Muscarinic Receptor Occupancy Research Articles

Brain distribution and muscarinic receptor occupancy of an active metabolite of fesoterodine in rats

Brain distribution and muscarinic receptor occupancy of an active metabolite of fesoterodine in rats

Predicting muscarinic receptor occupancy in human bladder mucosa from urinary concentrations of antimuscarinic agents for overactive bladder

To assess the pharmacologically relevant and selective muscarinic receptor occupancy in the bladder mucosa, we considered not only plasma drug concentrations but also urinary drug concentrations. The purpose of this study was to predict muscarinic receptor occupancy in the human bladder mucosa based on urinary concentrations in response to clinical dosages of antimuscarinic agents used to treat overactive bladder. The calculated mean plasma or serum unbound steady state concentrations were 0.06–11 nM in clinical dosages of five antimuscarinic agents. Urinary concentrations calculated from the mean plasma or serum and renal clearance ranged between 19 nM and 2 μM, which were >10-fold higher than the Ki values for bladder muscarinic receptors excluding propiverine. Bladder mucosal muscarinic receptor occupancy estimated from the urinary concentrations and the Ki values was >90 % at a steady state in clinical dosages of five antimuscarinic agents. The bladder muscarinic receptor occupancy was higher than that in the parotid gland calculated based on the mean plasma or serum unbound concentrations and Ki values for muscarinic receptors in the parotid gland. These results suggest that sufficient and selective muscarinic receptor occupancy by antimuscarinic agents, to exert pharmacological effects, in the bladder mucosa can be predicted using urinary concentrations.

Treating Lower Urinary Tract Symptoms in Older Adults: Intravesical Options.

This article provides an overview of the diagnosis and the treatment of lower urinary tract symptoms in older adults complicated by the neurodegenerative changes in the micturition reflex and further confounded by age-related decline in hepatic and renal clearance raising the propensity of adverse drug reactions. The first-line drug treatment for lower urinary tract symptoms, orally administered antimuscarinics, fails to reach the equilibrium dissociation constant of muscarinic receptors even at their maximum plasma concentration and tends to evoke a half-maximal response at a muscarinic receptor occupancy of just 0.206% in the bladder with a minimal difference from exocrine glands, which raises the adverse drug reaction risk. On the contrary, intravesical antimuscarinics are instilled at concentrations 1000-fold higher than the oral maximum plasma concentration and the equilibrium dissociation constant erects a downhill concentration gradient that drives passive diffusion and achieves a mucosal concentration around ten-fold lower than the instilled concentration for a long-lasting occupation of muscarinic receptors in mucosa and sensory nerves. A high local concentration of antimuscarinics in the bladder triggers alternative mechanisms of action and is supposed to engage retrograde transport to nerve cell bodies for neuroplastic changes that underlie a long-lasting therapeutic effect, while an intrinsically lower systemic uptake of the intravesical route lowers the muscarinic receptor occupancy of exocrine glands to lower the adverse drug reaction relative to the oral route. Thus, the traditional pharmacokinetics and pharmacodynamics of oral treatment are upended by intravesical antimuscarinics to generate a dramatic improvement (~ 76%) noted in a meta-analysis of studies enrolling children with neurogenic lower urinary tract symptoms on the primary endpoint of maximum cystometric bladder capacity as well as the secondary endpoints of filling compliance and uninhibited detrusor contractions. The therapeutic success of intravesical multidose oxybutynin solution or oxybutynin entrapped in the polymer for sustained release in the pediatric populationbodes well for patients with lower urinary tract symptoms at the other extreme of the age spectrum. Though generally used to predict oral drug absorption, Lipinski's rule of five can also explain the ten-fold lower systemic uptake from the bladder of positively charged trospium over oxybutynin, a tertiary amine. Chemodenervation by an intradetrusor injection of onabotulinumtoxinA is merited for patients with idiopathic overactive bladder discontinuing oral treatment because of a lack of efficacy. However, age-related peripheral neurodegeneration potentiates the adverse drug reaction risk of urinary retention that motivates the quest of liquid instillation, delivering larger fraction of onabotulinumtoxinA to the mucosa as opposed to muscle by an intradetrusor injection can also probe the neurogenic and myogenic predominance of idiopathic overactive bladder. Overall, the treatment paradigm of lower urinary tract symptoms in older adults should be tailored to individual's overall health status and the risk tolerance for adverse drug reactions.

Possible Involvement of Muscarinic Receptor Blockade in Mirabegron Therapy for Patients with Overactive Bladder.

The selective β 3-adrenoceptor agonist mirabegron, an established alternative to antimuscarinic therapy for patients with overactive bladder, induces additional effects against receptors, transporters, and hepatic enzymes. The present study aimed to elucidate the effects of mirabegron on muscarinic receptors in the rat bladder using radioligand binding and functional assays. Mirabegron (0.1-100 μM) inhibited specific [N-methyl-3H]scopolamine methyl chloride binding in the bladder and other tissues of rats in a concentration-dependent manner. Binding affinity in the bladder was similar to that in the heart and significantly higher than those in the submaxillary gland and brain. Mirabegron induced the concentration-dependent relaxation of carbachol-induced contractions in the rat isolated bladder. Further analyses using a two-site model revealed that the relative quantities of high- and low-affinity components for mirabegron were 44.5% and 55.5%, respectively. Respective pEC50 values were 7.06 and 4.97. Based on the receptor binding affinity and pharmacokinetics of mirabegron, muscarinic receptor occupancy in the human bladder for 24 hours after the administration of a single oral dose of 50 mg mirabegron was 37%-76%. The present results demonstrate for the first time that mirabegron may relax the detrusor smooth muscle not only by β 3-adrenoceptor activation but also muscarinic receptor blockade. SIGNIFICANCE STATEMENT: Mirabegron, the first selective β 3-adrenoceptor agonist, represents an alternative to antimuscarinic agents for management of overactive bladder (OAB). The present study aimed to clarify whether mirabegron directly binds to muscarinic receptors and affects cholinergic agonist-induced contractions in rat urinary bladder and to predict muscarinic receptor occupancy in human bladder after oral administration of mirabegron. The results demonstrated that mirabegron therapy for patients with OAB may be due not only to β 3-adrenoceptor activation but also muscarinic receptor blockade.

Pulmonary PET imaging confirms preferential lung target occupancy of an inhaled bronchodilator

BackgroundPositron emission tomography (PET) is a non-invasive molecular imaging technique that traces the distribution of radiolabeled molecules in experimental animals and human subjects. We hypothesized that PET could be used to visualize the binding of the bronchodilator drug ipratropium to muscarinic receptors (MR) in the lungs of living non-human primates (NHP). The objectives of this study were two-fold: (i) to develop a methodology for quantitative imaging of muscarinic receptors in NHP lung and (ii) to estimate and compare ipratropium-induced MR occupancy following drug administration via intravenous injection and inhalation, respectively.MethodsA series of PET measurements (n = 18) was performed after intravenous injection of the selective muscarinic radioligand 11C-VC-002 in NHP (n = 5). The lungs and pituitary gland (both rich in MR) were kept in the field of view. Each PET measurement was followed by a PET measurement preceded by treatment with ipratropium (intravenous or inhaled).ResultsRadioligand binding was quantified using the Logan graphical analysis method providing the total volume of distribution (VT). Ipratropium reduced the VT in the lung and pituitary in a dose-dependent fashion. At similar plasma ipratropium concentrations, administration by inhalation produced larger reductions in VT for the lungs. The plasma-derived apparent affinity for ipratropium binding in the lung was one order of magnitude higher after inhalation (Kiih = 1.01 nM) than after intravenous infusion (Kiiv = 10.84 nM).ConclusionQuantitative muscarinic receptor occupancy imaging by PET articulates and quantifies the therapeutic advantage of the inhaled route of delivery and provides a tool for future developments of improved inhaled drugs.

An original pharmacoepidemiological-pharmacodynamic method: application to antipsychotic-induced movement disorders.

Pharmacovigilance databases are usually used to detect new potential signals that are relevant for drug safety. They are seldom used for explanatory purposes, e.g. to understand the mechanisms of adverse drug reactions (ADRs). The aim of the present study was to combine pharmacovigilance and pharmacodynamic data to investigate the association between dopamine D2, serotonin 5HT2A, and muscarinic M1 receptor occupancy and the risks of antipsychotic drug (AP)-induced movement disorders. First, we performed a case-noncase analysis using spontaneous reports from the World Health Organization (WHO) Global Individual Case Safety Report (ICSR) database, VigiBase®. We thus measured the risk of reporting movement disorders compared with all other ADRs [expressed as a reporting odds ratio (ROR)] for APs. Second, we performed a linear regression analysis to explore the association between the estimated risk of reporting for individual drugs and their receptor occupancy properties, for D2, 5HT2A and M1 receptors. Compared with second-generation APs, first-generation APs were found to be significantly more associated with the reporting of movement disorders in general but also with dystonia, Parkinsonism, akathisia and tardive dyskinesia, irrespective of gender. A significant inverse correlation was found between the ROR for movement disorders and the receptor occupancy of 5HT2A [P < 0.001; R2 =0.51; slope=-0.014; 95% confidence interval (CI) (-0.029, 0.001)], M1 (P < 0.001; R2 =0.56; slope=-0.014; 95% CI (-0.028, 0.001) but not D2 dopamine (P = 0.54; R2 =0.02; slope=-0.003; 95% CI (-0.007, 0.001) receptors. Using the example of AP-induced movement disorders, the present study underlines the value of the pharmacoepidemiological-pharmacodynamic method to explore ADR mechanisms in humans and real-life settings.

The antagonist SPECT tracer 123I-iododexetimide binds preferentially to the muscarinic M1 receptor in-vivo, but is it also a potential tool to assess the occupancy of muscarinic M1 receptors by agonists?

Cognitive deterioration in neuropsychiatric disorders is associated with high attrition rates giving an urgent need to develop better pharmaceutical therapies. The underlying mechanisms of cognitive impairments are unclear but research has shown that the muscarinic receptor subtype 1 (M 1 receptor ) plays a critical role. Blocking the M 1 receptor gives rise to profound cognitive deficits, while the administration of M 1 agonist drugs improves cognitive functioning. In this research highlight we will outline supporting data that the radiotracer 123 I-iododexetimide preferentially binds to the M 1 receptor in-vivo and can be used to assess changes in M 1 receptor expression in-vivo associated with cognitive decline. These findings come from a previously published paper extensively examining binding characteristics of 123/127 I-iododexetimide to muscarinic receptors. Results of biodistribution studies also has shown that acute administration of the M 1 / 4 receptor agonist xanomeline could inhibit 127 I-iododexetimide binding in M 1 -rich brain areas in rats, suggesting that 123 I-iododexetimide may also be used to evaluate the occupancy of M 1 receptors by M 1 agonists in-vivo. This may be of clinical relevance considering the efficacy of M 1 agonist drugs in the treatment of cognitive deficits. Here we show the results from new biodistribution experiments in rats conducted to test the hypothesis that 123 I-iododexetimide may be a useful radiotracer to evaluate the M 1 receptor occupancy by M 1 agonists in-vivo. Contrary to our expectations, no significant change in 123 I-iododexetimide ex-vivo binding was observed after acute administration of xanomeline in M 1 receptor-rich brain areas, whereas significantly decreased 123 I-iododexetimide binding was found after chronic treatment with xanomeline. 123 I-iododexetimide single photon emission computed tomography (SPECT) may therefore be a useful imaging tool to further evaluate M 1 receptor changes in neuropsychiatric disorders, as a potential stratifying biomarker, to assess the occupancy of M 1 receptors after M 1 antagonist treatment, or after chronic treatment with M 1 agonists, although it may be less suited to evaluate the M 1 receptor occupancy after acute treatment with M 1 agonists. Future studies should concentrate efforts towards finding also an M 1 agonist radiotracer for positron emission tomography (PET) or SPECT to assess the working mechanism of M 1 agonists.

Comparing the cardiovascular therapeutic indices of glycopyrronium and tiotropium in an integrated rat pharmacokinetic, pharmacodynamic and safety model

Long acting inhaled muscarinic receptor antagonists, such as tiotropium, are widely used as bronchodilator therapy for chronic obstructive pulmonary disease (COPD). Although this class of compounds is generally considered to be safe and well tolerated in COPD patients the cardiovascular safety of tiotropium has recently been questioned. We describe a rat in vivo model that allows the concurrent assessment of muscarinic antagonist potency, bronchodilator efficacy and a potential for side effects, and we use this model to compare tiotropium with NVA237 (glycopyrronium bromide), a recently approved inhaled muscarinic antagonist for COPD. Anaesthetized Brown Norway rats were dosed intratracheally at 1 or 6h prior to receiving increasing doses of intravenous methacholine. Changes in airway resistance and cardiovascular function were recorded and therapeutic indices were calculated against the ED50 values for the inhibition of methacholine-induced bronchoconstriction. At both time points studied, greater therapeutic indices for hypotension and bradycardia were observed with glycopyrronium (19.5 and 28.5 fold at 1h; >200 fold at 6h) than with tiotropium (1.5 and 4.2 fold at 1h; 4.6 and 5.5 fold at 6h). Pharmacokinetic, protein plasma binding and rat muscarinic receptor binding properties for both compounds were determined and used to generate an integrated model of systemic M2 muscarinic receptor occupancy, which predicted significantly higher M2 receptor blockade at ED50 doses with tiotropium than with glycopyrronium. In our preclinical model there was an improved safety profile for glycopyrronium when compared with tiotropium.

Characterization of Bladder Selectivity of Antimuscarinic Agents on the Basis ofIn VivoDrug-Receptor Binding

The in vivo muscarinic receptor binding of antimuscarinic agents (oxybutynin, solifenacin, tolterodine, and imidafenacin) used to treat urinary dysfunction in patients with overactive bladder is reviewed. Transdermal administration of oxybutynin in rats leads to significant binding of muscarinic receptors in the bladder without long-term binding in the submaxillary gland and the abolishment of salivation evoked by oral oxybutynin. Oral solifenacin shows significant and long-lasting binding to muscarinic receptors in mouse tissues expressing the M3 subtype. Oral tolterodine binds more selectively to muscarinic receptors in the bladder than in the submaxillary gland in mice. The muscarinic receptor binding of oral imidafenacin in rats is more selective and longer-lasting in the bladder than in other tissues such as the submaxillary gland, heart, colon, lung, and brain, suggesting preferential muscarinic receptor binding in the bladder. In vivo quantitative autoradiography with (+)N-[11C]methyl-3-piperidyl benzilate in rats shows significant occupancy of brain muscarinic receptors with the intravenous injection of oxybutynin, solifenacin, and tolterodine. The estimated in vivo selectivity in brain is significantly greater for solifenacin and tolterodine than for oxybutynin. Imidafenacin occupies few brain muscarinic receptors. Similar findings for oral oxybutynin were observed with positron emission tomography in conscious rhesus monkeys with a significant disturbance of short-term memory. The newer generation of antimuscarinic agents may be advantageous in terms of bladder selectivity after systemic administration.

Effect of oxybutynin and imidafenacin on central muscarinic receptor occupancy and cognitive function: A monkey PET study with [11C](+)3-MPB

Although antimuscarinic agents are widely used to treat overactive bladder (OAB), they have been shown to induce side effects including dry mouth and cognitive impairment. The present study was aimed to investigate the effects of antimuscarinic agents, oxybutynin and imidafenacin, on temporal changes in cognitive function and central mAChR occupancy in conscious monkeys (Macaca mulatta). Three conscious monkeys underwent positron emission tomography (PET) scans with a mAChR radioligand N-[(11)C]methyl-3-piperidyl benzilate ([(11)C](+)3-MPB). The scan sequence was pre, and 1, 4, and 24h post oral administration of oxybutynin (0.1-1.0mg/kg) or imidafenacin (0.01-0.1mg/kg). Maximum cognitive impairment was observed 1h post-oxybutynin at oral doses of 0.3 and 1.0mg/kg, in a dose-dependent manner, and oxybutynin produced significant positive correlations between mAChR occupancy and cognitive impairment in the cortices, thalamus, brainstem, and striatum. The most significant correlation was observed in the brainstem, and then cortices. In contrast, imidafenacin did not induce discernible cognitive impairment, despite having obtained some lesser occupancy in cortices and brainstem. We propose that the thresholds of mAChR occupancy to produce cognitive impairment by antimuscarinic agents are ca. 30-40% in cortices and ca. 20-30% in brainstem, and a desirable drug for OAB treatment should not occupy central mAChR above these thresholds.

Muscarinic Receptor Occupancy and Cognitive Impairment: A PET Study with [11C](+)3-MPB and Scopolamine in Conscious Monkeys

The muscarinic cholinergic receptor (mAChR) antagonist scopolamine was used to induce transient cognitive impairment in monkeys trained in a delayed matching to sample task. The temporal relationship between the occupancy level of central mAChRs and cognitive impairment was determined. Three conscious monkeys (Macaca mulatta) were subjected to positron emission tomography (PET) scans with the mAChR radioligand N-[(11)C]methyl-3-piperidyl benzilate ([(11)C](+)3-MPB). The scan sequence was pre-, 2, 6, 24, and 48 h post-intramuscular administration of scopolamine in doses of 0.01 and 0.03 mg/kg. Occupancy levels of mAChR were maximal 2 h post-scopolamine in cortical regions innervated primarily by the basal forebrain, thalamus, and brainstem, showing that mAChR occupancy levels were 43-59 and 65-89% in doses of 0.01 and 0.03 mg/kg, respectively. In addition, dose-dependent impairment of working memory performance was measured 2 h after scopolamine. A positive correlation between the mAChR occupancy and cognitive impairment 2 and 6 h post-scopolamine was the greatest in the brainstem (P<0.00001). Although cognitive impairment was not observed 24 h post-scopolamine, sustained mAChR occupancy (11-24%) was found with both doses in the basal forebrain and thalamus, but not in the brainstem. These results indicate that a significant degree of mAChRs occupancy is needed to produce cognitive impairment by scopolamine. Furthermore, the importance of the brainstem cholinergic system in working memory in monkey is described.

Noninvasive evaluation of brain muscarinic receptor occupancy of oxybutynin, darifenacin and imidafenacin in rats by positron emission tomography

Aims The current study was conducted to evaluate, by the noninvasive positron emission tomography (PET), the binding of antimuscarinic agents used to treat overactive bladder (OAB) to muscarinic receptors in rat brain. Main methods Muscarinic receptor occupancy in the rat brain after the intravenous (i.v.) injection of oxybutynin, darifenacin and imidafenacin was evaluated by using a small animal PET system, and compared with the results by ex vivo autoradiographic and ex vivo radioligand binding experiments. Key findings In PET study, the i.v. injection of oxybutynin but not darifenacin or imidafenacin at pharmacological doses decreased significantly binding potential (BP) of (+) N-[ 11C]methyl-3-piperidyl benzilate ([ 11C](+)3-MPB) in the rat cerebral cortex and corpus striatum in a dose-dependent manner. Similarly, in the in vivo autoradiographic experiment, oxybutynin dose-dependently reduced binding of [ 11C](+)3-MPB in the brain, whereas darifenacin and imidafenacin did not. Following the i.v. injection of oxybutynin, darifenacin and imidafenacin, there was a similar degree of binding to muscarinic receptors in the bladder as demonstrated by a significant increase in apparent dissociation constant ( K d ) values for specific [N-methyl- 3H]scopolamine methyl chloride ([ 3H]NMS) binding. Significant binding of muscarinic receptors in the brain was observed after the injection of oxybutynin but not darifenacin or imidafenacin. Significance Oxybutynin but not darifenacin or imidafenacin has potential side effects on the central nervous system (CNS) in patients with OAB. The results reveal the noninvasive characterization of brain receptor occupancy by PET to be a powerful tool for precise evaluation of adverse CNS effects of antimuscarinic agents in pre-clinical and clinical evaluations.

TheN-Oxide Metabolite Contributes to Bladder Selectivity Resulting from Oral Propiverine: Muscarinic Receptor Binding and Pharmacokinetics

We characterized contribution of N-oxide metabolites [1-methyl-4-piperidyl diphenylpropoxyacetate N-oxide (M-1) and 1-methyl-4-piperidyl benzilate N-oxide (M-2)] to the binding of muscarinic receptors in relation to the pharmacokinetics of propiverine in rats. The in vitro muscarinic receptor binding activity of M-2 was equipotent to that of propiverine, whereas M-1 was much less active. After the oral administration of propiverine (24.8-248 micromol/kg), there was relatively selective and longer-lasting binding of muscarinic receptors in the rat bladder compared with the submaxillary gland as shown by a significant increase in the apparent dissociation constant (K(d)) for specific binding of [N-methyl-(3)H]scopolamine ([(3)H]NMS). In addition, the intravesical instillation of M-2 produced a significant increase in K(d) for specific [(3)H]NMS binding in the rat bladder. Extremely high concentrations of M-1 and M-2 were detected in plasma after the oral administration of propiverine. The concentration of unbound M-2 was much higher than that of M-1 and propiverine in the rat plasma. The sum of maximal plasma unbound propiverine equivalents (C(max)) after the oral administration of propiverine at doses of 24.8, 74.3, and 248 micromol/kg was 66.0, 303, and 509 nM, respectively. The sum of corresponding area under the time-concentration curve from 0 to 12 h was 194, 2123, and 4645 nM . h, respectively. In fact, the unbound concentration of M-2 comprised more than 90% of sum of unbound propiverine equivalents in the plasma. After oral treatment with propiverine, the bladder showed the highest concentration of M-2, indicating specific distribution of this metabolite into the target organ. Thus, M-2 may contribute greatly to the relatively selective and long-lasting occupation of bladder muscarinic receptors after oral administration of propiverine.

The Forefront for Novel Therapeutic Agents Based on the Pathophysiology of Lower Urinary Tract Dysfunction: Bladder Selectivity Based on In Vivo Drug–Receptor Binding Characteristics of Antimuscarinic Agents for Treatment of Overactive Bladder

We have reviewed the binding of antimuscarinic agents, used to treat urinary dysfunction in patients with overactive bladder, to muscarinic receptors in target and non-target tissues in vivo. Transdermal administration of oxybutynin in rats led to significant binding in the bladder without long-term binding in the submaxillary gland and the abolishment of salivation evoked by oral oxybutynin. Oral solifenacin showed significant and long-lasting binding to muscarinic receptors in mouse tissues expressing the M3 subtype. Oral tolterodine bound more selectively to muscarinic receptors in the bladder than in the submaxillary gland in mice. The muscarinic receptor binding activity of oral darifenacin in mice was shown to be pronounced and long-lasting in the bladder, submaxillary gland, and lung. In vivo quantitative autoradiography using (+)N-[11C] methyl-3-piperidyl benzilate in rats showed significant occupancy of brain muscarinic receptors on intravenous injection of oxybutynin, propiverine, solifenacin, and tolterodine. The estimated in vivo bladder selectivity compared to brain was significantly greater for solifenacin and tolterodine than oxybutynin. Darifenacin occupied few brain muscarinic receptors. Similar findings were also observed with positron emission tomography in conscious rhesus monkeys. The newer generation of antimuscarinic agents may be advantageous in the bladder selectivity after systemic administration.

In Vivo Quantitative Autoradiographic Analysis of Brain Muscarinic Receptor Occupancy by Antimuscarinic Agents for Overactive Bladder Treatment

We evaluated the effects of five clinically used antimuscarinic agents for overactive bladder (OAB) treatment on in vivo muscarinic receptor binding in rat brain by quantitative autoradiography. There was a dose-related decrease in in vivo specific +N-[11C]methyl-3-piperidyl benzilate ([11C](+)3-MPB) binding in each brain region of rats 10 min after i.v. injection of oxybutynin, propiverine, solifenacin, and tolterodine. Rank order of the i.v. dose for 50% receptor occupancy (RO(50)) of antimuscarinic agents in rat brain regions was propiverine > solifenacin > tolterodine, oxybutynin. There was a good linear relationship between in vivo (pRO(50) values in the rat hippocampus) and in vitro (pK(i) values in human M(1) receptors) receptor binding activities of propiverine, solifenacin, and tolterodine. The observed RO(50) value of oxybutynin was approximately five times smaller than the predicted in vitro K(i) value. The dose ratios of antimuscarinic agents for the brain receptor occupancy (RO(50)) to the inhibition of carbachol- and volume-induced increases in intravesical pressure (ID(50)), which reflects in vivo selectivity for the urinary bladder over the brain, were greater for solifenacin, tolterodine, and propiverine than oxybutynin. Darifenacin displayed only a slight decrease in specific [11C](+)3-MPB binding in the rat brain regions, and it was not dose-related. In conclusion, in vivo quantitative autoradiographic analysis of brain muscarinic receptor occupancy may provide fundamental basis for managing central nervous system (CNS) side effects in antimuscarinic therapy for OAB. It is suggested that in the treatment of OAB, CNS side effects can be avoided by antimuscarinic agents with high selectivity for the urinary bladder over the brain.

Concentration dependent contractile effect of methylene blue in human internal mammary artery.

Objective: Methylene blue (MB), an inhibitor of soluble guanylate cyclase, may a lifesaving drug which improves hemodynamic parameters in vasoplegic syndrome. We investigated the relation between MB concentration and vascular responses to clarify the rationale of its use in vasoplegic syndrome.Methods. The study was performed in organ bath in human isolated internal mammary artery (IMA). The responses were recorded isometrically by a force‐displacement transducer.Results: MB (10 nM‐100 μM) produced concentration‐dependent contraction in the arteries. The maximal contraction to MB was 44.2% ± 3.8 of 45 mM KCl maximum contraction. pEC50 value was 5.5 ± 0.1. MB caused an insignificant leftward shift of the concentration‐response curve of norepinephrine. Acetylcholine‐induced relaxation in submaximal contracted rings with phenylephrine was recovered nearly six hours later than MB challenge.Conclusions: We showed that MB caused concentration‐dependent contraction in human IMA. MB inhibited ACh‐induced relaxation during six hours considering muscarinic receptor occupation. The contractile effect of MB is predominantly related to its own effect which proves a rationale for its use in cathecolamine refractory vasoplegic syndrome.

In vivo characterization of muscarinic receptors in peripheral tissues: evaluation of bladder selectivity of anticholinergic agents to treat overactive bladder

The present study was undertaken to characterize in vivo muscarinic receptors in peripheral tissues (urinary bladder, submaxillary gland, colon, stomach, heart) of mice, and further to evaluate bladder-selectivity of anticholinergic agents to treat overactive bladder. Following i.v. injection of [3H]QNB in mice, the radioactivity in peripheral tissues was exclusively detected as the unchanged form. The in vivo specific [3H]QNB binding in particulate fraction of tissue homogenates of mice showed a pharmacological specificity which characterized muscarinic receptors. Binding parameters (Kd and Bmax) for in vivo specific [3H]QNB binding differed between mouse tissues. Oral administration of oxybutynin attenuated significantly in vivo specific [3H]QNB binding in all tissues of mice. From ratios of AUCurinary bladder/AUCother tissues of time-dependent muscarinic receptor occupancy, oral oxybutynin has been shown to exert little urinary bladder selectivity. Following oral administration of propiverine, there was a significant reduction of in vivo specific [3H]QNB binding in the urinary bladder, colon and submaxillary gland, but not in the stomach and heart. From the ratios of AUCurinary bladder to AUCsubmaxillary gland or AUCheart, it has been shown that oral propiverine exerts higher selectivity to muscarinic receptors in the urinary bladder than in the submaxillary gland and heart. Similarly, tolterodine displayed high selectivity to muscarinic receptors in the urinary bladder than in the submaxillary gland. Thus, the present study has demonstrated that [3H]QNB may be a useful ligand for in vivo characterization of muscarinic receptor binding of anticholinergic agents to treat overactive bladder. Propiverine and tolterodine have exhibited in vivo selectivity of muscarinic receptor in the mouse urinary bladder rather than in the submaxillary gland, and such receptor binding specificity may be the reason of lower incidence of dry mouth.

Analysis of Pharmacological Effects of Drugs Used for Treatment of Urinary Disturbance Based on Anticholinergic and Smooth Muscle-Relaxing Effects

Propiverine hydrochloride, oxybutynin hydrochloride and terodiline hydrochloride have both anticholinergic and antispasmodic effects, and are used for the management of urinary frequency and incontinence. The average standard therapeutic doses of these drugs differ greatly. We retrospectively analyzed their pharmacological effects with consideration given to muscarinic acetylcholine receptor binding affinities, anticholinergic activities, and inhibitory effects on KCl-induced contraction. Muscarinic acetylcholine receptor occupancies and the inhibitory ratios of the drugs for both acetylcholine-induced and KCl-induced contraction in a steady state after oral administration of standard doses were calculated based on pharmacokinetics and the receptor occupancy theory. The average muscarinic acetylcholine receptor occupancy and inhibitory ratio of acetylcholine-induced contraction were estimated to be 12.6+/-1.06% and 3.27+/-0.74%, respectively, with no significant differences found between the drugs for those parameters. A significant linear relationship was found between muscarinic acetylcholine receptor occupancy and the maximum ratio of increase in bladder urinary capacity. On the other hand, the inhibitory ratios of KCl-induced contraction varied from 0.01 to 0.48%. The present results suggest that muscarinic acetylcholine receptor occupancy is a principal determinant of the therapeutic effect of a drug used for treatment of urinary disturbance.

Fluorescent styryl dyes FM1‐43 and FM2‐10 are muscarinic receptor antagonists: intravital visualization of receptor occupancy

The fluorescent styryl dyes FM1-43 and FM2-10 have been used to visualize the endocytic and exocytic processes involved in neurotransmission in a variety of central and peripheral nerve preparations. Their utility is limited to some extent by a poorly understood vesicular-independent labelling of cells and tissues. We show here that one likely cause of this troublesome background labelling is that FM1-43 and FM2-10 are selective and competitive antagonists at both cloned and endogenously expressed muscarinic acetylcholine receptors. In radioligand binding studies, FM1-43 and FM2-10 bound with moderate affinity (23-220 nM) to membranes of Chinese hamster ovary (CHO) cells expressing cloned human muscarinic receptors (M1-M5). In functional studies in vitro, FM1-43 and FM2-10 inhibited electrical field stimulation (EFS) and acetylcholine-induced cholinergic contractions of guinea-pig tracheal strips (IC50: FM1-43, 0.4 +/- 0.1; FM2-10, 1.6 +/- 0.1 microM; concentration of antagonist producing a 2-fold leftward shift in the acetylcholine concentration-response curve (Kb): FM1-43, 0.3 +/- 0.1; FM2-10, 15.8 +/- 10.1 microM). Neither compound inhibited EFS-evoked, non-adrenergic non-cholinergic nerve-mediated relaxations or contractions of the airways, or contractions mediated by histamine H1 receptor or tachykinin NK2 receptor activation. Incubating freshly excised tracheal whole-mount preparations with 5 microM FM1-43 resulted in intense fluorescence labelling of the smooth muscle that was reduced by up to 90% in the presence of selective M2 and M3 receptor antagonists. The potency of the FM dyes as muscarinic receptor antagonists is within the concentration range used to study vesicular cycling at nerve terminals. Given that muscarinic receptors play a key role in the regulation of neurotransmitter release from a variety of neurones, the anticholinergic properties of FM dyes may have important implications when studying vesicular events in the nervous system. In addition, these dyes may provide a novel tool for visualizing muscarinic receptor occupancy in living tissue or cell preparations.

Painful sweating

The authors report a case of spontaneous and gustatory facial pain and sweating. The patient had frequent episodes of pain, sweating, and flushing bilaterally in the hairless skin of the ophthalmic and maxillary distributions of the trigeminal nerve. Gustatory stimuli (e.g., orange juice, pickled onions) reliably evoked episodes, but episodes also frequently came on spontaneously. The problem had begun during adolescence, about the time of topical treatment and then electrocauteries for facial warts. The patient reported benefit from tricyclic antidepressants, guanethidine, and trospium chloride (an anti-cholinergic quaternary amine used in Europe for urinary urgency). There was no pain or excessive sweating in other body areas, nor pain with exercise. Administration of edrophonium IV evoked pain and sweating, and ganglion blockade by IV trimethaphan eliminated pain and sweating and markedly attenuated responses to edrophonium. Trospium chloride also prevented edrophonium-induced pain and sweating. Bicycle exercise produced the same increment in forehead humidity as in a spontaneous episode but did not evoke pain. Tyramine infusion did not bring on pain or sweating, whereas iontophoretic acetylcholine administration to one cheek evoked pain and sweating bilaterally. Topical glycopyrrolate cream eliminated spontaneous, gustatory, and edrophonium-induced episodes. The findings indicate that facial pain and sweating can result from occupation of muscarinic cholinergic receptors after acetylcholine release from local nerves. The authors propose that after destruction of cutaneous nerves, aberrant regenerant sprouting innervates sweat glands, producing gustatory sweating as in auriculotemporal syndrome (Frey syndrome), and innervates nociceptors, producing pain.