William R. Martin

The effect of a benzodiazepine antagonist, R015-1788, in diazepam dependent rats

A benzodiazepine antagonist, RO15-1788, was administered intragastrically to diazepam-dependent gastric fistula rats and a precipitated abstinence syndrome was observed. The intensity of the RO15-1788 precipitated abstinence syndrome, calculated by the Precipitated Abstinence Scale, increased in intensity in a log-dose manner over a dose range of 1.0 to 15.0 mg/kg of RO15-1788 and plateaued at the 15.0 mg/kg dose. The RO15-1788 precipitated diazepam abstinence syndrome differed both qualitatively and quantitatively from the diazepam withdrawal syndrome.

Diazepam and pentobarbital dependence in the rat

Diazepam (100-133 mg/kg/day), administered chronically through a gastric fistula, and pentobarbital (ca 692 mg/kg/day), administered chronically in food, were studied for their dependence producing properties in Sprague-Dawley female rats. The diazepam abstinence syndrome was apparent 10 to 20 hours after withdrawal, persisted for over 60 hours and consisted of poker tail, explosive awakenings, digging in sawdust, jerks, tremors, wet dog shakes, hostility, decreased food and water consumption and weight loss. The pentobarbital abstinence syndrome came on rapidly peaking within 10 hours and was largely over by 16 hours. The pentobarbital abstinence syndrome differed from diazepams by the presence of grand mal, clonic and atypical convulsions. Diazepam completely and in a dose related way suppressed the diazepam abstinence syndrome. Similarly pentobarbital suppressed the pentobarbital abstinence syndrome. The signs which could be suppressed in a dose related manner were different for the diazepam and pentobarbital abstinence syndromes. Diazepam only partially suppressed the pentobarbital abstinence syndrome and pentobarbital only partially suppressed the diazepam abstinence syndrome. These data indicate that diazepam and pentobarbital produce different types of dependencies in the rat and are not equivalent in suppressing signs of abstinence.

Innervation of the spinal cord by sympathetic fibers

Abstract Pharmacologic and neurochemical studies suggest that catecholamines are still present below the level of transection in the spinal cord of the chronic spinal animal, despite the degeneration of bulbospinal catecholamine pathways. Histofluorescence studies of rat and dog spinal cord revealed noradrenergic fibers and varicosities remaining in the chronically decentralized spinal cord which can account for the low concentrations of norepinephrine (NE) found below the transection. The fibers appear to enter the spinal cord with blood vessels through the anterior median fissure, and are probably of sympathetic origin. In the spinal cord, these fibers can dissociate from blood vessels and continue through the neuropil; they are associated with neurons in the ventral horn and occasionally in the central gray. These peripheral sympathetic fibers may influence motor systems and other nervous functions.

Tobacco Smoking and Nicotine

Dose-related Nicotine Effects on CNS Binding and Behavior .•.••. 493 C. Ksir and R.L. Hakan [3H]Acetylcholine Binding to Nicotinic Cholinergic Receptors in Brain: Localization and Regulation Visualized by Autoradiography • • • . . . . . . .••• 494 R.D. Schwartz, B.B. Wolfe, T.C. Rainbow, and K.J. Kellar Acute Effects of Tobacco on Human Brain Stem Evoked Potentials •••••••••••••..•••.•. 495 V.J. Knott Effects of Nicotine on the Development of an Invertebrate Embryonic System • • • V. Martin, K. Kolberg, ~nd W. Archer Effect of Nicotine on the Turnover Rate of Catecholamine in the Rat Brain ••• T. Kubo, H. Amano, Y. Goshima, and Y. Misu Cigarette Smoking and Parkinsonism ••. J.A. Baron, P. Adams, and H. Quinton Stereospecific N-Methylation of Nicotine by Intact 495

Nature of nicotine binding to rat brain P2 fraction

(-)-Nicotine may bind to as many as 5 sites in the rat brain P2 preparation: A very high affinity site (KD approximately 2.2 X 10(-11) M); a positive cooperativity site; a high affinity site (KD approximately 5.2 X 10(-9) M); a low affinity site (KD approximately 4.5 X 10(-5) M) and a very low affinity site. The curvilinear nature of both Scatchard plots and kinetic curves indicates the presence of multiple binding sites. Evidence for a positive cooperativity site includes: (1) The configuration of Scatchard plots (at low concentrations) of saturation as well as inhibition curves for (-)- and (+)-nicotine. (2) The Hill number of 1.37 for the binding of low concentrations of (+/-)-[3H]nicotine. (3) Selectivity among cholinergic drugs for producing positive cooperativity. (4) Markedly different specificities of drugs for the positive cooperativity site. Thus while only (+)- and (-)-nicotine interacted with the very high affinity site, acetylcholine, atropine, mecamylamine, lobeline, carbachol, (+)-nicotine and (-)-nicotine enhanced the binding of (+/-)-[3H]nicotine and cytisine, anabasine, cotinine and choline selectively inhibited binding at the high affinity site. Several lines of evidence indicate that there is stereospecificity. (+)-Nicotine was more potent than (-)-nicotine in inducing positive cooperativity whereas (-)-nicotine was 80 times more potent than (+)-nicotine in inhibiting binding at the high affinity site. Further, the specificity of the binding sites can be altered by changing the concentration of the buffer which gives additional evidence for the lability of the nicotine binding site. Although the pharmacologic significance of the different binding sites has not been determined, these data taken together indicate that (+/-)-[3H]nicotine binds with specificity to multiple sites in the rat brain P2 preparation with a complexity not addressed heretofore.

Possible medullary κ hyperalgesic mechanism I. A new potential role for endogenous opioid peptides in pain perception

The kappa-agonist, ethylketazocine, produces hyperalgesia in the acutely decerebrated dog as indicated by a shortening of the skin twitch reflex latency whereas fentanyl is inactive. Naloxone produces analgesia and antagonizes the hyperalgesic effect of ethylketazocine. Spinal cord transection decreases the latency of the skin twitch reflex and allowed the analgesic effect of fentanyl and ethylketazocine on this nociceptive reflex to become manifest. These observations indicate that there is a non-opioid analgesic and kappa hyperalgesic mechanism present in the pontine-medullary region of the dog brainstem. It suggests that the hyperalgesic mechanism is mediated by an endogenous kappa-opioid peptide and that the analgesic effect of naloxone is in part related to antagonism of the activity of this hyperalgesia producing opioid peptide.

Interaction between nicotine and endogenous opioid mechanisms in the unanesthetized dog

Nicotine produced a distinct reproducible syndrome in the conscious dog when injected intravenously or intracerebroventricularly. Intravenously administered nicotine (40 micrograms/kg/min for 20 minutes) increased cardiac and respiratory rates and produced analgesia, miosis, hypothermia, behavioral restlessness and emesis. When microinjected into the third cerebral ventricle, nicotine (100-200 micrograms) similarly increased cardiac and respiratory rates and pupillary diameter; and produced behavioral restlessness, emesis, erratic analgesia and maintained wakefulness and a desynchronized EEG. Microinjection of nicotine (5-25 micrograms) into the periaqueductal gray failed to alter any of the parameters studied. Intravenous pretreatment with the opioid antagonist naltrexone (2 mg/kg) influenced the action of intravenous nicotine on certain physiological systems. While naltrexone alone produced a significant degree of tachycardia, miosis, and analgesia, it potentiated the tachypnea and antagonized the miotic response evoked by nicotine. Methionine-enkephalin was detected in perfusates obtained from the lateral cerebral ventricles of conscious dogs. Nicotine produced a non-significant decrease in enkephalin levels. These observations suggest that there are interactions between endogenous opioid and nicotinic processes. However, they are complex and may differ from one functional system to another.

Hyperalgesic and analgesic actions of morphine, U50-488, naltrexone, and (−)-lobeline in the rat brainstem

Morphine, U50-488, and (-)-lobeline produced dose-related shortening of a low-intensity thermally evoked tail avoidance response (LITETAR) (e.g., hyperalgesia) when microinjected into the dorsal posterior mesencephalic tegmentum (DPMT) of conscious rats. The hyperalgesic potency of (-)-lobeline was greater than either morphine or U50-488. With higher doses, morphines hyperalgesic actions diminished and prolongation of the LITETAR (e.g., analgesia) was observed. Naltrexone produced analgesia in the DPMT that diminished with increasing dose. The hyperalgesic actions of morphine, U50-488, and (-)-lobeline further suggest the presence of kappaergic opioid and nicotinic mechanisms in the DPMT of rats. The hyperalgesic actions of U50-488, a highly specific opioid kappa-receptor agonist, strongly suggest the presence of a kappa-opioidergic hyperalgesic mechanism in the DPMT.

Precipitated abstinence in the diazepam-dependent rat

Physical dependence was produced in the rat by exposure to continuous release of diazepam from silastic capsule implants (recrystallized diazepam) or by dosing through a gastric fistula. The precipitated abstinence syndrome induced by the IV infusion of flumazenil was characterized by clonic and tonic-clonic seizures, retropulsion, digging, rearing, head, limb and body tremors, twitches and jerks of the body, and ear twitches. This abstinence syndrome differed both qualitatively and quantitatively from the milder syndrome induced in previous experiments by the intragastric administration of flumazenil in the diazepam-dependent gastric fistula rat. Capsule-implanted rats had free plasma and extraneuronal brain levels of diazepam, oxazepam, and nordiazepam in the 10(-3) and 10(-4) mg/ml range, and their brain: plasma ratios were not significantly different from 1. The diazepam capsules had a sustained release of over 28 days. These studies show that the capsule implantation technique is an efficacious way of maintaining plasma levels of diazepam and its metabolites, and producing a high level of physical dependence in the rat.

Binding characteristics of (−)- and (+)-nicotine to the rat brain P2 fraction☆

Saturation studies employing (-)- and (+)-[3H]nicotine indicate that the isomers bind to different very high and high affinity sites since the binding density for (-)-[3H]nicotine is 10 times that for (+)-[3H]nicotine. Both isomers also bind to a low affinity site (KDS = approximately 10(-5) to 10(-4) M). Competition studies employing unlabelled (-)- and (+)-nicotine reveal greater complexities. The isomers also appear to bind to a separate site which enhances binding at the (-)- and (+)-nicotine high affinity sites. (+)-Nicotine is more effective in increasing the binding of (-)-[3H]nicotine at its high affinity site than (-)-nicotine. Further, (+)-nicotine has a greater specificity for enhancing binding than (-)-nicotine in that it enhances (-)-[3H]nicotine binding at lower concentrations and inhibits binding at higher concentrations than (-)-nicotine.