Pharmacokinetics of modified slow-release oral testosterone over 9 days in normal men with experimental hypogonadism.

Oral administration of testosterone has potential use for the treatment of hypogonadism. We have recently demonstrated that a novel formulation of oral testosterone transiently normalized serum testosterone in a single-dose pharmacokinetic study. In this report, we present the steady-state pharmacokinetics of this formulation. Twelve healthy young men were rendered hypogonadal with the gonadotropin-releasing hormone antagonist acyline (300 µg/kg subcutaneously) and administered 300 mg of oral testosterone 3 times daily for 9 days. Serum testosterone, dihydrotestosterone (DHT), estradiol, and sex hormone-binding globulin (SHBG) were measured before and 1, 2, 4, 5, 6, 8, 10, 11, 12, 14, 16, and 24 hours on the first and ninth day of dosing. Before testosterone administration, all men had serum testosterone under 75 ng/dL. Over day 1, the 24-hour average (geometric mean [%CV]) serum total testosterone was 378 (45) ng/dL. This decreased to 315 (41) ng/dL after 9 days of continuous treatment (P = .1 compared with day 1). The 24-hour average serum SHBG was 27 (46) nmol/L on day 1 and was significantly reduced to 19 (47) nmol/L by day 9 (P < .01). As a result, the calculated free testosterone values were similar between day 1 and day 9: 8.7 (43) and 8.3 (37) ng/dL, respectively. DHT was in the reference range and estradiol was slightly below on day 9. Oral testosterone (300 mg) dosed 3 times daily normalized serum testosterone in men with experimentally induced hypogonadism after 9 days of dosing and significantly suppressed SHBG. This formulation of oral testosterone may have efficacy for the treatment of testosterone deficiency.

Oral testosterone with and without concomitant inhibition of 5α-reductase by dutasteride in hypogonadal men for 28 days.

PURPOSE: Co-administration of the 5α-reductase inhibitor dutasteride increases the oral testosterone bioavailability in men with experimentally induced hypogonadism. We examined oral testosterone with and without dutasteride administration in hypogonadal men for 28 days. MATERIALS AND METHODS: We randomly assigned 43 hypogonadal men to twice daily oral doses of 150, 250 or 400 mg testosterone with 0.25 mg dutasteride, 400 mg testosterone alone or 0.25 mg dutasteride alone for 28 days in a multicenter study. Subjects underwent pharmacokinetic profiling of serum hormones on days 1 and 28. A total of 32 men completed all study procedures. RESULTS: Serum testosterone increased in all groups on testosterone compared with that in the dutasteride only group. At the 400 mg dose the combination of testosterone and dutasteride resulted in average testosterone concentrations that were 2.7 and 4.6 times higher than in the testosterone only group on days 1 and 28, respectively (p <0.01). On day 28 average testosterone was 20% to 30% lower in all groups on testosterone and dutasteride, and 50% lower in the testosterone only group compared with day 1. Serum dihydrotestosterone was suppressed in all groups on dutasteride and increased in the testosterone only group. CONCLUSIONS: Oral testosterone administration resulted in a therapeutic serum testosterone concentration in hypogonadal men. Dutasteride improved the oral bioavailability of testosterone while suppressing dihydrotestosterone. Compared with day 1, testosterone was decreased after 28 days of administration. Additional study is warranted of oral testosterone with dutasteride for testosterone deficiency.

Pharmacokinetics of 2 novel formulations of modified-release oral testosterone alone and with finasteride in normal men with experimental hypogonadism.

Oral administration of testosterone might be useful for the treatment of testosterone deficiency. However, current "immediate-release" formulations of oral testosterone exhibit suboptimal pharmacokinetics, with supraphysiologic peaks of testosterone and its metabolite, dihydrotestosterone (DHT), immediately after dosing. To dampen these peaks, we have developed 2 novel modified-release formulations of oral testosterone designed to slow absorption from the gut and improve hormone delivery. We studied these testosterone formulations in 16 normal young men enrolled in a 2-arm, open-label clinical trial. Three hundred-mg and 600-mg doses of immediate-release and modified fast-release or slow-release formulations were administered sequentially to 8 normal men rendered hypogonadal by the administration of the gonadotropin-releasing hormone antagonist acyline. Blood for measurement of serum testosterone, DHT, and estradiol was obtained before and 0.5, 1, 2, 3, 4, 6, 8, 12, and 24 hours after each dose. A second group of 8 men was studied with the coadministration of 1 mg of the 5α-reductase inhibitor finasteride daily throughout the treatment period. Serum testosterone was increased with all formulations of oral testosterone. The modified slow-release formulation significantly delayed the postdose peaks of serum testosterone and reduced peak concentrations of serum DHT compared with the immediate-release formulation. The addition of finasteride further increased serum testosterone and decreased serum DHT. We conclude that the oral modified slow-release testosterone formulation exhibits superior pharmacokinetics compared with immediate-release oral testosterone both alone and in combination with finasteride. This formulation might have efficacy for the treatment of testosterone deficiency.

Nanomilled oral testosterone plus dutasteride effectively normalizes serum testosterone in normal men with induced hypogonadism.

Oral androgen development has been hampered by the rapid metabolism of orally administered testosterone (T) and low bioavailibility. The addition of the 5alpha-reductase inhibitor dutasteride (D) to oral T in oil dramatically improves concentrations of serum T. In this study we evaluate the absorption of oral T+D, comparing nanomilled T (NmT+D) vs T dissolved in oil (Capmul; CpT+D), as nanomilling might offer a simpler, more practical means of oral T administration, given the limited solubility of T in oil. Twelve healthy men were administered leuprolide on Day -14 to suppress endogenous T biosynthesis and were pretreated with D to block 5alpha-reductase. Once hypogonadal, subjects were sequentially administered 200- and 400-mg doses of CpT+D and NmT+D in the fasted and fed states. Serum T and dihydrotestosterone (DHT) were measured: before dose and at 0.5, 1, 2, 3, 4, 6, 8, 10, 12, and 24 hours after each dose. Two weeks after leuprolide administration, T levels were below the normal range. A 400-mg dose of either formulation of oral T+D increased mean serum T above the lower limit of the normal range for 8-10 hours. Food had a minimal effect on the pharmacokinetic parameters of the NmT+D formulation but decreased the maximum observed concentration after dosing (C(max)) for CpT+D. Serum DHT remained below the normal range throughout the study period with both formulations. No significant changes in liver function tests or other adverse events were observed. A 400-mg dose of either oral T+D formulation normalized serum T for 8-10 hours and suppressed DHT. NmT allows for tablet formulation, and its pharmacokinetics were not affected by food, demonstrating the feasibility of oral nanomilled T as a promising and practical twice-daily therapy for the treatment of male hypogonadism.