Influence of striatal dopamine receptor blockade on a bulbar motor reaction

Neuropharmacologic correlates of deglutition: lessons from fictive swallowing

Pharmacologic investigations into the transmission processes underlying fictive swallowing in the rat have disclosed the potential diversity of chemical signals used in central deglutitive pathways. Monoaminergic mechanisms appear to serve as links between subcortical structures and the medullary pattern generator of swallowing (PGS), and may play a critical role in maintaining internal facilitatory drive, required by the PGS for optimal responsivity to peripheral sensory input. Cholinergic bulbar interneurons form an integral component of the PGS subnetwork controlling esophageal peristalsis. Local GABA neurons exert a tonic inhibition of the buccopharyngeal stage, may regulate buccopharyngeal-esophageal coupling, and may contribute to peristaltic rhythmic generation at both the premotoneuronal and motoneuronal level. Receptor subtypes for excitatory amino acids (glutamate, aspartate) are differentially associated with deglutitive premotoneurons for both the buccopharyngeal and esophageal stage, as well as with ambiguus motoneurons. Preliminary evidence suggests the existence of excitatory peptidergic mechanisms involving thyrotropin-releasing hormone, vasopressin, oxytocin, and somatostatin, a probable candidate for excitatory transmitter in the solitarioambigual internuncial projection to motoneurons innervating esophageal striated musculature. Further validation of this experimental model may ultimately help to establish a framework for the clinical recognition, management, and exploitation of drug actions on central deglutitive neuroeffectors.

Excitatory amino acid receptor-mediated activation of solitarial deglutitive loci

The deglutitive actions of glutamate were investigated in urethane-anaesthetised rats in order to determine whether different excitatory amino acid receptors mediate activation of pattern generator elements contained within the nucleus tractus solitarii. When applied by micropneumophoresis (0.01-10 pmol) from multibarrelled glass micropipettes (tip diameter 2-5 microns), the excitatory amino acid-receptor agonists, N-methyl-D, L-aspartate (NMA), N-methyl-D-aspartate (NMDA), quisqualate and kainate displayed a rank order of potency at glutamate-responsive pharyngeal sites, in the subnuclei ventralis and intermedialis, where KA greater than NMA/NMDA greater than QA; however, the potency followed the order NMA/NMDA greater than KA greater than QA at oesophageal sites within the subnucleus centralis. The NMDA-receptor blockers, 2-amino-5-phosphonovaleric acid (APV) and 2-amino-7-phosphonoheptanoic acid (AP7), selectively and reversibly inhibited the glutamate-evoked oesophageal responses, but had no corresponding effect on rhythmic oesophageal responses elicited by muscarine. At loci in the nucleus tractus solitarius, where glutamate elicited a complete swallowing sequence, APV/AP7 spared the pharyngeal component but selectively blocked the oesophageal component. The nonselective glutamate-receptor antagonist, gamma-D-glutamylglycine suppressed both pharyngeal and oesophageal responses elicited by glutamate. It is concluded that different types of excitatory amino acid receptors are associated with the deglutitive premotor subnuclei of the nucleus tractus solitarii; kainate receptors predominate within the subnuclei ventralis and intermedialis and NMDA receptors within the subnucleus centralis. Both kainate- and NMDA-mediated mechanisms can operate under physiological conditions.

Excitatory action of 5-HT on deglutitive substrates in the rat solitary complex

The excitatory effect of serotonin (5-HT) on the pharyngeal stage of swallowing was investigated in urethane anaesthetised rats with respect to the involvement of neural substrates located in the central and intermediolateral regions of the nucleus tractus solitarii (NTS). Micropneumophoretic ejection of 5-HT 5-50 pmol either produced deglutitory responses or selectively facilitated the S-glutamate-evoked pharyngeal responses when applied in 1-10 pmol prepulses. The excitatory/facilitatory effect of 5-HT was enhanced by intravenous threshold doses of the 5-HT-mimetic, quipazine (0.3-1 mumol/kg) and reversibly blocked by the 5-HT2-receptor antagonists, methysergide, metergoline and ketanserin. 5-HT doses exceeding 10-60 pmol gave rise to a non-selective reversible inhibition of glutamate- and acetylcholine (ACh)-evoked pharyngeal or oesophageal responses which was not prevented or reversed by 5-HT2-receptor antagonists, but was readily overcome by increasing the amount of glutamate or ACh ejected. Non-selective deglutitive inhibition after high doses of 5-HT could, therefore, result from neuronal desensitization secondary to excessive stimulation or activation of a different type of 5-HT receptor. These results corroborate an excitatory role of 5-HT in both reflex and automatic swallowing and demonstrate that the NTS is a major site of serotoninergic facilitation of swallowing.

Actions and interactions of benzodiazepine agonists, antagonists and inverse agonists on suprahyoid muscle twitching

Amphetamine-induced twitching of the suprahyoid muscle in nialamide-pretreated, urethane-anaesthetised rats was inhibited by the benzodiazepine agonists RU 32007, diazepam and chlordiazepoxide and the GABAA agonist muscimol. Ro15-1788 and CGS 8216 induced slight, or no reduction in twitching, respectively, but reversed the effect of RU 32007 and diazepam. Ro15-1788 did not reverse the effect of muscimol. Picrotoxin reversed both muscimol and RU 32007 effects at a dose which induced only a small increase in twitching alone. Higher doses of picrotoxin markedly increased amphetamine twitching and induced twitching in the absence of amphetamine. Ethyl-beta-carboline-3-carboxylate (BCE) weakly increased twitching and reversed the effect of RU 32007. CL 218872 weakly reduced twitching but also weakly antagonised RU 32007. In rats pretreated with a higher dose of nialamide methyl beta-carboline-3-carboxylate (BCM) and BCE induced twitching. BCE-induced twitching was antagonised by RU 32007, Ro15-1788, CGS 8216, muscimol and weakly by CL 218872. Thus, benzodiazepine agonists inhibit twitching and inverse agonists induce twitching, both being blocked by antagonists. Partial agonism (CL 218872) or partial inverse agonism (CGS 8216) may be detected by differential effects against different inducers of twitching.

Cerebral dopamine, apomorphine and oral activity in the neonatal pig

Neonatal piglets in which oral stimulation associated with feeding was reduced by intragastric tube feeding displayed an increase in stereotyped snout rubbing, licking and chewing behaviour. An investigation of a possible neurochemical basis for this behaviour was made by using sensitive radioenzymatic and microfluorimetric assays to estimate the concentrations of the catecholamines and of the dopamine metabolites homovanillic acid (HVA) and 3,4-dihydroxyphenyl-acetic acid (DOPAC) in different brain regions. These observations revealed that the increased non-nutritive oral activity of such piglets did not appear to be caused by an increased release of dopamine in the brain, since it was not associated with increases in the concentrations of the acidic metabolites of dopamine in either the caudate nucleus, the putamen, the nucleus accumbens, the olfactory tubercle, the hypothalamus, or the substantia nigra. The only neurochemical changes observed were small decreases in the concentration of HVA in the putamen and the nucleus accumbens. A lack of effect on catecholamine concentrations in any of the six brain regions examined suggested that the environmental manipulation caused no changes in the development of catecholamine-containing nerve endings. Subcutaneous injection of apomorphine was found to increase the non-nutritive oral activity of piglets. Apparent conditioning effects of the environment on apomorphine-induced stereotyped behaviour however, prevented any satisfactory testing of possible changes in cerebral dopamine receptor sensitivity following reduced oral stimulation.

Enkephalin-induced myoclonic twitches blocked by ergometrine and potentiated by haloperidol

Myoclonic twitches (MT) in the submandibular muscles induced by intraventricular administration of D-ala2-met-enkephalinamide (DALA) were studied electromyographically in the rat. Measurement of MT activity was selected since it permits parallel study of the effect of enkephalin on both dopaminergic and serotonergic transmitter systems. The twitches induced by enkephalin were blocked by naloxone, gamma-hydroxybutyrate, and ergometrine, but potentiated by haloperidol. Methysergide did not alter the stimulatory effect of DALA. These results were interpreted as a possibility for a specific enkephalin-induced activation of the so-called inhibition-mediating dopaminergic system, which is sensitive to the blocking action of ergometrine, but resistant to the blocking action of haloperidol.

Basal forebrain facilitation of reflex swallowing in the cat

In adult cats anaesthetized with urethane, electrical and chemical stimulation of the basal forebrain facilitated reflex swallowing elicited by electrical stimulation of the superior laryngeal nerve. A systematic stereotaxic mapping study using electrical stimulation revealed that the facilitatory sites were distributed along the course of the ansa peduncularis, specifically its rostral forebrain and hypothalamic components associated with the anterior amygdalar area, substantia innominata, lateral preoptic area, anterior hypothalamus and nucleus accumbens. By means of acute discrete radiofrequency lesions, the descending pathways mediating facilitatory influences from the nucleus accumbens and the amygdala to the brain stem were found to traverse the lateral hypothalamus. Ventral tegmental facilitatory sites in the midbrain are likely to be associated with these descending pathways; however, there is evidence for independent participation of this region of the brain in the control of swallowing. Chemical stimulation by means of microinjections of dopamine and apomorphine into the amygdala and nucleus accumbens also enhanced reflex swallowing. It is concluded that the results of this investigation implicate the basal forebrain as a site of integration of viscero-olfacto-gustatory information needed for the enactment of ingestive behaviour.

The emetic action of L-dopa and its effect on the swallowing reflex in the cat

In adults cats anesthetized with urethane it was shown that facilitation of reflexly-induced swallowing by dopaminomimetics is caused by a central action independent of the emetic of such drugs. It is suggested that this modulatory influence is mediated by dopamine receptors associated with the amygdala and ventral basal striatum.

Pharmacological evidence for a selective antidopaminergic action of gamma-hydroxybutyric acid

D-Amphetamine (Amph) and p-chloroamphetamine (PCA) induced dose-dependent increases in oropharyngeal myocloniform twitch activity (MTA) in rats anesthetized with urethane. In doses of 80-120 mg/kg, gamma-hydroxybutyric acid (GHB) blocked Amph-induced MTA. The blockade was readily surmountable. Pretreatment with reserpine markedly enhanced the myoclonigenic effect of Amph and rendered it insensitive blockade by GHB, 160 mg/kg. PCA and tryptamine also effectively stimulated MTA, but unlike Amph were antagonized by low doses of the serotonin (5-HT) antagonist methysergide. In doses which blocked Amph, GHB failed to antagonize the myoclonigenic effect of PCA. It is concluded that: (a) the actions of Amph and PCA on MTA is less sensitive to GHB blockade than DA-mediated MTA; and (c) the GHB-Amph antagonism may be of a functional nature, i.e. result from a depression of the firing activity of DA neurons produced by GHB. Since reserpinization abolished the GHB effect on Amph-induced MTA, the functional integrity of granular DA binding and releasing mechanisms appears to be a pre-requisite for the antagonism between GHB and Amph.