Effects of Neostigmine and Atropine on Motor Activity of Ileum,Colon, and Rectum of Anaesthetized Subjects

In unanaesthetized patients atropine and neostigmine in doses normally used by anaesthetists to reverse muscle relaxants produced a pronounced increase in bowel activity. This response occurred whether atropine was given before or simultaneously with neostigmine.The response still occurred in 38% of patients anaesthetized without halothane, and possibly this increase in motility might endanger a recently constructed anastomosis. The ileum appeared particularly prone to neostigmine stimulation, and anastomoses involving ileum would seem especially at risk. When halothane was used during anaesthesia the response was completely inhibited during the period studied.     

Delayed inhibition of gap-junctional intercellular communication in the acinar cells of rat submandibular glands induced by parasympathectomy and cholinergic agonists

In this study, the effects of parasympathectomy and cholinergic agonists on gap-junctional intercellular communication and salivary secretion were investigated to clarify the involvement of salivary secretion in delayed uncoupling between acinar cells of rat submandibular glands. Gap-junctional intercellular communication was monitored as dye-coupling in the acinar cells of isolated acini by the transfer of Lucifer Yellow CH. Parasympathectomy induced dye-uncoupling in the acinar cells isolated from denervated salivary glands 12 hr after parasympathectomy-induced salivary secretion. Intraperitoneal application of carbachol (CCh), acetylcholine, pilocarpine, but not isoproterenol, stimulated salivary secretion, and then induced dye-uncoupling in the acinar cells 12 hr later. Atropine suppressed both the salivary secretion and delayed dye-uncoupling induced by parasympathectomy and CCh, when atropine was applied intraperitoneally before the induction of salivary secretion. However, atropine did not suppress the delayed dye-uncoupling by intraperitoneal application of CCh, when atropine was injected after the cessation of CCh-induced secretion. These results suggest that delayed inhibition of gap-junctional intercellular communication by parasympathectomy and cholinergic agonists in rat submandibular glands might be related to the change of secretory function after salivary secretion.     

Mechanism of tachycardia caused by intracarotid PGE2 in conscious ewes

Conscious adult ewes prepared with nonocclusive indwelling vascular catheters were used to determine the mechanism by which heart rate increases during central administration of prostaglandin E2 (PGE2). Heart rate increased 14 bpm during steady-state intracarotid infusion of PGE2, 10 ng/kg/min (P less than 0.05). Intravenous atropine methyl bromide, 1 mg/kg, increased heart rate 26 bpm (P less than 0.05) 5 min after injection. Heart rate remained elevated 30 min after injection. The heart rate response to PGE2 plus atropine was greater than the heart rate response to either atropine or PGE2 alone (P less than 0.05). Propranolol, 1 mg/kg bolus plus intravenous infusion, 0.025 mg/kg/min, did not change resting heart rate. Propranolol attenuated but did not abolish the increase in heart rate caused by intracarotid PGE2. Although heart rate increased in response to PGE2 after administration of either propranolol or atropine alone, the combination of propranolol and atropine prevented any further increase in heart rate during subsequent PGE2 infusion. The increase in heart rate when all three drugs were given together was not different from the increase observed during atropine alone. Thus, both beta-adrenergic activation and muscarinic deactivation contribute to the PGE2-induced tachycardia.     

Differences in cardiac but not in neuroendocrine responses in healthy volunteers after administration of two antimuscarinic agents, atropine and pirenzepine

Neuroendocrine and cardiac responses were studied in healthy volunteers with the classical muscarinic antagonist, atropine and the new antimuscarinic agent, pirenzepine. The secretion of prolactin (PRL) and growth hormone (GH) was increased after metoclopramide. Typically, an antidopaminergic drug such as metoclopramide decreases rather than increases GH concentrations in serum. Pretreatment with both atropine and pirenzepine abolished the increase of GH secretion, which suggests an important role of cholinergic mechanisms in the regulation of GH secretion. The increase of PRL secretion was not inhibited by the two muscarinic antagonists. With the doses used, antimuscarinic activities in serum were comparable after atropine and pirenzepine treatments for the most part of the study. Heart rate was, however, significantly increased during atropine and higher than during saline or pirenzepine treatments throughout the study period. When compared to placebo, pirenzepine lowered heart rate slightly but significantly. The exact mechanism of this effect is unclear. We conclude that in contrast to the identical neuroendocrine effects, the cardiac responses clearly differ during atropine and pirenzepine treatments which confirms the ability of pirenzepine to distinguish muscarinic receptor sites in the central nervous system from those of the heart.     

Effect of substance P on mucus secretion of isolated submucosal gland from feline trachea

To elucidate how substance P (SP) produces submucosal gland secretion, we examined the effects of SP on the glandular contractile response and 3H-labeled glycoconjugate release in isolated submucosal glands from feline tracheae. SP (10(-12) to 10(-4) M) produced dose-dependent increases in the contractile response, and the maximal tension induced by SP was approximately 70% of the response to methacholine. SP-induced contraction is blocked completely by atropine and augmented by neostigmine. Pretreatment with hemicholinium 3, an acetylcholine synthesis inhibitor, inhibited the contractile response to SP. Pretreatment with tetrodotoxin did not inhibit the contractile response to SP. Capsaicin induced tension of a magnitude similar to that of SP. SP (10(-7) M) produced a significant increase (74% above control) in radiolabeled glycoconjugate release from isolated glands, whereas SP had no significant effects on glycoconjugate release from tracheal explants, probably because of epithelial suppression. Atropine abolished SP-evoked glycoconjugate release in isolated glands. Our findings indicate that 1) SP induces glandular contraction, which is related to the squeezing of mucus in the ducts and secretory tubules, 2) SP stimulates radiolabeled glycoconjugate release in isolated submucosal gland, probably involving mucus synthesis and/or cellular secretion, and 3) these two actions are mediated by a peripheral cholinergic mechanism.     

Difference in effects of pirenzepine and atropine on carbachol-induced pepsinogen secretion from isolated gastric glands

The effect of pirenzepine on carbamylcholine (carbachol)-stimulated pepsinogen secretion was compared with that of atropine in the isolated guinea pig gastric glands. Pirenzepine and atropine caused a dose dependent inhibition of carbachol-stimulated pepsinogen secretion. Moreover, pirenzepine as well as atropine produced a rightward shift in the dose response curve of carbachol-stimulated pepsinogen secretion but did not alter the maximum increase in pepsinogen secretion. Results therefore demonstrate that pirenzepine acts as a specific receptor antagonist in the interaction of carbachol with its receptor on gastric chief cells. However, pirenzepine was 50 times less potent than atropine in inhibiting pepsinogen secretion. Half maximal inhibitory concentration of pirenzepine was 2 X 10(-5) M when a maximally effective concentration of carbachol was used, while that of atropine was 4 X 10(-7) M. Results, therefore, suggest that muscarinic receptor on gastric chief cells to which pirenzepine binds may be an intermediate affinity type.     

The secretory activity of rat nasal glands and the effect of cholinergic drugs

Summary The secretory behaviour of rat nasal glands, under normal conditions and after the application of cholinergic drugs, has been studied using morphological and radiobiochemical techniques.Autoradiography and electrophoresis provide evidence for the selective incorporation of ³H-arginine into the glycoprotein containing fraction of the nasal glandular secretion. Radiobiochemical experiments show that labelled arginine is rapidly incorporated into the acinar cells of unstimulated glands, although it takes approximately 4 h before the labelled secretory proteins leave the cells. The secretion of proteins is stimulated by the parasympathetic agonist pilocarpine, whose main action is to promote discharge. Histological sections show a depletion of secretory granules after pilocarpine treatment. The cholinergic antagonist atropine inhibits the secretion; the acinar cells are completely filled with secretory granules following this treatment. The time course of the events following atropine administration suggests that there is no feed-back system controlling glycoprotein synthesis.The techniques employed here therefore appear to be useful for studying the effects of drugs that interfere with the secretory activity of the nasal glands.     

Chronic atropine administration diminishes the contribution of vasoactive intestinal polypeptide to heart rate regulation

Vasoactive intestinal polypeptide (VIP) is implicated in the modulation of vagal effects on the heart rate. In this study, the impact of acute and chronic atropine administration on VIP levels in rat heart atria was investigated in relation to heart rate in the course of vagus nerves stimulation. Anaesthetised control and atropinised (10 mg/kg/day for 10 days) rats pretreated with metipranolol and phentolamine that were either given or not a single dose of atropine were subjected to bilateral vagus nerve stimulation (30 min: 0.7 mA, 20 Hz, 0.2 ms). VIP concentrations in the atria were determined after each stimulation protocol. In control rats with or without single atropine administration, the heart rate upon vagal stimulation was higher than in atropinised animals with or without single atropine dose, respectively. VIP concentrations in the control atria were significantly decreased after the stimulation; the decrease was comparable both in the absence and presence of a single dose of atropine. Compared to controls, VIP levels were significantly decreased after chronic atropine treatment and they were not further reduced by vagal stimulation and single atropine administration. Administration of VIP antagonist completely abolished the differences in the heart rate upon vagal stimulation between control and atropinised groups. In conclusion, the data indicate that chronic atropine administration affects VIP synthesis in rat heart atria and consequently it modifies the heart rate regulation.     

Use of neostigmine to increase the rate of lung cancer detection by sputum cytology

Neostigmine induction was investigated as a method for increasing the rate of detection of lung cancer in respiratory cytology samples. Eleven patients with dry and essentially nonproductive cough were given neostigmine, 15 mg by mouth or 0.5 mg by hypodermic injection. The quality of sputum produced was increased in all cases; the sputum was also more easily expectorated. Eight patients suspected of having lung cancer had previously negative cytologic examinations of sputum obtained by conventional methods. Following the administration of neostigmine, malignant cells indicating squamous-cell carcinoma were found in the sputum samples of three of these patients while dysplastic cells were detected in the samples from two patients. It is postulated that neostigmine intake may increase the excretion of mucous glands in the bronchial submucosa as well as the bronchial epithelium itself.     

Bicarbonate stimulatory action of nizatidine, a histamine H(2)-receptor antagonist, in rat duodenums.

Nizatidine, a histamine H(2)-antagonist, is known to inhibit acetylcholinesterase (AChE) activity and is used clinically as a gastroprokinetic agent as well as the anti-ulcer agent. We examined whether or not nizatidine stimulates duodenal HCO(3)(-) secretion in rats through vagal-cholinergic mechanisms by inhibiting AChE activity. Under pentobarbital anesthesia, a proximal duodenal loop was perfused with saline, and the HCO(3)(-) secretion was measured at pH 7.0 using a pH-stat method and by adding 10 mM HCl. Nizatidine, neostigmine, carbachol, famotidine or ranitidine was administered i.v. as a single injection. Intravenous administration of nizatidine (3-30 mg/kg) dose-dependently increased the HCO(3)(-) secretion, and the effect at 10 mg/kg was equivalent to that obtained by carbachol at 0.01 mg/kg. The HCO(3)(-) stimulatory action of nizatidine was observed at the doses that inhibited the histamine-induced acid secretion and enhanced gastric motility. This effect was mimicked by neostigmine (0.03 mg/kg) and significantly attenuated by bilateral vagotomy and pretreatment with atropine but not indomethacin. The IC(50) of nizatidine for AChE of rat erythrocytes was 1.4 x 10(-6) M, about 12 times higher than that of neostigmine. Ranitidine showed the anti-AchE activity and increased duodenal HCO(3)(-) secretion, similar to nizatidine, whereas famotidine had any influence on neither AChE activity nor the HCO(3)(-) secretion. On the other hand, duodenal damage induced by acid perfusion (100 mM HCl for 4 h) in the presence of indomethacin was significantly prevented by nizatidine and neostigmine, at the doses that increased the HCO(3)(-) secretion. These results suggest that nizatidine increases HCO(3)(-) secretion in the rat duodenum, mediated by vagal-cholinergic mechanism, the action being associated with the anti-AChE activity of this agent.     

Influence of ventrolateral surface of medulla on tracheal gland secretion.

Airway secretion can be modified reflexly as well as locally. Previous studies indicate that neurons in a circumscribed region near the ventral surface of the medulla (VMS) can substantially modify airway tone and reflex responses to vagal inputs. In the present studies we assessed the importance of these neurons on tracheal gland secretion. We examined the changes in the number of hillocks of secretion appearing from submucosal glands in an exposed field of tracheal epithelium (1.2 cm2) coated with tantalum dust before and after interventions on the VMS. Experiments were performed in alpha-chloralose-anesthetized dogs paralyzed and ventilated with 40% O2. Stimulation of nicotinergic receptors by application of a pledget containing nicotine in 11 dogs caused a significant elevation in tracheal gland secretion in the subsequent 60 s, compared with a control period in which buffered saline was applied. Prior application of lidocaine or hexamethonium bromide to the VMS blocked the effect of topically applied nicotine. The central effects of nicotine were diminished by atropine methylnitrate given intravenously. In addition, lidocaine application to the VMS or focal cooling of intermediate areas to between 20 and 15 degrees C significantly decreased secretion rates reflexly produced by capsaicin-induced stimulation of pulmonary C-fiber receptors and by mechanical stimulation of the carina and larynx. These findings suggest that the ventral medulla contains cells near its surface that influence tracheal fluid secretion and modulate reflex responses of airway submucosal glands, probably by altering the level of general excitation within the central respiratory integrating circuits.     

Effects of common inhibitors of gastric acid secretion on secretagogue-induced respiration and aminopyrine accumulation in isolated gastric glands.

1. The effects of three inhibitors of gastric acid secretion, atropine, burimamide and thiocyanate, have been studied in isolated glands from the rabbit gastric mucosa. The glands were either resting or stimulated by carbachol, histamine or dibutyryl cyclic AMP. The effects were determined from changes in oxygen consumption and accumulation of the weak base aminopyrine. The latter gives an indirect measurement of the acid production in the glands. 2. Atropine (10 (-6) M) almost totally inhibited the transient response induced by carbachol (10 (-4) M) in both measured parameters. The histamine-induced increase in respiration was inhibited when the atropine concentration was raised to 10 (-4) M. To a lesser extent also, histamine-induced aminopyrine accumulation was reduced. The dibutyryl cyclic AMP stimulated oxygen consumption was not affected by atropine. 3. Burimamide competitively inhibited the histamine responses but was without effect on those of carbachol and dibutyryl cyclic AMP. 4. Thiocyanate (10 (-2) M) inhibited the increase in oxygen consumption induced by all three secretagogues but not down the prestimulatory level, in spite of total abolishment of the aminopyrine accumulation. 5. In unstimulated glands, burimamide (10 (-3) M) or atropine (10 (-4) M) did not alter the normal aminopyrine ratio (aminopyrine in intraglandular water/ aminopyrine in extraglandular water) of approximately 50. This may indicate the existence of preformed acid in resting parietal cells. Thiocyanate, on the other hand, lowered the aminopyrine ratio in unstimulated glands from 46 to 2. Possible mechanisms for the thiocyanate effect are discussed in terms of an inability to separate acid and base in the secreting membrane.     

Unexpected beta adrenergic effects of the antitumor agent, cyclocytidine, on rat salivary glands.

In addition to its potent antileukemic properties, cyclocytidine has a sialogogue action that depends on stimulation of beta adrenergic ereceptors of salivary glands. Furthermore, when chronically administered (for 3 days), cyclocytidine caused enlargement of parotid and submaxillary glands and heart that resembled the hypertrophy caused by chronic isoproterenol administration. The salivas evoked by cyclocytidine also closely resembled those evoked by isoproterenol, and were extremely viscous, and high in K+, (121 plus or minus 5.6, for submaxillary, and 42 plus or minus 2.9, for parotid), low in flow rate (0.007 mg/min times mg) and parotid saliva contained high concentrations of amylase (805 plus or minus 33 mg/mg gland). Cyclocytidine also caused marked emptying of parotid gland amylase. The cyclocytidine-induced salivary flow and gland emptying of amylase were prevented for 90 min when propranolol (but not dibenzyline or atropine) was administered prior to injection of the cyclocytidine. In addition, when the superior cervical ganglion was acutely removed, administration of cyclocytidine elicited salivary flow from the denervated as well as the innervated glands. These findings suggest that cyclocytidine does not affect salivary glands through indirect central or ganglionic actions. Cyclocytidine action does not exclusively involve beta receptors, since even in the presence of propranolol, secretory flow was evident after 90 min but when dibenzyline was given with the propranolol, complete blockade of cyclocytidine-stimulated saliva was effected. The dominant effect is, however, a beta adrenergic one. The undesirable side effects of cyclocytidine (parotid pain, postural hypotension, and cardiac hypertrophy) probably stem chiefly from its beta adrenergic properties and might be eliminated (or at least modified) by administration of propranolol with the cyclocytidine.     

Stimulation of muscarinic cholinoceptive neurons in the hippocampus evokes a pressor response with bradycardia.

The injection of neostigmine into the hippocampus of anesthetized rats increased the mean arterial blood pressure (17% of baseline after 60 min injection) and decreased the heart rate (24% of baseline after 60 min injection). These changes were blocked by the co-administration of methylatropine into the hippocampus. Intrahippocampal injection of neostigmine stimulated the secretion of epinephrine and norepinephrine. Adrenodemedullation did not suppress the increase in blood pressure and the decrease in heart rate. It is concluded that the stimulation of muscarinic cholinoceptive neurons in the hippocampus evokes a hypertensive response via an increase in sympathetic drive to the heart and peripheral vasculature, with bradycardia possibly mediated via the parasympathetic system.     

Salivary secretion induced by substance P

Secretion of fluid, ions, and amylase from parotid and submaxillary glands of rat, induced by intravenous injection of substance P (SP), was examined. The action of SP on salivary glands, like physalaemin, resembled that of cholinergic stimulation. While SP-evoked salivary flow from both glands was blocked by atropine, atropine did not modify composition of SP-evoked saliva. The present study suggests that salivary secretion and secretion of ions and amylase evoked by SP are mediated via SP-sensitive cholinergic receptors and specific SP receptors, respectively.     

Effect of atropine on plasma gastrin and somatostatin concentrations during sham feeding in man

The purpose of these studies was to measure circulating gastrin and somatostatin concentrations during sham feeding in humans and to evaluate the effect of two doses of intravenous atropine on circulating concentrations of these peptides. Gastric acid and bicarbonate secretion and pulse rate were also measured. Sham feeding increased plasma gastrin concentrations by approximately 15 pg/ml but had no effect on plasma somatostatin-like immunoreactivity (SLI). A small dose of atropine (5 micrograms/kg) augmented plasma gastrin concentrations during sham feeding significantly (P less than 0.01), but did not affect plasma SLI. Atropine also significantly inhibited gastric acid secretion and gastric bicarbonate secretion (by 62% and 52%, respectively), but pulse rate was not affected. A larger dose of atropine (15 micrograms/kg intravenously) suppressed plasma gastrin concentrations significantly compared to the smaller 5 micrograms/kg atropine dose (P less than 0.02), so that plasma gastrin concentrations when 15 micrograms/kg atropine was given were not significantly different from those during the control study. 15 micrograms/kg atropine reduced gastric acid and bicarbonate secretion by 81% and 66%, respectively, and also increased pulse rate by 15 min-1. These studies indicate that small doses of atropine enhance vagally mediated gastrin release in humans, probably by blocking a cholinergic inhibitory pathway for gastrin release. Although the nature of this cholinergic inhibitory mechanism is unclear, we found no evidence to incriminate somatostatin. Our finding that the larger dose of atropine reduced serum gastrin concentrations compared with the smaller dose suggests that certain vagal-cholinergic pathways may facilitate gastrin release.     

The chronotropic action of neurotensin in the guinea pig isolated heart

Neurotensin (NT) infusions into isolated, perfused, spontaneously beating hearts of guinea pigs evoked a concentration-dependent, positive chronotropic effect which was preceded in some hearts by transient bradycardia. The tachycardia caused by NT was not affected by propranolol, cimetidine, indomethacin, a mixture of methysergide and morphine or by atria removal. The incidence and amplitude of bradycardia caused by NT were increased by neostigmine but reduced by atropine. Neostigmine and atropine also tended to decrease and increase respectively, the tachycardia caused by NT. These results suggest that the positive chronotropic effect of NT in guinea pig isolated heart results from a direct effect on the specialized conduction system of the heart while its negative chronotropic effect is likely to reflect the activation by NT of cardiac vagal cholinergic neurons.     

兴奋或抑制汗液分泌对小鼠汗腺水通道蛋白5免疫定位的影响

目的 探讨兴奋或抑制汗液分泌过程中水通道蛋白-5（AQP5）在汗腺组织的分布及表达变化。方法应用硅橡胶印模及免疫荧光技术测定小鼠在毛果芸香碱或阿托品处理后不同时间点的泌汗功能状态及AQP5在汗腺组织的分布和表达。结果静息状态下,汗腺分泌细胞及导管细胞中的AQP5几乎只分布于管腔侧胞膜;在毛果芸香碱刺激后小鼠汗液分泌的高峰期（15min）、衰退期（1h）及刺激后静息期（6h）,AQP5在汗腺组织的亚细胞分布及表达量均未有明显变化;阿托品处理后10或20min,小鼠汗腺的分泌反应完全被抑制,但AQP5在汗腺组织的表达分布未受明显影响。结论在光镜水平,兴奋或抑制汗液分泌并不改变AQP5在活体小鼠汗腺的分布及表达。     

AF-DX 116 discriminates heart from gland M2-cholinoceptors in man

The M2-cholinoceptor subtype selective antagonist AF-DX 116 was compared with atropine with respect to effects on heart rate and salivary flow in healthy volunteers. These effects were related with in vitro occupancy of M-cholinoceptor subtypes in radioreceptor assays of plasma samples. Radioreceptor assays comprised M1-cholinoceptors in bovine cerebral cortex and M2-cholinoceptors in pig heart and rat salivary gland membranes. 3H-pirenzepine served as a label in the cerebral cortex 3H-N-methyl-scopolamine in the heart and gland preparations. Oral administration of 240 mg AF-DX 116 led to a time dependent increase in heart rate with a maximum effect comparable to atropine 40 micrograms/kg i.v. The effects of both drugs on heart rate were matched by a greater than 80% occupancy of heart M2-cholinoceptors in the radioreceptor assay of plasma samples. In contrast to the complete inhibition of salivary flow after atropine, AF-DX 116 induced an increase of salivation. The effects on salivary flow coincided with a greater than 80% occupancy of glandular M2-cholinoceptors after atropine but no detectable occupancy after AF-DX 116. Occupancy of the M1-subtype amounted to 61.7% after AF-DX 116 and a blockade of inhibitory, presynaptic M1-autoreceptors at missing postsynaptic blockade of glandular M2-cholinoceptors might explain the hypersalivation induced by AF-DX 116.     

头端延髓腹外侧区在侧脑室注射新斯的明所致升压中的作用

实验在47只乌拉坦(700m/kg)、氯醛糖(35mg/kg)麻醉,肌肉麻痹,人工呼吸的家兔上进行。结果观察到,侧脑室注射(icv)新斯的明引起血压升高,心率(HR)先减慢后有加快趋势,股动脉血流量(FBF)与股动脉血管通道性(COND)减小,左心室内压(LVP)增大,肾交感神经放电(RND)增加,延髓腹外侧头端(rVLM)微量注射阿托品则引起血压下降,HR减慢,FBF与COND增加,LVP与RND减小,若在icv新斯的明之前,预先向rVLM注入阿托品,可阻断新斯的明的升压效应,上述结果提示,rVLM是icv新斯的明升压效应的重要部位,rVLM区M受体功能完整是这种升压作用的关键因素。