EP2124956A1 - Use of 10-[(3r)-1-azabicyclo[2.2.2]oct-3-ylmethyl]-10h-phenothiazine for the preparation of a drug having a selective inhibition of muscarinic m1, m2 and m3 receptors - Google Patents

Abstract

The present invention relates to the use of 10-[(3R)-1- azabicyclo[2.2.2]oct-3-ylmethyl]-10H-phenothiazine as well as its pharmaceutically acceptable salts for the preparation of a drug having the particularity of treating or preventing urinary incontinence, by local and/or oral route.

Description

Use of 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine for the preparation of a medicament exerting a selective inhibition of muscarinic M ₁ , M ₂ and M ₃ receptors

The present invention relates to the use of 10 - [(3R) -I-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine as well as its pharmaceutically acceptable salts for the preparation of a medicament allowing in particular to prevent or treat urinary incontinence, locally and / or orally. 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine, the synthesis of which is described in the patent, is derived from a racemate: d, I-mequitazine. Initially mequitazine is a drug, effective in the treatment of allergic conditions such as seasonal or permanent allergic rhinitis, drug allergies, as well as dermatological manifestations of allergic or viral origin (pruritus). Mequitazine is an anti-histamine type anti-Ηl. It has an asymmetric carbon leading to two distinct spatial configurations: levorotatory and dextrorotatory (R configuration). The extensive analysis of the properties of the two enantiomers was able to show that the dextrorotatory enantiomer had a very high affinity for the muscarinic M1 / M2 / M3 receptors, which were lifted below, while the other enantiomer showed lower affinity for muscarinic receptors. Acetylcholine is the main neuromediator of the parasympathetic nervous system. The physiological actions of acetylcholine are mediated by muscarinic or nicotinic receptors. Each of these receptors is heterogeneous: eg, the family of muscarinic receptors comprises, to date, 5 subtypes (M.sub.l, M.sub.2, M.sub.3, M.sub.4, and M.sub.5) each of these receptors is encoded by a different gene and has a distinct physiological distribution and function. However, several muscarinic receptors can cooperate to induce a common physiological effect, as is the case with the regulation of incontinence.

The M3 receptor is one of the contributors to the contraction of the muscle involved in the control of the bladder sphincter (detrusor: all the smooth musculature of the bladder / bladder wall). There are causes of incontinence that can be eliminated when they are identified: urinary tract infection, stones (stones), constipation, for example. It can also happen that a continence disorder is linked to a drug treatment. Incontinence can, in the elderly, correspond to a change of the environment, to a maladaptation of the environment. In menopausal women, the decrease in estrogen impregnation is often implicated in the appearance of incontinence, hormonal substitution treatments are part of the therapeutic arsenal in this population of patients. Apart from these circumstances, the cause of incontinence can be identified by special examinations. Management of incontinence may involve medications, rehabilitation, or, in some cases, surgery. Excessive bladder reactivity can be treated with specific antispasmodic drugs. The weakness of sphincters can be improved by sympathomimetic drugs or, in women, by estrogen hormones. Sympatholytic drugs can be used to relax over-contracted sphincters.

There are several types of urinary incontinence that are temporary or continuous depending on the etiological factors. Thus we generally distinguish:

- urge incontinence (hyper-reflexion of the detrusor), abnormal contractions of the bladder occur involuntarily and cause an urge to urinate.

- urinary stress incontinence

It is a passive incontinence by diminution of the urethral resistances. The leakage of urine occurs when abdominal pressure is exerted during a cough, a sneeze, ...)

- Incontinence of neurological bladders, related to vesico-sphincter dysfunctions:

- Incontinence by trauma.

- Incontinence by ectopic dislocation of the urethra. - enuresis (at the child of more than four years). Incontinence by impetus, stress urinary incontinence and incontinence by ectopic contact with the ureter are only found in women while overflow incontinence is male.

The first-line treatment of "overactive bladder" is based on the use of anticholinergic or anti-muscarinic drugs. Recent meta-analyzes show that the clinical benefit versus placebo is indisputable even if the treatment is accompanied by adverse effects such as tachycardia, constipation or dry mouth, which may explain the low compliance of patients to treatment (Herbison P. et al ., BMJ, 2003). This is explained by the lack of bladder selectivity of antimuscarinics compared to other organs. Although muscarinic M ₂ receptors are those that are quantitatively most expressed in the bladder and lower urinary tract, the small proportion of muscarinic M3 receptors is proportionally more important in terms of functional regulation. contractions of the detrusor. In functional studies based on ex vivo models, using detrusor fragments in survival, it was shown that the muscarinic receptor subtype M3 was identified as the only receptor subtype involved in muscle contraction, in the rat (Longhurst PA et al., Br J. Pharmacol, 1995), rabbits (Choppin A., et al., Brit J. Pharmacol, 1998) and humans (Chess-Williams R., and coll., J. Auton Pharmacol, 2002). These data relating the importance in terms of regulation of the M ₃ receptor have been confirmed in models of transgenic mice deficient in M ₃ receptors (Matsui M., et al., PNAS, 2000). Mechanistically, in the normal state, acetylcholine binds to the M ₃ receptor, which releases the secondary messengers IP3 (inositol triphosphate) and DAG (diacylgycerol) inducing contraction of the smooth muscle. Acetylcholine also induces contraction by inhibiting the release of adenosine monophosphate and reversing norepinephrine-induced relaxation via β-receptors.

One of the major adverse effects of the use of anticholinergics in the inhibition of incontinence is the phenomenon of dry mouth. Paradoxically, it is thanks to this effect that the candidate drugs potentially usable in incontinence are selected in pharmacology, as is explained below. In preclinical animal studies, oxybutynin and darifenacin, two inhibitors used for incontinence, reduce salivation and are more selective for the M3 receptor than for the M ₂ receptor. In contrast, tolterodine reduces salivation and is more active on detrusor contractions. Tolterodine is more specific for the M ₂ receptor than for the M ₃ receptor (Gillberg PG, et al., Eur J. Pharmacol., 1998). However, even if it was supposed that a selectivity towards the M ₂ or M ₃ receptors could make it possible to differentiate the effects of the inhibitors, in clinical the results are less clear and it appears that a simultaneous action on the M ₂ and M ₃ receptors would be an effective combination for incontinence syndromes. Thus, darifenacin, which shows a 7-fold higher affinity for M ₃ muscarinic receptors than for M ₂ muscarinic receptors, does not confirm bladder or salivary gland selectivity. In conclusion, the M ₃ receptors regulate the contractions of the smooth muscle of the bladder, the M ₂ receptors intervening in the initiation of this contraction (Krichevski VP, et al., J. Urol, 1999).

For the reasons mentioned above, it appears that the inhibitory candidate should have a mixed binding action on both the M ₂ receptor and the M ₃ receptor to have a complete action with respect to the induction of contraction and on its regulation. In addition, the M ₁ muscarinic receptor, which has been deconsidered in this field, also seems to play a role in the detrusor (Maruyama S., et al., J. Urol., 2006).

In order to reduce the adverse effects induced by antimuscarinic agents, various devices have been used. They are transdermal, or placed in situ in women, in the form of vaginal ring extended release (Schroder A., et al., Urol, 2000). Transdermal oxybutynin transdermal patches have been successfully tested in order to limit side effects due to systemic dissemination of the active ingredient (Stakmann JS, et al., Urol., 2006). By this way, the limitation of the effects of dry mouth or ocular, disturbances of the vision, constipation, migraines is less observed; on the other hand the cutaneous intolerances to the device appear. Nevertheless, the phenomenon of first pass through the liver is canceled, which limits secondary activity induced by the very potent liver metabolite of oxibutynin (N-desoxybutynin) whose plasma level after oral administration of oxibutynin is 6 to 9 times greater than that of oxybutynin. It is the combination of these two entities that triggers the effects of inhibition of incontinence, but also the induction of side effects.

Thus, the limitation of the active plasma metabolite level of antimuscarinic drugs can also be based, in addition to a specific route of administration, on a particular hepatic metabolism not producing active metabolites, which may exacerbate the effect of the drug initially administered, but also increase the frequency and intensity of side effects.

In addition, the longer the half-life of the product, the lower the frequency of administration, thus facilitating compliance with the treatment.

The object of the present invention is based on the particular and unexpected properties of 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -1H-phenothiazine (dextrorotatory enantiomer of mequitazine, codified here under the name VO 162). The following examples show that:

the affinity for human M ₁ , M ₂ , M ₃ muscarinic receptors is very powerful and of nano molar level

the dextrorotatory enantiomer (VO 162) is more refined than the racemate and the levorotatory enantiomer vis-à-vis the muscarinic receptors.

the muscarinic targeting is mixed with, in order of affinity: Mi>M3> M ₂ , this inhibition being qualitatively and quantitatively judged optimal for the inhibition of the incontinence phenomenon.

- in vivo the dextrorotatory enantiomer is anticholinergic intravenously whereas the levorotatory enantiomer does not show any net activity. It is the same for the oral way.

in vivo mucosal application of the VO 162 suspension results in a net systemic passage resulting in a circulating level compatible with pharmacological activity vis-à-vis the muscarinic receptor targets. - in vivo in a model of sialorrhea in rats, VO 162 induces a significant decrease in salivary secretions after oral administration. - in vivo in the model of vesical hyperactivity (emergency incontinence) induced by exposure to acetic acid, the VO 162 reduces the intravesical pressure evaluated by cystomanometry.

The combination of all these properties, taken as examples of this patent, unexpectedly shows that VO 162 (10 - [(3R) -I-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine ) is an active compound in urinary incontinence and disorders associated therewith.

EXAMPLE 1: Affinity of VO162 (10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine) with respect to human muscarinic receptors, in vitro

The purpose of this study is to determine an affinity constant of the compound vis-à-vis the three classes of human muscarinic receptors in vitro. The model chosen is the CΗO cell stably transfected with the cDNAs encoding each of the three types of muscarinic human receptors. First, the affinity of the cells expressing each type of receptor for a ligand which has been determined to be 100% bound to the target muscarinic receptor is determined. The ligand that is optimal for the recombinant Mi receptor is 2 nM tritiated pirenzepine (Dorje F., et al., JPET, 1991), that of the recombinant M ₂ receptor is ₂ nM tritiated methoctramine, that of the M3 receptor is 4-DAMP at 0.2nM (Peralta EG, et al., EMBO, 1987). The binding specificity of the receptors expressed by each cell type was verified in parallel by evaluating non-binding of atropine to 1 μM. The binding to the receptors is defined as follows: the difference between the overall binding and the non-specific binding determined in the presence of excess cold ligand. The results are expressed as a percentage of the optimal binding obtained with the model ligand (100%). IC50 (concentration required to inhibit 50% of optimal ligand binding with corresponding target receptor) and Ηill (nu) coefficients were determined by nonlinear regression analysis of competition curves. Inhibition constants (K ₁ ) were calculated using the Cheng Prusoff equation (K ₁ = IC ₅₀ / (1 + L / K _D )); where L is the concentration of radio ligand and K _{D is} the affinity of the radio ligand for the receptor. Table 1: VO 162 receptor binding in vitro

These results show that V0162 ((10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine) is a compound that binds strongly to muscarinic receptors Its M2 specificity ratio / M3 is between 1.5 and 2. Its affinity for Mi is also nanomolar.

Thus in vitro this compound demonstrates a very strong affinity vis-à-vis the muscarinic receptors involved in the initiation, regulation and maintenance of detrusor contractions. The differences between enantiomers and racemate vis-à-vis these three receptors vary between a factor of 3 and a factor of 10, in terms of K ₁ . EXAMPLE 2: Ex vivo anticholinergic activity of VO 162 (10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -1H-phenothiazine).

The aim of this experiment is to confirm the anticholinergic activity of the VO162 on a surviving organ. For this purpose, explants taken from the guinea pig were put into survival. The morphology of the preparations was homogeneous from batch to batch. Each explant was placed in a survival chamber and immersed in a physiological solution of composition (mM): NaCl (118): KCl (4.7); MgSO ₄ (1.2); CaCl ₂ (2.5); KH ₂ PO ₄ (1.2); NaHCO ₃ (25); glucose (11) at a temperature of 37 ° C and a pH of 7.4. Prior to the assay, the following agents were dispersed in the survival buffer to block non-specific acetylcholine responses: propanolol (10 ^-6 M) to block β ₂ -adrenergic responses, cimetidine (10 ^-5 M) to block histaminergic type 2 responses; methysergide (10 ^-6 M) to block serotoninergic responses and indomethacin (3.10 ^-6 M) to prevent the occurrence of muscle tone due to release of prostaglandins by the preparation itself. During the acquisitions, the tissues were connected to transponders in order to continuously record the voltage variations. After 60 min of calibration of the preparations, the tissues were exposed to varying concentrations of VO162. Acetylcholine-induced contractions in dose responses were performed to determine the response of the preparation to stimulation in the absence of inhibitor putative.

Table 2: VO 162, anticholinergic effect ex vivo

Expression of results as mean ± sem, with n = 6 per group; *: p <0.05 in tra and #: p <0.05 extra The anticholinergic evaluation system is validated by the dose-effects obtained with acetylcholine as a physiological mediator of muscle contraction. These results analyzed by Student's "t" test for unmatched values show that VO162 is opposed to the contractile action of acetylcholine. In this ex vivo model the data obtained in vitro are confirmed: VO 162 behaves as an antagonist competitor of acetylcholine. Its action starts from 3OnM.

EXAMPLE 3: Inhibitory activity of VO 162 (10 - [(3R) -I-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine sialorrhea, in vivo.

Since anticholinergic activity has been demonstrated in vitro at the receptor and cell level and then ex vivo at the level of the target tissue, the purpose of these experiments is to ascertain whether, after oral administration, an inhibition of salivary secretion occurs. M ₃ receptor blockade, which is involved in detrusor contractions and salivary secretion, often causes dry mouth as a concomitant effect of treatment for oxybutynin or tolterodine incontinence. Investigations into new agents that inhibit incontinence have long been based on receptor selectivity. It was supposed that the specificity of an agent towards M ₃ receptors rather than M _{2 would} make it possible to limit the inhibition to the expression zones of the receptor and thus to avoid inhibition at the level of non-physiological targets. involved in incontinence, such as the heart sphere or salivary glands. However, as we have seen above, the selectivity of the incontinence agents does not depend exclusively on the tissue expression selectivity of the muscarinic receptor subtype. Indeed, the distribution of these receptors is not really related to a tissue difference (ie: M ₂ receptors are also found in the detrusor). Functionally, the activation of certain receptors controls the level of activation of other receptors of the same muscarinic family. Thus the elimination of compounds that can affect salivary secretion, in order to select exclusively active compounds on the detrusor (and thus on incontinence), leads to nonsense. As a result, the latest developments are pushing towards the evaluation of incontinence tests for inhibition of salivary secretion. A crucial point is the ability of the compound to diffuse to a target tissue. Thus compounds that can inhibit salivary secretion in models ex vivo or even in vivo in animals may be devoid of effects on oral dryness in human clinic. Nevertheless, the activity of inhibition of salivary secretion is a tool of choice and safe anticholinergic activity.

In order to evaluate the anticholinergic activity in the validated pilocarpine-induced rat sialorrhea model, groups of animals were fasted, the following day the products were administered orally 90 min before intraperitoneal injection of pilocarpine (O.Smg.kg ¹ ). The compounds tested were administered at doses of 2.5; 5 and 10 mg.kg- ¹ V0162 (10 - [(3R) -I-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine was previously suspended in a vehicle; 0.5% carboxymethylcellulose Atropine as a positive control of the experiment was administered at the dose of lmg.kg- ¹ . The animals were anesthetized and then salivary secretion was collected for 60 min, every ten min. The samples were then dried and weighed.

Table 3: Inhibition of salivary secretion in rats after po administration, anticholinergic effect in vivo

Expression of the results as averages with n = 10 per group; *: p <0.05

The evaluation system of salivation is validated by the action of atropine in the model. The results show that the exemplified compound significantly reduces salivary secretion in animals after oral administration. The effects obtained are dose-dependent. The potency of VO 162 (10- [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine) is similar to that obtained with atropine used here as a standard method. Thus, the VO 162 compound and its pharmaceutically acceptable salts are found to be useful for the manufacture of medicaments, particularly in a form adopted for nasal administration, for the treatment of rhinones.

In a second step, the anticholinergic activity of the two enantiomers was compared to a single dose, after oral administration according to the same experimental scheme as that previously described.

Table 4: Inhibition of salivary secretion in rats after po administration of racemic mixture and enantiomers, anticholinergic effect in vivo

Expression of the results as averages with n = 10 per group; *: p <0.05

In conclusion, these experiments confirm the results previously obtained in vitro and ex vivo, and demonstrate unexpectedly that VO 162 (10-

[(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine) is a potent oral anticholinergic. Moreover, it belongs to the class of potential inhibitors of incontinence because, like oxibutynin, darifenacine or tolterodine, it decreases the salivary secretion in the animal, after administration of pharmacological doses nontoxic and well tolerated. In addition, contrary to what was expected, inhibition of the cholinergic pathway is effective only after treatment of the animals by the dextrorotatory enantiomer. The laevorotatory enantiomer demonstrates anticholinergic activity in vitro, but these results are not the same after oral administration. Thus, these results show that only VO 162 exerts anticholinergic activity in vivo.

EXAMPLE 4 Transmucosal passage of a suspension of VO 162 (10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine), in vivo in the rabbit. We have seen that the compound was able to induce anticholinergic activity after oral administration. Furthermore, it is established that the selectivity of the action of anticholinergics on the urinary sphere, with the aim of inhibiting contractions of the detrusor and therefore incontinence, was not based on a selectivity with respect to the subtypes muscarinic receptors because they are expressed ubiquitously. Thus, one of the means of achieving selectivity is to reduce the systemic circulation of antimuscarinics while increasing their concentration at their site of action: the lower urinary tract. The vaginal application of this compound could limit the side effects while increasing the effectiveness. The bladder can be separated pharmacologically in two: the body and the base. The muscarinic receptors are distributed mainly in the body, and the contractile response to cholinergic stimulation is at the same level. In the same way, the other mechanism involved in the maintenance of continence, the direct activity on the relaxation of the muscle, sees its control situated in the same place. In addition, recent studies have shown the possibility of reducing contractions of the bladder by local injection of anticholinergic agents. Thus anticholinergics may act not only as an antagonist of acetylcholine at contractions of the detrusor, but also by blocking the muscarinic receptors of the bladder-related pathways. Therefore, the use in situ of an antagonist compound would be an approach of choice for the treatment of incontinence especially in menopausal women. The major limitation is the ability of the antimuscarinic agent to cross the vaginal mucosa to target muscarinic afferents in the vicinity of the bladder (Yongtae K., et al., J. Urol., 2005).

In order to analyze the propensity of the compound of interest to cross a model mucosa, the VO 162 was administered by spraying the nasal mucosa in rabbits, then blood samples were taken in order to measure a possible rate. circulating VO 162. 48 rabbits were treated nasally daily for 28 days with a suspension titrated at 0.4% mass / volume. The 3 groups of animals were distributed as follows: saline solution, vehicle, VO 162. Each group consisted of males and females, equal parts. Administration of the nasal suspension was performed twice daily for 28 days. Plasma samples were taken on D1, D2, D7, D28, D35. The samples were analyzed by a validated LC / MS / MS VO 162 assay method.

Table 5: Circulating VO 162 levels after repeated nasal administrations

Expression of the results as averages with n = 10 per group; BLQ: below the limit of quantification. The results show that the nasal administration of a VO 162 suspension induces a circulating level close to 4 nM, compatible with a pharmacological action. Indeed, we have previously seen that the IC50 of V0162 was 5 nM at the muscarinic receptor M3 and 1 nM for the muscarinic receptor Mi.

It can thus be concluded that the mucosal administration of VO 162 results in an effective passage consistent with the circulating levels required for its anticholinergic activity. This administration does not induce deleterious effects on the nasal mucosa. The circulating levels obtained do not lead to toxic effects in this model, either historically or in terms of vital functions: respiratory rate, heart rate, behavior.

Thus it is possible to administer the compound of interest by simple application to the mucosa for the purpose of locally delivering the anticholinergic agent.

EXAMPLE 5 Incontinent Incontinence Inhibition Activity of a Suspension of

V0162 (10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine), in vivo.

The objective of this study was to measure intravesical pressure and salivation, in animals, in order to test the uroselectivity of anti-muscarinics, when they are administered orally and vaginally. In order to evaluate the intravesical pressure, animal bladders were catheterized to allow recording (cystomanometry: continuous recording of bladder pressure). The products to be tested were administered either per os at a dose of Smg · kg- ¹ or by local application of suspension of VO 162 at 0.4% in a cyclodextrin and arginine-based vehicle The jugular vein was also cannulated in order to administer a muscarinic agonist: bethanechol (200 μg / kg, iv) At each bethanechol administration, the bladder pressure variation (ΔPV, mmHg) and the amount of saliva (mg) were evaluated and quantified. positive was a group of animals treated with oxybutynin (Ditropan®, 10, 100 and 1000 μg / kg, iv). The results (only expressed in the text) show that compared to oxybutynin, VO 162 orally or by local application significantly reduces the intravesical pressure increase induced by the reference agonist: bethachol. The foregoing experiments show that VO 162 is able to induce anticholinergic activity after oral administration. In addition, the compound is able to cross the mucosa. The VO 162 compound has the characteristics of a potent anticholinergic agent: nM in vitro and mg.kg- ¹ per os in vivo.It is orally active and can also be administered locally to the mucosa in the form of a gelled preparation for the purpose of targeting the zone where the muscarinic receptors directly controlling or regulating continence are represented.

Claims

Use of 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -1H-phenothiazine and a pharmaceutically acceptable salt thereof for the manufacture of a medicament for preventing or treat disorders, conditions and / or pathologies by selective inhibition of muscarinic M ₁ , M ₂ and M ₃ receptors.

2. Use according to claim 1 for the manufacture of a medicament for treating rhinorrhea, in particular in a form suitable for nasal administration.

3. Use according to claim 1 for the preparation of a medicament for preventing or treating urinary incontinence and related disorders.

4. Use according to one of claims 1 to 3 wherein, the 10 - [(3R) -I-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine is a mixture selected from mixtures comprising at least minus 95-100% of 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine, 96-100% of 10 - [(3R) -1-azabicyclo [2.2. 2] oct-3-ylmethyl] -10H-phenothiazine, 97-100% of 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine, 98-100% of - [(3R) -1-Azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine, 99-100% of 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl) ] -10H-phenothiazine, and pure 10 - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -1H-phenothiazine.

5. Use according to claim 3, characterized in that the incontinence and the associated disorders are selected from: incontinence urinary incontinence (hyper-reflexive detrusor), abnormal contractions of the bladder occurring unintentionally and causing a urge to urinate; stress urinary incontinence; incontinence of neurological bladders, related to vesico-sphincter dysfunctions; trauma incontinence; incontinence by ectopic dislocation of the urethra; enuresis (in children over four years).

6. Use according to claim 3, characterized in that the pathologies or symptoms associated with urinary disorders are bacterial or fungal infections derived from overactive bladder.

7. Use according to claim 3, characterized in that the drug is presented in a form suitable for oral administration.

8. Use according to claim 3, characterized in that the drug is presented in an oral dosage form at a dose of between lμg.kg- ¹ and lOmg.kg- ¹ , advantageously between O.Olmg.kg- ¹ and lmg.kg ^"1 .

9. Use according to claim 3, characterized in that the drug is presented in an intravaginal local dosage form in an active concentration gel form of between 0.01% and 10%.

10. Use according to claim 3, characterized in that the drug is presented in a dosage form intravaginally local form in the form of egg, suppository comprising between 10mg and 500mg equivalent of active ingredient.

11. Use according to claim 3, characterized in that the medicament is intended for intravaginal administration in the form of a sustained release device of the vaginal ring type, at a dose allowing the release into the peri-mucosal circulation of 0.2ng to 10 n - [(3R) -1-azabicyclo [2.2.2] oct-3-ylmethyl] -10H-phenothiazine lOOng per mL of plasma, preferably 2ng to 50 ng of 10- [(3R) -1-azabicyclo [2.2. 2] oct-3-ylmethyl] -10H-phenothiazine per mL of plasma.