Pharmacokinetics and Pharmacodynamics of Nandrolone Esters in Oil Vehicle: Effects of Ester, Injection Site and Injection Volume

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Vol. 281, Issue 1, 93-102, 1997

Pharmacokinetics and Pharmacodynamics of Nandrolone Esters in Oil Vehicle: Effects of Ester, Injection Site and Injection Volume¹

Charles F. Minto, Christopher Howe, Susan Wishart, Ann J. Conway and David J. Handelsman

Department of Anaesthesia and Pain Management, Royal North Shore Hospital (C.F.M.), and Andrology Unit, Royal Prince Alfred Hospital, Department of Medicine (C.H., S.W., A.J.C., D.J.H.), University of Sydney, Sydney, Australia

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

We studied healthy men who underwent blood sampling for plasma nandrolone, testosterone and inhibin measurements before andfor 32 days after a single i.m. injection of 100 mg of nandroloneester in arachis oil. Twenty-three men were randomized into groupsreceiving nandrolone phenylpropionate (group 1, n = 7) or nandrolonedecanoate (group 2, n = 6) injected into the gluteal muscle in4 ml of arachis oil vehicle or nandrolone decanoate in 1 ml ofarachis oil vehicle injected into either the gluteal (group 3,n = 5) or deltoid (group 4, n = 5) muscles. Plasma nandrolone,testosterone and inhibin concentrations were analyzed by a mixed-effectsindirect response model. Plasma nandrolone concentrations wereinfluenced (P < .001) by different esters and injection sites,with higher and earlier peaks with the phenylpropionate ester,compared with the decanoate ester. After nandrolone decanoateinjection, the highest bioavailability and peak nandrolone levelswere observed with the 1-ml gluteal injection. Plasma testosteroneconcentrations were also influenced (P < .001) by the ester andinjection site, with the most rapid, but briefest, suppressionbeing due to the phenylpropionate ester, whereas the most sustainedsuppression was achieved with the 1-ml gluteal injection. Plasmainhibin concentrations were also significantly influenced by injectionvolume and site, with the lowest nadir occurring after the nandrolonedecanoate 1-ml gluteal injection. Thus, the bioavailability andphysiological effects of a nandrolone ester in an oil vehicleare greatest when the ester is injected in a small (1 ml vs. 4ml) volume and into the gluteal vs. deltoid muscle. We concludethat the side-chain ester and the injection site and volume influencethe pharmacokinetics and pharmacodynamics of nandrolone estersin an oil vehicle in men.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

For decades, administration of androgens such as testosterone and 19-nor-testosterone has been most frequently via depot i.m.injections of steroid esters dissolved in a vegetable oil vehicle(Junkman, 1957; Behre et al., 1990). Such i.m. injections providesustained androgen release into the circulation and have remainedthe mainstay of androgen replacement therapy for the last fewdecades (Nieschlag and Behre, 1990), although the basic pharmacologicalmechanisms are complex and only partially understood (Zuidemaet al., 1988). The basic pharmacology of this depot androgen formulationdiffers among species (van der Vies, 1965) but has been littlestudied in humans. The current understanding is that the rate-limitingmechanism governing the appearance of active steroid in the bloodstreamis the retention of steroid esters from the oil vehicle depotdue to oil/water partitioning, with gradual release into the extracellularfluid, where esters are rapidly hydrolyzed to liberate biologicallyactive steroid. Other physiological and physico-chemical factorsthat could influence steroid appearance in the bloodstream includethe chemistry of the side-chain ester (hydrophobicity, sterichindrance of hydrolysis and solubility), injection factors (depth,site and volume, pH and osmolarity of the solution), exerciseand systemic illness. The influence of site and volume of injectionon the release kinetics of androgen esters from oil vehicle depotshas, however, not been systematically investigated in humans.

This study compared the pharmacokinetics and pharmacodynamics of two currently available esters of nandrolone, the decanoateand phenylpropionate, as well as the influence of i.m. injectionsites (gluteal vs. deltoid) and injection volumes (4 ml vs. 1ml). In addition to measuring plasma nandrolone to investigatepharmacokinetics, we measured plasma testosterone and inhibinby radioimmunoassay to determine the pharmacodynamic effects ofnandrolone-induced inhibition of pituitary gonadotrophin secretion,as reflected in LH-dependent Leydig (testosterone) and FSH-dependentSertoli (inhibin) cell function in healthy men. We analyzed thesedata using an indirect pharmacodynamic response model, which hasdemonstrated, for the first time, prominent pharmacological differencesbetween esters differing in only a single carbon in the side-chain,as well as systematic differences attributable to injection siteand volume in humans.

	Materials and Methods

Top Abstract Introduction Materials & Methods Results Discussion References

Experimental design. Twenty-three healthy volunteers were randomly allocated into four groups in two balanced blocks. The first stratum of thestudy involved comparing two different nandrolone esters whilecontrolling for dose, injection site and volume. In this stratum,volunteers received either nandrolone phenylpropionate (Durabolin;Organon) (group 1) or nandrolone decanoate (DecaDurabolin; Organon)(group 2), administered as a single deep i.m. injection of 100mg nandrolone ester into a single injection site (gluteal) ina fixed volume (4 ml of arachis oil vehicle). In the second stratum,a single ester (nandrolone decanoate) with fixed dose (100 mg)and volume (1 ml of arachis oil vehicle) was injected into twodifferent sites, gluteal (group 3) or deltoid (group 4) muscles.This design also allowed comparison between different injectionvolumes (4 ml vs. 1 ml) for a single nandrolone ester with fixeddose and injection site (i.e., group 2 vs. group 3).

Subjects. Healthy nonobese men, 18 to 40 years of age, with normal reproductive function, not competing in sports requiring InternationalOlympic Committee-sanctioned urinary drug screening for anabolicsteroids, not allergic to peanuts, free from chronic medical illness,not requiring regular prescribed medication and without abnormalitiesin routine clinical examination and biochemical screening wererecruited. Fully informed written consent was obtained from volunteers,and the study had approval from the University of Sydney HumanEthics Committee within National Health and Medical Research CouncilGuidelines on Human Experimentation, which conform to the Declarationof Helsinki.

Procedures. Blood (5 ml) was sampled before injection (8:00-9:00 A.M.) and at 1, 2, 4, 6, 8 and 10 hr and 1, 2, 3, 4, 7, 9, 11, 14, 16,18, 21, 23, 25, 28, 30 and 32 days after injection. During thefirst 10 hr, the participants were in a metabolic ward facilityand were allowed to undertake normal daily activities. Subsequently,participants returned for blood sampling on an ambulatory basiswhile resuming their habitual daily activities.

To calculate absolute bioavailability, two additional subjects received a single i.v. bolus of 1 mg of 19-nor-testosterone,with sampling before injection and at 2, 4, 6, 8, 10, 15, 20,30, 45, 60, 120, 180, 240, 360, 480, 720, 900, 1440, 1980 and2880 min. For this study, crystalline nandrolone (Steraloids Inc.,Wilton, NH) was dissolved in dehydrated ethanol BP (David BullLaboratories, P/L, Mulgrave, Australia) at a concentration of40 g/liter, from which a nandrolone stock solution (2 mg/ml in15% ethanol) was produced by appropriate dilution with sterilesaline. The nandrolone stock was filtered through a 0.2-µm celluloseacetate filter (Minisart NML; Sartorius GmBH, Gottingen, Germany),and the first 1 ml was discarded. Preliminary experiments showedthat >80% of tracer nandrolone was recovered after such filtration.At the start of the study, the stock solution was diluted 10-foldwith sterile normal saline in a 20-ml syringe (final ethanol concentration,1.5%) and 5.0 ml was infused rapidly (within 10 sec) via an indwellingcannula in a forearm vein (nominal dose, 1.0 mg), followed bya flush of the syringe and cannula with an additional 5 ml ofsterile saline solution. Aliquots of the injection solution werekept for subsequent assay of the exact amount of nandrolone administered.Blood sampling was from another cannula placed in the other arm.

Assays. Plasma samples were stored at $-$ 20°C until assay in a single batch per analyte. Steroids were measured by radioimmunoassayafter extraction from plasma by a modification of a solid-phasemethod (Vining, 1980). Serum (200 µl for the nandrolone assayand 75 µl for the testosterone assay) was applied to a 5-cm mini-columnof Extrelut (kieselguhr; Merck, Kilsyth, Australia) packed ina Pasteur pipette. Steroids were eluted by four washes of 750µl of hexane/ethyl acetate (3:2) at 5-min intervals, the combinedeluate was dried and the extract was reconstituted in assay buffer.Extraction efficiency was 97 ± 5% (n = 29) for testosterone and90 ± 5% (n = 25) for nandrolone; therefore, no corrections weremade for extraction losses. Radioactivity was measured with aWallac 1410 liquid scintillation counter (Wallac Oy, Turku, Finland)and a LKB 1261 Multigamma gamma counter (Wallac Oy), using RIACALCdata reduction software on an IBM-compatible computer. All steroidassay reagents were of analytical or higher grade.

Plasma nandrolone was measured by radioimmunoassay using a rabbit antibody to 19-nor-testosterone 17-hemisuccinate-bovineserum albumin (CER, Marloie, Belgium), tritiated tracer (19-[19-³H]nor-testosterone; specific activity, 1.37 TBq/mmol; Amersham,North Ryde, Australia), nandrolone standard (Steraloids), extractsof plasma equivalent to 100 µl/tube and a dextran-charcoal separationof bound and free steroid. Cross-reactivities (expressed as molarratios at the ED₅₀) with testosterone (0.04%), dihydrotestosterone(0.7%), androstenedione (0.3%), estradiol (0.02%), nandrolonephenylpropionate (6.3%) and nandrolone decanoate (1.3%) were negligiblein relation to circulating levels. The assay detection limit (B/Bo= 0.90) was 8 pg/tube (equivalent to 0.25 nM), and the ED₅₀ was100 pg/tube (equivalent to 3.5 nM). Coefficients of variationat low ( $approx$ ED₈₀), medium ( $approx$ ED₅₀) and high ( $approx$ ED₂₀) levels of thestandard curve (n = 16-24 assays) were 11.7, 9.8 and 11.9% (between-assay)and 6.2, 3.5 and 5.3% (within-assay), respectively.

Plasma testosterone was measured by radioimmunoassay using a rabbit antibody to testosterone-3-O-carboxymethyloxime-bovineserum albumin (SGT-1, supplied by Dr. B. Caldwell, Yale University),[1,2,6,7,16,17(N)-³H]testosterone (specific activity, 5.00-6.66 TBq/mmol; DuPont,North Ryde, Australia), testosterone standard (Steraloids), extractsof plasma equivalent to 12.5 µl/tube and a dextran-charcoal separationof bound and free steroid. Correction was made for cross-reactivitywith nandrolone (20.5%), but cross-reactivities with dihydrotestosterone(21.1%), androstenedione (2.5%), estradiol (0.17%), nandrolonephenylpropionate (0.04%) and nandrolone decanoate (<0.0002%) werenegligible in relation to circulating levels. The assay detectionlimit (B/Bo = 0.90) was 2 pg/tube (equivalent to 0.6 nM), andthe ED₅₀ was 22 pg/tube (equivalent to 6 nM). Coefficients ofvariation at low ( $approx$ ED₈₀), medium ( $approx$ ED₅₀) and high ( $approx$ ED₂₀) levelson the standard curve (n = 8-32 assays) were 12.6, 17.1 and 12.9%(between-assay) and 8.3, 3.7 and 6.0% (within-assay), respectively.

Plasma inhibin was measured by a heterologous double-antibody radioimmunoassay established in our laboratory (Handelsman etal., 1990

; Crawford and Handelsman, 1994

) and validated for humans(McLachlan et al., 1990

; Burger, 1992

; Dong et al., 1992

; Wallaceet al., 1993

). Reagents, provided by Dr. G. Bialy (ContraceptiveDevelopment Branch, National Institute of Child Health and HumanDevelopment), were rabbit antiserum to bovine inhibin (rAs-1989),purified 31-kDa inhibin from bovine follicular fluid for iodination(bINH-R-90/1) and bovine inhibin standard (bINH-R-90/1). Duplicateplasma samples (100 µl) were preincubated overnight with antibodybefore addition of ¹²⁵I-labeled inhibin. The standard curve was blanked with castratehuman serum to equalize serum protein concentrations in the assaytubes. The detection limit (B/B₀ = 0.90) was 19.5 pg/ml, and coefficientsof variation at inhibin standard levels of 90, 200 and 390 pg/mlwere 3.1, 7.3 and 7.4% (between-assay) and 1.8, 3.0 and 5.0% (within-assay),respectively.

Data analysis. Plasma nandrolone, testosterone and inhibin levels were initially analyzed to evaluate the full time course for each hormoneby repeated-measures analysis of variance with BMDP 5V software(Dixon, 1992), testing main effects by the Wald $chi$ ² test and using suitable linear contrasts to define effects ofester, injection site and volume. Due to the very different timecourses of the phenylpropionate and decanoate esters, the threegroups (groups 2-4) receiving the decanoate ester were also analyzedseparately.

Plasma nandrolone levels were also analyzed by standard pharmacokinetic methods involving polyexponential curve fitting (Gibaldiand Perrier, 1982

), with a weighted, nonlinear, least-squares,curve-fitting algorithm, by BMDP 3R software (Dixon, 1992

). Standardpharmacokinetic parameters (time of peak, peak concentration,mean residence time, apparent half-times for absorption and clearance,systemic clearance and area under the curve) were derived empiricallyfrom the plasma nandrolone concentrations and as mathematicalfunctions of the coefficients of the best-fit curve (Gibaldi andPerrier, 1982

). Estimates of absolute bioavailability of nandrolonewere calculated from the disappearance curves of plasma nandroloneafter i.v. administration, by fitting to a variance-weighted,triexponential curve with corrections for the molecular weightof nandrolone (274.4) and its decanoate (428.7) and phenylpropionate(406.6) esters.

This pharmacokinetic analysis was subsequently extended by building a population pharmacokinetic model using the approachof Mandema et al. (1992)

. The plasma concentration of nandrolonewas considered to be the convolution of a monoexponential or biexponentialabsorption function with a biexponential unit disposition function

UDF<IT>=</IT><LIM><OP>∑</OP><LL><IT>i</IT>=<IT>1</IT></LL><UL><IT>2</IT></UL></LIM><IT> A<SUB>i</SUB> · e</IT><SUP>−<IT>&lgr;<SUB>i</SUB> · t</IT></SUP>

(1)

The input rate (IR) for the monoexponential absorption model is given by

IR<IT>=D · F · k · e</IT><SUP>−<IT>k · t</IT></SUP>

(2)

where D is the dose, F is the fraction absorbed (bioavailability) and k is the first-order absorption rate constant. Theinput rate for the biexponential absorption model is given by

IR<IT>=D · F · </IT>[<IT>P · k<SUB>1</SUB> · e</IT><SUP>−<IT>k<SUB>1</SUB> · t</IT></SUP><IT>+</IT>(<IT>1−P</IT>)<IT> · k<SUB>2</SUB> · e</IT><SUP>−<IT>k<SUB>2</SUB> · t</IT></SUP>]

(3)

where k₁ and k₂ are first-order absorption rate constants, P is the proportion of the bioavailable dose absorbed by k₁ and(1 $-$ P) is the proportion of the bioavailable dose absorbed byk₂. The convolution of these input functions with a biexponentialdisposition function yielded equations 4 and 5, which describethe plasma concentrations over time after i.m. injection for themonoexponential and biexponential absorption models, respectively.

Cp(t)=D · F · k · <LIM><OP>∑</OP><LL>i=<IT>1</IT></LL><UL><IT>2</IT></UL></LIM><IT> </IT><FR><NU><IT>A</IT><SUB><IT>i</IT></SUB></NU><DE><IT>k−&lgr;</IT><SUB><IT>i</IT></SUB></DE></FR><IT> </IT>(<IT>e</IT><SUP>−<IT>&lgr;<SUB>i</SUB> · t</IT></SUP><IT>−e</IT><SUP>−<IT>k · t</IT></SUP>)

(4)

<LIM><OP>∑</OP><LL>i=<IT>1</IT></LL><UL><IT>2</IT></UL></LIM><IT> </IT><FENCE><FR><NU><IT>k<SUB>1</SUB> · P · A</IT><SUB><IT>i</IT></SUB></NU><DE><IT>k<SUB>1</SUB>−&lgr;</IT><SUB><IT>i</IT></SUB></DE></FR><IT> </IT>(<IT>e</IT><SUP>−<IT>&lgr;<SUB>i</SUB> · t</IT></SUP><IT>−e</IT><SUP>−<IT>k<SUB>1</SUB> · t</IT></SUP>)<IT>+</IT><FR><NU><IT>k<SUB>1</SUB> · </IT>(<IT>1−P</IT>)<IT> · A</IT><SUB><IT>i</IT></SUB></NU><DE><IT>k<SUB>2</SUB>−&lgr;</IT><SUB><IT>i</IT></SUB></DE></FR><IT> </IT>(<IT>e</IT><SUP>−<IT>&lgr;<SUB>i</SUB> · t</IT></SUP><IT>−e</IT><SUP>−<IT>k<SUB>2</SUB> · t</IT></SUP>)</FENCE>

(5)

The population pharmacokinetic model did not include the data from the two subjects who received nandrolone i.v. Thus, parameterF was not identifiable and was incorporated into the models asF·A₁ and F·A₂. The interindividual error on each of the modelparameters was modeled using a logarithmic-normal variance model

P<SUB>i</SUB>=&thgr;<SUB>TV</SUB><IT>e</IT><SUP><IT>&eegr;</IT><SUB><IT>i</IT></SUB></SUP>

where P_i is the value of the parameter in the individual, $theta$ _TV is the typical value of the parameter in the population and $eta$ is a random variable with mean 0 and variance $omega$ ². The estimates of $omega$ obtained with NONMEM are similar to the coefficientof variation for the parameter, which we report as the populationvariability, expressed as a percentage. We used a "constant coefficientof variation" model for the variance of the intraindividual residualerror. Empirical Bayesian estimates of the individual pharmacokineticparameters were obtained based on the typical values of the structuralmodel parameters and on the variances of the interindividual errors.These population pharmacokinetic models were implemented withthe computer program NONMEM (Beal and Sheiner, 1992

We used a GAM (Chambers and Hastie, 1993

) to permit identification of linear and nonlinear relationships between the Bayesianestimates of individual model parameters and the volunteer covariates(ester, site and volume of injection, group, age, weight, height,body surface area and lean body mass). The model that resultedin the biggest decrease in the Akaike information criterion wasreturned by the GAM function as the best model. The structuralmodel incorporating covariates identified by the GAM analysiswas then evaluated with NONMEM to develop the final parameterestimates. The final model was examined for parsimony by exclusionof individual covariates and demonstration of a statisticallysignificant increase in the NONMEM objective function and by analysisof the standard errors of the estimated parameters.

Pharmacodynamics. The pharmacodynamic effects of nandrolone on plasma testosterone and inhibin were estimated by nadir concentration, time ofnadir, net secretion and duration of suppression. The durationof suppression was defined as the time when plasma testosteronelevels were below normal (<10 nM) or inhibin levels were reducedby 50% of base line. The effects of ester, injection site andvolume were determined by parametric (testosterone) and nonparametric(inhibin) analysis of variance.

This pharmacodynamic analysis was extended by building a population pharmacodynamic model, again using the approach of Mandemaet al. (1992)

. The pharmacodynamic model was based on one of thefour basic indirect response models recently proposed by Daynekaet al. (1993)

. Because testosterone and inhibin secretion areboth suppressed by nandrolone, model I of Dayneka et al. was physiologicallythe most appropriate to describe the pharmacodynamic effects ofnandrolone and is shown in equation 6.

<FR><NU>dR</NU><DE>dt</DE></FR>=k<SUP><IT>0</IT></SUP><SUB>in</SUB><IT> · </IT><FENCE><IT>1−</IT><FR><NU><IT>Cp</IT>(<IT>t</IT>)</NU><DE><IT>Cp</IT>(<IT>t</IT>)<IT>+</IT>IC<SUB><IT>50</IT></SUB></DE></FR></FENCE><IT>−k</IT><SUB>out</SUB><IT> · R</IT>(<IT>t</IT>)

(6)

R represents the measured response variable (either testosterone or inhibin concentrations), k_in⁰ is a zero-order rate constant (the base-line testosterone orinhibin daily input rate), Cp(t) is the plasma concentration ofthe inhibiting drug (nandrolone) as a function of time and IC₅₀is the drug concentration that results in 50% of maximum inhibitionof the production rate. Under steady-state base-line conditions,it is noted that k_in⁰ = k_out · R₀, where R₀ is R(t) at t = 0, reducing the number ofparameters in the model. We have modified equation 6 to allowfor incomplete inhibition of testosterone and inhibin synthesisby nandrolone and have included a parameter ( $gamma$ ) to describe thesteepness of this relationship

<FR><NU>dR</NU><DE>dt</DE></FR>=k<SUB>out</SUB><IT> · </IT><FENCE><IT>R<SUB>0</SUB>+</IT>(<IT>R</IT><SUB>min</SUB><IT>−R</IT><SUB><IT>0</IT></SUB>)<IT> · </IT><FENCE><FR><NU><IT>Cp</IT>(<IT>t</IT>)<SUP><IT>&ggr;</IT></SUP></NU><DE><IT>Cp</IT>(<IT>t</IT>)<SUP><IT>&ggr;</IT></SUP><IT>+</IT>IC<SUB><IT>50</IT></SUB><SUP><IT>&ggr;</IT></SUP></DE></FR></FENCE></FENCE><IT>−k</IT><SUB>out</SUB><IT> · R</IT>(<IT>t</IT>)

(7)

where, for either testosterone or inhibin, R(t) is the measured concentration, R₀ is the base-line concentration, R_min isthe minimum concentration when the input rate is maximally suppressedby nandrolone, k_out is the first-order elimination rate constant,Cp(t) is the predicted plasma concentration for nandrolone (basedon individual dosing and Bayesian pharmacokinetic parameter estimates)and IC₅₀ is the concentration of nandrolone associated with 50%suppression of synthesis. The parameter $gamma$ was implemented as $gamma$ = 1 + $theta$ , to enable a comparison of the full model ( $gamma$ > 1) andreduced model ( $gamma$ = 1, $theta$ = 0) using the likelihood ratio test.

Alternatively, partial inhibition of the input rate can be modeled with an additional term expressing the fractional inhibition(I_max), as shown in equation 8.

<FR><NU>dR</NU><DE>dt</DE></FR>=k<SUP><IT>0</IT></SUP><SUB>in</SUB><IT> · </IT><FENCE><IT>1−</IT><FR><NU><IT>I</IT><SUB>max</SUB><IT> · Cp</IT>(<IT>t</IT>)</NU><DE><IT>Cp</IT>(<IT>t</IT>)<IT>+</IT>IC<SUB><IT>50</IT></SUB></DE></FR></FENCE><IT>−k</IT><SUB>out</SUB><IT> · R</IT>(<IT>t</IT>)

(8)

We used the parameterization shown in equation 7, because we were interested in estimating the base-line and maximally suppressedconcentrations of testosterone and inhibin (and the interindividualvariability in these parameters) directly. Based on the parameterizationin equation 7, I_max is readily calculated as

I<SUB>max</SUB><IT>=1−</IT><FR><NU><IT>R</IT><SUB>min</SUB></NU><DE><IT>R</IT><SUB><IT>0</IT></SUB></DE></FR>

(9)

The interindividual errors in the model parameters (R_o, R_min, k_out, IC₅₀ and $gamma$ ) were assumed to have a logarithmic-normaldistribution, and the variance of the residual errors was assumedto be homoscedastic. As described for the pharmacokinetic analysis,a GAM was used to identify significant covariates, and NONMEMwas used to develop the final pharmacodynamic model. All dataare expressed as mean ± S.E.M.

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Volunteers randomized into the four groups were comparable in anthropometric and hormonal variables (table 1). There wereno significant differences between groups in mean dehydroepiandrosteronesulfate, LH, FSH, prolactin, insulin-like growth factor-I, hemoglobin,urea or creatinine concentrations (data not shown), which werenormal for all men.

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TABLE 1
Base-line anthropometric and endocrine variables

Global statistical analysis. Considering all four groups, global statistical analysis demonstrated significant differences in the time course of plasmanandrolone concentrations (group, $chi$ ² = 84.6, 3 dF, P < .001 by Wald test; group × time interaction, $chi$ ² = 643, 66 dF, P < .001). These systematic differences were attributableto differences between different nandrolone esters (table 2).Similarly the time course of plasma testosterone concentrationsvaried significantly by group (group × time interaction, $chi$ ² = 266, 66 dF, P < .001) due to effects of both ester and injectionsite (table 2). To adjust for the dominating effect of differencesbetween esters, a global analysis conducted for the three groupsreceiving nandrolone decanoate (groups 2-4) demonstrated significanteffects of injection site on plasma nandrolone levels, as wellas effects of injection volume and site on plasma testosteroneand inhibin levels (table 3).

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TABLE 2
Global statistical analysis of plasma nandrolone and testosterone after nandrolone ester injection by time course, ester,injection site and volume

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TABLE 3
Global statistical analysis of plasma nandrolone, testosterone and inhibin after nandrolone decanoate injection by time course,injection site and volume

Pharmacokinetic analysis. Plasma nandrolone concentrations reached higher and earlier peak concentrations and had a shorter mean residence time afterinjection of the phenylpropionate ester (group 1; n = 7), comparedwith the other three decanoate ester groups (fig. 1; tables 2and 4). Analysis of the concentration data obtained from thetwo subjects who received i.v. nandrolone gave the following values:area under curve/unit dose = 1.3224 × 10³ days/liter, mean residence time = 25.65 ± 5.22 min, volume ofdistribution = 11.46 ± 0.30 liters and systemic clearance = 31.52± 7.26 liters/hr. From the optimal triexponential curve fit, thefollowing parameters were estimated: A = 153.3 ± 2.7 nM, $alpha$ = 0.4132± 0.0030 min¹, B = 8.8659 ± 0.4575 nM, $beta$ = 0.0098 ± 0.0022 min¹, C = 0.9708 ± 0.0066 nM and $gamma$ = 0.00043 ± 0.00045 min¹. Based on the area under the curve estimates for these two subjects,the absolute bioavailability of nandrolone from i.m. injectionsof esters was significantly higher for nandrolone decanoate injectedinto gluteal muscle with a 1-ml volume (73%), compared with theother three groups (53-56%).

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Fig. 1. Time course of plasma nandrolone concentrations in 23 healthy men over 32 days after i.m. injection of 100 mg of nandrolonephenylpropionate in 4 ml of arachis oil vehicle into the glutealmuscle (group 1) ( $black-diamond$ ) or injection of 100 mg of nandrolone decanoateinto the gluteal muscle in 4 ml of arachis oil vehicle (group2) ( $open circle$ ), into the gluteal muscle in 1 ml of arachis oil vehicle(group 3) ( $bullet$ ) or into the deltoid muscle in 1 ml of arachis oilvehicle (group 4) ( $black-square$ ). Results are expressed as mean and S.E.M.,unless the S.E. is smaller than symbol.

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TABLE 4
Pharmacokinetic variables

The final population pharmacokinetic model incorporated ester, site and volume of injection and height as significant covariates.Height was significantly superior to weight, body surface areaor lean body mass as a covariate. The type of ester influencedthe absorption profile of nandrolone, such that the phenylpropionateester was best described by a one-compartment absorption modeland the decanoate ester was best described by a two-compartmentabsorption model. This was implemented in the model with parameterP (table 5). The interpretation of this parameter was that, effectively,the total dose of the phenylpropionate ester is administered intothe "fast" compartment characterized by the rapid absorption rateconstant (k₁), whereas only ~14% of the total dose of the decanoateester is administered into this compartment, with the remaining~86% of the total dose being administered into the "slow" compartmentcharacterized by a slower absorption rate constant (k₂). Thisbasic difference in the profiles of the nandrolone concentrationdata is shown in figure 2. In figure 2, the individual in eachof the four groups with the median mean absolute prediction errorwas selected to represent the Bayesian predictions based on theindividual pharmacokinetic parameters. In addition, the rate ofabsorption from the fast compartment (k₁) was greater for thedeltoid muscle than the gluteal muscle.

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TABLE 5
Nandrolone population pharmacokinetic model

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Fig. 2. Observed and model-predicted time course of plasma nandrolone concentrations in four healthy men over 32 days after i.m. injectionof 100 mg of nandrolone ester. The four men were selected fromeach of the treatment groups according to the median predictederror in nandrolone concentrations, so that they were most representativeof that group. Note the logarithmic vertical scale. $bullet$ , observeddata; $---$ $---$ , individual Bayesian predictions.

A two-compartment disposition function performed significantly better than a one-compartment disposition function. Site andvolume of injection were important covariates for the two parameters,with bioavailability as a component (F·A₁ and F·A₂). F·A₁ wasgreater in the gluteal muscle, compared with the deltoid muscle,and F·A₂ was greater with a smaller injection volume (1 ml vs.4 ml). Although the slow hybrid rate constant $lambda$ ₂ was difficultto estimate accurately, it describes the very slow terminal eliminationphase (fig. 2) and significantly improved the logarithmic-likelihoodobjective function of the model, as exemplified by the improvedfit of the two-compartment, compared with one-compartment, dispositionfunction.

Pharmacodynamic analysis. Plasma testosterone concentrations were most rapidly and completely suppressed within the first week after injections of thephenylpropionate ester (fig. 3; tables 2 and 6), but this suppressionwas sustained for the shortest time. The duration of suppressionwas significantly longest after the gluteal 1-ml injection. Plasmatestosterone concentrations returned to base line by day 13 afterthe phenylpropionate ester but required >20 days to return tobase-line levels after the decanoate ester. Among the decanoateester injections, both injection volume and site significantlyinfluenced plasma testosterone concentrations (tables 3 and 6).Plasma inhibin levels after decanoate ester injections were suppressedto significantly lower nadir levels after 1-ml gluteal injection(fig. 3; table 6). Plasma inhibin was not assayed after nandrolonephenylpropionate (group 1) injection.

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Fig. 3. Time course of plasma testosterone concentrations in 23 healthy men over 32 days after i.m. injection of 100 mg of nandrolonephenylpropionate in 4 ml of arachis oil vehicle into the glutealmuscle (group 1) ( $black-diamond$ ) or injection of 100 mg of nandrolone decanoateinto the gluteal muscle in 4 ml of arachis oil vehicle (group2) ( $open circle$ ), into the gluteal muscle in 1 ml of arachis oil vehicle(group 3) ( $bullet$ ) or into the deltoid muscle in 1 ml of arachis oilvehicle (group 4) ( $black-square$ ). Results expressed as mean and S.E.M., unlessthe S.E. is smaller than the symbol.

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TABLE 6
Pharmacodynamic variables

The GAM analysis detected no statistically significant covariates for the testosterone pharmacodynamic model (table 7). Theinclusion of a parameter to estimate the nadir concentration oftestosterone resulting from maximal suppression of testosteronesynthesis by nandrolone and of a slope parameter describing thesteepness of the relationship between the nandrolone concentrationand the testosterone output rate significantly improved the model.Figure 4 shows the predicted testosterone concentrations for thesame individuals as shown in figure 2. These predictions werecalculated using the Bayesian estimates of the individual's nandrolonepharmacokinetic parameters and testosterone pharmacodynamic parameters.

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TABLE 7
Population pharmacodynamic models for testosterone and inhibin

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Fig. 4. Observed and model-predicted time course of plasma testosterone concentrations in four healthy men over 32 days after i.m.injection of 100 mg of nandrolone ester. The four men were thesame individuals as illustrated in figure 2, who were originallyselected from each of the treatment groups according to the medianpredicted error of nandrolone concentrations, so that they weremost representative of that group. $bullet$ , observed data; $---$ $---$ , individualBayesian predictions.

No statistically significant covariates were detected in the GAM analysis for the inhibin pharmacodynamic model (figs. 5 and6; table 7). Unlike testosterone, the inclusion of a parameterto estimate the nadir inhibin concentration did not improve themodel, although a slope parameter did significantly improve themodel fit. Figure 6 shows the predicted inhibin concentrationsfor the same individuals as shown in figure 2. Plasma inhibinwas not assayed after nandrolone phenylpropionate (group 1) injection.These predictions were calculated using the Bayesian estimatesof the individual's nandrolone pharmacokinetic and inhibin pharmacodynamicparameters.

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Fig. 5. Time course of plasma inhibin concentrations in 23 healthy men over 32 days after i.m. injection of 100 mg of nandrolone decanoateinto the gluteal muscle in 4 ml of arachis oil vehicle (group2) ( $open circle$ ), into the gluteal muscle in 1 ml of arachis oil vehicle(group 3) ( $bullet$ ) or into the deltoid muscle in 1 ml of arachis oilvehicle (group 4) ( $black-square$ ). Results are expressed as mean and S.E.M.unless the S.E. is smaller than the symbol.

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Fig. 6. Observed and model-predicted time course of plasma inhibin concentrations in three healthy men over 32 days after i.m. injectionof 100 mg of nandrolone decanoate. No inhibin data were availablefor the group that received nandrolone phenylpropionate injections.The three men were selected from three of the four treatment groupsaccording to the median predicted error, so that they were mostrepresentative of that group. $bullet$ , observed data; $---$ $---$ , individualBayesian predictions.

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

The present study demonstrates that, in addition to the chemistry of the side-chain ester, both injection site and volumecan systematically influence blood nandrolone levels after i.m.injection of nandrolone esters in an oil vehicle formulation.Corresponding to the patterns of blood nandrolone concentrations,pharmacodynamic indices reflecting androgen-induced inhibitionof pituitary-testicular function, namely blood testosterone andinhibin concentrations, are also systematically influenced bythese factors. Crucially, the mixed-effects pharmacodynamic modelingdemonstrated that essentially all of the pharmacodynamic variabilityin plasma testosterone and inhibin concentrations was accountedfor by the variability between esters and the site and volumeof injection of the nandrolone injections. The present study extendsknowledge of the clinical pharmacokinetics of nandrolone esters,which were reported in two previous studies concerning nandrolonedecanoate kinetics in humans (Belkien et al., 1985; Wijnand etal., 1985); there are no reports of the pharmacokinetics of thephenylpropionate ester.

One feature of this study is the use of the population pharmacokinetic approach to integrating pharmacokinetic and pharmacodynamicdata. Whereas the global statistical analysis indicates the significanceof some key variables, a structural model allows more physiologicalinterpretation of the findings, especially identifying the relationshipsbetween the pharmacokinetic and pharmacodynamic effects. We haveused an indirect response model (Dayneka et al., 1993), whichallows for more physiologically meaningful models, more realisticinterpretation of derived estimates and statistically valid testingfor categorical covariables, while more efficiently using allof the experimental data (Jusko and Ko, 1994). The indirect physiologicalmodel-based approach also readily allows incorporation, into ageneral model, of data from different subpopulations where thekinetics and dynamics had differing shapes for the effective dose-responserelationships. It is a striking validation of the model-basedestimates that the nadir concentrations of testosterone and inhibincorrespond very accurately to the known concentrations of thesehormones in castrated men (1-3 nM and 0 pg/ml, respectively) (McLachlanet al., 1990; Handelsman, 1994).

An interesting feature of this analysis of testosterone suppression is that the first-order rate constant for the responsecompartment (k_out) does not correspond to the metabolic clearancerate for testosterone. Using either bolus injection or steady-stateinfusion, the metabolic clearance rate for testosterone in menis ~540 liters/m²/day (Gandy, 1977) and the volume of distribution is 10 to 20liters, which is similar to the 11.5 liters estimated in thisstudy for nandrolone, a molecule almost identical to testosterone.These estimates would indicate a k_out value of ~50 day¹, whereas our observed estimate for k_out was 0.708 day¹; the latter is consistent with a much slower rate (half-time,~1 day). This discrepancy is attributable to the fact that theoverall kinetics of suppression of testosterone are dominatedby the slow negative feedback system, rather than the much fastermetabolic clearance of testosterone. This negative feedback ismediated via inhibition of pulsatile gonadotropin-releasing hormonesecretion from hypothalamic neurons into the pituitary portalsystem and then pituitary LH secretion from gonadotropes. Forexample, a highly potent and specific gonadotropin-releasing hormoneantagonist that causes immediate cessation of gonadotropin-releasinghormone action leads to castrate testosterone concentrations within12 hr (Behre et al., 1992), compared with 5 to 10 days in thisstudy. This illustrates the need for physiological insight wheninterpreting indirect pharmacodynamic models because, in thisinstance, the relationship between circulating nandrolone concentrationand the input function to the model may itself be indirect. Ourparadigm exemplifies a paradigm where the k_out parameter may accuratelypredict the time course of overall behavior of a system withoutcorresponding to the metabolic clearance rate of the drug or thepharmacodynamic endpoint under study.

In the present study we have used specific radioimmunoassays to measure the nandrolone, testosterone and inhibin concentrations,with the latter two representing effective markers of endogenouspituitary gonadotropin (LH and FSH, respectively) secretion. Thisreflects the physiological fact that pituitary LH acts exclusivelyupon testicular Leydig cells, due to their unique expression ofcell surface membrane LH receptors. In healthy men, virtuallyall circulating testosterone originates from Leydig cells, withan absolute requirement for trophic influence from LH derivedfrom the bloodstream. Similarly, pituitary FSH acts exclusivelyupon testicular Sertoli cells, which uniquely express FSH receptorson their cell surface membranes, and virtually all circulatingimmunoreactive inhibin originates from the gonads (Burger, 1992).As a result, blood levels of these two hormones are useful integratedbioassay indicators of endogenous pituitary gonadotropin secretion,as reflected by the testicular hormonal response to ambient bloodLH and FSH levels. In the present study, these two pharmacodynamicindices showed physiologically meaningful distinctions betweenthe esters and the effects of injection site and volume.

Variations in side-chain ester chemistry are important in the pharmacokinetics of androgen esters in oil vehicle (Behre etal., 1990). Experimental studies suggest that absorption ratesare predicted by the oil/water partition coefficients (or hydrophobicity)and that the oil vehicle is absorbed more slowly than the androgenester (Tanaka et al., 1974). In humans, the very short propionate(three-carbon aliphatic) ester of testosterone has distinctlyshorter duration of action than esters with longer (seven- oreight-carbon) side-chains (Nieschlag et al., 1976; Schulte-Beerbuhland Nieschlag, 1980; Schurmeyer and Nieschlag, 1984; Belkien etal., 1985; Fujioka et al., 1986). More subtle changes in side-chainester structure have proven ineffective in altering human clinicalpharmacokinetics, because substitution of a linear aliphatic side-chainof seven carbons (enanthate) with either a saturated, cyclized,seven-carbon aliphatic chain (cyclohexanecarboxylate) (Schurmeyerand Nieschlag, 1984) or a linear, aliphatic, eight-carbon chain(cypionate) (Schulte-Beerbuhl and Nieschlag, 1980) resulted invirtually unchanged kinetics. Wider variation in ester side-chainchemistry to include greater chain length and/or aromatic ringstructures is a more effective determinant of ester pharmacokinetics,because nandrolone hexoxyphenylpropionate ester (aromatic ringwith 18 carbons) had far better depot properties, with a prolongedand retarded release profile, compared with the decanoate (aliphaticchain with 10 carbons) (Belkien et al., 1985). The present studyindicates that a side-chain ester consisting of a 10-carbon aliphaticchain has better depot properties than a nine-carbon chain includingan aromatic ring. Because the vehicle (arachis oil) was unchangedduring this study and because of the experimental observationthat the oil vehicle influences local reaction to the oil injection(Brown et al., 1944), as well as androgen ester pharmacology (Ballard,1980; Al-Hindawi et al., 1986), the present conclusions may beextrapolated to other vegetable oil injection vehicles only withcaution.

Injection technique, including injection site, volume and concentration, as well as the nature of the vehicle, could theoreticallybe important for androgen ester release rate. Injection site maybe important because of differences in tissue composition (Cockshottet al., 1982) and blood flow (Bederka et al., 1971); indeed, i.m.oil-based injections may more accurately be termed intermuscular(Ballard, 1968) or intralipomatous (Cockshott et al., 1982). Theformer reflects the tendency of oil vehicle to distribute alongintermuscular fascial planes (Ballard, 1968), whereas the latterdepends upon the amount of fat at the injection site (includingsystematic gender differences) (Modderman et al., 1983) togetherwith needle geometry and anatomy of the injection depot. Intralipomatousdeposition of injections with a larger vehicle volume may explainthe slower release kinetics of nandrolone decanoate in the glutealregion, as well as the differences from the deltoid site, whichhas a lower fat content. The higher blood flow in the deltoid,compared with the gluteal, muscle (Evans et al., 1975) may alsobe important. Analogous site-dependent differences in absorptionrate and physiological effects have been described for a varietyof drugs in aqueous solution (Greenblatt and Koch-Weser, 1976).To our knowledge, there are no previous reports examining thesystemic pharmacokinetic and pharmacodynamic effects of injectionsite and volume for androgen esters in oil vehicle in men.

One possible clinical impact of these observations may lie in recent observations of differences between population groupsin the efficacy of regular i.m. injections of testosterone enanthatein an oil vehicle to suppress testicular function for male contraception(World Health Organization Task Force on Methods for the Regulationof Male Fertility, 1990). In that and related (World Health OrganizationTask Force on Methods for the Regulation of Male Fertility, 1993)studies, interethnic differences in susceptibility to androgen-inducedazoospermia were not due to differences in overall body size orrelated differences (Handelsman et al., 1995). Evaluation of thepossibility of ethnopharmacological differences, however, requireda greater understanding of the rate-determining mechanisms ofandrogen release from androgen ester depots in oil vehicles. Thepresent findings suggest that differences in absorption of androgenesters may contribute to such interethnic differences throughpossible local mechanical factors (e.g., exercise, compressionand muscle and fat mass) at the injection site, and this issuewarrants further study. Analogous variations in the pharmacokineticsof steroid esters have been reported among women from differentcountries using long-acting contraceptive steroids (Garza-Flores,1994), although no explanation has been advanced. Further analysisof the present observations may facilitate such ethnopharmacologicalstudies, as well as clinical applications of androgen esters inoil vehicle formulations.

	Acknowledgments

The authors thank Paul Mutton for his help in conducting this study. The authors are also grateful to Dr. G. Bialy of theContraceptive Development Branch, National Institute of ChildHealth and Human Development, for kindly supplying inhibin kitsand to Christine Young and Jennifer Spaliviero for assisting withassays.

	Footnotes

Accepted for publication November 26, 1996.

Received for publication September 10, 1996.

¹ This study was supported by Organon (Australia) Pty Ltd.

Send reprint requests to: Dr. D. J. Handelsman, Andrology Unit, Royal Prince Alfred Hospital, Department of Medicine (D02), University of Sydney, Sydney NSW 2006, Australia.

	Abbreviations

FSH, follicle-stimulating hormone; GAM, generalized additive model; LH, luteinizing hormone.

	References

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Pharmacokinetics and Pharmacodynamics of Nandrolone Esters in Oil Vehicle: Effects of Ester, Injection Site and Injection Volume1

Pharmacokinetics and Pharmacodynamics of Nandrolone Esters in Oil Vehicle: Effects of Ester, Injection Site and Injection Volume¹