Anderson R A, Wu F C
Medical Research Council Reproductive Biology Unit, Edinburgh, Scotland.
J Clin Endocrinol Metab. 1996 Mar;81(3):896-901. doi: 10.1210/jcem.81.3.8772547.
Hormonal suppression of spermatogenesis is currently being investigated as a method of reversible male contraception. However, administration of exogenous testosterone (T) induces azoospermia in only 40-70% of Caucasian men, whereas the remainder suppresses to severe oligozoospermia (< 5 x 10(5)/mL). The reason(s) for the heterogeneity in the spermatogenic response is not clear. We have prospectively investigated the possibilities that higher plasma concentrations of T and/or differences in the extent and rate of gonadotropin suppression could maintain a low level of spermatogenesis in subjects taking part in a clinical efficacy trial of hormonal male contraception. Thirty-three healthy adult men, aged 21-41 yr, were given 200 mg T enanthate (TE), im, weekly for up to 18 months. Azoospermia was achieved in 18 men (55%) after 20 weeks of treatment, at which time the remaining 15 (45%) stabilized at a mean sperm density of 2.0 +/- 0.8 (+/- SD) x 10(6)/mL. These 15 subjects remained oligozoospermic for the rest of the efficacy study. To compare the pharmacokinetics and pharmacodynamics of TE between the azoospermic and oligozoospermic responders, plasma samples were obtained immediately before and 1, 2, 4, and 7 days after the 1st and 16th TE injections. Further samples were taken after 2, 4, 8, and 12 weeks of treatment. Plasma concentrations of total, free, and non-sex hormone-binding globulin (non-SHBG)-bound T, estradiol, LH, and FSH were measured. Compared to baseline, preinjection levels of total T increased 2.5-fold, reaching a steady state around 12 weeks of treatment. Peak concentrations of total T increased by 5-fold, but free and non-SHBG-bound T levels were increased by 10-fold after 16 weeks. The plasma levels of estradiol showed similar changes as T. However, neither T (bound or free) nor estradiol was significantly different between azoospermic and oligozoospermic responders. Plasma SHBG was reduced to a similar degree in both groups of men after 16 weeks of TE treatment. Plasma concentrations of both LH and FSH decreased rapidly after the first TE injection; a significant decline in LH was detectable after 24 h. Mean levels of both gonadotropins decreased to less than 0.5 U/L by the end of 4 weeks and to below the limit of sensitivity of the assays (0.05 IU/L) by 12 weeks. There were no significant differences in plasma concentrations of LH or FSH or in the rates of suppression between azoospermic and oligozoospermic responders. We conclude that the polymorphism of spermatogenic suppression in response to exogenous T is unlikely to be due to differences in the pharmacokinetics or pharmacodynamics of TE or in the sensitivity of the hypothalamo-pituitary-testicular axis to sex steroid inhibition. Measurements of total plasma T considerably underestimate the increase in bioavailable T during the weekly TE regimen.
目前正在研究通过激素抑制精子发生作为一种可逆的男性避孕方法。然而,给予外源性睾酮(T)仅能使40% - 70%的白种男性出现无精子症,其余男性则抑制到严重少精子症(<5×10⁵/mL)。精子发生反应异质性的原因尚不清楚。我们前瞻性地研究了在参与激素男性避孕临床疗效试验的受试者中,较高的血浆T浓度和/或促性腺激素抑制程度及速率的差异是否可能维持低水平的精子发生。33名年龄在21 - 41岁的健康成年男性,每周肌肉注射200mg庚酸睾酮(TE),持续长达18个月。治疗20周后,18名男性(55%)达到无精子症,此时其余15名(45%)稳定在平均精子密度为2.0±0.8(±标准差)×10⁶/mL。在疗效研究的剩余时间里,这15名受试者一直处于少精子症状态。为比较无精子症和少精子症反应者之间TE的药代动力学和药效学,在第1次和第16次TE注射前及注射后1、2、4和7天立即采集血浆样本。治疗2、4、8和12周后采集更多样本。测量总T、游离T、非性激素结合球蛋白(非SHBG)结合的T、雌二醇、促黄体生成素(LH)和促卵泡生成素(FSH)的血浆浓度。与基线相比,注射前总T水平增加了2.5倍,在治疗约12周时达到稳态。总T的峰值浓度增加了5倍,但游离T和非SHBG结合的T水平在16周后增加了10倍。雌二醇的血浆水平显示出与T类似的变化。然而,无精子症和少精子症反应者之间的T(结合或游离)和雌二醇均无显著差异。TE治疗16周后,两组男性的血浆SHBG均降低到相似程度。第1次TE注射后,LH和FSH的血浆浓度迅速下降;24小时后可检测到LH显著下降。到4周结束时,两种促性腺激素的平均水平均降至低于0.5U/L,到12周时降至检测限以下(0.05IU/L)。无精子症和少精子症反应者之间LH或FSH的血浆浓度及抑制速率均无显著差异。我们得出结论,对外源性T的精子发生抑制多态性不太可能是由于TE的药代动力学或药效学差异或下丘脑 - 垂体 - 睾丸轴对性类固醇抑制的敏感性差异所致。在每周TE治疗方案期间,测量总血浆T大大低估了生物可利用T的增加。
