicity while a predominant frequency around 2 Hz was revealed by the spectral analysis (data not shown). Given the noisy-like activity in the EEG and SONs, we calculated crosscorrelations of simultaneously recorded cortical potentials and striatal depolarizations to test whether temporal correlations could be detected between the two types of activity. No significant peak was found in the cross-correlogramms (Fig. 9B
), indicating the absence of a temporal correlation between the EEG waves and fluctuations of the membrane potential of SONs. However, because of the sporadic occurrence of relatively large amplitude EEG waves (asterisk in Fig. 9A
), we examined the intracellular activity in SONs associated with these larger cortical potentials. We selected periods of paired recordings where such EEG waves were observed (Fig. 9
C1). The corresponding EEG wave-trigger average did not reveal any correlated synaptic depolarization in SONs (Fig. 9
C2). It is important to stress that the largest EEG potentials under neurolept-analgesia had a weak amplitude and duration compared with the standard EEG waves recorded under barbiturate or ketaminexylazine anesthesia.
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Discussion |
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EEGs and Anesthetic-dependent Activity of C-S Neurons
It is well established that activity in cortical cells is critically dependent on the type of anesthesia, different anesthetics inducing distinctive cortical rhythms mimicking different sleep stages (Steriade, 1997). This was obvious in the present study where the three different anesthetics we used induced EEG waves that were associated with dissimilar patterns of activity in C-S neurons. In the first series of experiments we used a barbiturate, an agonist of the
-aminobutyric acid (GABAA) receptor that potentiates chloride-dependent synaptic activity (Barker and McBurney, 1979
). This compound induced an EEG activity dominated by the occurrence of spindles that consisted of rhythmic, large amplitude EEG waves recurring with a strong periodicity in the 57 Hz range. This cortical spindling has been classically described in barbiturate-anesthetized rats (van Luijtelaar, 1997
; Charpier et al., 1999a
). Barbiturate EEG waves, which were mainly negative, symmetrical in shape and short in duration (<50 ms), had a systematic clear-cut temporal relation with large amplitude sub- or supra-threshold EPSPs in C-S neurons. This is consistent with results obtained in barbiturate- anesthetized cats, where cortical cells were found to display rhythmic depolarization at ~6 Hz during EEG spindles sequences (Steriade, 1997
). Our data are also consistent with the widely assumed correlation between excitatory synaptic events in single cortical cells and negative surface cortical waves and support the assumption that EEG potentials are an averaging of synchronized synaptic potentials from a large number of cortical neurons (Klee et al., 1965
; Creutzfeld et al., 1966
; Contreras and Steriade, 1995
). Therefore, it is likely that barbiturate anesthesia produced synchronized synaptic oscillations in cortical networks (Contreras et al., 1997a
) leading to coherent firing in C-S neurons.
Use of the ketaminexylazine mixture produced another state of cortical synchrony. Ketamine is known to block the N-methyl- D-aspartate (NMDA) receptor (Anis et al., 1983) while xylazine is an adrenergic
2 mimetic (Nicoll et al., 1990
). EEG records under ketaminexylazine exhibit a slow rhythm at ~1 Hz. These slow cortical potentials are similar to the slow oscillations present throughout resting sleep in mammals and in urethane or ketaminexylazine-anesthetized cats (see Steriade, 1993; Steriade et al., 1993a,b; Contreras and Steriade, 1995). They had an asymmetric shape and consisted of an early sharp deflection of high amplitude followed by a slow envelope of smaller amplitude (see Fig. 8A,D
). The corresponding intracellular activity of C-S neurons was characterized by step-like membrane potential shifts, the so-called up and down states, which have been widely described in C-S neurons under urethane- and ketaminexylazine anesthesia (Cowan and Wilson, 1994
; Stern et al., 1997
). However, the present study provides the first EEG correlates of the up and down states in C-S neurons. Here we have shown that transition to the up state in C-S cells is closely related to the initial high amplitude positivity of the EEG potential. Moreover, individual up states had approximately the same duration and time course as the corresponding cortical field potential. Altogether, these observations suggest that entry into the up state in the C-S neuron population is synchronized and that the dwell time in the up state of individual C-S neurons would be similar.
Finally, in the last series of experiments anesthesia was achieved by the use of fentanyl, a synthetic opioid acting mainly on the opioid receptor Mu (Inoue et al., 1994), combined with haloperidol, a D2 dopaminergic antagonist (Meshul and Allen, 2000
). This neurolept-analgesia induced slow cortical waves that were often hidden by a higher frequency background activity and no regular rhythmic activity could be clearly detected. However, some EEG waves of relatively high amplitude could be observed, but they were noticeably smaller than those obtained under barbiturate and ketaminexylazine anesthesia. This arhythmic EEG was associated with a temporally disorganized firing activity in C-S neurons, probably resulting in a lack of synchronized firing among C-S neurons.
The different patterns of cortical activity described here did not result from an anesthetic-dependent alteration in intrinsic membrane properties of cortical neurons. Indeed, we did not notice any significant difference in the basic electrical features of C-S cells recorded under the different anesthetics. Therefore, it is likely that the various temporal patterns of C-S firing mainly result from modulation of synaptic activity within the cortical networks and/or in the cortico-thalamic loops, due to the specific actions of the different anesthetics.
Synchronization of C-S Neurons is Required for SON Firing
The cortico-striatal pathway establishes divergenceconvergence links connecting C-S neurons to SONs. Previous morphological studies (Cowan and Wilson, 1994; Kincaid et al., 1998
) have shown that axons of C-S neurons form extended arborizations within the striatum making glutamergic synapses onto numerous SONs. In turn, each SON receives excitatory inputs from a large number of converging C-S neurons. While it is widely assumed that this cortical pathway constitutes the main excitatory input to the striatum, a possible involvement of glutamergic thalamostriatal inputs (Wilson et al., 1983
) cannot be excluded. However, several arguments suggest a relatively minor role of the thalamus in the electrical activity of the SONs recorded in this study. First, we previously showed (Charpier et al., 1999a
) that local cortical cooling suppressed the corresponding EEG waves as well as synaptic potentials in the related striatal neurons, while barbiturate-induced spindles in the thalamus are still present following decerebration (Contreras et al., 1997b
). Second, morphological studies have shown that thalamic and cortical terminals contact distinct SONs (Dubé et al., 1988
). Finally, extracellular recording of identified thalamo-striatal neurons shows that spontaneous firing of these cells is not correlated with the rhythmic striatal depolarizations (unpublished observation). Therefore, we can assume that the striatal synaptic depolarizations described in the present study mainly result from activity of the afferent cerebral cortex. In addition, since the current-induced voltage responses of SONs were similar under the three anesthetics, it is very unlikely that the different patterns of sub- and supra-threshold synaptic depolarizations in SONs described here result from an anesthetic-dependent alteration in their intrinsic membrane properties.
In the barbiturate-anesthetized preparation, which provides a reliable model of C-S neuron synchronization, SONs displayed spontaneous large amplitude oscillation-like depolarizations at ~6 Hz that were systematically associated with large amplitude EEG waves. Since C-S neuron firing was in phase with these cortical waves, it is likely that large synaptic depolarizations in SONs resulted from synchronized discharges in a large population of cortical afferents. This rhythmic behavior of SONs (Charpier and Deniau, 1997; Charpier et al., 1999a
) is similar to that described for extracellular single-unit recordings of striatal neurons in barbiturate-anesthetized cats (Sedgwick and Williams, 1967
; Katayama, 1978
; Katayama et al., 1980
). Assuming a uniform behavior within the population of C-S neurons and that of SONs under barbiturate anesthesia, we found that C-S cells had a higher level of spontaneous firing compared to SONs and that the temporal dispersion of cortical firing on synaptic depolarization was significantly wider than that of striatal cells. In addition, the mean timing of striatal firing was delayed by ~25 ms with respect to the cortical discharge. This temporal shift can be explained by the time required for integration of cortico-striatal information. This includes the conduction time of C-S spikes from the cerebral cortex to the contralateral striatum (mean
7 ms), the synaptic delay [~0.3 ms (Eccles, 1964
)] and the rise time of synaptic potentials due to the membrane time constant of SONs [~8 ms (Kawaguchi et al., 1989
)]. The time lag between spontaneous firing of SONs and C-S neurons is also consistent with the time-to-peak of EPSPs evoked by electrical stimulation of the contralateral cortex [~22 ms (Wilson, 1986
)].
A recent computer model (Marsalek et al., 1997; Diesmann et al., 1999
) of propagation of synchronous activity in neural networks similar to the cortico-striatal pathway, i.e. a large number of active neurons converging onto target neurons, predicted that if the firing probability density of afferent neurons has a Gaussian distribution, the firing probability density of the target neurons would also have a Gaussian fit, but with a smaller standard deviation and a decrease in the number of active cells. This theoretical study is in accordance with our experimental data obtained under barbiturate anesthesia, which therefore strongly suggest a causal link between cortical synchrony and firing of striatal neurons.
Ketaminexylazine anesthesia provided another model of cortical synchronization. Under these anesthetics C-S neurons displayed step-like membrane potential fluctuations. Similarly, SONs exhibited rhythmic plateau-like depolarizations that could trigger APs. This alternation of up and down states in striatal cells has been extensively studied by Wilson's group (Wilson and Kawaguchi, 1996; Stern et al., 1997
, 1998
). As discussed above, the relationship between EEG waves and C-S neuron up states suggests that transition into the up state occurs simultaneously among C-S cells. Moreover, the firing of C-S neurons was mainly clustered during the first 200 ms of the up state, the probability of firing decreasing progressively on membrane depolarization. Therefore, it is likely that synchronization of entry into the up state among the C-S neuron population leads to coherent firing of these cells, at least during the earliest part of the up state. This will produce highly correlated excitatory synaptic potentials in SONs leading to a sharp depolarization that causes transition to the up state and spike firing. How do we explain the fact that the striatal up state often lasted >200 ms in spite of the decreasing firing probability during C-S neuron up states? It has been proposed by Wilson and Kawaguchi that the level of membrane depolarization (
60 mV) reached during the striatal up state leads to deactivation of the potassium current responsible for inward rectification in the down state (Wilson and Kawaguchi, 1996
). This would result in an increase in membrane resistance, allowing sustained membrane depolarization during the striatal up state, while the weight of excitatory synaptic inputs is weakened due to the decrease in the probability of firing in C-S neurons. During the later part of the up state in C-S neurons the lowering and temporal spreading of firing probably results in a lack of synchrony of spike discharges among C-S neurons. Therefore, the uncorrelated excitatory synaptic events in SONs will become ineffective in maintaining membrane depolarization and will act in synergy with activation of the inwardly rectifying potassium current, leading striatal cells to return to the down state (Wilson and Kawaguchi, 1996
). Altogether, these mechanisms could explain, first, the significantly shorter mean duration of striatal up states compared with that of cortical up states and, second, that striatal up states could last >200 ms.
Under neurolept-analgesia C-S cells and SONs displayed arhythmic synaptic depolarizations that were associated with a temporally disorganized EEG. While the activity of C-S neurons could be supra-threshold for spike discharge, their firing did not present any predominant frequency and any obvious recurrent rhythmic patterns. This uncorrelated activity in C-S cells resulted in an absence of large amplitude synaptic potentials and consequently a lack of firing in SONs.
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Concluding Remarks |
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Notes |
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Address correspondence to S. Mahon, Chaire de Neuropharmacologie, INSERM U114, Collège de France, 11 Place Marcelin Berthelot, F-75005 Paris, France.
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References |
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