Differential pharmacological reactivity of aversion induced by stimulation of periaqueductal gray or mesencephalic locomotor region

Rats were trained to switch-off aversive electrical brain stimulations applied to the periaqueductal gray (PAG) or mesencephalic locomotor region (MLR) by pressing a bar (switch-off behavior). We investigated the effects of IP injections of the benzodiazepine (BZ) receptor inverse agonist FG 7142 (2.5, 5, 10 mg/kg) or BZ receptor agonist chlordiazepoxide (CDP: 5 mg/kg) on the switch-off latency, i.e., the time elapsed between the onset of the stimulation and its offset by a press of the bar. It was found that FG 7142 decreased, whereas CDP increased the mean switch-off latency for electrical stimulation of the PAG, which is interpreted as a potentiating effect of FG 7142 and a reducing effect of CDP on the electrically induced aversive state. By contrast, neither FG 7142 nor CDP were found to affect the mean switch-off latency for MLR stimulations. These results suggest a difference in the pharmacological sensitivity to BZ receptor ligands between aversive states elicited by electrical stimulation of the PAG or MLR.     

Effects of opioid receptor blockade on defensive behavior elicited by electrical stimulation of the aversive substrates of the inferior colliculus in Rattus norvegicus (Rodentia, Muridae)

RATIONALE: Electrical or chemical stimulation of some structures of the midbrain tectum, such as the dorsal periaqueductal gray matter, deep layers of the superior colliculus and inferior colliculus induce fear and flight behavior. These structures constitute the main neural substrates commanding defensive behavior in brainstem. Many neurotransmitters are implicated in the modulation of aversion at the mesencephalic level. OBJECTIVE: The aim of this work is to investigate the involvement of opioid mechanisms in modulation of defensive behavior in dorsal mesencephalon. METHODS: Male Wistar rats were fixed in a stereotaxic frame and a chemitrode was implanted into the midbrain, targeted to the central nucleus of the inferior colliculus. In the present study, the effects of peripheral and central administration of naloxone, naltrexone or naloxonazine on aversive thresholds (freezing and escape reactions) elicited by electrical stimulation of the midbrain tectum were determined. RESULTS: Peripherally and centrally administered naloxone caused a significant increase in the freezing and flight thresholds elicited by electrical stimulation of the aversive substrates of the inferior colliculus. These effects were confirmed by peripheral and central administration of naltrexone and by microinjections of naloxonazine in inferior colliculus. CONCLUSIONS: These findings suggest that endogenous opioids are involved in the modulation of the aversive behavior elicited by midbrain tectum stimulation. Since microinjections of naloxonazine in the central nucleus of the inferior colliculus caused a significant increase in the aversive thresholds elicited by electrical stimulation of this structure, it is possible that micro1 opioid receptor located in this nucleus may be critically implicated in this neural circuitry.     

Morphine applied to the mesencephalic central gray suppresses brain stimulation induced escape

In the rat, microinjections of morphine (1.5 to 15 nmoles) into the dorsal part of the mesencephalic centray gray (CG) were found to suppress both escape responding induced by electrical stimulations applied to either the medial hypothalamus (MH) or the CG and behavioral responsiveness to peripheral nociceptive stimulations. The time course of these two effects proved quite similar (Experiments 1 and 2). A systemic injection of naloxone reverse—in a dose dependent manner—the effects of morphine on the centrally induced escape responses (Experiment 3). The possibility that microinjections of morphine decrease both responsiveness to peripheral nociceptive stimulation and the reactivity of higher structures involved in the generation of aversive effects is discussed.     

Opposite effects of low and high doses of morphine on neural substrates of aversion in the inferior colliculus

The inferior colliculus (IC) is a well known relay station for auditory pathways in the brainstem. Much evidence has implicated this structure as part of a brain system mediating aversive states, and changes in its functioning as responsible for the occurrence of audiogenic seizures. Rats were implanted with chemitrodes, devices which allow electrical stimulation and microinjections of drugs in the same brain sites. Stepwise increases in the intensity of electrical stimulation of the IC of rats placed inside a circular arena allowed the determination of thresholds for freezing and escape behavior. Morphine (10-40nmol) caused dose-dependent increases in both aversive thresholds. A systemic injection of naloxone reversed the effects of morphine on the centrally induced aversive responses. These data suggest that neural substrates controlling defensive behavior in this structure are under opioid inhibitory control. Higher doses of morphine (80nmol) induced a non-naloxone reversible fearful hyper activity. It is suggested that opioid mechanisms exert an inhibitory control on the neural substrates of aversion in the IC and that high doses of morphine microinjected into IC cause pro-aversive actions probably through non-opioid mechanisms.     

Effects of caroverine and diltiazem on synaptic responses, L-glutamate-induced depolarization and potassium efflux in the frog spinal cord.

The frog spinal cord was used to determine the characteristics of the actions of caroverine and diltiazem, two organic Ca2+-antagonists, on synaptic responses and L-glutamate-induced depolarization. Caroverine and diltiazem (10(-4)M) depressed the dorsal root potential (DR-DRP) induced by electrical stimulation of an adjacent dorsal root. Diltiazem also depressed the ventral root potential (DR-VRP), whereas caroverine augmented both the polysynaptic component in the ventral root reflex and the size of the DR-VRP. The root potentials induced by high frequency stimulation (20 Hz, for 1 s) were markedly depressed by these Ca2+-antagonists at a concentration of 10(-4)M. When the preparation was perfused with normal medium, the compounds depressed L-glutamate-induced depolarizations in ventral and dorsal roots. In preparations treated with tetrodotoxin (TTX) (2 X 10(-7)M), the antagonizing actions of the drugs against L-glutamate-induced depolarizations in the ventral root were markedly reduced or abolished, while significant antagonizing actions on the depolarization in the dorsal root were still observed. The increase in extracellular K+ activity induced by L-glutamate in the TTX-treated preparation was significantly reduced by the compounds. Caroverine and diltiazem had no effect on the presynaptic nerve spike and on the focal synaptic potential induced by a single stimulation of a dorsal root; however, the focal synaptic potential induced by high frequency stimulation (20 Hz, 1 s) was attenuated. Motoneuronal action potentials were abolished by the drugs, while the excitatory postsynaptic potential remained unaffected.(ABSTRACT TRUNCATED AT 250 WORDS)     

Neuroanatomical and psychopharmacological evidence for interaction between opioid and GABAergic neural pathways in the modulation of fear and defense elicited by electrical and chemical stimulation of the deep layers of the superior colliculus and dorsal periaqueductal gray matter.

The effects of central administration of opioid antagonists on the aversive responses elicited by electrical (at the freezing and escape thresholds) or chemical stimulation (crossings, rearings, turnings and jumps, induced by microinjections of bicuculline) of the midbrain tectum were determined. Central microinjections of naloxone and naltrexone in the mesencephalic tectum caused a significant increase in the freezing and escape thresholds elicited by electrical midbrain tectum stimulation. Furthermore, both opioid antagonists caused a significant decrease in the mean incidence of aversive behavioral responses induced by microinjections of bicuculline in the deep layers of the superior colliculus (DLSC) and in dorsal aspects of the periaqueductal gray matter (DPAG), as compared with controls. These findings suggest an opioid modulation of the GABAergic inhibitory inputs controlling the aversive behavior elicited by midbrain tectum stimulation. In fact, immunohistochemical evidence suggests that the dorsal mesencephalon is rich in beta-endorphin-containing neurons and fibers with varicosities. Iontophoretical microinjections of the neurotracer biodextran in the substantia nigra, pars reticulata (SNpr), show nigro-tectal pathways connecting SNpr with the same neural substrate of the DPAG rich in neuronal cells immunoreactive for opioid peptides. Labeled neurons of the DLSC and periaqueductal gray matter send inputs with varsicosities to ipsi- and contralateral DPAG and ipsilateral SNpr. These findings, in addition to the psychopharmacological evidence for the interaction between opioid and GABAergic mechanisms, offer a neuroanatomical basis of a possible presynaptic opioid inhibition of GABAergic nigro-tectal neurons modulating the fear in aversive structures of the cranial mesencephalon, in a short link, and maybe through a major neural circuit, also in GABA-containing perikarya of nigro-tectal neurons.     

Conditioned antinociception and freezing using electrical stimulation of the dorsal periaqueductal gray or inferior colliculus as unconditioned stimulus are differentially regulated by 5-HT2A receptors in rats

RATIONALE: Electrical stimulation of the dorsal periaqueductal gray matter (dPAG) and the inferior colliculus (IC) has been used as an aversive unconditioned stimulus. However, studies on the behavioral, sensorial and autonomic components of the conditioned fear elaborated in the midbrain tectum are lacking. OBJECTIVES: This study was undertaken to investigate the nature of the aversiveness of stimulation of the dPAG and IC as well as the modulation by 5-HT mechanisms of the fear conditioned responses to these stimulations. METHODS: Animals chronically implanted with an electrode glued to a guide cannula into the dPAG or the IC were submitted to one, two or three sessions of conditioning. Each session consisted of ten pairings of the light in a distinctive chamber (CS) with the electrical stimulation of one of these regions at the escape threshold determined previously. Control groups were submitted to the same procedure, except for the conditioning sessions in which the conditioned stimuli were presented alone in one case and performed in a different context in the other. On the next day, each animal was exposed only to the CS (testing) and the duration of freezing, number of rearings, grooming, bouts of micturition and fecal boli were recorded for 5 min. Before and after the testing session, the animals were submitted to the tail-flick test. RESULTS: The data showed that the conditioning with electrical stimulation of the dPAG and the IC caused significant increases in the time of freezing, defecation and micturition, and significant reductions in the number of rearings and grooming. On the other hand, only the conditioning with electrical stimulation of the dPAG produced significant conditioned antinociception. Microinjections of methysergide, a non-specific antagonist of 5-HT receptors, or ketanserin, an antagonist of 5-HT2A receptors, into the dPAG before testing significantly inhibited the antinociception without affecting any of the behavioral or autonomic conditioned responses. CONCLUSIONS: 1) Conditioned freezing may be produced using the electrical stimulation of the dPAG or IC as unconditioned stimuli, 2) only the pairing of CS plus dPAG but not with IC stimulation, produces significant conditioned antinociception, 3) blockade of 5-HT2A receptors inhibits conditioned antinociception but not the conditioned defensive behavior using the electrical stimulation of the dPAG as unconditioned stimulus.     

The role of nitric oxide in non-adrenergic non-cholinergic relaxation in the guinea-pig gastric fundus

The role of nitric oxide (NO) in non-adrenergic non-cholinergic (NANC) neurotransmission was studied on circular muscle strips of the dorsal part of the guinea-pig gastric fundus. In the presence of atropine and guanethidine, a low frequency of electrical stimulation (1≈10 Hz) induced frequency-dependent relaxation which were not affected by adrenergic and cholinergic blockage but abolished by tetrodotoxin. N^G-nitro-L-arginine (L-NNA), a stereospecific inhibitor of NO-biosynthesis, inhibited the relaxations induced by electrical stimulations but not the relaxations to exogenous nitric oxide. The effect of L-NNA was prevented by L-arginine, the precursor of the NO biosynthesis but not by its enantiomer, D-arginine. Exogenous administration of NO caused concentration-dependent relaxations which showed a similarity to those obtained with electrical stimulation. Hemoglobin, a NO scavenger, abolished the NO-induced relaxations and also markedly reduced those induced by electrical stimulation. The inhibitory effect of hemoglobin was similar to that of L-NNA. Application of ATP caused weak relaxations compared with those to electrical stimulation, which were unaffected by L-NNA. Exogenously applied vasoactive intestinal polypeptide (VIP) induced concentration-dependent relaxation which was not affected by L-NNA. These results suggest that NO is produced and released mainly as a neurotransmitter from enteric neurons during NANC relaxation induced by low frequencies and short trains of electrical stimulation and has a main role in NANC neurotransmission at relaxation induced by these electrical stimulations in the guinea-pig gastric fundus.     

Apomorphine enhances conditioned responses induced by aversive stimulation of the inferior colliculus.

Consistent evidence has shown that learning may be produced in paradigms using electrical stimulation of the inferior colliculus (IC) as unconditioned stimulus (UCS). Recent reports have also demonstrated that aversive stimulation of the IC, at the escape threshold, enhances dopamine (DA) release in the prefrontal cortex. The purpose of the present study was to determine whether dopaminergic mechanisms are involved in the Pavlovian conditioning and latent inhibition using IC stimulation as UCS and light as conditioned stimulus (CS). Rats were placed inside a shuttle box and subjected to a two-way avoidance paradigm. IC aversive electrical stimulation was used as UCS and shuttle box illumination as CS. The rats quickly learned to avoid or interrupt the IC stimulation. Apomorphine injections produced a dose-dependent increase in the number of avoidance responses. On the other hand, chlorpromazine administration promoted a dose-dependent reduction of the avoidance responses. Previous injections of chlorpromazine inhibited the effects of apomorphine. Also, previous exposure to unreinforced light weakened the strength of the conditioning. Apomorphine blocked this latent inhibition effect, which was antagonized by previous injections of chlorpromazine. These findings bring evidence for the involvement of DA in the setting up of adaptive responses to aversive states generated at the IC level, which may underlie stressful situations present in anxiety.     

HA autoreceptor assay with superfused slices of rat brain cortex and electrical stimulation

Slices of rat brain cortex previously loaded with [3H]histamine ([3H]HA) via de novo synthesis from [3H]histidine released tritiated histamine ([3H]HA) Ca2+ dependently in a superfused system. Both electrical field stimulation and high levels of K+ ions elicited this release. The extent of release depended on stimulation intensity. Rather strong stimuli, either by high frequency or longer stimulation, were required to elicit sufficient HA release for proper assessment of the concentration-dependence of release inhibition by drugs. The system showed marked depletion (less response per pulse) upon long-continued or successive stimulations. HA added to the superfusion medium inhibited the release evoked by stimulation at frequencies up to 10 Hz or with 30 mM K+ but not the release at higher frequencies or with 45 mM K+. The inhibition was mediated by H3 receptors, was concentration-dependent (pD2 = 7.4) and was complete at 10(-6) M. The H2 agonist impromidine antagonized the inhibition competitively (pA2 = 7.1). It is concluded that this assay in a superfusion system with electrical stimulation is suitable for the assessment of H3 receptor activity of drugs.     

Relaxations of the isolated portal vein of the rabbit induced by nicotine and electrical stimulation

1. A pharmacological analysis of the inhibitory innervation of the isolated portal vein of the rabbit has been made.2. In untreated preparations, transmural stimulation elicited a long-lasting relaxation at low frequencies (0.2-1 Hz); at higher frequencies a contraction followed by a prolonged after-relaxation occurred. Tetrodotoxin abolished the contractions but a higher dose was required to abolish the relaxations. Veratrine lowered the threshold of stimulation for producing relaxations in the untreated vein. The relaxations were unaffected by hyoscine or hexamethonium. They were reduced or altered by antagonists of alpha-adrenoceptors for catecholamines and by adrenergic neurone blockade. They were sometimes slightly reduced by antagonists of beta-adrenoceptors.3. In the presence of antagonists of alpha-adrenoceptors, electrical stimulation elicited relaxations which increased with frequency of stimulation and became maximal at 20-30 Hz. These relaxations were partially reduced by antagonists of beta-adrenoceptors, or by adrenergic neurone block; the antagonisms were more pronounced at the higher frequencies of stimulation. Noradrenaline also caused relaxations which were abolished by beta-adrenoceptor blocking drugs. Cocaine increased the sensitivity to noradrenaline by 7-8 fold after alpha-adrenoceptor blockade but had little or no effect on the relaxations induced by electrical stimulation at high frequencies.4. In the presence of antagonists of alpha- and beta-adrenoceptors, or adrenergic neurone blocking agents, or in veins taken from rabbits pretreated with reserpine, electrical stimulation elicited rapid relaxations which were greatest at 20-30 Hz. These relaxations were increased by veratrine and abolished by tetrodotoxin or by storing the vein for 9 days at 4 degrees C. They were unaffected by antagonists of acetylcholine, or by dipyridamole.5. Prostaglandins E(1), E(2) and F(2alpha) inhibited contractions elicited by electrical stimulation and noradrenaline, but in higher doses caused contractions themselves.6. Nicotine (10(-6)-10(-5) g/ml) relaxed the portal vein; higher concentrations elicited mixed inhibitory and excitatory effects. All these effects were abolished by tetrodotoxin, cocaine, hexamethonium or storage. The contractor effects were abolished by drugs or procedures that blocked adrenergic mechanisms.7. The relaxations produced by nicotine in untreated preparations and in veins from rabbits pretreated with reserpine were mediated mainly by a non-adrenergic non-cholinergic nervous mechanism. Relaxations induced by nicotine in the presence of antagonists of a-adrenoceptors were only partially antagonized by antagonists of f3-adrenoceptors.8. It was concluded that all the effects of nicotine and transmural stimulation were mediated by nerves. Part of the inhibitory effects was mediated by non-adrenergic, non-cholinergic nerves.     

Tolerance to the anticonvulsant effects of phenobarbital, trimethadione, and clonazepam in kindled rats: cross tolerance to carbamazepine.

The kindled-convulsion model was used to assess the development of tolerance and cross tolerance to the anticonvulsant effects of antiepileptic drugs. In Experiment 1, tolerance developed to the anticonvulsant effects of bidaily (one every 48 h) IP injections of phenobarbital, trimethadione, and clonazepam on convulsions elicited 1 h after each injection in kindled rats by amygdala stimulation. In Experiment 2, kindled rats that were tolerant to the anticonvulsant effects of phenobarbital, trimethadione, or clonazepam received bidaily IP injections of carbamazepine, each followed 1 h later by a convulsive amygdala stimulation. There was a statistically significant transfer of tolerance from phenobarbital to carbamazepine, but not from either trimethadione or clonazepam to carbamazepine. Apparently, tolerance to anticonvulsant drugs is most likely to transfer between drugs that are effective against similar kinds of clinical and experimental seizures and have similar putative mechanisms of action.     

Changes in excitability of amygdaloid and septal nuclei induced by medazepam hydrochloride

Electrical stimulations of the central and basolateral part of the amygdaloid complex and of the septum in freely moving cats elicit changes in arterial pressure (i.e., an increase in pressure during stimulation of the central part of the amygdala, and a decrease followed by an increase during stimulation of the basolateral part of the amygdala and of the septum). These changes within the cardiovascular system are followed by rage reactions when the central part of the amygdala is stimulated, defense patterns when the basolateral part of the amygdala is stimulated, and pitiful mewing as a result of septal stimulation.Medazepam hydrochloride in a dose of approximately 15 mg/kg i.v. given over a period of 3 h, in order to maintain constant blood levels of the drug, attenuated slightly the cardiovascular reactions and elevated markedly the thresholds for psychomotoric behavior. The latencies between the onset of electrical stimulation and the beginning of the increase in arterial pressure were only slightly increased, whereas the latencies for psychomotoric behavior were markedly prolonged due to drug application. The data support the view that medazepam hydrochloride exerts depressant effects on the limbic-hypothalamic level with respect to psychomotoric responses.The effect was not identical for all nuclei tested. The basolateral part of the amygdala was significantly less sensitive to medazepam hydrochloride than the central part of the amygdala.Data presented in part at the IXth Congress of C.I.N.P., Paris, July, 1974 (Stock, 1974).     

GABA mediation of the anti-aversive action of minor tranquilizers

Earlier observations have shown that systematically injected minor tranquilizers decrease the aversive consequences of electrical stimulation of the dorsal periaqueductal gray (DPAG) matter of the rat brain. In order to verify if these drugs can act directly on the DPAG, chlordiazepoxide (CDP) and pentobarbital (PB) were locally injected into the dorsal midbrain of rats chronically implanted with chemitrodes, allowing electrical stimulation of the same brain area. Microinjection of doses of 0.16 and 0.32 mumol of CDP and 0.16 mumol of PB significantly increased the threshold electrical current including flight behavior by stimulating the dorsal midbrain. Flight behavior was measured by the number of times rats crossed dividing line while running from one compartment of a shuttle-box to the other. The same effect was caused by the intracerebral injection of 0.32 and 0.64 mumol of the inhibitory neurotransmitter, gamma-aminobutyric acid (GABA). Conversely, local injection of the GABA antagonists. bicuculline (5-20) nmol) or picrotoxin (0.3 and 0.6 nmol), into the dorsal midbrain induced flight behavior, like the electrical stimulation. On the other hand, the glycine antagonist, strychnine (40 nmol) caused convulsive behavior only, while the intracerebral injection of the cholinergic agonist, carbachol (10-40 nmol), increased locomotion, sniffing and turning behavior, but did not induce flight. Pretreatment with locally injected GABA (0.64 mumol) antagonized the aversive effect of either bicuculline (10 nmol) or picrotoxin (0.3 nmol), whereas CDP (0.32 mumol) antagonised bicuculline only and PB (0.16 mumol) was ineffective against either bicuculline or picrotoxin. These results suggest that minor tranquilizers act directly upon the DPAG by enhancing the tonic inhibitory influence of endogenous GABA. This action may underly the antiaversive affects of these drugs.     

Nerve pathways involved in adrenergic regulation of electrical and mechanical activities in the chicken rectum.

Peripheral nerve pathways responsible for adrenergic inhibition of mechanical and electrical activities in the chicken rectum and receptors mediating the adrenergic inhibition were investigated in isolated extrinsically-innervated rectum of the chicken. Electrical stimulation of the anal end (Ra) or the ileal cut end (Ri) of Remak's nerve, or perivascular nerves (P) elicited relaxation of the rectum pretreated with atropine (0.5 microM) and hexamethonium (0.3 mM) to block the cholinergic and non-cholinergic, non-adrenergic excitatory innervations. Ri stimulation was much less effective than Ra and P stimulations. The relaxation was shown to be related to cessation of spontaneous spike discharge of the longitudinal muscle which was accompanied by membrane hyperpolarization. The inhibitory effects elicited by Ra and P stimulations, which were prolonged beyond the period of the stimulation, were converted to transient ones by propranolol (3.4 microM). Phentolamine (2.6 microM) reduced effectively the residual effects. In contrast, the effects of Ri stimulation were little affected by these drugs. The present results provide evidence for the existence of two nerve pathways responsible for direct adrenergic inhibitory innervation to the chicken rectum, one running orally in Remak's nerve trunk, leaving it and descending in the branches to the rectum, and the other running as the perivascular nerves along the arterial supplies of the rectum. The direct innervation is mediated predominantly by beta-adrenoceptors.     

The blockade of AMPA-kainate and NMDA receptors in the dorsal periaqueductal gray reduces the effects of diazepam withdrawal in rats

It is well established that the most persistent sign of withdrawal from chronic benzodiazepine use in humans is anxiety. In contrast to other types of drugs of abuse, the emergence of this anxiety does not seem to be linked directly to alterations in the levels of dopamine in the mesolimbic system. Some studies have proposed that fear-like behaviors elicited by benzodiazepine withdrawal could be the result either of alterations in the sensitivity of GABAA receptors or in the neuronal hyperexcitability that results from neuroadaptative responses to chronic treatment, probably mediated by glutamate. The increased fear-like behaviors induced by benzodiazepine withdrawal are similar to the defense reaction displayed by animals exposed to dangerous situations or submitted to electrical or chemical stimulation of the dorsal periaqueductal gray (dPAG), a key structure of the brain aversive system. However, the involvement of the dPAG in drug abuse has been investigated only in the context of the physical effects of drug dependence. Thus, in this study we investigated the effects of injections into the dPAG of the glutamic acid diethyl ester (GDEE) and 2-amino-7-phosphonoheptanoate (AP-7) (AMPA-kainate and NMDA receptors antagonists, respectively) on fear-like behaviors promoted by benzodiazepine withdrawal in rats submitted to aversive events (foot-shocks) immediately before chronic diazepam administration in a conditioning place-preference paradigm, using a light-dark box. Our results showed that inhibition of the glutamatergic neurotransmission in the dPAG reduces the consequence of the diazepam withdrawal in rats, implicating the excitatory amino acids of the dPAG in the modulation of the aversive state induced by benzodiazepine drugs withdrawal.     

Changes in the EEG-reactions to repetitive peripheral and central electrical stimulation by intraraphedorsal kainic acid in the cat

The effect of kainic acid (KA) microinjected into the dorsal raphe nucleus (NRD) of the cat through glass micropipette by means of an air pressure system in doses ranging from 2.3 to 23.5 nmol on the electroencephalographic (EEG)-reactions elicited by repetitive (6-10 Hz) peripheral (somatic and visual) or central electrical stimulation was investigated. A significant facilitation of the driving reaction evoked by rhythmic subcutaneous electrical stimulation of the forepaw was found after KA, while the driving reaction elicited by repetitive photostimulation did not change. The cortical rhythmic reactions to repetitive electrical stimulation of the specific and nonspecific nuclei of the thalamus and of the caudate nucleus (where inhibitory mechanisms are known to be involved) diminished or disappeared when generalized paroxysmal spontaneous activity occurred after kainic acid. The EEG-reaction to stimulation of the mesencephalic reticular formation was significantly facilitated after KA. The repetitive electrical stimulation of the ventral posterolateral nucleus, the centre median and the mesencephalic reticular formation also provoked the appearance of paroxysmal EEG activity or afterdischarge which in some cases developed into epileptic seizures. The data show that kainic acid injected into the dorsal raphe nucleus increases (probably by disinhibition) the excitability level of some forebrain structures connected with the nucleus.     

Chlordiazepoxide and morphine reduce pressor response to brain stimulation in awake rats

The effects of intravenous as well as dorsal midbrain injections of morphine and chlordiazepoxide on the blood pressure rise induced by electrical stimulation of the dorsal periaqueductal gray matter (DPAG) were studied in unanesthetized rats. Chlordiazepoxide applied systemically or locally into the DPAG, as well as locally applied but not systemically injected morphine were found to attenuate the centrally-induced hypertension. These data together with others suggest that benzodiazepines as well as local injections of morphine into the DPAG decrease the aversive effect induced by DPAG stimulation.     

Contingent tolerance to the anticonvulsant effects of carbamazepine, diazepam, and sodium valproate in kindled rats.

The effect of convulsive stimulation during periods of drug exposure on the development of tolerance to the anticonvulsant effects of carbamazepine (CBZ), diazepam (DZP), or sodium valproate (VPA) was studied in three similar experiments. In each experiment, amygdala-kindled rats were assigned to one of three groups: one group received a drug injection (CBZ, 70 mg/kg, IP; DZP, 2 mg/kg, IP; VPA, 250 mg/kg, gavage) 1 h before each of a series of 10 bidaily (one every 48 h) convulsive stimulations, a second group received the same dose of the drug 1 h after each of the 10 stimulations, and a third group served as a vehicle control. The drug tolerance test occurred in each experiment 48 h after the 10th tolerance-development trial; every rat received the appropriate dose of CBZ, DZP, or VPA 1 h before being stimulated. In each experiment, only the rats from the drug-before-stimulation group displayed a significant amount of tolerance to the drug's anticonvulsant effect. Thus the development of tolerance to the anticonvulsant effects of CBZ, DZP, and VPA was not an inevitable consequence of drug exposure; the development of tolerance was contingent upon the occurrence of convulsive stimulation during the periods of drug exposure. These results support the idea that functional drug tolerance is an adaptation to a drug's effects on ongoing patterns of neural activity, rather than to drug exposure per se.     

Electrophysiological studies with a 2,3-benzodiazepine muscle relaxant: GYKI 52466

The effects of GYKI 52466, a new 2,3-benzodiazepine with muscle relaxant and anticonvulsant properties, were investigated and compared to those of midazolam in electrophysiological experiments. The effects of the drugs on the reflex potentials evoked by afferent nerve stimulation and recorded from the spinal roots in unanesthetized spinal cats were studied. GYKI 52466 exerted a strong inhibitory effect on the monosynaptic as well as the polysynaptic ventral root reflexes, while the dorsal root responses decreased slightly. In contrast, midazolam markedly enhanced the dorsal root responses, did not modify the monosynaptic reflex and partially inhibited the polysynaptic reflex. The spontaneous firing of cerebellar Purkinje cells was depressed by midazolam, but not by GYKI 52466. These results suggest strongly that, contrary to the classical 1,4-benzodiazepines, potentiation of the GABA-A receptor-mediated inhibition does not play a significant role in the pharmacological actions of GYKI 52466.