The Biochemical and Neurologic Basis for the Treatment of Male Erectile Dysfunction

Assistant Professor of Medicine (Clinician-Educator)

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Erectile Dysfunction

Vol. 296, Issue 2, 225-234, February 2001

The Biochemical and Neurologic Basis for the Treatment of Male Erectile Dysfunction

Robert B. Moreland, Gin Hsieh, Masaki Nakane and Jorge D. Brioni

Neurological and Urological Diseases Research, Abbott Laboratories, Abbott Park, Illinois

	Introduction

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

Male erectile dysfunction (MED) is defined as the "inability to achieve or maintain an (penile) erection adequate for sexualsatisfaction" (National Institutes of Health Consensus Statement,1993). Erectile dysfunction occurs in varying degrees in an estimated20 to 30 million U.S. men and is associated with adverse effectson quality of life, particularly personal well being, family,and social interrelationships (Laumann et al., 1999; Johanneset al., 2000). The worldwide prevalence of MED has been estimatedat over 152 million men, and the projections for 2025 suggesta prevalence of approximately 322 million with MED. Recent reportsof quality of life data suggest that the importance of MED incontributing to other chronic health conditions such as depressionhas been largely underestimated (Laumann et al., 1999).

The treatment of MED has been revolutionized over the last decade from only surgical options (penile prostheses or revascularization)to intracavernosal and intraurethral administered agents [e.g.,prostaglandin E₁ (PGE₁)_, papaverine, phentolamine] that pavedthe way to an effective oral therapy such as sildenafil. The clinicalefficacy of oral agents such as sildenafil, apomorphine, phentolamine,IC351, and vardenafil represent the beginnings of noninvasivepharmacological treatment for MED.

Over the past 25 years, research on MED has focused on the mechanisms of corpus cavernosum smooth muscle relaxation, and thiswork has provided the basis for our current knowledge of the physiologyof erection. On the other hand, the fields of experimental psychologyand neuroscience have also unraveled critical information on thebrain areas and the neuroanatomical connections regulating sexualbehavior. In view of the latest developments in the clinical arenaand the potential utility of several novel molecular targets forthe pharmacological treatment of MED (Moreland et al., 2000),this review will summarize biochemical and neural mechanisms thataffect corpus cavernosum smooth muscle tone and penileerection.

	Epidemiology

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

Erectile dysfunction or impotence throughout most of the 20th century was considered predominantly as a psychological condition.The National Institutes of Health Consensus Development Panelon Impotence recognized that although it is difficult to separatepsychogenic effects from organic disease, vasculogenic impotenceaccounts for about 75% of MED patients (National Institutes ofHealth Consensus Statement, 1993). In the literature before 1993,the term impotence is used and encompasses all forms of MED. Epidemiologicalstudies suggest an association between impotence and increasingage and/or peripheral vascular disease (Laumann et al., 1999;Johannes et al., 2000). One recent study examined a random populationof 1709 noninstitutional men aged 40 to 70 in the Boston area(Feldman et al., 1994; Johannes et al., 2000). The overall probabilityof some degree of sexual dysfunction was 52%. After adjustingfor age, impotence was correlated with heart disease (39%), diabetes(28%), and hypertension (15%) as well as other vascular risk factorssuch as cigarette smoking. Treated heart disease (vasodilatingdrugs 36%), use of cardiac drugs (28%), and use of antihypertensiveagents were also strongly associated. Correlations were also foundwith untreated medical conditions such as ulcers (18%), arthritis(15%), and allergies (12%). The follow-up study almost 9 yearslater allowed estimation of a risk of MED of about 26 cases per1000 men annually, with correlation with vascular risk factors(heart disease, diabetes, and hypertension), age, and lower education(Johannes et al., 2000).

	Physiology of Penile Erection

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

The tone of the corpus cavernosum smooth muscle is controlled by complex biochemical events coordinated at the level of theperipheral and central nervous system (Figs. 1 and 2). Sympathetic,parasympathetic autonomic, and somatic nerves control the toneof the corpus cavernosum smooth muscle and its vascular systemvia neuroanatomical connections that are an integral part of theinnervation of the lower urinary tract (de Groat and Booth, 1993;Andersson and Wagner, 1995).

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Fig. 1. Peripheral mechanisms involved in flaccidity and erection. A conceptual framework depicting mechanisms involved in regulating corpus cavernosum smooth muscle tone as well as the mechanisms of action of peripheral pharmaceutical treatments for MED. AC, adenylate cyclase; AA, arachidonic acid; eNOS, endothelial NOS; GC, guanylate cyclase; L-Arg, L-arginine; IP3, inositol trisphosphate; PLC, phospholipase C.

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Fig. 2. Neuroanatomical connections and putative neurotransmitters in the central nervous system involved in penile erection. MFB, medial forebrain bundle; OXYT, oxytocin; PAG, periaqueductal gray matter; ZI, zona incerta; MPOA, medial preoptic area; PVN, paraventricular nucleus; NO, nitric oxide.

Peripheral Control of Penile Erection. The penis is composed of three bodies of erectile tissue: the corpus spongiosum, encompassing the urethra and terminatingin the glans penis, and the two corpora cavernosa, which functionas blood-filled capacitors, providing structure to the erect organ(de Groat and Booth, 1993; Andersson and Wagner, 1995). The corpuscavernosum is a unique vascular bed consisting of sinuses (thetrabeculae) whose arterial blood supply arises from the resistancehelicine arterioles, which in turn are fed from the deep penilecavernosal artery. The trabeculae are drained by the emissaryvenules that in turn communicate with the cavernosal veins. Thetrabeculae, while arterially fed, have measured blood PO₂ of 20to 40 mm Hg when the penis is in the flaccid state (Kim et al.,1993).

Ultimately, corpus cavernosum smooth muscle tone regulates penile flaccidity and erection (Fig. 1). During flaccidity, thehelicine resistance arterioles are constricted, principally through $alpha$ -adrenergic mechanisms (Traish et al., 1999

). Sympathetic efferents,via T11 through L2 including the pudendal nerve, supply a norepinephrine-inducedtone in the corpus cavernosum, insuring flaccidity. Within thecorpus cavernosum, $alpha$ _1a-, $alpha$ _1d-, $alpha$ _2a-, and $alpha$ _2c-adrenoceptors areexpressed in the smooth muscle, while $alpha$ _1b- and $alpha$ _2b-adrenoceptorsare expressed in the endothelium and/or nerves (Traish et al.,1999

; Fig. 1). Endothelin (ET) synthesized both by the smoothmuscle and endothelium may also play an autocrine/paracrine rolein the maintenance of smooth muscle tone. Both types of endothelinreceptors (ET_A and ET_B) are present in corpus cavernosum tissue(Andersson and Wagner, 1995

). Other vasoconstrictors in this tissueinclude prostaglandin F₂ (PGF₂) and thromboxane A₂,synthesized both by smooth muscle and endothelium. Both PGF₂and thromboxane A₂ potently constrict corpus cavernosum stripsin organ baths and may be elevated in vascular complications suchas diabetes and hypercholesterolemia. Functional M₂ and M₄ muscarinicacetylcholine (ACh) receptors have been demonstrated in humancorpus cavernosum smooth muscle and cultured smooth muscle cells(Nehra et al., 1999

). As these receptors are coupled to G_i proteins,they would be expected to result in corpus cavernosum smooth musclecontraction. However, carbachol relaxes phenylephrine-precontractedhuman corpus cavernosum strips in organ baths, and this processis thought to proceed through M₃ receptors on the endothelium.In this case, ACh increases intracellular calcium via M₃ receptors,which in turn activate endothelial nitric-oxide synthase (NOS)(Andersson and Wagner, 1995

). The endothelial synthesis of nitricoxide (NO) acts on the underlying smooth muscle in an autocrinefashion to potentiate corpus cavernosum smooth musclerelaxation.

Penile erection is the end result of smooth muscle relaxation, and this relaxation can be initiated by sensory stimulationthat activates central nervous system (CNS) pathways (de Groatand Booth, 1993

; Andersson and Wagner, 1995

). These processesactivate peripheral nerves innervating the penis, which includecholinergic, nonadrenergic-noncholinergic (NANC; e.g., NO), vasoactiveintestinal peptide (VIP)-, and potentially calcitonin gene-relatedpeptide (CGRP)-containing nerves entering the pelvic plexus fromS2-S4. NO from NANC nerves mediates the dilation of the helicinearterioles as well as the trabecular smooth muscle. The influxof arterial blood is associated with a rise in blood PO₂ (90-100mm Hg), and this increase in oxygen tension further activatesNOS as well as prostaglandin G/H synthase, which both utilizemolecular oxygen as a substrate (Kim et al., 1993

). Shear stressand muscarinic ACh receptors on the corpus cavernosum endotheliumincrease intracellular calcium, activating the endothelial NOSand stimulating the production of NO. NO diffuses into the smoothmuscle, further enhancing relaxation (Fig. 1).

As the corpus cavernosum sinuses relax and fill with blood, intracavernosal pressure and volume increase. Veno-occlusion developsthrough stretching and compressive forces by expandable corpuscavernosum tissue on subtunical venules, and the penis becomesa blood-filled capacitor (Andersson and Wagner, 1995

). VIP- andCGRP-mediated pathways proceed through cAMP-dependent pathwaysconcomitant with the NANC nerve-mediated pathways and also contributeto corpus cavernosum smooth muscle relaxation. VIP and CGRP receptorsremain to be fully characterized in this tissue. PGE is synthesizedby the corpus cavernosum endothelial and smooth muscle cells andbinds to specific PGE (EP) receptors on the smooth muscle, whichcan also increase intracellular cAMP levels and potentiate smoothmuscle relaxation. PGE can bind to four different pharmacologicclasses of receptor, and all four are expressed in the penis (Morelandet al., 2000

). Both EP₂ and EP₄ are coupled to G_s and are probablyresponsible for the increased cAMP synthesis observed in tissuesand in cultured smooth muscle cells when these are treated withexogenous PGE₁ (Narumiya et al., 1999

). Research continues toelucidate other receptors and potential pathways for mediatingcorpus cavernosum smooth muscletone.

While the pathways involved in smooth muscle myosin phosphorylation and dephosphorylation that are fundamental for corpuscavernosum smooth muscle tone remain to be elucidated, it is clearthat intracellular calcium as well as ion channels play a keyrole. K_ATP, Maxi K, L-type calcium channels, and sodium potassiumATPase have all been identified in corpus cavernosum smooth muscle.K_ATP channel openers like cromakalin can relax corpus cavernosumstrips in organ baths, and nicorandil can relax corpus cavernosumalbeit by a dual mechanism that includes K_ATP channel openingand guanylate cyclase activation (Hsieh et al., 2000

). TransfectingMaxi K channels into aging rat corpus cavernosum has been shownto improve erectile function (Christ et al., 1998

The relative importance of the cAMP and cGMP pathways is still unclear, but recent studies have observed that mice lackingcGMP-dependent protein kinase I (PKG-I) fail to reproduce (Hedlundet al., 2000

). Corpus cavernosum strips from these mice do notrelax in organ baths upon activation of the NO-cGMP cascade. However,forskolin, which directly activates adenylate cyclase and thecAMP pathway, relaxes phenylephrine-precontracted tissues, althoughto a significantly lesser degree than in the wild-type mice. Asthe cAMP system remained intact, these data demonstrate that thecAMP pathways alone cannot compensate for the cGMP deficienciesin vivo. Alternatively, PKG (cAMP/cGMP cross-talk) may be essentialin some portion of the adenylate cyclase signaling pathway inthesecells.

Central Mechanisms Controlling Penile Erection. The neural pathways involved in penile erection are just beginning to be integrated into a unified body of knowledge as therole of specific CNS pathways is corroborated by experimentalfindings from independent laboratories. The different areas inthe brain and the neuroanatomical connections presently knownto regulate penile erection are shown diagrammatically in Fig.2. External information can stimulate sexual activity via thedifferent sensory (visual, olfactory, tactile, and auditory) pathwaysthat, with the exception of the olfactory system, reach the correspondingcortical areas and then project to polymodal cortical associationareas. The piriform and entorhinal cortexes have extensive neuronalconnections with limbic structures like the amygdala (de Groatand Booth, 1993). Lesions of the medial amygdala significantlyimpaired copulatory behavior in rats, while bilateral lesionsof the temporal lobes including the amygdala induced a syndromeof hypersexuality and frequent penile erections in monkeys knownas the Kluver-Bucy syndrome (Kluver and Bucy, 1938). Similar behavioralchanges in sexual behavior have also been observed in humans,suggesting that the amygdala plays an important role regulatingmale sexual activity besides its participation in learning, memory,and the control of emotional behavior (Brioni, 1993).

Connections between the amygdala and midbrain structures like the periaqueductal gray and the hypothalamus have been describedin several species. Stimulation and electrolytic lesions of theperiaqueductal gray modulate sexual activity as well as the selectivelesioning or stimulation of the medial preoptic area (MPOA) andthe paraventricular nucleus (PVN) of the hypothalamus in the rat(McKenna, 1998

). The MPOA and PVN nuclei play a critical rolein sexual behavior as bilateral lesions of these areas completelyeliminate male sexual behavior; this effect is also observed afterlesion of the medial forebrain bundle, the major efferent pathwayof the hypothalamic centers to the midbrain. Although the primaryefferents of the MPOA project to the midbrain area via the medialforebrain bundle, the MPOA also sends projections to the PVN.

The zona incerta is a diencephalic structure that represents the rostral extension of the reticular formation. The incerto-hypothalamicdopaminergic pathway (originally described as the A13 group) arisesfrom the medial part of the zona incerta and innervates the amygdala,the PVN, and the MPOA nuclei. Substantial preclinical evidencedemonstrate that central dopamine (DA) plays a role in penileerection in animals. Systemic administration of DA receptor agonistslike apomorphine, quinpirole, lisuride, quinelorane, and 3-PPPfacilitate penile erection in rats and rabbits (Bitran and Hull,1987

), an effect blocked by haloperidol, a central DA antagonist.As the erectogenic effect cannot be blocked by domperidone, aperipheral DA antagonist, it is believed that the proerectileeffect of DA agonists is centrally mediated (Morales et al., 1995

).Systemic injections of apomorphine increase intracavernosal pressurein awake rats, and this effect can be blocked by bilateral transectionof the pudendal or cavernous nerves (Andersson et al., 1999

).Intracerebroventricular injections of apomorphine as well as localizedinjections in the hypothalamus facilitate penile erections, whileinjections in the striatum and the nucleus accumbens do not reachsimilar efficacy (Andersson et al., 1999

). Direct injections ofapomorphine into the PVN of the hypothalamus significantly increaseintracavernosal pressure in rats (Chen et al., 1999

). These datasuggest that the incerto-hypothalamic dopaminergic projectionthat innervates both the MPOA and PVN of the hypothalamus playsan important role regulating male sexual activity. The participationof other DA pathways cannot be completely ruled out as the mesolimbicand mesocortical DA systems play significant roles in motivation,emotional, and reward mechanisms (Bitran and Hull, 1987

; Melisand Argiolas, 1995

DA agonists increase NO in the PVN of the hypothalamus. This suggests a role for the NO-cGMP system in the CNS besides itsaction at the level of the cavernosal smooth muscle (Anderssonet al., 1999

; Sato et al., 2000

). A potential site of action ofNO is the PVN in the hypothalamus as administration of nitroglycerinor L-arginine in the PVN induces penile erections, and injectionsof N-nitro-L-arginine methyl ester (L-NAME) in the PVN block apomorphine-and oxytocin-induced effects in rats (Argiolas and Melis, 1995

).The central role for NO is further emphasized in studies in whichthe phosphodiesterase 5-selective inhibitor sildenafil was injectedintrathecally in a rat animal model (Sato et al., 2000

). A significantincrease in MPOA-stimulated erections (monitored by intracavernouspressure increases) was noted in the presence of sildenafil. Itis unknown whether sildenafil citrate crosses the blood-brainbarrier in humans and exerts a CNS effect on penile erection.However, in clinical trials, sildenafil did not have a significanteffect on libido or desire, both CNS measures (Goldstein et al.,1998

). These specific actions in the PVN suggest that NO activityin the PVN is a common mediator of the effects of several centralneurotransmitters on penile function (Argiolas and Melis, 1995

).The central NO-cGMP system can regulate penile erection in viewof the experimental evidence in rats and could represent a potentialtarget for the development of new therapeutic agents for the treatmentof MED.

The proerectile effect of DA agonists may also be related to their ability to release oxytocin. The doses of apomorphine thatinduce penile erection also increase plasma levels of oxytocin,and oxytocin antagonists can block apomorphine-induced erections.Haloperidol blocks apomorphine-induced erections, but it is unableto block oxytocin-induced erections, indicating that oxytocinrelease is a downstream neurochemical event related to the proerectileaction of apomorphine (Carter, 1992

Oxytocinergic neurons from the parvocellular division of the PVN specifically project to the spinal cord, a paraventriculo-spinalprojection to thoracolumbar and lumbosacral spinal neurons thatcontrol penile erection in rats (Veronneau-Longueville et al.,1999

). Oxytocin induces a significant facilitatory effect on penileerection when injected in the PVN. The proerectile effect of oxytocincan be blocked by specific oxytocin antagonists and by $omega$ -conotoxin,indicating that this effect is mediated by oxytocin receptorslinked to voltage-dependent calcium channels (Argiolas and Melis,1995

Limbic structures send projections to areas of the pons-medulla that are critical for regulation of male sexual and urinaryfunction. The MPOA provides a dense and selective innervationto discrete regions in the pons, namely Barrington's nucleus andsurrounding areas of the locus coeruleus. Barrington's nucleusis believed to be a regulator of pelvic visceral function as itprojects to sacral parasympathetic nucleus known to regulate themicturition reflex and gastrointestinal and genital function (Valentinoet al., 1999

). Terminals from neurons located in Barrington'snucleus form excitatory synapses with preganglionic parasympatheticneurons, indicating that it exerts a direct excitatory effecton pelvic function probably by releasing corticotrophin-releasingfactor. Spinal and brainstem neurons that innervate penile muscleshave been identified by trans-neuronal tracing techniques. Pseudorabiesvirus injection in penile muscles labeled spinal interneurons,spinal sympathetic, and parasympathetic preganglionic neurons,as well as neurons in the raphe, periaqueductal gray area, locuscoeruleus, and Barrington's nucleus (McKenna, 1998

). Electricalstimulation of the Barrington's nucleus slightly increased intracavernosalpressure in decerebrate rats, while stimulation of areas ventrolateraland caudal to the Barrington's nucleus significantly increasedintracavernosal pressure, demonstrating their role in male sexualfunction (Moreland et al., 2000

). The sacral projections of theBarrington's nucleus, its connection to the locus coeruleus, andthe afferent projections coming from the periaqueductal gray,MPOA, lateral hypothalamus, and cortex, allow it to integratelumbosacral parasympathetic activity and limbic/forebrain activityto coordinate pelvic visceral information and behavioral responses(Valentino et al., 1999

Anatomical studies have also identified an important source of 5-HT neurons related to sexual function, as injection of pseudorabiesvirus into penile tissue consistently labeled neurons in the nucleusparagigantocellularis (nPGi). The projection from the nPGi tothe sacral spinal cord is mainly serotoninergic, and lesions ofthe nPGi facilitate penile reflexes in rats (McKenna, 1998

). Theeffect of serotoninergic ligands on male sexual behavior has beenextensively investigated due to the availability of a large numberof agonists and antagonists. In vivo pharmacological studies showedthat MK-212, TFMPP, mCPP, and Ro60-0175 facilitate penile erectionin rats, while PAPP, 5-MeOMDT, ORG-6997, and BW723C86 are inactive(Moreland et al., 2000

). Molecular biological and biochemicalefforts have allowed the present classification of 5-HT receptorsin seven families (5-HT_1-7) comprising a total of 17 receptorsubtypes (Barnes and Sharp, 1999

). The available information suggeststhat 5-HT_2C receptors are related to the facilitatory effect of5-HT and that 5-HT_1A receptors exert inhibitory effects on malesexual behavior. A detailed understanding of the role of the 5-HTsubtypes on penile erection could be obtained after further pharmacologicalevaluation with available subtype-selectiveagents.

The proerectile effects of yohimbine ( $alpha$ ₂-adrenoceptor antagonist) in humans indicate that central noradrenergic systems couldplay a role in male sexual behavior. However, the efficacy ofyohimbine in humans is modest, and it may be related to arousalor motivational aspects of sexual behavior (Morales et al., 1995

).Recent data on the proerectile effect of phentolamine in phaseIII trials in humans has renewed interest in this area (Wyllieand Andersson, 1999

). It is generally assumed that the proerectileeffect of phentolamine is due to the blockade of $alpha$ -adrenoceptorsin the corpus cavernosum (Traish et al., 1999

), but the blockadeof adrenoceptors located in spinal or brain sites cannot be excluded.A recent report on the lack of effect of the adrenergic antagonistRo70-004/003 (Choppin et al., 2000

) continues to demonstrate that $alpha$ -adrenoceptor blockade alone might not be useful for the treatmentof MED.

The participation of other central neurotransmitters/neuromodulators and hormones (ACh, glutamate, $gamma$ -aminobutyric acid, adrenocorticotrophichormone, melanocyte-stimulating hormone, opioids, prolactin) hasalso been documented in relation to male sexual behavior and hasbeen the subject of several reviews (Dornan and Malsbury, 1989

;de Groat and Booth, 1993

; Andersson and Wagner, 1995

). Male sexualfunction is a complex behavioral phenomenon that is unique toeach animal species, and for that reason extrapolations from animal(rat, rabbit, or monkey) to human sexual function should be madewith care. Penile erection is part of a complex behavioral repertoirerelated to physiological and psychological aspects like motivation,reward, interaction with a receptive female, and ejaculation.A detailed knowledge on the central neurotransmitter systems involvedin the control of sexual function will certainly be importantfor the discovery of novel pharmacological agents for the treatmentof MED.

	Pathophysiology of Male Erectile Dysfunction

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

MED can be classified into four types: 1) psychogenic, 2) vasculogenic or organic, 3) neurologic, and 4) endocrinologic. MEDcan also result as a side effect of pharmacological treatmentssuch as antihypertensive medications ( $beta$ -adrenoceptor blockers),serotonin reuptake inhibitors, diuretics, and cardiac medications(Meinhardt et al., 1997).

There are currently two hypotheses of pathophysiology: one proposes a structural basis of MED, while the other focuses onmetabolic imbalances in the corpus cavernosum. The penis is comprisedof soft tissue and functions as a blood-filled capacitor of sufficientrigidity during erection for vaginal penetration (Nehra et al.,1999). The two bodies of erectile tissue, the corpora cavernosa,that are integral to this function are composed of a specializedvascular bed, which has a high content of connective tissue (48-55%).The corpus cavernosum smooth muscle cells also synthesize connectivetissue that contributes to the structural integrity of the corpora,and a functional corpus cavernosum smooth muscle/connective tissueratio is necessary for veno-occlusion (Moreland, 1998). The implicationsof this finding are that regardless of the amount of corpus cavernosumsmooth muscle relaxation, veno-occlusion cannot occur in somepatients due to higher content of connective tissue and an inabilityto occlude the drainingvenules.

One area of active research in MED is to identify vasoactive factors, cytokines, autacoids, and/or neurotransmitters thatmay play a role in maintaining the connective tissue/smooth musclebalance (Moreland, 1998). Among the potential candidates are transforminggrowth factor $beta$ ₁ (TGF- $beta$ ₁) and prostaglandin E, both of which aresynthesized by the corpus cavernosum smooth muscle cells. Thesevasoactive substances are regulated by oxygen tension; TGF- $beta$ ₁is induced under lower oxygen tension conditions consistent withflaccidity, while PGE is synthesized under conditions consistentwith oxygen tensions during erection. In human corpus cavernosumsmooth muscle cells in culture, TGF- $beta$ ₁ can induce a 2.5- to 4-foldincrease in collagen synthesis in these cells, and this synthesiscan be repressed by a single dose of PGE₁. While these are invitro observations, it is interesting to note that nocturnal peniletumescence may provide a daily oxygenation of the corpus cavernosumregardless of sexual activity that may help to maintain a functionalcorpus cavernosum smooth muscle/connective tissue balance (Moreland,1998). While research has yet to supply an answer to a numberof the questions involved, strategies to alter the corpus cavernosumstructure could be a future means to treat MED.

An alternate hypothesis regarding the pathophysiology of MED is attributed to a metabolic imbalance between contractile andrelaxatory factors in the corpus cavernosum (dysfunctional antagonism;Melman and Gingell, 1999). Under normal physiological conditionsin the penis, contractile factors (norepinephrine, ET, and contractileprostanoids) are in balance with relaxatory factors (NO, VIP)such that when the contraction of the corpus cavernosum diminishesand relaxatory factors are present, erection ensues. In the caseof dysfunctional antagonism, contractile factors predominate,are overexpressed or relaxatory factors are inhibited, such thatthe trabecular smooth muscle remains contracted and the penisremains flaccid. However, in most cases of vasculogenic MED, adecrease in NO production and release probably plays some rolein the dysfunction. In actual practice, the pathophysiology oferectile dysfunction probably has both structural and metaboliccomponents.

	Experimental Approaches to Study MED

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

In Vitro Models. As penile erection involves relaxation of corporal vascular and smooth muscle during sexual stimulation, the application ofin vitro models of isolated corpus cavernosal tissue has significantlyenhanced our understanding of the biochemical events at the cellularlevel (Andersson and Wagner, 1995). From a scientific perspective,these models allow dissection of the various neurotransmittersand vasoactive factors involved in this process and the signaltransduction pathwaystherein.

There are two major in vitro models currently in use: muscle strips in organ baths and cell cultures derived from the corpuscavernosum. Central nervous system experiments involving brainslices have yet to be used with great utility in this area ofresearch. Sources of tissues for experimentation have relied onhuman surgical biopsies of corpus cavernosum obtained at the timeof penile prosthesis insertion in men with MED or from penilecancer patients undergoing partial penectomy. The restricted availabilityof human penile erectile tissues has lead to the use of cavernosaltissues isolated from rabbit as a major in vitro model both forscreening and for detailed analysis of mechanisms previously demonstratedto exist also in human tissue. Similar information has been obtainedby using tissues from mouse, rat, dog, horse, and pig (Anderssonand Wagner, 1995

; Giuliano et al., 1999

). The advantages of thismethod include ease in preparation, minimal equipment requirements,and the fact that reproducible concentration-effect curves canbe obtained when studying either contractile or relaxant agents.The response to pharmacological stimulation by adding contractingagents such as phenylephrine, potassium chloride, or other contractilefactors is the most common method used to contract the corpuscavernosal tissues in vitro to assess potency and efficacy ofrelaxing agents. Smooth muscle strip contractions in organ bathpreparations can also be achieved by electric field stimulationsimilar to that used to study neural responses (Kim et al., 1993

During the last decade, primary cultures of cavernosal cells from human or animals have provided useful insights into factorsthat can modulate the intracellular events. These studies haveincluded cultures of human corpus cavernosum endothelial as wellas smooth muscle cells (Moreland et al., 2000

). Such experimentshave been helpful in defining which receptors are localized ineach cell type within the corpus cavernosum and in understandingthe association to specific signal transduction mechanisms. Asthe degree of smooth muscle tone is mainly controlled by the intracellularCa²⁺ concentration (Horowitz et al., 1996

), any event that limitsCa²⁺ entry to the cell or release of Ca²⁺ from intracellular storage will ultimately have a significantimpact on corporal smooth muscle tone (Andersson and Wagner, 1995

;Stief et al., 1997

). Two main intracellular messenger molecules,cAMP and cGMP, modulate the continuous transmembrane Ca²⁺ flux through voltage-dependent calcium channels that are criticalto the sustained contraction of corporal smooth muscle. Studiesin tissue strips and primary cell cultures have provided the availableinformation on intracellular events described in Fig. 1.

In Vivo Animal Models. Intracavernosal pressure (ICP) changes in animal models as an index of penile erection have greatly enhanced our understandingof basic erectogenic pathways and systems. As discussed above,ICP increases as the corpus cavernosum relaxes and fills withblood, and the plateau of ICP is indicative of successful veno-occlusionand functional erection. Some researchers prefer ICP models forstudies of penile erection to in vitro organ bath chamber experiments.Both approaches have merit in dissecting various aspects of maleerectile physiology. Advantages of the ICP model aside from anintact animal preparation include the ability to perform continuousmonitoring of ICP, duration of erection, and concomitant measurementof arterial pressure. A combination of intracavernosal drug administrationand selective nerve stimulation or ablation has greatly increasedunderstanding of the neurophysiology of erection (Andersson andWagner, 1995; Christ et al., 1998; Sato et al., 2000). Many physiologicalstudies on penile erection are carried out in larger animals,including monkeys, dogs, and cats (Giuliano et al., 1999). Thelarge volume of tissues and prominent peripheral nervous and bloodvessel supplies to the penis in these animals provide convenientaccess for pharmacological, neurological, and hemodynamic evaluations.The rabbit model has also been used for studying the erectileresponse to the intracavernosal injection of vasoactive drugs.The important differences among species should be considered forevery specificstudy.

The rat has been a primary animal model for studying penile erection in vivo. Mating tests have been accepted as a standard,and the parameters of mating tests are well established (cup,flips, number of intromissions, latency to mounting, and latencyto ejaculation) (Bitran and Hull, 1987

; de Groat and Booth, 1993

;Pfaus, 1999

). These observational tests document a range of interlinkedbehaviors among which erection is one component. The female rat,ovariectomized and primed with estradiol before the copulatorytesting, responds to the mounting from the male rat with the lordosisresponse (a primary behavioral component of female sexual behaviors):dorsoflexion of spine and deflection of the tail to one side,allowing vaginal access to the male (Bitran and Hull, 1987

; Pfaus,1999

Since subcutaneous injection of apomorphine causes an observable erectile response in nearly all normal rats, apomorphineadministration can be used as a standard challenge to producea quantifiable erectile response. This simple model can also beused to determine augmentation and synergy with different agentsthat when administered alone do not directly induce erection (Moraleset al., 1995

; Giuliano et al., 1999

). An example of such a studyis the recent report that apomorphine augments the effects ofsildenafil on ICP following nerve stimulation in a rat model (Anderssonet al., 1999

). The model can also be applied to monitor ICP oroxygen tension-mediated changes if one uses anesthetizedrats.

Erectile dysfunction is associated with vascular risk factors (Feldman et al., 1994

; Laumann et al., 1999

; Johannes et al.,2000

). Unfortunately, by the time a patient presents with MED,the endpoints of disease may be well on their way to being obtained.Animal models of disease offer an opportunity to understand themechanisms of pathophysiology with the progression of the disease.A variety of potential animal models have been described basedon associated risk factors, especially diabetes, aging, atherosclerosis,and other vascular disorders (Giuliano et al., 1999

). Erectiledysfunction is a common and devastating consequence of diabetesin adult men. Studies in animal models of diabetes have revealedpathological changes in the penile arteries, morphological alterationsof autonomic nerves, and a depletion of neurotransmitters withinthe corpus cavernosum. Several strategies have been developedin chemical-induced diabetes (hyperglycemia-dependent) in ratsor rabbits to analyze neural, vascular, and biochemical changes.Both CNS (hypothalamic MPOA) and peripheral (pelvic nerve) nervestimulation (Giuliano et al., 1999

) have described streptozotocin-induceddiabetes in rats as a neuropathy model to assess penile erection.Rabbits fed with alloxan for 8 weeks to destroy pancreatic isletcells have also been established as a MED chronic diabetic modelthat mimics the impaired NOS response as well as induction ofconstrictor prostanoids. Hypercholesterolemia is a cardiovascularrisk factor and also a predictor of MED in both humans and animalmodels (Feldman et al., 1994

; Johannes et al., 2000

). Rabbitsfed with a diet enriched with cholesterol for 16 weeks are ableto produce functional hypercholesterolemia, and the structuraland morphometric changes within the cavernosal tissues have beencharacterized (Giuliano et al., 1999

). Although this type of modelcan be used in the identification of agents that affect the underlyingdisease progression rather than of agents that produce acute symptomaticrelief, it is limited by the extreme conditions to induce themodel. Another important aspect of drug discovery is the designof clinical trials. A review of recent clinical trials for MEDand tools for assessing efficacy have been recently published(Moreland et al., 2000

	Advances in the Treatment of MED

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

A variety of drug targets have been proposed for the potential treatment of MED. The large number and diversity of targetsis indicative of the significant interest in the pharmaceuticalarena to identify novel agents for MED, as it is still an unmetmedical need for a substantial portion of patients. In view ofthe recent success of sildenafil, a major area of activity isin the development of PDE5 inhibitors. There is also interestin several other molecular targets at the smooth muscle levelas well as in the CNS. Drugs used presently in clinical practiceare shown in Table 1 and Fig. 1. Peripheral treatment of erectiledysfunction focuses on enhancing corpus cavernosum smooth musclerelaxation as described below.

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TABLE 1
Drugs used in the treatment of male erectile dysfunction

Agents That Increase cAMP Synthesis. The finding that erection proceeds through mechanisms that increase intracellular levels of cyclic nucleotides (cAMP and cGMP)have allowed the development of several classes of therapeuticagents. The first class of agents that increases intracellularcAMP synthesis works either via specific cell surface receptors,which are then coupled to adenylate cyclase, or drugs that activateadenylate cyclase directly. Prostaglandin E₁ binds to specificEP receptors on the corpus cavernosum smooth muscle cells, elevatingintracellular cAMP levels by coupling through G_s protein mechanismand activation of adenylate cyclase (Narumiya et al., 1999). Thisincrease in cAMP activates a signal transduction cascade whoseultimate result is phosphorylation/dephosphorylation events withthe actin-myosin system leading to smooth muscle relaxation (Fig.1).

PGE₁ administered via intracorporal injection was the first therapeutic agent approved by the FDA to treat MED (Nehra et al.,1999

; Spahn et al., 1999

). As an injectable agent, PGE₁ is effectivealone as well as in combination with other agents. Unlike papaverine,and papaverine in combination with phentolamine, PGE₁ injectionis associated with a much lower incidence of corpus cavernosalfibrosis (Spahn et al., 1999

). Formulations of PGE₁ with $alpha$ -cyclodextrindesigned to enhance its solubility and delivery have been reported(Spahn et al., 1999

). Undue side effects of the injection of PGE₁include penile pain (approximately 25% of patients), an effectprobably related to the lack of selectivity of PGE₁ for the fourEP receptor subtypes (Narumiya et al., 1999

). Pain associatedwith PGE₁ administration may be due to cross-reactivity with EP₁receptors in the corpus cavernosum. Another side effect can beprolonged erections (observed in about 4% of patients), whichcan result in veno-occlusive priapism (Spahn et al., 1999

). Onthe other hand, PGE₁ can have a prophylactic effect on the recoveryof erectile function following surgery. Radical retropubic prostatectomy,even when performed by nerve-sparing techniques, often resultsin either a temporary or permanent loss of erectile function.A recent prospective study of nerve-sparing radical prostatectomypatients found that patients treated with postoperative, prophylacticintracavernosal PGE₁ injections were more likely to recover erectilefunction than those on placebo (Nehra et al., 1999

Intraurethral delivery of PGE₁ has been proposed to mediate erection by drug entry via the urethra and into the draining cavernosalvenules and the corpus cavernosum by retrograde flow (Nehra etal., 1999

). Recently, this therapy was improved by the inclusionof a restriction band applied to the base of the penis beforeinsertion of the suppository. The dosages for PGE₁ range from25 to 100 times that for corporal injection. While this meansof drug delivery alleviates some of the unpleasantness of corporalinjection, recent studies suggest that efficacy is low. This mayreflect clinical trial selection of MED patients with minimaldysfunction followed by marketing to a wider range of MED etiologiesor poor clinical trial endpoints. A recent development in intraurethraltherapy has been the combination of the $alpha$ -antagonist prazosinand PGE₁ (Nehra et al., 1999

VIP also increases intracorporal smooth muscle cAMP synthesis by coupling with specific VIP receptors. While VIP may be oneof the neurotransmitters involved in mediating erection, intracorporalinjection of VIP alone does not result in erection (Anderssonand Wagner, 1995

). Injectable VIP/phentolamine combinations arein clinical trials in the United Kingdom. Forskolin, a plant diterpenefrom Coleus forskolii, directly activates adenylate cyclase bya mechanism independent of G-protein coupling. Forskolin has beenshown to elevate cAMP levels in human corpus cavernosum smoothmuscle cells in culture and in particular can augment the effectsof PGE. This property may result in an agent that is useful inmultidrug formulations to improve efficacy (Nehra et al., 1999

$alpha$ -Adrenoceptor Antagonists. Sympathetic $alpha$ -adrenoceptors are thought to maintain the flaccidity of the corpus cavernosum (Andersson and Wagner, 1995; Traishet al., 1999), and blockade of these receptors by $alpha$ ₁-, $alpha$ ₂-, ormixed $alpha$ -adrenoceptor antagonists have been used to treat MED.In contrast to the general view that $alpha$ -adrenoceptor antagonistsact only at the level of the smooth muscle, these agents can acteither in the CNS or peripherally pre- andpostsynaptically.

Phentolamine has been administered intracavernosally as a single medication, but it is most effective in combination therapy(Spahn et al., 1999

). Oral phentolamine has undergone clinicaltrials in Europe and in the United States (Wyllie and Andersson,1999

). A recent study to determine whether the oral $alpha$ -adrenoceptorantagonist doxazosin used to treat benign prostatic hypertrophywas effective in enhancing the effects of intracavernosal therapyfound limited efficacy. However, it is interesting to note thatin a study of the treatment of mild hypertension, patients takingdoxazosin reported a lower incidence of erectile dysfunction.Similarly, tamsulosin has been reported to improve sexual functionin benign prostatic hypertrophy patients (Moreland et al., 2000

).Chlorpromazine, delequamine, moxisylyte, prazosin, and yohimbineact on $alpha$ ₁- or $alpha$ ₂-adrenoceptors, and in some cases both $alpha$ -adrenoceptorsin a combination of CNS and peripheral effects (Morales et al.,1995

; Wyllie and Andersson, 1999

). Trazodone has been shown toinduce erection when injected intracavernosally. It has been furtherdemonstrated that these effects are mediated by a dual mechanismincluding $alpha$ -adrenoceptor antagonism and serotoninergic activity.Oral trazodone has been used to treat psychogenic erectile dysfunction(Nehra et al., 1999

). Another oral agent for the treatment ofpsychogenic impotence is yohimbine, an $alpha$ ₂-adrenoceptorantagonist.

It has recently been reported that the $alpha$ _1A-adrenoceptor antagonist Ro70-0004/003 did not improve erectile function in a clinicalstudy including 24 men (Choppin et al., 2000

). The lack of effectof this adrenoceptor antagonist continues to demonstrate thatorally administered $alpha$ -antagonists might not be useful for thetreatment of MED despite the positive data generated with oralphentolamine. The approval of phentolamine (Vasomax, Zonagen,Woodlands, TX) has recently been delayed by the FDA due to abnormalproliferation of brown fat tissue in rats, and this agent maynot reach the market in the next 2years.

Agents That Increase cGMP Synthesis. The discovery that NO is one of the major effectors in penile smooth muscle relaxation and erectile function has led to thedevelopment of two classes of agents: NO donors and agents thatelevate and/or potentiate cGMP levels (PDE inhibitors). As discussedabove, NO is synthesized by neural NOS in the NANC nerve terminalsas well as by the corpus cavernosum endothelial cells (endothelialNOS) in response to shear stress, acetylcholine, or bradykinin(Andersson and Wagner, 1995). Examples of drugs that work as NOdonors include nitroglycerin, minoxidil, and sodium nitroprusside.However, NO donors themselves can activate guanylate cyclase notonly in corpus cavernosum but also in other tissues because ofthe ubiquitous distribution of guanylate cyclase. Recently, theuse of NO donors attached by nitrosylation either to $alpha$ -receptorantagonists or to PDE inhibitors has been investigated. AttachedNO was shown to significantly improve the therapeutic efficacyof both compound classes, increasing intracavernosal pressureand the duration of the erection. The development of these compounds,while promising, is still at the preclinical stage (Moreland etal., 2000).

PDE Inhibitors. PDEs are enzymes that hydrolyze cAMP and cGMP to their respective monophosphates to terminate signal transduction by thesesecond messengers within the corpus cavernosum. To date, of the11 known PDEs, types 2, 3, 4, and 5 have been identified in thecorpus cavernosum (Stief et al., 1997; Corbin and Francis, 1999).PDE5 is the major cGMP hydrolytic activity in the corpus cavernosumsmooth muscle cell (Corbin and Francis, 1999). Sildenafil is aselective PDE5 inhibitor that has been shown to be a safe andeffective oral treatment for MED (Goldstein et al., 1998; Cheitlinet al., 1999). The mechanism of action of sildenafil requiresan intact NO response as it blocks the hydrolysis of cGMP inducedby NO as well as constitutive synthesis of cGMP in the cells.This may explain why sexual arousal is necessary for the effectivenessof sildenafil in men. Sildenafil is a potent competitive inhibitorof PDE5 (IC₅₀ = 3.5 nM) and is selective over PDE1 to -4 (80-to 19,000-fold) and retinal PDE6 (10-fold). Sildenafil enhancedcGMP accumulation driven with NO in the corpus cavernosum of rabbitswithout affecting cAMP accumulation. More importantly, in theabsence of NO release, sildenafil had no functional effect onthe human and rabbit isolated corpus cavernosum but potentiatedthe relaxant effects of NO on these tissues (Moreland et al.,2000). In the anesthetized dog, sildenafil enhanced the increasein intracavernosal pressure induced by electrical stimulationof the pelvic nerve or intracavernosal injection of sodium nitroprussidewithout effects on blood pressure. Consistent with its mode ofaction, sildenafil potentiated the vasorelaxant effects of glyceryltrinitrate on rabbit isolated aortic rings (Corbin and Francis,1999).

The major cellular receptor for cGMP in causing vascular smooth muscle relaxation is PKG. PKG is thought to cause relaxationof the smooth muscle through lowering of cellular Ca²⁺, which may involve phosphorylation of inositol trisphosphatereceptor, Ca²⁺-ATPase, Ca²⁺ channels, or other proteins (Andersson and Wagner, 1995

; Stiefet al., 1997

). After cessation of erotic stimuli, NO release fromthe parasympathetic nerves of the penis declines, and the cGMPlevel in the smooth muscle cells falls because of a decrease insynthesis coupled with the ongoing degradation of cGMP byPDEs.

Papaverine was the first drug reported for intracavernosal injection (Spahn et al., 1999

). It is thought that papaverine exertspart of its action as a nonselective PDE inhibitor. As such itwould be expected to increase both cAMP and cGMP levels withinthe corpus cavernosum smooth muscle cell. Used now primarily incombination with other agents, the complications of papaverineinclude potential liver damage and the tendency to develop penilefibrosis. Although there are no cAMP PDE inhibitors availablefor the treatment of MED, the recent report of both type 3 andtype 4 PDE in human corpus cavernosum (Stief et al., 1997

; Nehraet al., 1999

) leads to the possible use of drugs such as milrinone(type 3 PDE selective) or rolipram (type 4 PDE selective) in MEDpatients. However, the importance of cAMP for physiological functionsin the heart and other tissues may preclude such anapproach.

ET Receptor Antagonists. It has been recently reported that ET receptor antagonists may be used as effective treatment of MED. ET is a potent vasoconstrictorsynthesized by the corpus cavernosum smooth muscle cells and endothelium(Andersson and Wagner, 1995). In addition to acting as a vasodilatorof corpus cavernosum smooth muscle, NO regulates the expressionof endogenously produced ETs (Nehra et al., 1999). The pharmacologyof the interaction between nitric oxide and endothelin receptorsystems is an area of research still to beresolved.

Dopamine Receptor Agonists. Apomorphine is a dopamine receptor agonist known to induce penile erection in men when administered orally (Morales et al.,1995). It has been tested in clinical trials in a sublingual formulation,which overcomes the major side effect of mild nausea. It is expectedthat it will be effective in a population of patients similarto that of sildenafil (psychogenic and mild-to-moderate vasculogenicMED patients) but without the cardiovascular side effects. A sublingualformulation of apomorphine (Uprima, TAP, Deerfield, IL) has recentlybeen withdrawn from FDA review until the safety profile is furtherinvestigated. Although several dopaminergic agents like apomorphine,quinpirole, and 3-PPP can induce penile erections in animals,it is unclear which dopamine receptor subtype mediates the proerectileeffect (Vallone et al., 2000).

	Future Prospects

Top Introduction Epidemiology Physiology of Penile Erection Pathophysiology of Male... Experimental Approaches to... Advances in the Treatment... Future Prospects References

The development of noninvasive or minimally invasive routes of administration is a key issue in the drug discovery area forthe treatment of MED. While a number of reports focus on the useof topical agents to treat erectile dysfunction, success usingthis route of administration has been limited. Topical PGE₁, papaverine,and nitroglycerin have been tested (Nehra et al., 1999). In mostof these limited clinical trials, penile blood flow increasedand most subjects reported tumescence, but the number of subjectsresponding with erections sufficient for vaginal penetration waslow and in most instances indistinguishable from the placebo.These results are consistent with the problem of drug deliverythrough the tunica albuginea. Recently, iontophoresis has beentested using an intraurethral catheter. While this report is promising,further studies are necessary to determine whether this meansof delivery is effective as a minimally invasive method oftreatment.

Oral agents have the advantage of convenience but the disadvantages of systemic side effects. Since the penis is a vascularorgan, many of these side effects center around vascular liabilitiessuch as hypotension and incidence of myocardial infarction. Thereare three PDE5 inhibitors in late stages of clinical development(IC351, ICOS/Lilly; vardenafil, Bayer; E8010, Eisai Pharmaceuticals).Any cGMP-based therapy will have to contend with liabilities ofnitrate-based heart diseasemedications.

Research defining the peripheral pathways of erectile physiology and investigating the pathogenesis of erectile dysfunctionhas led to the recognition of a predominant vascular basis fororganic male sexual dysfunction, while the role of the centralnervous system is just beginning to emerge. These scientific advanceshave laid the foundation for the advent of new treatments. Significantadvances in the research of erectile dysfunction indicate thatvascular disease appears to exacerbate the changes in corpus cavernosumstructure seen with aging. The recent availability of new oraland minimally invasive medications offers the possibility of multiplepharmacological approaches for the treatment of MED. The new frontierof understanding the central control of erection is still in itsinfancy, and future research into CNS regulation of erection maylead to novel, safer, and efficaciouspharmacotherapies.

	Footnotes

Accepted for publication September 5, 2000.

Received for publication June 27, 2000.

Send reprint requests to: Jorge D. Brioni, Ph.D., Neurological and Urological Diseases Research, Bldg. AP9A-3rd Floor, Abbott Laboratories, Abbott Park, IL 60064. E-mail: jorge.brioni{at}abbott.com

	Abbreviations

MED, male erectile dysfunction; PG, prostaglandin; ET, endothelin; ACh, acetylcholine; NOS, nitric-oxide synthase; NO, nitric oxide; CNS, central nervous system; NANC, nonadrenergic-noncholinergic; VIP, vasoactive intestinal peptide; CGRP, calcitonin gene-related peptide; PKG, cGMP-dependent protein kinase; MPOA, medial preoptic area; PVN, paraventricular nucleus; DA, dopamine; nPGi, nucleus paragigantocellularis; 5-HT, 5-hydroxytryptamine; TFMPP, trifluoro-methylphenyl piperazine; mCPP, meta-chlorophenylpiperazine; 5-MeOMDT, 5-methoxy-N,N-dimethyl-tryptamine; TGF- $beta$ ₁, transforming growth factor $beta$ ₁; ICP, intracavernosal pressure; PDE, phosphodiesterase; EP, PGE receptor; 3-PPP, 3-[3-hydroxypheny]-N-(1-propyl)piperidine; M, muscarinic.

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Erectile Dysfunction

				R. d. di Villa Bianca, R. Sorrentino, R. Sorrentino, C. Imbimbo, A. Palmieri, F. Fusco, M. Maggi, R. De Palma, G. Cirino, and V. Mirone Sphingosine 1-Phosphate Induces Endothelial Nitric-Oxide Synthase Activation through Phosphorylation in Human Corpus Cavernosum J. Pharmacol. Exp. Ther., February 1, 2006; 316(2): 703 - 708. [Abstract] [Full Text] [PDF]

				C. E. Teixeira, Z. Ying, and R. C. Webb Proerectile Effects of the Rho-Kinase Inhibitor (S)-(+)-2-Methyl-1-[(4-methyl-5-isoquinolinyl)sulfonyl]homopiperazine (H-1152) in the Rat Penis J. Pharmacol. Exp. Ther., October 1, 2005; 315(1): 155 - 162. [Abstract] [Full Text] [PDF]

				L. De Young, D. Yu, R. M. Bateman, and G. B. Brock Oxidative Stress and Antioxidant Therapy: Their Impact in Diabetes-Associated Erectile Dysfunction J Androl, September 1, 2004; 25(5): 830 - 836. [Abstract] [Full Text] [PDF]

				J. D. Brioni, R. B. Moreland, M. Cowart, G. C. Hsieh, A. O. Stewart, P. Hedlund, D. L. Donnelly-Roberts, M. Nakane, J. J. Lynch III, T. Kolasa, et al. Activation of dopamine D4 receptors by ABT-724 induces penile erection in rats PNAS, April 27, 2004; 101(17): 6758 - 6763. [Abstract] [Full Text] [PDF]

				R. B. Moreland, J. D. Brioni, and J. P. Sullivan Emerging Pharmacologic Approaches for the Treatment of Lower Urinary Tract Disorders J. Pharmacol. Exp. Ther., March 1, 2004; 308(3): 797 - 804. [Abstract] [Full Text] [PDF]

				G. C. Hsieh, P. R. Hollingsworth, B. Martino, R. Chang, M. A. Terranova, A. B. O'Neill, J. J. Lynch, R. B. Moreland, D. L. Donnelly-Roberts, T. Kolasa, et al. Central Mechanisms Regulating Penile Erection in Conscious Rats: The Dopaminergic Systems Related to the Proerectile Effect of Apomorphine J. Pharmacol. Exp. Ther., January 1, 2004; 308(1): 330 - 338. [Abstract] [Full Text] [PDF]

				T. J. Bivalacqua, M. F. Usta, H. C. Champion, P. J. Kadowitz, and W. J. G. Hellstrom Endothelial Dysfunction in Erectile Dysfunction: Role of the Endothelium in Erectile Physiology and Disease J Androl, November 1, 2003; 24(6_suppl): S17 - S37. [Full Text] [PDF]

				T. Karkanis, L. DeYoung, G. B. Brock, and S. M. Sims Ca2+-activated Cl- channels in corpus cavernosum smooth muscle: a novel mechanism for control of penile erection J Appl Physiol, January 1, 2003; 94(1): 301 - 313. [Abstract] [Full Text] [PDF]

				J. Malysz, G. Farrugia, Y. Ou, J. H. Szurszewski, A. Nehra, and S. J. Gibbons The Kv2.2 {alpha} Subunit Contributes to Delayed Rectifier K+ Currents in Myocytes From Rabbit Corpus Cavernosum J Androl, November 1, 2002; 23(6): 899 - 910. [Abstract] [Full Text] [PDF]

				L. H. T. Van der Ploeg, W. J. Martin, A. D. Howard, R. P. Nargund, C. P. Austin, X. Guan, J. Drisko, D. Cashen, I. Sebhat, A. A. Patchett, et al. A role for the melanocortin 4 receptor in sexual function PNAS, August 20, 2002; 99(17): 11381 - 11386. [Abstract] [Full Text] [PDF]

				H. Wang, M. Eto, W. D. Steers, A. P. Somlyo, and A. V. Somlyo RhoA-mediated Ca2+ Sensitization in Erectile Function J. Biol. Chem., August 16, 2002; 277(34): 30614 - 30621. [Abstract] [Full Text] [PDF]

				K.-E. Andersson Pharmacology of Penile Erection Pharmacol. Rev., September 1, 2001; 53(3): 417 - 450. [Abstract] [Full Text] [PDF]