Enhancement of mesencephalic reticular neuronal responses to sensory stimuli with pentylenetetrazol

Anterior thalamic mediation of experimental seizures: selective EEG spectral coherence

PURPOSE

Physiological evidence has shown that the anterior thalamus (AN) and its associated efferents/afferents constitute an important propagation pathway for pentylenetetrazol (PTZ)-mediated generalized seizures in rodents. Previous work demonstrated metabolic, physical, chemical, and electrical stimulation data supporting a role for AN in the expression of PTZ seizures. We now extend these observations through examination of neuroelectric signal indicators during seizure epochs. We show that the EEG recorded from AN is highly coherent with surface cortical (CTX) EEG during the immediate preconvulsant period and during the ictal stateough.

METHODS

Awake rats were continuously infused with PTZ until clonic seizures were recorded by using both subcortical AN, posterior thalamus (PT), or hippocampal (HPC) bipolar electrodes and cortical EEG. Through the signal-analysis techniques of ordinary and partial coherence, it was possible to focus selectively on signal correlations between AN and CTX (AN/CTX) by removing the effects of unaffiliated regions such as PT and HPC.

RESULTS

Coherence of PT/CTX was observed to be modest, and partial coherence of PT/CTX with the effects of AN/CTX removed did not improve the signal coherence of PT/CTX (PT/CTX-AN). In contrast, AN/CTX coherence was observed to be high, with undiminished correlation when PT/CTX influence was removed (AN/CTX-PT). The most robust band of AN/CTX coherence was centered around the spike-wave clonic frequency of 1-3 Hz. Partial multiple coherence-analysis techniques were used to remove the possible signal contributions from hippocampus in addition to PT. The AN/CTX coherence remained fully preserved in the low-frequency bands.

CONCLUSIONS

These data provide electrophysiologic evidence supporting the special role of the anterior thalamus in the propagation of seizure activity between subcortex and cortex.

Mapping of neuronal networks underlying generalized seizures induced by increasing doses of pentylenetetrazol in the immature and adult rat: a c-Fos immunohistochemical study

Previous studies from our group have shown that pentylenetetrazol (PTZ)-induced status epilepticus (SE) leads to age-dependent acute and long-term metabolic and circulatory changes in immature rats. In order to define the neural substrates involved in PTZ seizures according to age, the purpose of the present study was to map the areas of cellular activation during seizures of increasing severity in 10-day-old (P10), 21-day-old (P21) and adult rats. Seizures were induced by repetitive injections of subconvulsive doses of PTZ. The total dose received by the animals ranged from 4 to 125 mg/kg. These doses induced a variety of seizure profiles including absence-like, clonic seizures and SE. The cellular activation was measured as the density of c-Fos immunoreactive cells in animals at 2 h after the onset of the seizures. In P10 rats receiving a behaviourally non-active dose of PTZ, c-Fos immunoreactivity appeared only in the amygdala. The dose of 40 mg/kg that induced absence-like seizures led to a weak c-Fos expression in the medial thalamus, some cortical areas and globus pallidus. Clonic seizures reinforced labelling in the previous areas and induced a spread of c-Fos immunoreactivity to other cortical areas, thalamus, hypothalamus and some brainstem nuclei. At that age, only SE led to a widespread and stronger expression of c-Fos which was, however, totally lacking in the midbrain, and remained incomplete in the brainstem and forebrain limbic system, including the hippocampus. In P21 and adult rats, the inactive dose of PTZ induced c-Fos immunoreactivity in thalamus and hypothalamus. With absence-like seizures, c-Fos labelling spread to the cerebral cortex, amygdala, septum and some brainstem regions. With clonic seizures, immunoreactivity was reinforced in all areas already activated by absence-like seizures, and appeared in the striatum, accumbens, brainstem and hippocampus, except in CA1. After SE, c-Fos was strongly expressed in all brain areas. The intensity of c-Fos labelling was higher in most regions of P21 compared to adult rats. These data are in agreement with the immaturity of cellular and synaptic connectivity in P10 rats, the known greater sensitivity of rats to various kinds of seizures during the third week of life and the nature of the neural substrates involved in PTZ seizures.

An experimental model of generalized seizures for the measurement of local cerebral glucose utilization in the immature rat. II. Mapping of brain metabolism using the quantitative [14C]2-deoxyglucose technique

The quantitative autoradiographic [14C]2-deoxyglucose technique (2DG) was applied to measure the effects of pentylenetetrazol (PTZ)-induced status epilepticus (SE) on local cerebral metabolic rates for glucose (LCMRglc) in 10 (P10)-, 14 (P14)-, 17 (P17)- and 21 (P21)-day-old rats. To produce long-lasting SE (55 min), the animals received repetitive, timed intraperitoneal injections of subconvulsive doses of PTZ until SE was reached. At P10 and P14, SE induced a marked increase in LCMRglc which affected 66 of the 76 structures studied. Increases were especially high (200-400%) in limbic and motor cortices at P10 and in some brainstem areas at these 2 ages. At P17 and P21, average brain glucose utilization was similar in seizing and control rats, but in PTZ-treated rats reflected a redistribution in local metabolic rates with increases in brainstem, midbrain, hypothalamus and septum, decreases in cortex, hippocampus, some sensory areas and white matter and no change in many motor and limbic structures. In a few cerebral regions, such as hippocampus, dentate gyrus and mammillary body, LCMRglc did not increase at P10 and P14 and decreased at P17 and P21 in PTZ- vs. saline-treated rats. The results of the present study show that the immature brain responds to sustained seizure activity in a specific way according to its maturational state. Moreover, these data allow the mapping of the vulnerability of cerebral structures to seizures, according to their metabolic response to convulsions.

Excitant amino acids and audiogenic seizures in the genetically epilepsy-prone rat. II. Efferent seizure propagating pathway

Previous studies indicate that the inferior colliculus is the brain stem auditory nucleus most sensitive to the chemical blockade of audiogenic seizures in the genetically epilepsy-prone rat. Other auditory structures do not appear to be as important. This study attempted to define the efferent pathways involved in propagation of the seizure from the colliculus to the spinal cord where the motor components of the convulsion are generated. This study also determined whether certain nuclei which have been implicated in the propagation of seizures in other epilepsy models are involved in audiogenic seizures. The excitant amino acid antagonist, 2-amino-7-phosphonoheptanoate, was infused bilaterally into several of those sites. The drug was effective in significantly reducing seizure severity with infusion of 5 nmol bilaterally into the midbrain and the pontine reticular formation or the substantia nigra. However, similar drug doses were not effective when infused into the entopeduncular nucleus even though prominent behavioral effects were observed with this infusion. Infusion of 2-amino-7-phosphonoheptanoate into the prepiriform cortex resulted in a small but significant reduction in seizure severity. These results suggest that inhibition of excitatory transmission within the substantia nigra and the reticular formation effectively blocks the output pathway for the audiogenic seizures, whereas the role of the prepiriform cortex in this process is relatively minor.

Functional anatomy of pentylenetetrazol and electroshock seizures in the rat brainstem

The ability of discrete brainstem injections of gamma-vinyl-gamma-aminobutyric acid (GVG), an irreversible inhibitor of gamma-aminobutyric acid transaminase, to prevent pentylenetetrazol (PTZ) seizures and maximal electroshock seizures (MES) was studied and compared in rats. PTZ seizures were prevented by GVG injections in the anterior thalamus, the caudal hypothalamus, the superior colliculus, cerebellar nuclei, and in a large area of the medial medullary, pontine, and mesencephalic tegmentum encompassing the vestibular nuclei, the reticular formation, and portions of the central gray. GVG injections in the substantia nigra did not protect against PTZ seizures. In contrast, tonic hindlimb extension in MES was prevented consistently by injections in the substantia nigra. A minority of injections in the vestibular nuclei, cerebellar nuclei, and parts of the reticular formation also protected against tonic hindlimb extension of MES. These results indicate a striking difference in the functional anatomy of PTZ-induced seizures and MES. PTZ seizures appear to be mediated by an extensive system involving the reticular formation, diencephalic regions in the vicinity of the anterior medial thalamus and caudal hypothalamus, and bulbar regions which give rise to descending motor pathways to the spinal cord. In contrast to PTZ seizures, MES appears to be mediated by a different neuroanatomical substrate with the present data implicating only the substantia nigra definitely in that process.

Anterior thalamus and substantia nigra: two distinct structures mediating experimental generalized seizures

Injection of gamma-vinyl aminobutyric acid (GVG) into the anterior thalamus protected rats against pentylenetetrazol (PTZ) seizures but not against maximal electroshock (MES) seizures. Injection of GVG into the substantia nigra protected against MES seizures but not against PTZ seizures. Both types of seizures were prevented by injections into both of the above brain regions. These data indicate that separate neuronal circuits mediate PTZ and MES seizures.

Selective metabolic activation of the mammillary bodies and their connections during ethosuximide-induced suppression of pentylenetetrazol seizures

Electroencephalographic (EEG) activity and regional [14C]2-deoxyglucose incorporation in brain were examined in guinea pigs treated with pentylenetetrazol (PTZ), ethosuximide (ESM), phenytoin (PHT), or combinations of these drugs. Convulsant doses of PTZ induced EEG epileptiform discharges in paralyzed and ventilated animals and resulted in a large increase in labeled glucose accumulation in essentially all brain areas. ESM alone depressed EEG activity and accumulation of label, whereas PHT alone had little or no effect. Autoradiographs of PTZ-infused animals pretreated with PHT, which facilitated the onset and increased the severity of the PTZ seizures, were similar to those of animals treated with convulsant alone, with additional label uptake in the globus pallidus and substantia nigra. Pretreatment of PTZ-infused animals with sufficient ESM to prevent most EEG spike activity reduced glucose incorporation in most brain regions, but increased it in some. Selective enhancement of label uptake was observed in the mammillary bodies, mammillothalamic tracts, the anterior nuclei of the thalamus, the mammillary peduncles, and the dorsal and ventral tegmental nuclei of the midbrain. These data suggest that the mammillary nuclei and their projections to the anterior thalamic nucleus and their reciprocal projections to and from the tegmental nuclei may be important in the mediation of seizure activity induced by PTZ and/or the anticonvulsant action of ESM.

Comparative effects of convulsant drugs on the sensory responses of neurons in the amygdala and brainstem reticular formation

The sensory responses of neurons in the amygdala and mesencephalic reticular formation in the cat were enhanced following the intravenous administration of subconvulsant doses of bicuculline, strychnine, bemegride, pentylenetetrazol and physostigmine. The degree and intensity of the enhancement of the response was considerably greater in the reticular formation than in the amygdala. The latency of the response in simultaneously-recorded pairs of neurons in the amygdala and reticular formation was significantly shorter in the mesencephalic reticular formation. The enhancement induced by convulsants does not appear to be transmitter-specific, since enhancement was produced with sequential administration of convulsant drugs which affect gamma-aminobutyric acid (GABA), glycine or acetylcholine. These findings suggest that the reticular formation is involved, to a larger degree than the amygdala, in the ability of sensory stimuli to initiate generalized convulsive seizures in animals treated with these convulsant drugs. The enhancement of the response in the hippocampus and cortex, which has previously been shown to exhibit a longer latency and a lower degree of enhancement than the reticular formation, coupled with the findings in the amygdala, suggest that the reticular formation may mediate the enhancement of the response of these other regions of the brain. The spread of the enhancement of the response to other structures in the brain via the widely distributed output pathways from the reticular formation may lead to initiation of generalized seizures by a recruitment-like process, which may involve enlargement of the sensory hyperresponsive neural network of the brain until a critical neural mass is reached and initiation of seizures results.

Interruption of the mammillothalamic tract prevents seizures in guinea pigs

Interruption of the connection between the mammillary bodies and the anterior nucleus of the thalamus in guinea pigs, by discrete bilateral electrolytic lesions of the mammillothalamic tract, resulted in essentially complete protection from the behavioral and electroencephalographic convulsant action and lethal effect of pentylenetetrazol. This result demonstrates that the mammillary bodies and their rostral efferent connections are important for the propagation and perhaps initiation of generalized seizures.

Effects of iontophoretic application of convulsants on the sensory responses of neurons in the brain-stem reticular formation

Iontophoretic or pneumatic application of convulsants produced enhancement of the sensory responses of brain-stem reticular formation (RF) neurons in cat and rat. Enhanced sensory responsiveness is observed with visual, auditory, somatosensory and vibrissa manipulation following application of strychnine, bicuculline or pentylenetetrazol. The effect was not transmitter-specific, since it could be produced by sequential application of bicuculline and strychnine which are thought to affect different neurotransmitters. Intravenous administration of convulsant also enhanced the responsiveness of RF neurons which had previously been affected by application of a different convulsant. Both systemic and iontophoretic effects could be antagonized by application of GABA and glycine. These data, coupled with previous findings in primary sensory pathways, indicate that sensory response enhancement in the RF induced by intravenous administration of these convulsants is in large part due to actions on synaptic elements of reticular formation neurons.

Phencyclidine (PCP): effects on auditory evoked potentials in the rhesus monkey

Effects of acute and chronic administration of phencyclidine (PCP) on auditory evoked potentials (AEPs) were studied in rhesus monkeys with encephalic electrodes permanently implanted. AEPs were evoked by single clicks (1.0 pps in frequency) generated by an externally triggered audiomonitor. Single PCP injections (dose, 2.0 or 4.0 mg/kg IV) in monkeys produced a striking distortion in the amplitudes of major AEP components. This AEP distortion was manifested in superior temporal cortex (ST) by a complex pattern of amplitude reduction and enhancement, and was manifested in the medial geniculate body (MGB) by amplitude reduction. These effects persisted for 4 to 5 hours. Upon chronic administration (dose, 4.0 mg/kg IV daily), the effects of PCP on AEP components in ST were enhanced while little change was noted in its effect on AEP components in MGB. These results suggest that PCP administration in rhesus monkeys causes a significant disturbance of AEPs within central nervous system structures associated with auditory processing (i.e., ST and MGB), and that chronic PCP administration enhances its effects on AEPs predominantly in the primary auditory cortex while having little additional effects on AEPs from the subcortical auditory pathways.

On the site of pentylenetetrazol-induced enhancement of auditory responses of the reticular formation: localized cooling and electrical stimulation studies

Pentylenetetrazol (PTZ), administered systemically, enhanced the auditory responses of neurons of the mesencephalic reticular formation (MRF). Responses evoked in the mesencephalic reticular formation by electrical stimuli in several primary auditory nuclei (cochlear nucleus, superior olivary complex and lateral lemniscus, but not inferior colliculus) were also enhanced by pentylenetetrazol in the majority of cases. Bilateral cryoprobe cooling in the lateral lemniscal tract substantially reduced the auditory-evoked field potentials (EPs) in the mesencephalic reticular formation before and after administration of pentylenetetrazol. Cooling in the inferior colliculus (IC) produced a small reduction in auditory-evoked field potentials in the mesencephalic reticular formation before drug but a more substantial degree of reduction after administration of pentylenetetrazol. A relatively small degree of pentylenetetrazol-induced enhancement of the response was seen in neurons of the inferior colliculus (158% of control) as compared to that of neurons in the mesencephalic reticular formation (410%). These findings would be consistent with the reported ability of pentylenetetrazol to block presynaptic inhibition if the input from the inferior colliculus to the mesencephalic reticular formation has inhibitory as well as excitatory components. These data along with the present authors' recent finding of enhancement of response with microapplication of convulsants strongly suggest that enhancement of responses of neurons of the mesencephalic reticular formation, induced by systemically administered convulsants such as pentylenetetrazol is exerted, to a large extent, by direct actions on synaptic elements of the reticular formation.

Serotonin mediation of the protective effect of clonidine against pentylenetetrazol-induced seizures in rats

An intraperitoneal injection of 0.5 mg/kg clonidine significantly increased the latency to the first convulsion and reduced tonic seizures and mortality caused by pentylenetetrazol (PTZ), 90 mg/kg, administered subcutaneously to rats. 1 mg/kg clonidine produced similar effects except that tonic seizures were not significantly affected. No effect was observed with 0.01 or 0.1 mg/kg clonidine. Metergoline (1 mg/kg) and methysergide (10 mg/kg), administered intraperitoneally, completely prevented the effect of 0.5 mg/kg clonidine on PTZ-induced seizures. An intraperitoneal injection of 5 mg/kg of d-fenfluramine, a releaser of 5HT from nerve terminals, significantly reduced tonic seizures and completely blocked mortality caused by PTZ but did not significantly modify the latency to the first convulsion. The results suggest that serotonin plays an important role in the protective effect of 0.5 mg/kg clonidine against PTZ-induced seizures. Possible reasons for the different effects of clonidine on different experimental seizures are discussed.

Bicuculline-induced enhancement of sensory responses and cross-correlations between reticular formation and cortical neurons

The visual, auditory and somatosensory responses of neurons in the brain stem reticular formation (RF) and pericruciate cortex of the cat are enhanced by intravenous administration of subconvulsant doses of bicuculline. The degree of enhancement in RF neurons is somewhat greater in magnitude and occurs in a greater percentage of RF neurons. The latency of response is shorter in the RF than in the cortex in 70% of cases. A large percentage of simultaneously recorded RF and cortical neurons which became responsive to the same stimulus exhibited consistent convulsant-induced cross-correlations of firing which were not present before drug treatment. The latency and correlation data are consistent with the possibility that the RF may subserve the cortical enhancement. Auditory response thresholds in RF neurons are reduced by bicuculline administration. Enhancement of RF neuronal responsiveness has previously been observed with several other convulsant drugs which are thought to act on different neurotransmitters suggesting that it may reflect a general action of these agents beyond the effects on specific neurotransmitters. The bicuculline-induced correlation of firing of RF and pericruciate neurons may be involved in the mechanism of initiation of convulsant-mediated seizure generalization induced by sensory stimuli.

Differences in the responses of raphe nuclei to repetitive somatosensory stimulation

The responses of single units in raphe (R.) nuclei dorsalis, magnus, pallidus, and obscurus to repetitive stimulation of peripheral nerves were studied in the chloralose-anesthetized cat. Low-intensity electrical stimuli (1.5T) which activated the large-diameter fibers were applied to the common peroneal and lateral gastrocnemius nerves at 0.25, 0.5, 1 and 2 Hz. Responses evoked at each frequently were compared with the control response evoked at 0.1 Hz. All units isolated demonstrated response decrements during periods of stimulation greater than or equal to 0.5 Hz. The long-term effects of repetitive stimulation, however, varied among the four nuclei. After 150 stimulus presentations at 0.5, 1, or 2 Hz, sensory responsiveness decreased in R. dorsalis but was enhanced in caudal R. obscurus units. Changes in the responsiveness of the other two nuclei were not significantly different from control. Responses to twin pulses indicated that R. neurons are not well suited to relay rapid, repetitive stimuli. The functional significance of these observations has implications for the role of the raphe in habituation and in the modulation of sensory traffic to higher centers. Raphe responses are also contrasted to the known responses of reticular formation neurons to repetitive stimulation.

Effects of bemegride on the sensory responses of neurons in the hippocampus and brain stem reticular formation

Administration of subconvulsant doses of bemegride results in extensive enhancement of sensory responsiveness to auditory, visual, somatosensory and vibrissa stimulation of neurons in the medullary and mesencephalic reticular formation (RF). This effect is not altered by cord transection. Most neurons in the dorsal hippocampus do not show enhanced sensory responsiveness. In the minority of hippocampal neurons which do show enhancement the effect is much less extensive than that seen in the RF despite larger doses of bemegride. The enhancement of RF neuronal response may involve the reversal of repetition induced response attenuation ('habituation') and reductions in response threshold. During EEG seizures the firing of neurons in RF and hippocampus are temporally correlated with the spikes in the cortical EEG. The effects of bemegride on RF neurons are similar to those previously reported for strychnine and pentylenetetrazol and preliminary studies with physostigmine and bicuculline. These findings further extend the concept that a relatively selective enhancement of the sensory responses of brain stem reticular formation neurons may be indicative of a general neuronal effect of convulsants which may play an important role in the initiation of sensory-induced seizures.

Strychnine effects on the sensory response patterns of reticular formation neurons

Strychnine (ST) administration results in enhanced responses of reticular formation neurons of the cat to visual, auditory, or somatosensory stimuli. Neurons in the bulbar reticular formation (BRF) also exhibited ST-induced spike-bursting which coincides with the onset of 10--20 Hz high amplitude rhythmic discharge in the lower brain stem often obscuring sensory response enhancement. Mesencephalic reticular formation (MRF) neurons showed enhanced sensory responsiveness at higher doses of ST but rarely showed spike-bursting. The rhythmic discharge in the EEG of BRF and spike-bursting in BRF neurons was not observed in animals with spinal cord transection suggesting that this bursting activity is due to the action of ST on the spinal cord. The enhancement of sensory responses may be due in part to reversal of repetition-induced response attenuation (habituation) mechanisms in RF neurons. The ST-induced enhancement of RF neuronal responses to sensory stimuli is similar to that reported previously with pentylenetetrazol. These findings extend the concept that enhancement of RF responses to sensory stimuli may be indicative of a general neuronal action of convulsant agents which may be important in sensory-induced seizures.

Comparative effects of pentylenetetrazol on the sensory responsiveness of lateral geniculate and reticular formation neurons

The responses of bulbar and mesencephalic reticular formation (MRF) neurons to visual, auditory and/or somatosensory stimuli were considerably enhanced after subconvulsant doses of pentylenetetrazol (PTZ) in a similar fashion suggesting a general action of PTZ on reticular formation (RF) neurons. PTZ enhanced MRF responses evoked by electrical stimuli in the lateral geniculate nucleus (LGN) or cochlear nucleus but only modestly enhanced LGN neuronal responses. These findings indicate that the effects of this convulsant on the first brain sensory 'relay' nuclei and primary sensory receptors do not appear to be sufficient to account for the extensive PTZ-induced enhancement of RF neuronal responses, and direct effects of PTZ on the reticular formation may play a major role in this enhancement.