Unique Preclinical Characteristics of GG745, A Potent Dual Inhibitor of 5AR

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Vol. 282, Issue 3, 1496-1502, 1997

Unique Preclinical Characteristics of GG745, A Potent Dual Inhibitor of 5AR

H. Neal Bramson, David Hermann, Kenneth W. Batchelor, Frank W. Lee, Michael K. James and Stephen V. Frye

Department of Clinical Pharmacology (D.H.), Divisions of Biochemistry (H.N.B.) and Metabolic Diseases Research (K.W.B.), Bioanalysis and Drug Metabolism (F.W.L.), and Chemistry (S.V.F.), Glaxo Wellcome Research Institute, Research Triangle Park, North Carolina, and Inspire Pharmaceuticals Inc., Durham, North Carolina (M.K.J.)

	Abstract

Top Abstract Introduction Procedures Results Discussion References

Selective inhibition of type 2 5 $alpha$ -reductase has been shown to be efficacious in the treatment of benign prostatic hyperplasia.Pharmacokinetic and pharmacodynamic results are reported of treatmentwith a potent inhibitor of both 5 $alpha$ -reductase isozymes, GG745,in rats, dogs and men. In the rat, GG745 has a similar effecton DHT-driven prostatic growth as finasteride, another dual 5 $alpha$ -reductaseinhibitor in this species. However, GG745 appears to be more potentin the rat, a result that likely reflects the greater inherentpotency and terminal half-life of GG745 (14 hr) compared withthat of finasteride (1 hr). These pharmacokinetic differencesare also maintained in the dog (65 and 4 hr for GG745 and finasteride,respectively). From these results, the literature, and in vitrostudies, we estimated doses of GG745 likely to prove efficaciousin reducing DHT levels in man. These estimated values were predictiveof single-dose effects of GG745 in man. Results from single-doseevaluations in man indicate that GG745 has a terminal half-lifeof ~240 hr, and single doses of >10 mg decreased DHT levels significantlymore than did single 5-mg doses of finasteride. These data supportthe hypothesis that a molecule (GG745) that effectively inhibitsboth 5 $alpha$ -reductases will lower serum DHT levels significantly morethan a molecule that inhibits only a single 5 $alpha$ -reductase isozyme(e.g., finasteride, a selective inhibitor of the type 2 enzymein man).

	Introduction

Top Abstract Introduction Procedures Results Discussion References

Pharmacological intervention to treat lower urinary tract symptoms and bladder outlet obstruction secondary to BPH is desirabledue to the high incidence of this disease and its resulting erosionin the quality of life for affected men (Geller, 1991). Fiftypercent of males over the age of 60 have lower urinary tract symptomssuggestive of bladder outlet obstruction; ultimately, 25% to 30%of them require surgery (Lange, 1992). Although facets of theBPH etiology remain to be explored, the permissive role of DHTfor hyperplastic growth of the prostate is well established (Geller,1991; Lange, 1992; Russell and Wilson, 1994). 5ARs catalyze thetransfer of hydride from NADPH to the 5 $alpha$ position of T to producethe more potent androgen DHT, and there has been considerableinterest in developing inhibitors for these enzymes. Two 5ARshave been identified; these are referred to as the type 1 andtype 2 enzymes on the basis of their order of discovery (Russelland Wilson, 1994). Although the relative physiological roles ofthese enzymes are not yet understood, the type 2 5AR is the primaryisozyme present in human prostates (Russell and Wilson, 1994).Treatment of patients with finasteride, a selective type 2 5ARinhibitor, reduces circulating DHT concentrations to 20% to 40%of base-line values and has been proved to be partially efficaciousfor the treatment of BPH (Russell and Wilson, 1994; Moore et al.1995). We previously made the case that drug molecules that inhibitboth the type 1 and type 2 enzymes would more effectively reducecirculating DHT levels than would selective inhibitors of a single5AR isozyme alone (Frye et al., 1993, 1994). Because it is possiblethat a further reduction in DHT would prove to have clinical advantages,we sought potent dual inhibitors (Frye et al., 1993, 1994, 1995),with our work culminating in GG745 [17 $beta$ -N-(2,5-bis(trifluoromethyl)phenylcarbamoyl)-4-aza-5 $alpha$ -androst-1-en-3one], a potent dual 5ARinhibitor (fig. 1).

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Fig. 1. The structure of 5a-reductase inhibitors. A, GG745. B, Finasteride. C, 4-MA.

Both GG745 and finasteride are time-dependent inhibitors of the human type 1 and 2 5 $alpha$ -reductases (Faller et al., 1993; Tianet al., 1994, 1995). Finasteride has been suggested to be an irreversibleinhibitor of both 5ARs (Faller et al., 1993; Tian et al., 1994,1995), but recent studies have indicated that this inhibitionprocess instead results from the enzyme-catalyzed formation ofthe potent disubstrate inhibitor NADP-dihydrofinasteride (Bullet al. 1996). Just as 5ARs catalyze the reduction of the C5 positionof testosterone by NADPH, these enzymes also catalyze the NADPH-dependentreduction of the C1 position of finasteride. In the case of the1,2-ene-containing finasteride, reduction of C1 enables the nucleophilicattack of C2 on the nicotinamide C4, resulting in the formationof NADP-dihydrofinasteride, which has a half-life for dissociationfrom the type 2 5AR of $>=$ 1 month (Bull et al. 1996). Thus, finasterideeffectively is an irreversible inhibitor of the type 2 5AR invivo. We presume that the structurally related GG745, which alsoappears to irreversibly inhibit the 5ARs (Tian et al. 1995), doesso by a similar mechanism.

The kinetics of types 1 and 2 5AR inhibition by GG745 and finasteride fit well to a mechanism in which inhibitor binds toenzyme in a fast equilibrium (K_i), which is followed by an irreversiblerate-determining inactivation step (k₃) (Faller et al., 1993;Tian et al., 1994, 1995). At pH 7.0 and 37°C, values for k₃/K_idescribing the interactions of the type 1 5AR with GG745 and finasterideare 1.8 ± 0.3 × 10⁵ and 4.0 ± 0.6 × 10³ M/sec, respectively (Tian et al., 1995). Under equivalent conditions,values for k₃/K_i obtained from the inhibition of the type 2 5ARby GG745 and finasteride are 6.8 ± 2.9 × 10⁵ and 3.2 ± 0.4 × 10⁵ M/sec, respectively (Tian et al., 1995). These data indicatethat both GG745 and finasteride are potent inhibitors of the humantype 2 5AR but that finasteride is a 50-fold weaker inhibitorof the human type 1 5AR.

The degree to which slow inhibition of type 1 5AR by finasteride influences the efficacy of this drug in man was predictedby a modeling study that considered the above k₃/K_i values, drugtissue distribution, and pharmacokinetics of finasteride dispositionin man (Tian, 1996). The conclusion of this study was that therate of type 1 5AR inhibition by finasteride was sufficient atthe predicted tissue drug concentrations and rates of enzyme synthesisto only partially inhibit this enzyme (Tian, 1996). Thus, finasteridefails to suppress circulating DHT levels by >60% to 80%. Interestingly,the k₃/K_i describing GG745 inactivation of the type 1 5AR is nearlyas fast as the k₃/K_i describing finasteride interactions withthe type 2 5AR (Faller et al., 1993; Tian et al., 1994, 1995).These data provided an indication that GG745 would be more effectivethan finasteride at reducing serum DHT concentrations in man.

We report initial preclinical pharmacokinetic and pharmacodynamic results of the potent dual 5AR inhibitor GG745 and how theseresults were used to estimate effective exposures in humans. Theseresults include (1) initial studies to explore the efficacy ofGG745 performed in an intact rat model of 5AR-dependent prostaticgrowth and (2) the pharmacokinetics of GG745 in rats and dogs.

On the basis of these preclinical data, we estimated probable therapeutic doses of GG745 in man. These estimates are comparedwith results obtained from the first evaluation of GG745 in humans.

	Experimental Procedures

Top Abstract Introduction Procedures Results Discussion References

Materials. Tween-80 and Cremophor EL were purchased from Sigma Chemical (St. Louis, MO). Finasteride and 4-MA were synthesized accordingto Rasmusson et al. (1986), and GG745 was synthesized as previouslydescribed.¹

In vitro determinations of GG745 selectivity. The inhibition of human adrenal 3 $beta$ -hydroxy- $Delta$ ⁵-steroid dehydrogenase/3-keto- $Delta$ ⁵-steroid isomerase was measured according to Frye et al. (1995).Androgen receptor binding assays were performed by Novascreen(Hanover, MD) as described in their catalog.² Inhibitors were tested in duplicate for potency at three concentrations:10⁵, 10⁷ and 10⁹ M. For the androgen receptor assays, T, DHT and 4-MA (fig. 1),a Merck inhibitor known to be a low-affinity inhibitor of androgenbinding to the androgen receptor (Russell and Wilson, 1994), wereused as controls. All inhibitors and controls were coded by GlaxoWellcome, so their identities were unknown by Novascreen. DHTand T were found to be potent inhibitors of [³H]methyltrienolone binding to the androgen receptor, whereas 4-MAwas intermediate and of the magnitude expected (Brooks et al.,1982).

Pharmacodynamics of GG745 and finasteride in intact adult male rats. This study was designed to compare the efficacy of new 5AR inhibitors with the approved 5AR inhibitor finasteride. GG745 andfinasteride were evaluated in experiments performed on differentdays. For each inhibitor to be evaluated, male Sprague-Dawleyrats (n = 32, ranging from 200 to 225 g) were divided into fourgroups of eight on the basis of body weight. Rats in each group(n = 8) were dosed (5 ml/kg) for 14 days by oral gavage with eitherinhibitor or vehicle alone (1 part cremophor/2 parts saline/0.5%Tween 80). On day 15, each rat was killed by asphyxiation. Afterdetermination of total body weight, the adrenal glands, liver,ventral prostate, seminal vesicles and right testicle were removed,cleared of adherent tissue and weighed. The data in table 1 wereobtained using GG745 doses of 1, 10 or 100 mg/kg/day and equimolaramounts of finasteride (0.7, 7.2 or 72 mg/kg/day).

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TABLE 1
Effects of 14-day oral administration of GG745 on organ weights and body weight of intact male rats

Values are reported as mean ± S.E.M. for actual weights and percentage of vehicle control and were obtained by using the analysisof variance feature in Excel 5.0 for Windows (Microsoft, Redmond,WA). Pairwise comparisons between treatment groups were made usingt test with the Bonferroni adjustment for multiple comparisons(Kleinbaum et al., 1988

Pharmacokinetics of GG745 and finasteride in the dog. The pharmacokinetics of GG745 was determined in a total of six male beagle dogs weighing ~10 kg (Marshall Farms, North Rose,NY; Hazelton Laboratories, Cumberland, VA). Dog 1 was preparedwith two venous cannulae and received an i.v. infusion dose of5 mg/kg GG745 over a 10-min period, whereas dogs 2 to 5 were preparedsimilarly but received a i.v. bolus dose of 0.1 mg/kg. Dog 6 wasprepared with a single venous cannula and dosed by oral gavageat a dose level of 5 mg/kg. The dogs were fasted overnight beforedose administration. The doses for dogs 1 and 6 were preparedby dissolving GG745 in propylene glycol, and doses for dogs 2to 5 were prepared in 40% Molecusol (PharmaTech, Alachua, FL).After dose administration, blood samples (2 ml) were withdrawnfrom dogs 1 and 6 via the cephalic vein cannula into a heparinizedsyringe at 0 (predose), 5, 15, 30 and 45 min and 1, 1.5, 2.5,4, 6, 8 and 24 hr after the start of the infusion or oral bolusdosing. Samples were removed from dogs 2 to 5 similarly at 0 (predose),5, 15 and 30 min and 1, 2, 4, 6, 8, 10, 24, 48, 72, 96, 120, 144,168, 192, 240, 312, 360, 408, 576, 744, 912, 1080, 1248 and 1416hr. All samples were stored at $-$ 70°C in a freezer before analysis.

For comparison, the pharmacokinetic characteristics of finasteride were studied (n = 3). These dogs received finasteride throughi.v. dose administration (10 mg/kg). The finasteride dose solutionwas prepared in a 40% Molecusol water solution (pH 6). Blood sampleswere collected in a similar fashion as described for dog 1 inthe GG745 dog study.

Pharmacokinetics of GG745 and finasteride in the rat. A total of four male wu/Wistar rats (Harlan, Indianapolis, IN) with body weight ranging from 320 to 350 g were used in thestudy of GG745 pharmacokinetics. Rats were randomly divided intotwo groups. Jugular vein cannulation was performed the day beforestudy drug administration. Femoral vein cannulation was also performedin the two rats that received an i.v. dose. The first group ofrats received an i.v. dose of GG745 (1 mg/kg), and the secondgroup of rats received an oral dose of GG745 (1 mg/kg). GG745was dissolved in a 40% Molecusol water solution (pH 6) to givea concentration of 0.33 mg/ml. Blood samples were withdrawn viathe jugular cannula at 0 (predose), 15, 30 and 45 min and 1, 1.5,2.5, 4, 6, 8, 24 and 96 hr after dose administration and transferredinto heparinized microfuge tubes. The blood samples were storedat $-$ 70°C in a freezer until analysis.

For the pharmacokinetic study of finasteride, a total of 10 SpragueDawley rats (250-300 g) were purchased from the CharlesRiver Laboratory (Raleigh, NC). An i.v. bolus dose was administeredto rats in one of the lateral tail veins at 15 mg/kg. Two ratswere killed with carbon dioxide at each time point (1, 2, 4, 6and 24 hr after administration), and blood samples were collected.Blood was allowed to clot and centrifuged to obtain serum.

HPLC assay. For the analysis of GG745 blood samples, blood (100 µl) was first mixed with 300 µl of acetonitrile to precipitate protein.After centrifugation at 3500 rpm for 10 min, the supernatant wasdecanted into a fresh vial and evaporated to dryness under a gentlestream of nitrogen at 45°C. The residue was reconstituted into100 µl of HPLC mobile phase. HPLC analysis was performed usinga 5 micron Hypersil BDS C8 (25 × 0.46 cm) HPLC column. GG745 waseluted with acetonitrile and 50 mM ammonium acetate buffer (pH4.2) over a 10-min linear gradient from 50% to 80% acetonitrileat a flow rate of 1 ml/min and detected by UV at 304 nm. A similarmethod was applied to analysis of finasteride blood samples.

For the analysis of finasteride serum samples, serum was first extracted with ethyl acetate. The ethyl acetate solution wasevaporated to dryness, reconstituted into 100 µl of methanol/water(50:50 v/v), and 50 µl of the sample was analyzed by HPLC. A Spectra-PhysicsHPLC-UV system (SP8800) equipped with a 5 micron Hypersil BDSC8 (25 × 0.46 cm) HPLC column was used. The UV detection was setat 210 nm, and samples were eluted with a mobile phase consistingof acetonitrile and water (38:62 v/v) at 35°C and a flow rateof 1 ml/min.

Estimation of pharmacokinetic parameters in rat and dog. Area under the GG745 or finasteride concentration in blood or serum vs. time curve and half-life were determined with RSTRIP(MicroMath Scientific Software, Salt Lake City, UT). Pharmacokineticparameters were determined using a model-independent method.

Pharmacokinetics of GG745 and effects on DHT concentration in man. Single doses of GG745 in 7.5 ml of PEG400 were administered orally to healthy male subjects at doses ranging from 0 to 40mg. Serum samples were collected and analyzed by gas chromatography-massspectometry to quantify DHT and GG745 levels. These gas chromatography-massspectometry measurements and the following extraction were performedat Pharmaco International (Richmond, VA). Briefly, DHT and GG745were extracted from serum with an organic solvent mixture, purifiedby solid phase extraction and stored at $-$ 20°C before analysis.Samples were evaporated under nitrogen when solvent changes werenecessary. DHT-d₃ was included as an internal standard in samplesused for DHT determinations, and all steroids in these sampleswere derivatized before purification. Samples for DHT determinationswere collected at 2, 4, 8, 12 and 24 hr and 2, 3, 7, 14, 21 and28 days after dosing. GG745 determinations were made using samplescollected at 0.5, 1, 2, 3, 4, 6, 8, 12, 16 and 24 hr and 2, 3,14, 21 and 28 days after dosing. Base-line samples were also collectedfor the DHT and GG745 measurements. The analysis of these sampleswas accomplished by capillary GC/negative ion chemical ionizationms using a splitless injection with methane as the reagent gas.

	Results

Top Abstract Introduction Procedures Results Discussion References

GG745 is an extremely potent and selective inhibitor of human 5 $alpha$ -reductases. This inhibitor appears to irreversibly inhibit5 $alpha$ -reductases but is a weak and competitive inhibitor of the humanadrenal 3 $beta$ -hydroxy- $Delta$ ⁵-steroid dehydrogenase/3-keto- $Delta$ ⁵-steroid isomerase (K_I = 11 µM) and does not inhibit androgenbinding to the androgen receptor, even at a concentration of 10⁵ M. The inhibition of the isomerase is ~3 orders of magnitudeweaker than the initial K_i that describes the interactions ofGG745 with either of the human 5 $alpha$ -reductases (Tian et al., 1995).

We performed studies in the rat both to select the most potent dual 5AR inhibitor (e.g., Frye et al., 1993, 1994, 1995) andto assess the relative potency of GG745 and finasteride in ananimal model. Rats were a good choice because finasteride is apotent dual inhibitor of the rat 5ARs (Russell and Williams 1994)just as GG745 is of the rat³ and human enzymes (Tian et al., 1995). Because the potency ofthe effect of finasteride on DHT levels in man is known (Ohtawaet al., 1991; Vermeulen et al. 1989), the relative potencies ofGG745 and finasteride in rats together with our in vitro enzymologicaldata formed a good basis for estimating the potency of GG745 inman. Similarly, to estimate the half-life and suitable doses ofGG745 in man, we compared the pharmacokinetics of GG745 and finasteridein the rat and the dog.

Pharmacodynamics of GG745 and finasteride in intact adult male rats. As in man, androgens stimulate the proliferation of prostatic tissue in the rat (Frye et al., 1994; Russell and Wilson, 1994).5AR inhibitors prevent the conversion of testosterone to the morepotent androgen DHT; therefore, animals treated (2 weeks) witheither finasteride or GG745 were expected to have prostate volumessignificantly smaller than those of control animals. Consistentwith these expectations, finasteride produced a dose-related changein prostate volume. The highest dose of finasteride (72 mg/kg/day,which is equimolar to the 100 mg/kg/day doses of GG745) producedsimilar effects on prostatic volume as those observed in the GG745groups. Rats treated daily with GG745 at 1, 10 or 100 mg/kg/dayfor 2 weeks had prostates approximately half as large as thosein rats treated with vehicle alone (table 1). There was no significantdifference between the GG745 dose groups, suggesting that themaximum effect of GG745 in this model had been achieved at muchlower doses than those necessary to produce similar effects withfinasteride. Because rats were treated with GG745 and finasterideon different days and the size of the prostates in the differentcontrol groups for each experiment were different (table 1),it is difficult to directly compare the potencies of GG745 andfinasteride. Effects of GG745 and finasteride on seminal vesicleweights were similar to those on prostate weights (i.e., 50% decrease;see table 1). There were no significant differences between treatmentgroups in adrenal weight, body weight, liver weight, or testicularweights of rats at the conclusion of these studies. In addition,no significant histological changes were found in the tissuesof any of the treatment groups.

GG745 and finasteride in the dog. The half-life, total body clearance, volume of distribution at steady state and oral bioavailability of GG745 in the dog were65 hr, 0.5 ml/min/kg, 3 liters/kg and 43%, respectively. The GG745blood level reached the peak (745 ng/ml) at 2.5 hr after oraldosing. The GG745 blood concentration at the end of i.v. infusion(10 min) was 3430 ng/ml. The half-life, total body clearance andvolume of distribution at steady state of finasteride in the dogwere 3.9 hr, 4.9 ml/min/kg and 1.6 liters/kg, respectively. Thesedata are summarized in table 2.

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TABLE 2
Pharmacokinetic parameters of GG745 and finasteride in individual animals

GG745 and finasteride in the rat. The half-life, total body clearance, volume of distribution at steady state and oral bioavailability of GG745 in the rat were13.7 hr, 4.1 ml/min/kg, 4 liters/kg and 100%, respectively. TheGG745 blood level reached peak (139 ng/ml) at 7 hr after oraldosing. The GG745 blood concentration was 200 ng/ml at 15 minafter i.v. dosing. The half-life, total body clearance and volumeof distribution at steady state of finasteride in the rat were0.9 hr, 13.4 ml/min/kg and 0.6 liters/kg, respectively. Thesedata are summarized in table 2.

Dose selection and first human exposure. With the data generated in these preclinical pharmacokinetic studies (table 2), estimates of human pharmacokinetic parameterswere obtained using basic allometric principles (Boxenbaum, 1982;Ings, 1990; Mordenti, 1986). Volume of distribution (log) andsystemic clearance (log) were plotted against weight (log) (fig.2). Estimates of clearance and volume of distribution were predictedfor humans based on the relationship between body weight/sizeand pharmacokinetic parameters. Estimates of 0.7 liters/hr and180 liters were predicted for clearance and steady-state volumeof distribution for a 70-kg human. These estimates indicated thatGG745 would have a long terminal half-life of ~180 hr. This compareswith the 6- to 8-hr half-life of finasteride in man (Rittmaster,1994).

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Fig. 2. Interspecies scaling to estimate pharmacokinetic parameters of GG745. Horizontal line, predicted clearance for GG745 basedon pharmacokinetic data from the rat and dog. Note that only theresults from dog 1 treated with GG745 were used in this estimation(see table 2). The observed pharmacokinetic parameters determinedafter the administration of a single oral dose of GG745 to humansare plotted for comparison. Absolute bioavailability studies conductedin animals indicate that GG745 is ~50% absorbed. Therefore, theactual clearance and distribution volume in man may be closerto the predicted values than indicated in the graph.

Second, a target GG745 concentration was estimated for humans through analysis of data from the rat pharmacodynamic studyand indexing of the result to published clinical literature onfinasteride. Although it is difficult to directly compare thepotencies of GG745 and finasteride on the basis of table 1, bothGG745 and finasteride are orally bioavailable steroidal inhibitorsof the types 1 and 2 rat 5 $alpha$ -reductase and can be assumed to achieveequivalent inhibition of prostatic growth at maximally effectivedoses. Because GG745 achieves a maximal effect at 1 mg/kg/dayand a peak blood level at 140 ng/ml, whereas finasteride achievesa maximal effect at 70 mg/kg/day and a peak blood level at 7840ng/ml, an estimated potency ratio of 56 based on the peak bloodlevels was used in the prediction of GG745 human dose. In humans,the relationship between single doses of finasteride and maximalDHT suppression appeared to become asymptotic (approaching maximumeffective exposure) at doses of 50 to 100 mg (De Schepper et al.,1991). The mean peak plasma concentration (C_max) observed aftera single 100-mg dose of finasteride was ~836 ng/ml (Ohtawa etal., 1991

). Using the in vivo potency of 56:1, a target GG745concentration of ~15 ng/ml was estimated to be needed to reachthe top of the GG745 dose-response (DHT reduction) curve.

Pharmacokinetic simulations were performed using the parameters determined from interspecies scaling. Absorption was consideredto be rapid and complete. Based on these assumptions, a dose of3 mg was estimated to provide peak concentrations of ~15 ng/mland provide significant DHT suppression.

Because GG745 was expected to have a long terminal half-life, a conservative starting dose of 0.01 mg was selected. This dosewas ~2 orders of magnitude lower than the proposed clinicallyeffective dose of 3 mg and was well below doses found to produceno toxicologically significant findings in long-term toxicologystudies.

Subsequently, 48 healthy male subjects received single oral doses of GG745, placebo or finasteride (5 mg) in a randomized,blinded, sequential-cohort dose-escalation study. GG745 dosesof 0.01 to 40 mg were studied in cohorts consisting of four GG745,one placebo and one finasteride subject. Doses were escalatedin subsequent groups after an evaluation of safety. Serial serumsamples were collected for determination of circulating DHT andGG745 concentrations. DHT samples were assayed via GC-MS witha limit of detection of 10 pg/ml and interday coefficient of variationof $<=$ 9.5%. These data are shown in table 3. GG745 samples wereassayed via a liguid chromatography-MS method with a limit ofdetection of 0.1 ng/ml and interday coefficient of variation of $<=$ 11.6% (Morris et al., 1995

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TABLE 3
Effects of a single oral GG745 dose on blood DHT levels in man

Pharmacokinetics. Pharmacokinetic parameters were determined using standard noncompartmental methods. The parameters determined in humans wereconsistent with estimates obtained from interspecies scaling (seefig. 2 and table 3). For doses in which the pharmacokinetic profilewas fully described, the clearance, steady-state volume of distributionand terminal half-life were 1.3 liters/hr, 385 liters and 247hr, respectively. The model predicted (based on interspecies scaling)peak concentration after the 2.5-mg dose was 12.5 ng/ml, whichcompared well with the observed mean peak of 14.3 ng/ml.

Pharmacodynamics. GG745 produced dose-related decreases in DHT (table 3). DHT reduction across GG745 dose groups were compared with finasterideusing a general linear model with pairwise comparisons. Responsesto GG745 increased sharply at doses of 0.1 to 2.5 mg and startedto asymptote at doses of >5 to 10 mg. This agrees well with the3 mg that was predicted based on the preclinical data for GG745obtained in rat and dog.

	Discussion

Top Abstract Introduction Procedures Results Discussion References

The goal of our discovery program was to identify a molecule that was a potent inhibitor of both human isozymes with suitableselectivity and drug properties for administration to patients.This goal was based on the postulate that finasteride is potentin the rat because it inhibits both rat isozymes (Russell andWilson, 1994) but is only partially effective in man (Moore etal., 1995) due to its inability to effectively inhibit the type1 5AR (Tian et al., 1994; Tian, 1996). Although the type 1 5ARis expressed primarily in skin and the liver (Thigpen et al.,1993), the virilization at puberty of pseudohermaphrodites lackingtype 2 5AR correlates with increasing type 1 5AR expression inskin (Thigpen et al., 1993). This suggests that DHT can have paracrineeffects and that effective control of DHT actions requires theinhibition of both the type 1 and 2 5ARs.

Because finasteride is potent against both rat isozymes, a drug molecule that is a potent inhibitor of all human and rat isozymeswas expected to be equally effective in the rat as finasteride.The identification of such molecules justified pharmacokineticstudies of these candidates in the rat and dog to evaluate theirdrug properties. On the basis of these studies, GG745 was chosento test the hypothesis that a potent inhibitor of both human 5 $alpha$ -reductaseswould be more effective than finasteride at reducing serum DHTlevels in man and, ultimately, the symptoms of BPH.

In vitro, GG745 was shown to be a potent and selective inhibitor of both human 5 $alpha$ -reductases; in fact, GG745 is nearly aspotent against the type 1 5AR as finasteride is against the type2 enzyme (Tian et al., 1995). Both finasteride and GG745 wereeffective at reducing prostate weights when administered to rats,with GG745 appearing to be more potent than finasteride (table1). This increased potency likely results largely from the longerhalf-life and decreased total body clearance of GG745 comparedwith finasteride in the rat (table 2).

GG745 showed a longer terminal half-life than finasteride in both dog and rat. The long terminal half-life of GG745 (65 hr)in the dog was the result of low total body clearance (0.5 ml/min/kg)and high volume of distribution (3 liters/kg) compared with finasteride.The half-life of GG745 in the rat was shorter (14 hr) than thatin the dog; this is due to the higher total body clearance ofGG745 in the rat. A similar pharmacokinetic pattern in the dogand rat was also observed for finasteride. The half-life of finasteridein the dog (4 hr) was longer than that in the rat (1 hr). Theterminal half-life of finasteride in humans (6-8 hr) was longerthan that observed in the dog (Carlin et al., 1992; Rittmaster,1994). These information provided added confidence in the estimatesof human GG745 pharmacokinetic parameters from interspecies scaling.

Single oral doses of GG745 of >10 mg decreased DHT significantly more than finasteride. The level of DHT reduction attainedby administration of GG745 was >90% at the maximal doses usedin this study. Finasteride, in contrast, decreased DHT levelsby ~70% at single doses of 40 mg (Vermeulen et al., 1989) and100 mg (Ohtawa et al., 1991). Increasing the dose of finasteridefrom 5 to 100 mg achieved negligible further reduction in serumDHT (Ohtawa et al., 1991; Vermeulen et al., 1989), which is consistentwith an interpretation that finasteride effectively inhibits thetype 2 but not type 1 5 $alpha$ -reductase. From the results of thesestudies, we conclude that GG745, a potent dual inhibitor of human5 $alpha$ -reductases, is more effective than finasteride, a type 2 5ARselective inhibitor, in reducing serum DHT levels in man. Furtherstudies will determine whether this greater reduction in serumDHT concentrations offers clinical advantages.

	Acknowledgments

The hard work and dedication of the 5AR project team are gratefully acknowledged.

	Footnotes

Accepted for publication May 12, 1997.

Received for publication October 7, 1996.

¹ Patent WO95/07927, March 23, 1995.

² Receptor Assay Descriptions, 1994.

³ D. Stuart, unpublished observations.

Send reprint requests to: H. Neal Bramson, Glaxo Wellcome Research Institute, 5 Moore Drive, Research Triangle Park, NC 27709.

	Abbreviations

BPH, benign prostatic hyperplasia; i.v., intravenous; 5AR, 3-oxo-steroid- $Delta$ ⁴-reductase; r5AR1, rat 5 $alpha$ -reductase 1; r5AR2, rat 5 $alpha$ -reductase 2; GC, gas chromatography; ms, mass spectometry; GG745, 17 $beta$ -N-(2,5-bis(trifluoromethyl))phenyl-carbamoyl-4-aza-5 $alpha$ -androst-1-en-3-one; finasteride, 17 $beta$ -[N-(1,1-dimethylethyl)carbamoyl]-4-aza-5 $alpha$ -androst-1-en-3-one; 4-mA, 17- $beta$ -N,N-diethylcarbamoyl-4-methyl-4-aza-5 $alpha$ -androstan-3-one; T, testosterone; DHT, dihydrotesterone; HPLC, high-performance liquid chromatography; NADPH, nicotinamide adenine dinucleotide phosphate.

	References

Top Abstract Introduction Procedures Results Discussion References

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