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Overactive bladder syndrome pharmacotherapy: future treatment options

Andrzej Wróbel

Prz Menopauzalny 2015; 14(4): 211-217
Online publish date: 2015/12/16
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Introduction

Overactive bladder syndrome (OAB) is a symptom-based diagnosis defined by the International Continence Society as urinary urgency with or without urinary incontinence, usually with frequency and nocturia in the absence of local pathological lesions which could cause the aforementioned symptoms. The incidence of this condition ranges from 14% to 30.9% and increases with age. Therefore, it is considered a social disease with incidence almost equal to hypertension, bronchial asthma and heart diseases.
The majority of drugs currently used in OAB therapy appear to have peripheral effects. They can be categorised as drugs whose primary objective is to reduce the contractility of the detrusor urinae muscle and to affect the sensory nerves. Antimuscarinics are considered the first-line therapy of OAB. However, the compliance and persistence of this group of medications is low. Their use is limited by their poor clinical effectiveness, which is sometimes unsatisfactory, and with well-known side effects.
These limitations of modern-day OAB pharmacotherapy have provided a stimulus for exploring the issue of the pathophysiology of this condition, which, in turn, has facilitated the development of new drug treatments. The effectiveness of OAB treatment depends on the accurate identification of potential pharmacotherapy goals. Below there is a revised discussion of potential areas of operation and mechanisms that could become the basis for synthesising new effective substances in OAB pharmacotherapy.

The serotonergic system

Pre-clinical studies have shown that serotonin receptor agonists inhibit parasympathetic activity and facilitate sympathetic and somatic activity, while antagonists have opposite effects. The use of methysergide, a non-selective 5-HT receptor antagonist, or zatosetron, a 5-HT3 receptor antagonist, leads to a reduced micturition threshold. Serotonin activity in the spinal cord seems to inhibit the detrusor function and facilitate the urethral sphincter function, which is mediated by the 5-HT1A, 5-HT2 and 5-HT3 receptors [1]. The central serotonergic system is activated indirectly by the 5-HT inhibitors of reuptake and directly by the 5-HT1A and 5-HT2 receptor agonists, and weakens the contractions of the detrusor and increases the threshold capacity of the bladder. Detrusor urinae has a high 5-HT4 receptor density. Clinical studies have proven that cisapride, a selective 5-HT4 receptor agonist, shows positive outcomes in patients with urinary retention following a spinal cord injury. In turn, the use of piboserod, a selective 5-HT4 receptor agonist, has proven to inhibit detrusor hyperreflexia.

The dopaminergic system

The dopaminergic system can both inhibit and stimulate the micturition cycle by affecting, respectively, either D1-like (D1 and D5) receptors, which tonically inhibit the micturition reflex, or D2-like (D2, D3 and D4) receptors, which pave the way for it. When this tonic, inhibiting effect of the dopaminergic system is blocked by destroying the nigrostriatal pathways, patients show motor symptoms that are similar to those observed in Parkinson’s disease and OAB. Patients with Parkinson’s disease have been found to be more likely to experience detrusor overactivity (DO), which seems to be a consequence of dopamine deficiency in the striatum structures and the insufficient activation of D1-like inhibiting receptors. Detrusor overactivity symptoms in these patients are suppressed as a result of D1 receptors being stimulated by selective agonists (pergolide). On the other hand, D2 receptor stimulation with quinpirole or bromocriptine has proven to increase the reactivity of detrusor urinae. Cerebral infarction was found to cause increased D2 receptor density and decreased D1 receptor density, resulting in DO symptoms [2]. Therefore, it seems that selective D2 receptor antagonists can be used in OAB pharmacotherapy in patients after cerebral infarction. The stimulation of central D1-like dopamine receptors, with the simultaneous blocking of D2 receptors, could prove to be an alternative of interest in OAB pharmacotherapy.

Glutamic acid

Acting as a neurotransmitter for both, the supraspinal efferent pathways and the afferent limb of the micturition reflex, glutamic acid affects the micturition cycle. Its increased concentration in Onuf’s nucleus stimulates the pudendal nerve to release acetylcholine, which induces, via nicotinic receptors, contractions of the external sphincter muscle of the urethra.
Glutamic acid is a trigger that regulates the activity of the urethral sphincter, and 5-HT and NA determine the strength of the signal that reaches the sphincter. Without glutaminergic stimulation, increased 5-HT and NA concentrations will not cause any changes in the activity of the urethral sphincter. However, with glutaminergic stimulation, 5-HT and NA will amplify the stimulating effect of glutamic acid, leading to increased contraction in the urethral sphincter.
Ionotropic glutamate receptors can be divided into three sub-types: NMDA, AMPA and kainate receptors. Detrusor overactivity symptoms visible in animals suffering from cerebral infarction caused by the closing of the middle cerebral artery (MCA) are accompanied by increased NMDA receptor density in the brainstem, and its reduced density in the forebrain. Detrusor overactivity symptoms in these animals were not visible when, before the MCA was closed, dizocilpine, a non-selective NMDA receptor antagonist, or a selective AMPA receptor antagonist, had been used [3]. The direct stimulation of glutamic acid receptors seems to be difficult to achieve. Moreover, it has been shown that agonists of these receptors can have hypertensive effects, which would constitute a major adverse effect of this group of compounds.

Gamma-aminobutyric acid

Gamma-aminobutyric acid (GABA) serves the role of an inhibiting neurotransmitter in central nervous system (CNS). GABAA and GABAB receptors are involved in spinal and supraspinal mechanisms that control the micturition reflex. Positive treatment outcomes in bladder overactivity seem to be achieved by enhancing GABAergic transmission by stimulating GABAA and GABAB receptors, inhibiting GABA reuptake, or inhibiting GABA transaminase. It has been shown that the pontine micturition centre is under the tonic, inhibitory influence of the GABAergic system. The centre causes urinary bladder contractions by directly stimulating parasympathetic bladder motor neurons, while also inducing the relaxation of the external sphincter muscle of the urethra by stimulating GABAergic interneurons in the gray commissure of the spinal cord, which, in turn, inhibits the motor neurons of the external sphincter muscle of the urethra. Experimental studies have proven that the administration of exogenous GABA or muscimol, a GABAA receptor agonist, inhibits the detrusor urinae contraction reflex. These outcomes were reversed by administering bicuculline, a GABAA receptor antagonist. In patients with spinal cord injuries, the use of baclofen, a GABAB receptor agonist, has proven to reduce detrusor hyperreflexia [4]. The GABAergic system can potentially be of interest in OAB pharmacotherapy. GABAB receptor agonists, such as baclofen, are used to treat detrusor hyperreflexia secondary to spinal cord injuries, also in patients with bladder spasticity.
Four different types of GABA transporters have been identified. Tiagabine is a selective inhibitor of one of them, GAT1. It has been shown that this drug inhibits the reuptake of GABA to increase the extracellular level of this neurotransmitter and to inhibit micturition. Tiagabine has been found to reduce micturition pressure and post-void residual volume, and to increase the volume of the urinary bladder.

Ion channels

In humans, the detrusor muscle includes at least two types of K+ channels, namely ATP-sensitive channels (KATP) and calcium channels (KCa). When these channels are opened, smooth muscles are hyperpolarised, which, in turn, inhibits Ca2+ channel opening, thus reducing the influx of calcium into the cell. Under physiological conditions, KATP channels are closed when involved in myorelaxant activity.
It has also been shown that KCa (BK and SK) channels are important for bladder functioning. BKCa and SKCa channels play a significant role by being a part of the negative feedback that reduces the influx of extracellular Ca2+, thus affecting the activity of the urinary bladder.
Compounds that open K+ channels inhibit spontaneous bladder contractions without affecting micturition pressure [5]. Drugs that operate in this way can be useful in OAB therapy by inhibiting detrusor hypersensitivity during the urine collection stage, but appear not to affect the micturition stage.
It has been established that nifedipine inhibits detrusor contractions in humans, which suggests that these contractions require the influx of extracellular Ca2+ through stretch-activated L-type Ca2+ channels.
The increased sensitivity of bladder neurons can be induced by changes in Na+ channel expression. These channels are divided into tetrodotoxin-sensitive (TTX-S) and tetrodotoxin-resistant (TTX-R). Cystitis has been found to be accompanied by an increased TTX-R Na+ channel expression, and spinal cord injuries to be accompanied by changes in TTX-S Na+ channel expression. It seems that the selective Na+ channel block can be an effective OAB treatment method. Gabapentin is a sodium-channel-blocking drug currently undergoing clinical trials.

Prostanoids

Prostaglandins modulate the afferent limb of the micturition reflex. Since changes in afferent impulse activity are considered one of the OAB causes, it seems that drugs that affect mechanisms involving prostaglandins can be of interest in the modern pharmacotherapy of this disease.
It has been shown that the use of non-selective cyclooxygenase (COX) inhibitors such as ketoprofen or indomethacin, causes a rise of the micturition threshold and the urinary bladder volume in detrusor hyperreflexia. Cyclooxygenase inhibitors reduce bladder-hyperactivity symptoms by blocking COX-2 activity and, consequently, inhibiting the stimulation of capsaicin-sensitive fibres. These are not recommended in haemorrhagic and interstitial cystitis, i.e. in conditions in which the epithelium of the urinary tract is not protected by prostaglandins. Indomethacin and ketoprofen improve the subjective symptoms of OAB but their impact on bladder functioning has not been confirmed in urodynamic testing. Beneficial effects on cystometric parameters have been demonstrated in relation to flurbiprofen, which have proved to reduce the frequency of urinary urgency and to increase bladder capacity. However, in view of the reports on the influence of selective COX-2 inhibitors on the cardiovascular system, the future of this research and development line is uncertain.
Therefore, desirable OAB treatment outcomes will be achievable without damaging the urinary bladder walls, perhaps not so much through the impact on COX as on specific prostanoid receptors. This statement is supported by research which has shown that animals which have been genetically deprived of the EP1 receptor do not show hyperreflexia symptoms following the intravesical administration of PGE2 [6].

Tachykinin receptors

Increased afferent impulsation plays an important role in OAB aetiopathogenesis. Tachykinins serve as transmitters for sensory nerves. They operate via specific receptors. There are three types of tachykinin receptors: NK-1, NK-2 and NK-3. It has been shown that the contractions of human detrusor, induced by tachykinins, are only mediated by NK-2 receptors. The release of tachykinins from afferent nerve endings causes detrusor urinae hypersensitivity through NK-2 receptors, leading to a reduced micturition reflex threshold and the appearance of phasic contractions. The findings of a pre-clinical study which used NK-2 receptor antagonists allow the conclusion that these compounds can become a promising group of medications in OAB pharmacotherapy. Interestingly enough, it has been established that the use of Rho-kinase inhibitors leads to the inhibited contractile activity of the bladder, mediated by NK-2 receptors. NK-1 receptor antagonists also increase the micturition threshold, which suggests that tachykinins are involved in supraspinal mechanisms and makes NR receptors in the spinal cord a potential objective of new pharmaceuticals that could become effective in OAB therapy. Urodynamic testing has proven that NK-2 receptor antagonists inhibit hyperreflexia in bacterial cystitis and in cases of a spinal cord injury, which suggests their possible application in patients suffering from such injuries or multiple sclerosis, which are often accompanied by OAB symptoms [7].

TRPV1 receptors

TRPV1 receptors are located on afferent neurons (mainly type C, but also type A). Capsaicin and resiniferatoxin, their selective agonists, affect the sensory functions of the bladder, thus decreasing TRPV1 receptor density. A single administration of vanilloids causes the depolarisation of afferent fibres with TRPV1 receptors, and long-term exposure reduces sensitivity, disturbs the functioning, and completely destroys the peripheral nerve endings. With the aforementioned changes, vanilloids increase urinary bladder capacity in OAB patients. It seems that TRPV1 receptor antagonists can become an alternative of interest in OAB pharmacotherapy. It has been demonstrated that they block ATP from being released from the urothelium as a result of urinary bladder walls’ being stretched, and their use has proven not to produce adverse effects typical of TRPV1 agonists. The possibility of using TRPV1 receptor blocking in OAB pharmacotherapy is supported by the capsazepine-caused reduction of detrusor urinae contractions induced by the administration of cyclophosphamide [8].

Opioid receptors

Opioid receptors (µ,  and ) are located in a number of structures that play significant roles in micturition control. It has been shown that morphine can increase the cystometric capacity of urinary bladder and block detrusor contractions. Furthermore, the use of naloxone, a µ-opioid receptor antagonist, has proven to stimulate micturition, which suggests that the tonic activation of µ-opioid receptors has a suppressive effect on the micturition reflex. It has also been established that the epidural administration of morphine to patients with OAB induced by spinal cord damage leads to a reduced sensitivity of detrusor urinae.
A drug that is widely used in pre-clinical studies is tramadol, a weak agonist of µ-opioid receptors. Its mechanism of operation is of particular interest for OAB treatment, as this drug is a racemic mixture, and its (+) enantiomers stimulate µ-opioid receptors, and (–) enantiomers inhibit noradrenaline uptake. It has proven to increase urinary bladder capacity and threshold pressure by inhibiting DO induced by apomorphine and caused by brain ischaemia, which makes it an option of interest for the pharmacological treatment of OAB. Tramadol is further characterised by the broad difference between a dose which inhibits micturition and one which induces urinary retention, which results from the simultaneous inhibition of the serotonin and noradrenaline uptake.
Nociceptin, an endogenous agonist of OP4 opioid receptors, is now undergoing clinical trials. Its effectiveness has been demonstrated in relation to patients with neurogenic bladder incontinence. It affects both the central structures that control micturition and peripheral mechanisms, by inhibiting the activity of neurons with TRPV1 receptors, which results in the reduced amplitude of terminal detrusor contractions. Therefore, it is likely that OP4-receptor agonists can become a pharmacological option of interest for the neurogenic bladder and an alternative for the intravesical instillation of vanilloids [9].

Purinergic receptors

ATP released from nerve endings in the urothelium affects specific (purinergic) receptors located in detrusor urinae and on afferent fibres. There are two families of purinergic receptors: P2X and P2Y. So far, as many as 7 sub-types of P2X, and 8 sub-types of P2Y, have been identified.
When ATP is administered into the arterial vessels of the urinary bladder, afferent fibres are stimulated and the activity of the detrusor increases. On the other hand, the desensitisation of purinergic receptors or the use of suramin, their antagonist, inhibits the afferent impulse activity of the urinary bladder. Urodynamic testing has shown that the application of the purinergic receptor antagonist causes an increase in urinary bladder volume. A significant reduction in DO symptoms in animals without P2X2 and P2X3 receptors suggests that selective antagonists of these receptors can become useful in clinical practice. These animals have been found to exhibit reduced micturition frequency and increased bladder volume, which suggests that these receptors are connected with the functioning of bladder mechanoreceptors.
P2X1 and P2X3 receptors appear to play a fundamental role in the micturition reflex. When P2X3 receptors are blocked, the sensitivity threshold of the urinary bladder increases. High density in P2X3 receptors has been demonstrated in IB4 nociceptors. It has been further shown that when saporin, a cytotoxin that selectively destroys IB4 neurons, is administered at the level of L6-S1 of the spinal cord, it reduces bladder overactivity induced by ATP. Therefore, it seems that these fibres can become an objective of interest in OAB pharmacotherapy. Drugs that affect P2X receptors can become a very effective group of pharmaceuticals for patients suffering from neuropathy or elderly patients, due to their increased purinergic transmission [10].

Oestrogen receptors

The presence of oestrogen receptors (ER) has been demonstrated in the detrusor urinae, the urothelium, the urethra, and in the pelvic floor muscles. Oestrogen receptors also appear in the pelvic parasympathetic ganglionic neurons that supply the bladder, which proves that these hormones can modulate the release of acetylcholine (Ach). Post-menopause oestrogen deprivation leads to increased micturition frequency and reduced voided volume, and induces an increase in basal and stretch-induced Ach release. This results in symptoms characteristic of OAB, such as urgency, frequency and nocturia.
It has been shown that oestrogens have K+ channel opening and Ca2+ antagonist activities in the bladder, and can inhibit the rho kinase (ROCK) function in bladder detrusor without affecting ROCK expression. Oestrogen therapy directly affects the contractile activity of detrusor urinae by inhibiting the influx of calcium ions from the extracellular space into the cell and modifying the function of muscarinic receptors. It also reduces the amplitude and frequency of spontaneous rhythmic contractions, which are characteristic of detrusor instability, and the contractile response of the isolated detrusor muscle. Oestrogens modulate urogenital tissue perfusion and the cholinergic and adrenergic innervation of the bladder. It has been demonstrated that oestrogen replacement therapy can lead to an increased sensory threshold of the bladder.
The beneficial effects of oestrogens on OAB symptoms have been proven in clinical studies. It has been shown that the use of 17-oestradiol vaginal tablets leads to a significant reduction in frequency, urgency and urge incontinence. Low doses of oestriadol or estriol administered intravaginally proved to reduce the frequency of nocturia and urge incontinence incidents, while also leading to an early first sensation to void and increased bladder capacity. Meta-analysis findings on oestrogen impact on OAB symptoms suggest that intravaginal replacement therapy is more effective than the systemic one. Moreover, another study has demonstrated that combination therapy using tolterodine and oestrogen cream increases the effectiveness of OAB treatment in post-menopausal female patients [11].

Cannabinoid receptors

The central nervous system shows a high density of cannabinoid receptors (CB1, CB2). The presence of CB1, but not CB2, receptors has also been demonstrated on dorsal root neurons. It has been established that CB1 receptor stimulation inhibits DO induced by the intravesical administration of NGF, this outcome being reversed by using its selective antagonist. Clinical trials have shown that cannabis sativa extract, which includes delta-9-tetrahydrocannabinol, administered sublingually, reduces OAB symptoms in patients suffering from multiple sclerosis [12]. Therefore, it seems that CB1, and probably CB2, receptors can potentially be of interest to OAB pharmacotherapy.

Kinin receptors

Under physiological conditions only the B2 receptor was found in the bladder, but in an infected bladder both kinin receptors (B1 and B2) were expressed. The presence of B1 receptors in an infected urothelium, and the fact that their stimulation induces the release of ATP, seem to prove that the participation of kinins in OAB pathogenesis can be mediated by ATP. It has been established that bradykinin, a B2 receptor agonist, induces ATP release from the urothelium cells, thus causing the detrusor to contract, an outcome that is inhibited by capsaicin and COX inhibitors. B1 receptor antagonists, in turn, have proven to inhibit the overactivity of the detrusor induced by the administration of cyclophosphamide, leading to a considerable improvement in urodynamic parameters [13].

Phosphodiesterase inhibitors

Phosphodiesterases (PDE) regulate cAMP and cGMP levels in cytosol. It has been demonstrated that increased cAMP and cGMP concentrations in the detrusor urinae induces a decrease in intracellular calcium levels, and, in consequence, leads to its relaxation. The human bladder has been found to include PDE 1, 3, 4, 5 and probably 7. PDE1 and PGE3 inhibition induces an increase in cAMP levels, while PDE5 inhibition induces an increase in cGMP. Clinical trials on the effectiveness of vinpocetine, a PDE1 inhibitor, in OAB pharmacotherapy, did not show any statistically significant effectiveness compared to the placebo [14]. Nevertheless, it seems that, due to their ability to increase the urinary bladder compliance, PDE inhibitors could possibly be used in combination therapy with muscarinic receptor antagonists, especially in patients suffering from neuropathy.

Nerve-growth factor

So far, two types of nerve-growth factor (NGF) receptors have been discovered, i.e. TrkA, with a high affinity, and p75, with a low affinity, with NGF. TrkA is located on capsaicin-resistant fibres covered with neurolemma, and its density increases during inflammation processes. On the other hand, the high expression of p75 receptors in the urothelium has been demonstrated in OAB patients. This proves that NGF can increase afferent impulse activity, and, in consequence, induce OAB by stimulating both TrkA and p75 receptors. This is corroborated by study findings, which showed that the intravesical administration of NGF induces DO. These symptoms were reversed by NGF-neutralising antibodies, which also proved to inhibit overactivity induced by inflammation. This suggests that when TrkA receptors are blocked, the activity of capsaicin-sensitive neurons is reduced.
In addition to affecting TrkA and p75, NGF also modulates the functions of TRPV1, NK and voltage-gated sodium channels (Nav 1.8, SNS, PN3). It has been established that the activation of TrkA by NGF produces the expression of TRPV1 receptors, which suggests that the use of selective TrkA antagonists would inhibit afferent impulse activity. Although TrkA and p75 receptor blocking seems like an alternative of interest in OAB pharmacotherapy, it is important to bear in mind the influence of NGF on the trophic function of sympathetic neurons [15].

Corticotropin-releasing factor

It is a generally accepted fact that the hypothalamic-pituitary-adrenal (HPA) axis plays a significant role in the aetiopathogenesis of both depression and OAB. Medical literature often uses the informal term uropsychiatry, which emphasises the close relationship between these conditions. It has been demonstrated that the corticotropin-releasing factor (CRF) reduces the afferent impulse activity threshold of the micturition reflex and increases the contractile activity of the detrusor urinae. Its effects are mediated by endogenous ligands for CRF-R1. Clinical trials have confirmed that the areas characterised by a high CRF-R1 density, such as Barrington’s nucleus in brainstem amygdala, prefrontal cortex or hippocampus, play an important role both in response to stress factors and in controlling the micturition reflex. Corticotropin-releasing factor stimulates micturition, and selective CRF-R1 antagonists were found to reduce DO symptoms. Corticotropin-releasing factor also affects micturition at the spinal cord level. Indeed, it has been demonstrated that the administration of capsaicin, leading to the selective destruction of afferent C-fibres, also induces a decrease in CRF expression, which confirms its significant role in conducting afferent impulses from the bladder. Therefore, CRF-R1 seems to be an objective of interest in OAB treatment, especially in patients with depression as co-morbidity [16].

D3 vitamin receptors

D3 vitamin receptors have been found in the human bladder and urethra. They have been found both in the urothelial cells and in the detrusor smooth muscle cells. It has been proven that vitamin D analogues can affect the contractile activity of the detrusor through the up-regulation of Ca2+entry through L-type Ca2+ channels and by inhibiting ROCK signalling. Clinical trials have proven that the use of elocalcitol in patients with clinical OAB symptoms and the urodynamic diagnosis of DO leads to a reduced number of urinary incontinence episodes and the subjective improvement in patient perception of the bladder condition. However, no impact of this therapy has been found in relation to DO symptoms visible in urodynamic tests. The use of elocalcitol in patients with benign prostatic hyperplasia was demonstrated to result in reduced urgency and daytime and night-time frequency. On the other hand, patients with idiopathic overactive bladder who took elocalcitol experienced an increase in the bladder volume at the first desire to void and in the voided volume [17]. These findings suggest that vitamin D is involved in mechanisms that control suburothelial afferent nerves, which, in turn, regulate detrusor activity.

Rho-kinase inhibitors

Rho-kinase (ROCK) is serine/threonine kinases. Rho-kinase impacts on the tone of the bladder detrusor through several mechanisms, which can increase myosin light chain (MLC) phosphorylation by MLC phosphatase phosphorylation (inactivation), modify actomyosin interaction by activating LIM-kinase, which promotes actin fibre formation by inactivating the actin-depolymerisation factor cofilin, and also directly phosphorylate MLC.
The role of ROCK in bladder contractility is not restricted to its links with M receptors, as it was proven that it also has an impact on purinergic receptors and receptors for neurokinins and bradykinins. Rho-kinase pathways can change in pathological conditions such as bladder hypertrophy, hypertension and diabetes. It was demonstrated that ROCK inhibitors not only suppress bladder contractions induced by exogenous compounds, but also lower the basal tone of the bladder in the absence of stimulation, which can point to the role of the ROCK pathway in keeping the basal tone of the bladder. The evidence demonstrated that muscarinic acetylcholine receptor signal transduction pathway is linked to ROCK [18]. Due to the above, it appears that the pharmacological inhibition of the ROCK pathway leading to the inhibition of Ca2+ sensitisation and MLC phosphorylation can turn out to be a very effective option of the pharmacological treatment of OAB.

β3 adrenergic receptor agonists

β3 receptors are of crucial importance for the correct functioning of the bladder. When these are stimulated, adenylate cyclase is activated via a G protein, which leads to an increase in the intracellular concentration of cAMP and the subsequent activation of cAMP-dependent protein kinase A. This kinase, in turn, phosphorylates myosin light chains responsible for inhibiting interactions between actin and calcium-calmodulin-dependent myosin. An increased cAMP level also reduces Ca2+ concentration in cytoplasm. The clinical outcome of these changes is a significant increase in the functional volume of the bladder, which decreases micturition frequency. An mRNA analysis has shown that 97% of -adrenergic receptors in the human bladder are sub-type β3, and about 1.5% are sub-types 1 and 2 [19].
The detrusor muscle contracts when muscle contraction neurotransmitters (acetylcholine and ATP) are released, and, consequently, β3 receptor agonists do not prevent bladder voiding. Although by blocking M2 and M3 receptors anti-muscarinic preparations inhibit involuntary detrusor contractions and can produce micturition disorders, β3 receptor stimulation causes the bladder to relax during the urine collection stage, without affecting the micturition stage [20].

Conclusions

Previous pre-clinical studies have identified new objectives for OAB pharmacotherapy. Currently, clinical assessment is being carried out for organ-specific M3 receptor antagonists, β3receptor agonists, potassium channel opening compounds, and Rho-kinase inhibitors. Other alternatives include substances that affect afferent impulse activity, such as NK2, TRPV1 and P2X receptor antagonists. The advancement of knowledge on OAB pathophysiology has also made it possible to influence the CNS centres that regulate the micturition cycle by affecting dopamine, serotonin, glutaminergic or CRF receptors. It seems that these new options of pharmacological OAB treatment will facilitate the customisation of treatment on the basis of aetiopathogenetic mechanisms that lead to the development of disease symptoms.

Disclosure

Author reports no conflicts of interest.

References

1. Espey MJ, Downie JW. Serotonergic modulation of bladder function before and after spinal transection. Eur J Pharmacol 1995; 287: 173-177.
2. Yoshimura N, de Groat WC. Neural control of the lower urinary tract. Int J Urol 1997; 4: 111-118.
3. Yotsuyanagi S, Yokoyama O, Komatsu K, Kodama K. Expression of neural plasticity related genes in the pontine tegmental area in rats with overactive bladder following cerebral infarction. J Urol 2001; 166: 1148-1156.
4. Igawa Y, Mattiasson A, Andersson KE. Effects of GABA-receptor stimulation and blockade on micturition in normal rats and rats with bladder outflow obstruction. J Urol 1993; 150 (2 Pt 1): 537-542.
5. Shieh CC, Feng I, Bucknel SA. Functional implication of spare ATP-sensitive K(+) channels in bladder smooth muscle cells. Ex Pharmacol Ex Ther 2001; 296: 669-675.
6. Andersson KE, Weln AJ. Pharmacology of the lower urinary tract: basis for current and future treatments of urinary incontinence. Pharmacol Rev 2004; 56: 581-631.
7. Lecci A, Maggi CA. Tachykinins as modulators of the micturition reflex in the central and peripheral nervous system. Regul Pept 2001; 101: 1-18.
8. Ost D. Topography of the vanilloid receptor in the human bladder: more than just nerve fibers. J Urol 2002; 168: 293-297.
9. Lecci A, Giuliani S, Meini S. Nociceptin and the micturition reflex. Peptides 2000; 21: 1007-1021.
10. Moore KH, Ray FR, Barden JA. Loss of purinergic P2X(3) and P2X(5) receptor innervation in human detrusor from adults with urge incontinence. J Neurosci 2001; 21: 166-172.
11. Cardoso L, Lose G, McClish D. A systematic review of the effects of estrogens for symptoms suggestive of overactive bladder. Acta Obstet Gynecol Scand 2004; 83: 892-897.
12. Brady CM. An open-label pilot study of cannabis-based extracts for bladder dysfunction in advanced muitiple selerosis. Mult Scler 2004; 10: 425-433.
13. Chopra B. Expression and function of bradykinin B1 and B2 receptors in normal and inflamed rat urinary bladder urothelium. J Physiol 2005; 562: 859-871.
14. Truss MC. Initial clinical experience with the selective phosphodiesterase-I isoenzyme inhibitor vinpocetine in the treatment of urge incontinence and low compliance bladder. World J Urol 2000; 18: 439-443.
15. Zhang YH, Nicol GD. NGF-mediated sensitization of the excitability of rat sensory neurons is prevented by a blocking antibody to the p75 neurotrophin receptor. Neurosci Lett 2004; 366: 187-192.
16. Klausner A. Corticotrophin Releasing Factor reduce the micturition threshold when administered at central, spinal and peripheral levels. J Urol 2004; 171: 453-459.
17. Crescioli C, Morelli AM, Adorini L, et al. Human bladder as a novel target for vitamin D receptor ligands. J Clin Endocrinol Metab 2005; 90: 962-972.
18. Peters SL, Schmidt M, Michel MC. Rho kinase: a target for treating urinary bladder dysfunction? Trends Pharmacol Sci 2006; 27: 492-497.
19. Cerruto MA, Asimakopoulos AD, Artibani W, et al. Insight into new potential target for the treatment of overactive bladder and detrusor overactivity. Urol Int 2012; 89: 1-8.
20. Bhide A, Digesu GA, Fernado R, Khullar V. Mirabegron – a selective 3-adrenoreceptor agonist for the treatment of overactive bladder. Res Rep Urol 2012; 4: 41-45.
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