Zero-Order Release of Gossypol Improves Its Antifertility Effect and Reduces Its Side Effects Simultaneously.

Gossypol was considered a promising male contraceptive but finally failed due to two side effects: hypokalemia and the irreversibility of its contraceptive effect. Here we demonstrate that sustained zero-order release could be a solution for these problems. The in vitro release of gossypol from gossypol/PEG layer-by-layer films follows a perfect zero-order kinetics. In vivo tests indicate that the films can maintain the plasma drug concentration constant in male SD rats for ∼20 days for a 30-bilayer film. The plasma drug concentration is 2 orders of magnitude lower than the peak plasma drug concentration when administered orally and the daily dose is >50-fold lower than the commonly used contraceptive oral dose. However, significant antifertility effects were still observed. Furthermore, hypokalemia was not observed, and the antifertility effects can be reversed after a recovery period. The results suggest that zero-order release can significantly improve the desired antifertility effect of gossypol and, meanwhile, significantly reduce its side effects. We envision the drug could be developed to be an effective, safe, and reversible male contraceptive by zero-order release.

A multicenter contraceptive efficacy study of injectable testosterone undecanoate in healthy Chinese men.

This report describes a Phase II, multicenter, contraceptive efficacy clinical trial using monthly injections of testosterone undecanoate (TU) alone at a dose of 500 mg in healthy Chinese men. Three hundred eight healthy men were recruited in six centers distributed throughout China. Volunteers underwent a control period with no treatment, then a 12-month treatment period including a 6-month suppression phase followed by a 6-month efficacy phase and a 12-month recovery period. During the suppression phase, an initial loading dose of 1000 mg TU, followed by 500 TU at monthly intervals were given until azoospermia or severe oligozoospermia was achieved, up to a maximum of six injections. During the efficacy phase, 500 mg TU were administered at monthly intervals for 6 months. Nine of 308 men did not achieve azoospermia or severe oligozoospermia (<3 x 10(6)/ml) within the 6-month suppression phase. This gave a methodological failure rate of 2.9/100 couple years (95% confidence interval of 1.0-4.8/100 couple years). Two hundred ninety-six men entered the efficacy phase. The continuation rate during the efficacy phase was 95/100 couple years. There were no pregnancies caused by men who achieved azoospermia or severe oligozoospermia. Reappearance of sperm occurred in six men during the efficacy phase, and one pregnancy was attributed to sperm rebound. This gave a secondary failure rate of 2.3/100 couple years (95% confidence interval of 0.5-4.2/100 couple years). Thus, the total failure rate was 5.2%, and total efficacy was 94.8%. Spermatogenesis in all subjects returned to the normal reference range within the recovery period. The mean serum testosterone concentration increased 131%, and the mean serum LH and FSH concentrations decreased 72% and 70%, respectively, after TU injections during the treatment period. The mean level of serum high density lipoprotein cholesterol decreased (14%), and the mean hematocrit increased 6% compared with baseline. No serious adverse events and no significant changes in serum chemistry occurred during the study. The results showed that monthly TU injection at a dose of 500 mg after an initial loading dose of 1000 mg can effectively, safely, and reversibly suppress spermatogenesis in healthy Chinese men without serious adverse effects.

Levonorgestrel implants (Norplant II) for male contraception clinical trials: combination with transdermal and injectable testosterone.

Recent studies demonstrate that combinations of androgens and progestagens are highly effective in the suppression of spermatogenesis in normal volunteers. To test whether progestagen and androgen delivery systems designed to produce steady serum levels will be as effective as other androgen plus progestagen combinations, we compared Norplant II and testosterone (T) transdermal patch to T patch alone on the suppression of spermatogenesis in normal men. Thirty-nine healthy male volunteers (age, 20-45 yr) were randomly assigned to one of two groups. Group 1 (n = 19) received two transdermal T patches daily (Testoderm TTS, each patch designed to deliver about 5 mg/d T) alone, and group 2 (n = 20) received combined Norplant II [Jadelle, four capsules delivering approximately 160 microg/d levonorgestrel (LNG)] plus T patch. Neither of these regimens were very effective, with suppression of spermatogenesis to severe oligozoospermia occurring in less than 60% of subjects. We then expanded the study to include two more groups to determine whether T patch or Norplant II was the main factor causing the inadequate suppression of spermatogenesis. Another 29 subjects were randomized to one of two groups. Group 3 (n = 15) received oral LNG (125 microg/d) plus T patch, and group 4 (n = 14) received Norplant II plus T enanthate (TE) injection (100 mg/wk i.m.). After a pretreatment phase of 4 wk, all subjects received treatment for 24 wk, followed by a recovery period of 12-24 wk. Steady-state serum LNG levels (800-1200 pmol/liter) were achieved from wk 3-24 after Norplant II insertion and decreased rapidly after the removal of the implants at wk 24. Trough serum LNG levels after oral LNG administration were at a comparable range (940-1300 pmol/liter). Azoospermia was achieved in 24%, 35%, 33%, and 93%, and severe oligozoospermia (<1 x 10(6)/ml) developed in 24%, 60%, 42%, and 100% of the subjects in groups 1, 2, 3, and 4, respectively, during treatment phase. All subjects in the Norplant II plus TE groups had persistent sperm concentrations less than 3 x 10(6)/ml from wk 12 until the end of treatment. Concomitant with the marked suppression of spermatogenesis in the Norplant II plus TE group, serum FSH and LH levels were most decreased in this group compared with all other groups. In the T patch-only group, serum SHBG was not suppressed, and total serum T was higher than baseline levels. In the other three groups administered progestagens, serum SHBGs were significantly suppressed, and serum total T remained similar to baseline levels. Serum free T levels were not changed in any group. Except for a suppression of serum high-density lipoprotein cholesterol, there was no significant change in weight, hematocrit, clinical chemistry, or prostate-specific antigen levels in any of the treatment groups. Although more efficacious than T patch alone, Norplant II or oral LNG plus T patch was not as effective in suppressing spermatogenesis to severe oligo- or azoospermia as in previous reports using oral LNG plus TE. This relative lesser efficacy occurred despite the achievement of serum LNG levels by Norplant II that were equivalent to those reported after administration of oral LNG. Substituting the transdermal T delivery system with TE injections resulted in very effective suppression of sperm output. The difference in spermatogenesis suppression of these combined regimens is likely due to less T delivered by the transdermal patch compared with the TE weekly injections. We conclude that Norplant II implants plus TE 100 mg/wk were very efficient in suppressing spermatogenesis to a level acceptable for contraceptive efficacy. This study demonstrates that the dose or route of administration of androgens is critical for sperm suppression in combined androgen-progestagen regimens for hormonal male contraception.

Gossypol blood levels and inhibition of spermatogenesis in men taking gossypol as a contraceptive. A multicenter, international, dose-finding study.

The safety and efficacy of gossypol continues to be controversial. The aim of this study was to evaluate gossypol as a contraceptive pill for men at doses lower than those previously prescribed and in men from various ethnic origin. A total of 151 men from Brazil, Nigeria, Kenya, and China were divided into two groups. Both groups received 15 mg gossypol/day for 12 or 16 weeks to reach spermatogenesis suppression. Subjects were then randomized to either 7.5 or 10 mg/day for 40 weeks. In addition, 51 men were enrolled as a control group. In all, 81 subjects attained spermatogenesis suppression. Only one man discontinued treatment because of tiredness. Potassium levels fluctuated within the normal range. FSH increased consistently. Testicular volume decreased, but after discontinuation, values returned to levels not statistically different from admission. Of 19 subjects on the 7.5 mg/day dose group, 12 recovered sperm counts >20 million/mL within 12 months of discontinuing gossypol. In the 10 mg/day group, sperm counts recovered in only 10 of 24 subjects. Eight of the 43 patients remained azoospermic 1 year after stopping gossypol. All men diagnosed with varicocele failed to reverse spermatogenesis suppression. Gossypol blood levels indicated that sperm suppression occurs independently of concentration, whereas spermatogenesis recovery appears to be concentration-dependent. Gossypol may become a medical alternative to surgical vasectomy when the delay in onset of infertility is acceptable. When taken for 1 year, gossypol causes no reduction in sexual desire or frequency of intercourse. The possibility of reversal, occurring in 51% of the men on this regimen within 1 year after stopping gossypol, is an advantage of this compound as compared with surgical sterilization in many parts of the world.

PIP: The safety and efficacy of gossypol continues to be controversial. The aim of this study was to evaluate gossypol as a contraceptive pill for men at doses lower than those previously prescribed and in men from various ethnic origin. A total of 151 men from Brazil, Nigeria, Kenya, and China were divided into two groups. Both groups received 15 mg gossypol/day for 12 or 16 weeks to reach spermatogenesis suppression. Subjects were then randomized to either 7.5 or 10 mg/day for 40 weeks. In addition, 51 men were enrolled as a control group. In all, 81 subjects attained spermatogenesis suppression. Only 1 man discontinued treatment because of tiredness. Potassium levels fluctuated within the normal range. FSH increased consistently. Testicular volume decreased, but after discontinuation, values returned to levels not statistically different from admission. Of 19 subjects in the 7.5 mg/day dose group, 12 recovered sperm counts higher than 20 million/ml within 12 months of discontinuing gossypol. In the 10 mg/day group, sperm counts recovered in only 10 of 24 subjects. 8 of the 43 patients remained azoospermic 1 year after stopping gossypol. All men diagnosed with varicocele failed to reverse spermatogenesis suppression. Gossypol blood levels indicated that sperm suppression occurs independently of concentration, whereas spermatogenesis recovery appears to be concentration-dependent. Gossypol may become a medical alternative to surgical vasectomy when the delay in onset of infertility is acceptable. When taken for 1 year, gossypol causes no reduction in sexual desire or frequency of intercourse. The possibility of reversal, occurring in 51% of the men on this regimen within 1 year after stopping gossypol, is an advantage of this compound as compared with surgical sterilization in many parts of the world.

A lower dosage levonorgestrel and testosterone combination effectively suppresses spermatogenesis and circulating gonadotropin levels with fewer metabolic effects than higher dosage combinations.

Studies using exogenous high-dosage testosterone (T) or a combination regimen of physiologic T plus high-dosage levonorgestrel (LNG) administration in normal men have shown that oligoazoospermia (<3 million/mL) or azoospermia can be achieved in the majority of the men. However, these hormonal regimens have been associated with significant weight gain and suppression of serum high-density lipoprotein (HDL) cholesterol levels. We hypothesized that a combination of physiologic exogenous testosterone and lower dosage LNG would result in uniform severe oligoazoospermia or azoospermia in normal men but would cause fewer adverse metabolic side effects. We conducted a randomized, placebo-controlled, single-blind trial comparing 6 months of T enanthate (100 mg IM, weekly) plus LNG, 125 microg by mouth, daily (LNG 125; n = 18) or LNG, 250 microg by mouth, daily (LNG 250; n = 18) and compared these regimens with our previous study of the same dosage of T enanthate combined with placebo LNG (LNG 0; n = 18) or with 500 mg of LNG (LNG= 500; n = 18). All three combination regimens of T enanthate and LNG suppressed spermatogenesis more rapidly and resulted in significantly more uniform severe oligoazoospermia (<1 million/mL) than the T-alone regimen. Severe oligoazoospermia was achieved in 89% of the LNG 125, 89% of the LNG 250, and 78% of the LNG 500 groups, respectively, versus 56% of the men in LNG 0 (P < 0.05 for the combination groups vs. LNG 0), but there were no significant differences between the combination regimens (P = NS). All four groups gained significant weight compared with their baselines, although the gain tended to be greater as the dosage of LNG increased (2.0+/-0.9, 2.9+/-1.1, 3.6+/-1.0, and 5.4+/-1.0 kg gained, compared with baseline in the LNG 0, 125, 250, and 500 groups respectively; P < 0.05 compared with baseline). Serum levels of HDL cholesterol decreased in all of the groups, but the effect was larger as the dosage of LNG increased (4+/-4% vs. 13+/-4%, 20+/-3%, and 22+/-4% decrease in HDL levels from baseline in the LNG 0, LNG 125, LNG 250, and LNG 500 groups respectively; P = 0.06 for LNG 125 compared with LNG 0, and P < 0.05 for LNG 250 and LNG 500 compared with LNG 0). We conclude that 1) the combination of physiologic exogenous T enanthate and LNG suppresses spermatogenesis more effectively than T enanthate alone and that 2) the combination regimen of T enanthate plus lower dosage LNG suppresses sperm production comparably to T enanthate plus higher dosage LNG, while causing less weight gain and HDL cholesterol suppression. A combination regimen of physiologic testosterone plus a low dosage of levonorgestrel offers great promise as a safe and effective male contraceptive regimen.

Potentiating effect of buserelin acetate, an LHRH agonist, on the proliferation of ventral prostatic epithelial cells in testosterone-treated castrated rats.

BACKGROUND: We used buserelin acetate ([D-Ser(But)6] LHRH ), an LHRH agonist and strong blocker of LH secretion, as a treatment for prostatic cancer. It is possible that this LHRH agonist has a proliferative effect on the prostate in addition to suppressing LH secretion. The purpose of this study was to examine the proliferative effect of LHRH agonist on rat prostatic epithelial cells. METHODS: We determined the optimal dose of testosterone necessary to maintain a positive level of proliferating cell nuclear antigen (PCNA) in the ventral prostatic epithelial cells of castrated Wistar rats. Testosterone-treated rats then received various doses of buserelin acetate. Castrated rats without exogenous testosterone also received buserelin acetate. The PCNA positivity was determined by immunohistochemistry with anti-PCNA monoclonal antibody. RESULTS: The optimal dose of testosterone enanthate was 4 mg at 0 and 28 days after castration. Administration of buserelin acetate on day 0 and 28 in doses of 0.16 mg to 1.28 mg significantly increased PCNA positivity in a dose-dependent manner. Administration of buserelin acetate to castrated rats without testosterone also increased PCNA positivity but there was no statistical significance. CONCLUSIONS: Buserelin acetate has a potentiating effect on the proliferation of ventral prostatic epithelial cells of castrated rat in the presence of a physiological level of exogenous testosterone. This effect may slightly influence the result of hormonal therapy by LHRH agonist.