Gene/Protein Disease Symptom Drug Enzyme Compound
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Query: UMLS:C0020672 (hypothermia)
 17,327 document(s) hit in 31,850,051 MEDLINE articles (0.00 seconds)

Thyrotropin-releasing hormone (TRH), administered intraperitoneally, was found to antagonize ethanol-induced sleep and hypothermia in mice without affecting brain ethanol content. This reduction of the actions of ethanol was also apparent after oral or intracisternal administration of TRH. In addition, TRH reduced ethanol-induced sleep in rats, hamsters, gerbils and guinea pigs. Evidence that the pituitary-thyroid axis is not necessary for the effects of TRH was provided by observations that hypophysectomy did not reduce TRH antagonism of ethanol narcosis and findings that neither triiodothyronine nor thyrotropin mimicked its action. Certain analogs of TRH, which have little effect on the pituitary, were also found to antagonize ethanol-induced sleep and hypothermia. Pretreatment with the antiadrenergic drugs, alpha-methyltyrosine, phentolamine and propranolol did not antagonize the ability of TRH to reduce sleep induced by ethanol. However, after intracisternal administration of atropine methyl nitrate, TRH no longer caused a significant reduction of sleep, even though TRH antagonism of the ethanol-induced hypothermia was still apparent. In contrast, central administration of other anticholinergic drugs, such as delta-tobocurarine and hexamethonium, reduced ethanol-induced sleep and this effect was additive with TRH. Carbachol also reduced ethanol sleeping time and this effect was also blocked by atropine methyl nitrate. The antagonism of ethanol-induced sleep by dibutyryl cyclic adenosine 3', 5'-monophosphate was significantly reduced but not blocked by atropine methyl nitrate. Results provide evidence that TRH has a direct extrapituitary action on brain and that both TRH and ethanol may interact with central cholinergic systems.
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PMID:Investigations into the mechanism of reduction of ethanol sleep by thyrotropin-releasing hormone (TRH). 17 53

Hypothermia has previously been demonstrated to induce supersensitivity (defined as a decrease in the ED50) of guinea pig left atria to the negative inotropic effect of carbachol. In the present investigation, the dissociation constant (pKA or -log KA) for carbachol, determined using benzilylcholine mustard, was found to be significantly increased at 25 degrees C compared to 37 degrees C. However, the increase in pD2 (-log ED50) for carbachol at 25 degrees C was much less than would be predicted from the increase in pKA. Increasing the extracellular Ca2+ concentration or the frequency of stimulation, both of which, like hypothermia, are believed to increase Ca2+ influx into cardiac cells, resulted in a decrease in sensitivity to carbachol. Carbachol had no significant effect on cAMP or cGMP levels at either 37 degrees C or at 25 degrees C. These results suggest that the hypothermia-induced increase in sensitivity of left atria to carbachol can be explained by an increase in the affinity of the muscarinic receptor for this agonist. However, the expression of this increased affinity appears to be limited. This may be due to a concurrent decrease in the efficacy of the carbachol muscarinic receptor complex.
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PMID:The mechanism of hypothermia-induced supersensitivity of guinea pig left atria to carbachol. 285 62

The effects of thyrotropin-releasing hormone (TRH) on brain temperature in response to pentobarbital were examined in male rats. After intraperitoneal injection of pentobarbital sodium (55 mg/kg body wt), the rats were fixed stereotaxically and received intraventricular (ivt) injection of varying doses (0.03-30 nmol) of TRH and 17 nmol atropine. Following the injection of 3 nmol TRH, 100 nmol of carbocholine was administered in the same manner. A thermocouple microprobe was unilaterally placed in the midbrain reticular formation so that brain temperature was continuously monitored at room temperature. Brain temperature after pentobarbital injection progressively decreased. While ivt injection of saline did not affect this change in temperature, ivt administration of TRH produced a dose-dependent antagonism of the brain hypothermia induced by pentobarbital. Atropine injection also reversed the pentobarbital-induced decrease in brain temperature. Carbocholine injection led to a significant decrease in brain temperature in response to TRH administration. The present study indicates that brain TRH may play a pivotal role in brain thermoregulation and its mechanism may involve at least in part the central cholinergic pathway in the rat.
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PMID:Antagonism by thyrotropin-releasing hormone of brain temperature in response to pentobarbital in the rat: possible involvement of cholinergic mechanism. 309 3

1. An investigation of central cholinoceptors in the mouse has been made by injecting cholinomimetic drugs into the cerebral ventricles and seeing how their effects were modified by prior administration of atropine-like substances and other drugs.2. Carbachol or oxotremorine injected in small doses intracerebroventricularly into conscious mice caused hypothermia, gross tremor and a variety of parasympathomimetic effects including lachrymation and salivation. Acetylcholine injected in this way was active only in much larger doses.3. Methacholine and pilocarpine also caused a variety of parasympathomimetic effects after intracerebroventricular injection but virtually no hypothermia or tremor.4. Nicotine injected intracerebroventricularly caused mild hypothermia, fine tremor but no parasympathomimetic effects.5. Atropine-like drugs, tricyclic antidepressants and amphetamine antagonized the hypothermia induced by intracerebroventricular carbachol or oxotremorine.6. The sites of action of the atropine-like drugs are in the brain; those of the tricyclic antidepressants and amphetamine are in the periphery probably on heat generating beta-adrenoceptor mechanisms.7. It is concluded that the atropine sensitive cholinoceptors in the brain vary in their sensitivities to cholinomimetic drugs, other than acetylcholine, and may exist in isoreceptor forms.8. Peripheral atropine sensitive cholinoceptors may also exist in isoreceptor forms.
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PMID:Investigation of central cholinergic mechanisms in the conscious mouse. 558 Jun 97

Tachyphylaxis develops to the hypertensive response to central (i.c.v.) injection of carbachol in conscious rats. This pressor response exhibits tachyphylaxis if the injection is repeated within 8 hr of the first injection. Blockade of brain prostaglandin synthesis with indomethacin does not inhibit the pressor response to carbachol in naive rats, but eliminates the pressor response to carbachol when the muscarinic agonist is repeated within a few hours of the first injection. If the time interval is extended to permit return of the full response (i.e., 24 hr later), indomethacin no longer inhibits the pressor response. The related cyclooygenase inhibitor meclofenamate produced effects which were identical to those of indomethacin, but at approximately 10-fold higher doses. When shorter acting drugs (duration of action < 30 min), physostigmine or arecoline, were used according to the same paradigm, indomethacin was less effective at inhibiting the pressor response to the second injection, even when the two agonist injections were spaced only 30 min apart. The ability of indomethacin to enhance central muscarinic receptor tachyphylaxis was also observed in carbachol-induced hypothermia. The density of diencephalic muscarinic receptors was estimated by using N-[3H]methylscopolamine as a probe. Carbachol-induced a down-regulation of muscarinic receptors, and indomethacin increased the extent of this down regulation. These findings suggest that prostaglandins play a role in the development of tachyphylaxis to brain muscarinic receptor stimulation: activation of prostaglandin synthesis may decelerate the development of desensitization to muscarinic agonists.
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PMID:Role of prostanoids in the regulation of central cholinergic receptor sensitivity. 833 66