Erectile dysfunction in spontaneously hypertensive rats: pathophysiological mechanisms

doi:10.1152/ajpregu.00349.2002

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Erectile dysfunction in spontaneously hypertensive rats: pathophysiological mechanisms

Delphine Behr-Roussel¹, Philippe Chamiot-Clerc¹, Jacques Bernabe¹, Katell Mevel, Laurent Alexandre¹, Michel E. Safar², and François Giuliano¹^,³

¹ Pelvipharm, Domaine Centre National de Recherche Scientifique, 91190 Gif sur Yvette; ² Department of Internal Medicine, Broussais Hospital, 75014 Paris; and ³ Groupe de Recherche en Urologie, Unité Propre de Recherche de l'Enseignement Supérieur, Medical University of Paris South, 94275 Le Kremlin Bicêtre Cedex, France

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
METHODS
RESULTS
DISCUSSION
REFERENCES

Hypertensive men have a higher prevalence of erectile dysfunction (ED) than the general population. Experimental evidenceof ED in hypertensive animals is scarce. This study evaluatesthe erectile function of spontaneously hypertensive rats (SHR)and age-matched normotensive Wistar-Kyoto rats (WKY) in vivo bythe increase in intracavernosal pressure after electrical stimulationof the cavernous nerve (CN) and by isometric tension studies oncorporal strips. Frequency-dependent erectile responses to CNstimulations were reduced in SHR. Phenylephrine induced lowercorporal contractions in SHR although pD₂ values were similarto WKY. Endothelium-dependent relaxations to ACh were impairedsignificantly in SHR, and indomethacin improved these relaxationsin both WKY and SHR, the latter thus reaching values similar toWKY. Corporal relaxations to sodium nitroprusside were enhancedin SHR. Thus a dysfunctional $alpha$ -adrenergic contraction of the corporalsmooth muscle, an increased cyclooxygenase-dependent constrictortone, and/or a defect in endothelium-dependent reactivity areassociated with the altered erectile mechanisms in SHR. Drugstargeting endothelial dysfunction may delay the occurrence ofED as a complication ofhypertension.

hypertension; endothelial dysfunction; corpus cavernosum

	INTRODUCTION

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IN MEN WITH HYPERTENSION, prevalence of erectile dysfunction (ED) is significantly higher than in the general population (9,11). In fact, 8-10% of untreated hypertensive patients are foundto be suffering from ED once their hypertension is diagnosed (26).The question has been raised as to whether the higher rate ofsexual dysfunction in hypertensive individuals is the result ofhypertension per se and/or to antihypertensive medications. Strongarguments indicate a possible causative role for some antihypertensivedrugs such as diuretics and noncardioselective $beta$ -blockers (4,9, 17, 38). Nevertheless, the functional and structuralmodifications induced by hypertension may also be strongly implicatedin ED even though pathophysiological studies of ED induced byhypertension are surprisingly scarce (6).

The basal tone of the corpus cavernosum (CC) smooth muscle is controlled both at the level of the central and peripheral nervoussystem (13, 15). The sympathetic nervous system principallyensures flaccidity by producing an $alpha$ -adrenergic-dependent toneof the corporal smooth muscle maintaining the penis in a flaccidstate and thus minimizing intracavernosal blood flow and pressure(ICP). Upon sexual stimulation, penile erection occurs in responseto the activation of proerectile autonomic pathways and is greatlydependent on adequate inflow of blood to the erectile tissue.It requires coordinated arterial endothelium-dependent vasodilatationand sinusoidal endothelium-dependent corporal smooth muscle relaxation(2, 7). Nitric oxide (NO) is the principal peripheral proerectileneurotransmitter implicated, since it is released in responseto a sexual stimulation both by nonadrenergic, noncholinergic(NANC) neurons and the sinusoidal endothelium to produce cGMPand relax corporal smooth muscle, resulting ultimately in increasedICP (3, 22). This increase in ICP activates pressure-dependentvenoocclusive mechanisms to limit the outflow of blood, thus furtherpromoting elevated ICP and erectile response. The increased bloodflow is thus ultimately driven by the force of the arterial pressure(14). Therefore, any factors modifying the basal corporal tonein the flaccid state, the arterial inflow of blood to the corpora,and/or the synthesis/release of neurogenic and/or endothelialNO within the corpora may be involved in the pathophysiology ofED.

Several arguments support the concept that pathophysiological modifications induced by hypertension by itself may be implicatedin the occurrence of ED. Among the hallmarks of hypertension arean increased peripheral sympathetic activity (20), an elevatedvasoconstrictor tone, and decreased endothelium-dependent vasodilatationsin arteries from both conductance and resistance vasculature (24,25, 32). The resulting imbalance in regulatory vascular tonecan either be linked to an increased release of vasoconstrictingand/or reduced release of dilating substances. In fact, the cyclooxygenasepathway has been identified as mainly involved in vascular endothelium-dependentalterations observed in hypertension (25). Interestingly, anincreased norepinephrine content has also been found in nonvasculartissue of spontaneously hypertensive rats (SHR), implying thathyperinnervation is not restricted to the vasculature and mayinclude other sympathetically innervated tissue, i.e., the genitourinaryorgans (20, 28, 35). Furthermore, hypertension also inducesmodifications in the vascular structure, i.e., remodeling thatcould participate in an overall reduced dilatory capacity (12).Interestingly, remodeling may also occur at the corporal level(27, 34) and thus participate in the pathophysiology of EDby altering the mechanical properties of the erectiletissue.

The primary goal of this study was to demonstrate the occurrence of ED in a genetic model of hypertension, i.e., SHR. A reliableand standardized way to study erectile function in the anesthetizedrat is to electrically stimulate the peripheral proerectile neuralpathways and concomitantly measure the ICP and blood pressure(10, 13, 14, 30). To date, these experiments have notbeen reported in SHR. Our second objective was to investigatethe pathophysiology of ED in SHR by studying the corporal endothelium-dependentand -independent reactivities in vitro, with particular attentionpaid to the cyclooxygenasepathway.

	METHODS

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Male 12-wk-old SHR, their age-matched normotensive Wistar-Kyoto rats (WKY), and age-matched Sprague-Dawley rats (SD) (Iffa-Credo,France) were housed 7 days before the experiments with free accessto food and water. All procedures were performed in accordancewith the Guiding Principles in the Care and Use of Animals establishedby the American Physiological Society (1) and the legislationon the use of laboratory animals (NIH publication no. 85-23, revised1996, and Animal Care Regulations in force in France as of1988).

Erectile responses were elicited by electrical stimulation of the cavernous nerve (CN) in anesthetized rats, as previouslydescribed (10, 13, 14, 30). Briefly, SHR (n = 5) and WKY(n = 5) were anesthetized with an intraperitoneal injection ofxylazine (10 mg/kg) and ketamine (90 mg/kg), tracheotomized, andmaintained at 37°C. In an another set of experiments, WKY, SHR,and SD were anesthetized with an intraperitoneal injection ofurethane (1.2 g/kg). The carotid artery was catheterized to recordarterial pressure, and a 21-gauge needle was inserted in one ofthe CC of the penis to record ICP simultaneously via pressuretransducers (Elcomatic 750). The CN was exposed at the lateralaspect of the prostate and mounted on a bipolar platinum electrodeconnected to an electrical stimulator (AMS 2100). For each animal,electrical stimulations of the CN (square-wave pulses of 1 ms,duration of 45 s, 6 V) at different frequencies (1, 2, 3, 4, 5,and 10 Hz) were performed in a randomized manner and repeatedtwo times in view of establishing frequency-response curves. Theerectile responses elicited by each electrical stimulation werequantified by calculating the ratio $Delta$ ICP (mmHg)/MAP (mmHg) × 100,with $Delta$ ICP being the difference between ICP in the flaccid state,i.e., before stimulation and ICP during the plateau phase andwith MAP being the mean arterial pressure during the plateau phase.This ratio accounts for the strong influence of the systemic bloodpressure in the amplitude of ICP increase during the plateau phase(14). At the end of the experiments, rats were killed with anoverdose ofurethane.

For in vitro experiments, SHR (n = 12) and WKY (n = 12) rats were deeply anesthetized with pentobarbital sodium (50 mg/kgip). In all rats, the penis was carefully harvested, transferredto ice-cold Krebs bicarbonate solution (in mmol/l: 118.0 NaCl,4.6 KCl, 2.5 CaCl₂, 1.2 KH₂PO₄, 1.2 MgSO₄, 11.1 glucose, and 25.0NaHCO₃, pH 7.2-7.4), and dissected. Corporal strips (1-2 mm ×0.5 mm) were placed in 5-ml organ baths filled with Krebs maintainedat 37°C, bubbled with 95% O₂-5% CO₂, and connected to a force-displacementtransducer (Marty Technologie). Tissues were equilibrated for45-60 min before being stretched progressively to their optimaltension defined in preliminary experiments (200 mg for both WKYand SHR). A concentration-response curve to phenylephrine (Phe,10⁸ to 10⁴ mol/l) was performed for each sample. Next, concentration-responsecurves to ACh (10⁸ to 10⁵ mol/l) were constructed on Phe-induced (10⁵ mol/l or 3 × 10⁵ mol/l, depending on the individual responses of each tissue tomaintain comparable levels of stimulated forces between SHR andWKY) precontracted tissues in the absence and in the presenceof indomethacin (10⁵ mol/l). At last, responses of Phe-induced precontracted corporalstrips to cumulative additions of sodium nitroprusside (SNP, 10⁸ to 10⁵ mol/l) werestudied.

Values are expressed as means ± SE. For in vitro experiments, contractile responses are expressed as the absolute change inmaximal developed tension (in g) normalized per gram tissue weightand relaxations as the percentage of change in Phe-induced tone.Concentrations inducing 50% of the maximal effect were expressedas pD₂ values and calculated using GraphPad Prism (5). Forboth in vivo and in vitro experiments, comparisons were performedusing two-way ANOVA with repeated measures followed by Bonferroni'scomplementary analysis where relevant. A P value <0.05 was consideredto besignificant.

	RESULTS

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Mean body weights of SHR were significantly lower than those of WKY rats (311.8 ± 3.9 vs. 395.2 ± 8.8 g, respectively, P <0.005). Mean body weights of SD rats were significantly higherthan those of WKY and SHR (445.8 ± 14.5 g, P < 0.001). MAP wassignificantly higher in anesthetized SHR compared with anesthetizedWKY rats (169.9 ± 18.0 vs. 133.0 ± 5.7 mmHg, respectively, P <0.01). Both MAP from WKY and SHR were higher compared with SDrats (71.5 ± 4.7mmHg).

In vivo experiments. Typical erectile responses elicited by electrical stimulations (6 V, 10 Hz, 1 ms, 45 s) of the CN of WKY and SHR are displayedin Fig. 1. In both WKY and SHR, maximal electrical stimulation(6 V, 10 Hz, 1 ms, 45 s) of the CN induced a rapid increase inICP associated with visible tumescence of the penis. This ICPincrease was maintained as long as the stimulation lasted (plateauphase) and, at the end of the 45-s period of stimulation, ICPreturned directly to its prestimulation level. The profile oferectile responses was similar in SHR and in WKY (Fig. 1). TheICP/MAP ratio increased in parallel with the frequency of CN electricalstimulation both in SHR and WKY rats (Fig. 2A). However, the magnitudeof the erectile responses was reduced drastically in SHR comparedwith WKY rats (P < 0.01), and this lower amplitude of erectileresponses was found to be significant for all frequencies except1 Hz (P < 0.001; Fig. 2A). When repeating these experiments inanimals anesthetized with urethane, erectile responses in SHRare also reduced compared with WKY rats for all frequencies except1 Hz (P < 0.01; Fig. 2B). Furthermore, we have compared theseerectile responses with those obtained in normotensive SD ratsand again observed reduced erectile responses in SHR comparedwith this control strain. Interestingly, each strain of controlrats (SD and WKY) yields erectile responses of different magnitude,with those of WKY rats being slightly but significantly greaterthan those of SD rats at 3 and 4 Hz (P < 0.05; Fig. 2B).

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Fig. 1. Representative digitalized tracing of an original recording of intracavernous pressure when stimulating the cavernous nerve (6 V, 10 Hz, 1 ms, 45 s) in spontaneously hypertensive rats (SHR) and in age-matched Wistar-Kyoto rats (WKY). Mean arterial pressures for SHR and WKY were 170 ± 18 vs. 133 ± 6 mmHg, P < 0.01, Student's t-test.

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Fig. 2. Effect of cavernous nerve stimulation at increasing stimulation frequencies on the intracavernosal pressure (ICP) of SHR and WKY rats anesthetized with ketamine and xylazine (A) or Sprague-Dawley (SD), SHR, and WKY rats anesthetized with urethane (B). Results are expressed as the ratio $Delta$ ICP (mmHg)/MAP (mmHg) × 100 during the plateau phase, with $Delta$ ICP being the difference between ICP in the flaccid state and ICP during the plateau phase of the erectile response and MAP the mean arterial pressure during the tumescence phase. ^&&&P < 0.001, WKY vs. SHR, 2-way ANOVA. ^##P < 0.01 and ^###P < 0.001 vs. SD, 2-way ANOVA. **P < 0.01 and ***P < 0.001, Bonferroni's complementary analysis.

In vitro experiments. Developed tensions to Phe (10⁸ to 10⁴ mol/l) were significantly lower in corporal strips of SHR compared with WKY rats (P <0.001, two-way ANOVA; Fig. 3), whereas the mean pD₂ value calculatedfor Phe was similar in SHR compared with WKY [5.64 ± 0.14 vs.5.87 ± 0.05; not significant (NS)].

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Fig. 3. Concentration-response curve for phenylephrine (Phe; 10⁸ to 10⁴ mol/l) in corporal strips from SHR and WKY rats. Results are expressed as the maximal developed tension values induced by Phe normalized by the wet weight (ww) of the strip. ***P < 0.001, SHR vs. WKY, 2-way ANOVA followed by Bonferroni's complementary analysis.

During Phe-induced contractions (349.4 ± 34.3 vs. 399.1 ± 43.8 g/g wet wt, respectively, NS, Student's t-test), endothelium-dependentrelaxations to ACh were impaired significantly in SHR corporalstrips compared with age-matched WKY rats (relaxations at 10⁵ mol/l of 16 ± 7 vs. 31 ± 3%, P < 0.05, Fig. 4). Conversely, pD₂values for ACh-induced relaxations were not significantly differentbetween SHR and WKY rats.

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Fig. 4. Maximal relaxations induced by increasing concentrations of ACh (10⁸ to 10⁵ mol/l) in corporal strips from 12-wk-old WKY and SHR in the presence or absence of indomethacin (Indo; 10⁵ mol/l). Results are expressed as a percentage of the initial developed tension obtained with Phe (10⁵ mol/l). **P < 0.01, SHR vs. WKY. ^§P < 0.05 and ^§§§P < 0.001, with vs. without indomethacin, Bonferroni's complementary analysis.

In the presence of indomethacin (10⁵ mol/l), the ACh-induced relaxations were improved significantly in the CC of both WKY(31 ± 3 vs. 43 ± 4%) and SHR [16 ± 7 vs. 38 ± 8%, the latter achievinga relaxation similar to that in the WKY tissues (NS, 2-way ANOVAwith Bonferroni's complementary analysis); Fig. 4], whereas therewere no loading tension differences between the two strains (359.9± 41.7 vs. 359.4 ± 34.5 g/g wet wt, respectively, NS, Student'st-test).

Concentration-response relaxation curves were evoked by cumulative addition of SNP (10⁸ to 10⁵ mol/l) on corporal strips precontracted with Phe (10⁵ mol/l) in the presence of indomethacin (Fig. 5). SNP-inducedrelaxations were enhanced significantly in corporal strips fromSHR compared with WKY rats (maximal relaxations of 100 ± 1 vs.74 ± 4%, respectively; P < 0.005), although stimulated forcesattained with Phe in both strains were similar (254.8 ± 21.5 vs.314.1 ± 37.1 g/g wet wt, respectively, NS, Student's t-test).

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Fig. 5. Concentration-response curves for sodium nitroprusside (SNP; 10⁸ to 10⁵ mol/l) in corporal strips from WKY and SHR in the presence of indomethacin (10⁵ mol/l). Results are expressed as a percentage of the initial tension obtained with Phe (10⁵ mol/l). ^§§§P < 0.001, SHR vs. WKY, 2-way ANOVA. ***P < 0.001, Bonferroni's complementary analysis.

	DISCUSSION

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In this study, we have determined that there are differences in the mechanisms involved in penile erection in vivo and invitro in an experimental model of hypertension, the SHR. We havefound that 1) the erectile responses induced by electrical stimulationof the CN in anesthetized SHR were reduced, 2) the endothelium-dependentrelaxations of corporal strips were impaired in SHR, 3) cyclooxygenaseproducts contributed to the normal and impaired endothelium-dependentrelaxations in corporal strips of WKY and SHR, and 4) endothelium-independentrelaxations were enhanced in corporal strips of SHR compared withWKY.

First, we have demonstrated that the magnitude of erectile responses was reduced considerably in SHR compared with age-matchedWKY anesthetized with ketamine and xylazine. Interestingly, althoughthis cocktail is the anesthesia of choice when working with theseanimals, we have repeated these experiments using urethane, whichis known to have less effect on the cardiovascular system, atleast in normal animals (16), and have reached the same conclusionsconcerning the reduction in erectile responses of SHR after electricalstimulation compared with WKY. We used 12-wk-old SHR, which areconsidered to be mature adults able to have normal reproductivebehavior and which feature a fully developed increase of bloodpressure and major alterations of both structural and mechanicalvascular properties, with in particular an established decreasein the endothelium-dependent relaxations at all levels of thearterial tree (5, 12, 20, 24, 25, 32). Despite thefact that the magnitude of an erectile response is driven directlyby the magnitude of the arterial blood pressure (14), we observeda severely reduced ICP plateau after electrical stimulation inSHR compared with normotensive rats from the same stock from whichSHR are derived (WKY) or from a different strain (SD). A risein ICP is an important predictor of penile rigidity and erectilefunction and, as such, is a major determinant of erectile capacityand function per se (14, 36). In normal rats, electrical stimulationof the CN elicits an increase in ICP within the same range ofvalues as pressures necessary for penile rigidity to occur inhumans (60-90 mmHg; see Ref. 36). A decrease in the amplitudeof the erectile response will lead to a decrease in penile rigidity,and thus ED. In this respect, it is likely that SHR is very predictiveto assess the effects of hypertension on penile erection in hypertensivepatients. Interestingly, SHR exhibit unchanged copulatory behaviorbut display fewer erections than normotensive rats (<20% comparedwith WKY) (8). Very recently, other experimental models ofhypertension have been used and describe decreased penile erectionsassociated with hypertension as well (6, 18).

Hypertension is commonly associated with structural and functional modifications that take place at the level of the endothelium,vascular smooth muscle, and extracellular matrix of blood vessels(5, 12, 20, 24, 25, 32). Some studies have providedevidence that the penile vasculature could undergo similar modifications(18, 19, 27). However, the reactivity of the erectile tissueitself had never been studied to date. We found decreased developedtensions to Phe, an $alpha$ ₁-adrenoceptor agonist, in SHR corporal stripsdespite unchanged pD₂ values. Interestingly, we have previouslydemonstrated that $alpha$ ₁-adrenoceptors are present and functionallyrelevant within the erectile tissue in rats (31, 37). Thepresent results support the concept that there may be a modifiedresponsiveness to $alpha$ -adrenergic stimulation in the corporal smoothmuscle of SHR, which mediates, at least in part, some of the alterationsin erectile mechanisms, as suggested previously (18), althoughthe sensitivity of the contractile machinery of the smooth muscleto Phe is intact. A change in the expression of adrenoceptor subtypesin the corporal smooth muscle, similar to the one occurring inblood vessels of SHR (21), could explain the modified $alpha$ -adrenergic-mediatedcontraction of corporal strips fromSHR.

In this study, we have also focused on the corporal endothelium-dependent and -independent relaxations implicated in the localphysiology of penile erection. Interestingly, the ACh-inducedrelaxations were impaired significantly in corporal strips ofSHR. Although endothelium-dependent impairment has already beenwell described in aortas and resistance arteries of SHR (23-25),impairment of endothelium-dependent responses in corporal stripsof SHR has never been reported before. These observations areof major importance since endothelium-dependent relaxation ofcorporal smooth muscle plays a key role in the erectile responseto sexual stimulation (7, 22). Interestingly, we found thatcyclooxygenase-dependent products contributed to the reduced endothelium-dependentreactivity of the erectile tissue in both SHR and WKY. Such resultsare in accordance with experiments establishing the role of vasoconstrictorprostanoids in rabbit corporal strips (3). Moreover, it hasalready been suggested that the release of endothelium-derivedcontracting factors such as cyclooxygenase products is augmentedin hypertension (24), leading to an increase in the vascularconstrictor tone (25, 32). Indeed, indomethacin improves theimpaired ACh-induced relaxations in SHR to reach similar valuesof WKY. This leads us to propose that, in SHR, there is a highervasoconstrictor tone resulting from an overproduction of cyclooxygenaseproducts within the erectile tissue, making it harder for thecorporal smooth muscle to relax and thus compromising erection.More importantly, these results indicate that there are similaritiesin the pathological functional modifications between systemicarterial and local corporal tissue reactivities in SHR, suggestingthat the erectile tissue of SHR is not protected from the functionalchanges induced by hypertension. Moreover, previous experimentshave suggested that structural changes exist in the penile vasculaturefrom SHR (18, 19, 27), and functional alterations have alsobeen described in rat resistance arteries (23). Indeed, theseobservations are also of interest, since the important controlsite for pressure is at the level of the small arteries/arterioles.However, because the concomitant release of other endothelium-derivedsubstances than NO may also occur in these smaller vascular beds,the parallel with corporal smooth muscle relaxation mechanismsis more difficult to make since these substances have not yetbeen characterized in corporal smooth muscle. In any case, a decreasein both corporal smooth muscle relaxation and arterial relaxation,both participating in the reduction of blood inflow to the penis,are very likely to be, at least partly, responsible for the bluntederectile response observed invivo.

Finally, we report an increase in endothelium-independent corporal relaxations elicited by the NO donor, SNP, in SHR comparedwith WKY. Thus the corporal smooth muscle of SHR retains its fullability to relax via the guanylate cyclase pathway. Even more,the sensitivity of the corporal smooth muscle from SHR to NO donorsseems to be increased. This increased sensitivity or effectivenesscould be a tissue-specific compensatory mechanism of the solubleguanylate cyclase pathway to defective endothelium-dependent relaxations(29). It is, however, not powerful enough to overcome the alterationsinduced by hypertension and responsible for the altered erectileresponses to sexual stimulation, suggesting that other mechanismsare involved. In fact, in addition to NO from endothelial origin,NO released by NANC neurons at the level of the erectile tissueis also involved in the corporal relaxation. An altered releaseof neurogenic NO at the level of the erectile tissue could beanother pathophysiological mechanism involved in hypertension-inducedED inSHR.

In summary, we report herein that ED occurs in a genetic model of hypertension and that there appears to be a common pathophysiologicalfunctional alteration between the reactivity of large and smallvessels and the reactivity of the erectile tissue in geneticallyhypertensive rats. Indeed, we found a dysfunctional $alpha$ -adrenergic-mediatedcontraction and blunted endothelium-dependent relaxations in SHRcorporal strips. Conversely, we demonstrate an increase in corporalendothelium-independent relaxations in SHR. Based on these findings,we propose that the pathophysiology of ED in hypertension is theresult of an increase in cyclooxygenase-dependent constrictortone, although a defect of endothelial or neuronal NO productionand/or bioavailability cannot be excluded. Additionally, remodelingresulting from hypertension may also significantly interfere witharterial blood inflow to the penis (34). The latter aspect needsfurther investigations. Considering these results, it is temptingto postulate that drug therapy improving vascular and corporalendothelial function (33) may be of interest to treat hypertensionpatients withED.

	ACKNOWLEDGEMENTS

We are grateful to Joël Ménard for precious scientific contribution to thiswork.

	FOOTNOTES

Address for reprint requests and other correspondence: F. Giuliano, Dept. of Urology, CHU de Bicêtre, 78 rue du GénéralLeclerc, 94270 Le Kremlin Bicêtre Cedex, France (E-mail: giuliano{at}cyber-sante.org).

The costs of publication of this article were defrayed in part by the payment of page charges. The article must thereforebe hereby marked "advertisement" in accordance with 18 U.S.C.Section 1734 solely to indicate thisfact.

First published November 7, 2002;10.1152/ajpregu.00349.2002

Received 13 July 2002; accepted in final form 4 November 2002.

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