1 Institute of Reproductive Medicine of the University (WHO Collaborating Centre for Research in Human Reproduction), D-48129 Münster, Germany
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Abstract |
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Key words: GnRH antagonist/gonadotrophins/male contraception/19-nortestosterone/spermatogenesis
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Introduction |
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With testosterone injections alone [even with high doses of 200 mg testosterone enanthate (TE) per week], spermatogenesis was suppressed to azoospermia only in two-thirds of Caucasian men within 6 months (WHO, 1995). The attempt to augment suppression of gonadotrophins by simply increasing the dose of TE has failed (Matsumoto, 1988). In order to accelerate the onset of testosterone effectiveness and to increase azoospermia rates, testosterone is combined with other gonadotrophin-suppressing substances such as gestagens and GnRH antagonists.
GnRH antagonists cause an immediate and highly effective suppression of both gonadotrophins in normal men. Five clinical trials of male contraception using combined administration of TE and the experimental gonadotrophin-releasing hormone (GnRH) antagonist Nal-Glu demonstrated a rapid and highly effective suppression of gonadotrophins and spermatogenesis (Nieschlag et al., 2000).
However, the need for daily subcutaneous administration of GnRH antagonists of even the newest generation over extended periods of time are not feasible and too expensive for contraception. It has been demonstrated previously in non-human primates that the suppression of spermatogenesis by the combination of a GnRH antagonist and testosterone can be maintained by testosterone alone (Weinbauer et al., 1994). These promising results prompted us to perform a clinical study with the modern GnRH antagonist cetrorelix and the long-acting androgen 19-nortestosterone hexyloxyphenylpropionate (19NT-HPP) for induction of azoospermia and maintenance of suppression by the androgen alone.
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Materials and methods |
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Initially, eight male volunteers were enrolled in the study, but two left the study during the injection phase for personal reasons. Ultimately, six normal healthy men (mean ± SD, age 26.0 ± 2.9 years; body weight 71.0 ± 7.6 kg; height 1.76 ± 0.08 m; body mass index 23.0 ± 1.2 kg/m2) completed the injection phase and were included in the final analysis.
After the baseline control examinations, the GnRH antagonist cetrorelix was injected subcutaneously in all volunteers into adipose tissue at the abdominal wall laterally to the rectus abdominis muscle. For the first 5 days the volunteers received 10 mg cetrorelix per day, given as two injections of 5 mg at two sites (Figure 1). These loading-dose injections were followed by maintenance injections of 2 mg cetrorelix per day given at one site up to the end of study week 12 (Behre et al., 1997
). At 14 days after the first cetrorelix injection, all volunteers received 400 mg 19NT-HPP intramuscularly. After this loading dose, maintenance dose injections of 200 mg 19NT-HPP were given every 3 weeks up to the end of the treatment period in study week 26. Follow-up examinations were performed every 3 weeks up to week 47, and thereafter in weeks 52 and 60 (Figure 1
).
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Androgen
19NT-HPP (Anadur; Pharmacia Arzneimittel GmbH, Ratingen, Germany) is a long-acting testosterone derivative. Injection of 200 mg 19NT-HPP every 3 weeks has been shown to support sexual function in male volunteers with hormonally suppressed endogenous testosterone secretion (Knuth et al., 1985; Behre et al., 1992
).
Local side effects
Local side effects after subcutaneous cetrorelix administration were documented daily on transparency paper. The erythema area was determined in a blinded manner applying a digital planimeter (Haff GmbH, Pfronten, Germany).
Evaluation of sexual function
For evaluation of possible effects on sexuality, a questionnaire on sexual thoughts and fantasies, sexual interest and desire, satisfaction with sexuality, frequency of erections and number of morning erections and ejaculations was used every week up to study week 14, then every 3 weeks up to study week 47, and finally in study weeks 52 and 60 (Behre et al., 1992).
Blood samples
Blood samples for hormone determinations were withdrawn between 08:00 and 10:00 at two pretreatment control examinations, shortly before the first cetrorelix injection (baseline level), on study days 2, 4, 7, 9, 12, 14, 16, 18, 21, 23, 25, 28, 30 and 35, then weekly up to study week 17, then every 3 weeks up to study week 47, and finally at week 52 and 60 (Figure 1). Blood samples for hormone determinations were separated by centrifugation at 800 g and the serum stored at 20°C until assayed. Blood samples for haematology and clinical chemistry (including lipids) were withdrawn after 12 h of fasting at the two control examinations, weekly up to study week 12, every 3 weeks from week 14 to 47, and finally at weeks 52 and 60.
Immunoassays
Serum LH, FSH, prolactin, sex hormone-binding globulin (SHBG), prostate-specific antigen (PSA), testosterone, oestradiol and inhibin B concentrations were determined as described previously (Behre et al., 1997; Eckardstein et al., 1999
). In the authors' laboratory, the normal ranges for LH are 210 IU/l, for FSH 17 IU/l, for SHBG 1171 nmol/l and for inhibin B 94327 pmol/l. The lower normal limit for testosterone is 12 nmol/l. The upper normal limit for prolactin is 500 mIU/l, for PSA 4 µg/l, and for oestradiol 250 pmol/l.
Semen analysis
Semen analyses were performed according to the WHO guidelines at the two pretreatment control examinations, weekly up to study week 12, every 2 weeks up to week 20, every 3 weeks up to week 47, and finally in weeks 52 and 60. The volunteers were requested to abstain from sexual activity for 48 h to 7 days before investigation.
Testicular and prostate volumes
Changes in testicular volume were determined by scrotal sonography as described previously (Behre et al., 1989) at the second pretreatment control examination, then weekly up to week 5, every 3 weeks from study week 8 to 47, and finally in week 52. Prostate volume was measured by transrectal ultrasonography (Behre et al., 1994
) before the first cetrorelix injection, then weekly up to study week five, every 3 weeks from week 8 to 47, and finally in study week 52. Volume was calculated applying the ellipsoid method.
Statistical analysis
Significant variations over time of any parameter were evaluated by analysis of variance (ANOVA) for repeated measures. In case of a general effect over time, values at single time points were analysed in more detail by comparison with the pretreatment baseline value using the Duncan multiple comparison test for repeated measures. For LH, FSH, testosterone, oestradiol, SHBG, PSA, ejaculate and psychosexual variables the values shortly before the first cetrorelix injection were defined as baseline levels. For inhibin B, testicular volume, prostate volume, clinical chemistry including lipids, haematology and physical examinations the values at the second pretreatment control examination were defined as baseline levels. When necessary, analysis was performed on logarithmically transformed data. A P value < 0.05 was considered significant. Unless otherwise stated, results are given as mean ± SEM.
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Results |
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Ejaculate parameters
Abstinence times remained constant throughout the study. Ejaculate volume decreased significantly from a baseline of 3.0 ± 0.2 ml to 1.7 ± 0.3 ml in study week 2, and returned to the normal baseline range following week 3.
A significant suppression of sperm concentration was first seen in week 3 (Figure 2, upper panel). The first volunteer achieved azoospermia in week 3, the second in week 6, two more in week 8, one in week 9 and the last in week 12 (Figure 2
, lower panel). During the injection phase with 19NT-HPP alone only one volunteer remained continuously azoospermic up to study week 38. In four of the six volunteers spermatozoa reappeared in the ejaculate in week 14, an additional one in week 16 (Figure 2
, lower panel). One of these five volunteers was again suppressed to azoospermia from week 26 to 35. At study week 52 all volunteers showed sperm concentrations back in the normal range.
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Gonadotrophins
Serum LH concentrations were significantly suppressed by cetrorelix injections to the assay detection limit up to the end of study week 12 (Figure 3, upper panel). After cessation of the GnRH antagonist injections, LH concentrations increased within 1 week and were in the normal range in week 14. During continued 19NT-HPP injections, LH concentrations declined again to a nadir in week 29, without achieving the same degree of suppression which had been seen constantly during the GnRH antagonist injection period. Serum concentrations of LH in the prestudy range were seen following week 44.
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Testosterone, oestradiol, SHBG and prolactin
Serum concentrations of testosterone mirrored LH concentrations. Cetrorelix injections suppressed serum concentrations of testosterone to a nadir of 2.1 ± 0.2 nmol/l on day 9 (Figure 4, upper panel). Mean serum concentrations of testosterone remained constantly low during the first 12 study weeks. At 2 weeks after cessation of cetrorelix injections testosterone concentrations were restimulated to a maximum of 11.4 ± 3.1 nmol/l. During continued 19NT-HPP injections mean serum concentrations declined again and then rose to the normal range following study week 41.
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Serum concentrations of SHBG remained statistically unchanged throughout the study course (Figure 5, upper panel). No significant change was seen in prolactin concentrations throughout the study course, with all individual values remaining within the normal range.
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Sexual function
Standardized questionnaires revealed a decrease in the frequency of morning erections during the first two injection weeks without androgen supplementation, and in study week 3 (Figure 6). This effect was paralleled by a decrease of sexual thoughts and fantasies. In view of the high variability, these changes did not reach statistical significance. Thereafter, mean levels of sexual function variables were restored to the prestudy range and remained unchanged throughout the rest of the study.
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No significant change was seen in serum concentrations of PSA throughout the study course. Individual values never exceeded the upper normal limit for PSA, with mean concentrations remaining constantly below 1 µg/l.
Haematology, lipids and clinical chemistry
Haemoglobin decreased significantly during the first 2 weeks of cetrorelix injections (Figure 8, upper panel). During 19NT-HPP administration, haemoglobin concentration increased significantly to maximal values at the end of the injection period. Subsequently, mean concentrations decreased and returned to baseline at the end of the recovery period. A similar pattern was noted for erythrocyte concentrations and for the haematocrit. No significant changes were seen in either leukocyte or platelet concentrations during the study course.
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Discussion |
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In contrast to GnRH agonists, GnRH antagonists administered to men produce a precipitous and prolonged fall in serum concentrations of both LH and FSH. To date, the results of six clinical trials using GnRH antagonists for male contraception have become available (Pavlou et al., 1991, 1994
; Tom et al., 1992
; Bagatell et al., 1993
; Swerdloff et al., 1998
; and the present study). Within these studies, 47 of 55 volunteers (85%) became azoospermic, demonstrating the high efficacy of the GnRH antagonisttestosterone combination for complete suppression of spermatogenesis. In addition, the mean time to achieve azoospermia (8 weeks in the present study) was considerably shorter than when testosterone was used alone (mean 17 weeks in Caucasian men; WHO, 1995).
Although GnRH antagonists are very effective for suppression of spermatogenesis, the high costs and need for daily subcutaneous administration renders them impracticable for widespread and long-term contraceptive use in males. Therefore, an approach to reduce the dose and duration of GnRH antagonist administration seems mandatory. One possible dose schedule, which was first tested in cynomolgus monkeys, showed that spermatogenesis could be suppressed by daily subcutaneous administration of 450 µg/kg body weight of cetrorelix, and maintained after withdrawal of the GnRH antagonist by using long-acting testosterone buciclate (Weinbauer et al., 1994).
In a clinical trial, 10 mg/day of the second-generation GnRH antagonist Nal-Glu in combination with weekly intramuscular injections of 100 mg TE were given to 15 healthy male volunteers (Swerdloff et al., 1998). At study week 12, 10 of the 15 volunteers had achieved azoospermia, and four were suppressed to a detectable sperm concentration lower than 3x106/ml. The 14 volunteers with severely suppressed spermatogenesis during the induction phase of the Nal-Glu plus TE thereafter received weekly injections of 100 mg TE for another 20 weeks (Swerdloff et al., 1998
). During this maintenance period, eight volunteers showed persistent azoospermia, whereas five remained severely oligozoospermic and one escaped suppression, showing sperm concentration in the normal range while receiving TE alone.
In the present study, all six volunteers were suppressed to azoospermia within 12 weeks, and with a much lower dose of the modern GnRH antagonist cetrorelix. While receiving 19NT-HPP alone, only one of the six men remained consistently azoospermic. This restimulation of spermatogenesis can be explained by the restimulated serum concentrations of LH and FSH after study week 12. Injections of 19NT-HPP at the given dose and injection interval were unable to maintain the significant suppression of gonadotrophins achieved by the GnRH antagonist. Similar restimulated LH and FSH concentrations were seen in the volunteer who escaped suppression of spermatogenesis in the maintenance phase of the Nal-Glu plus TE study (Swerdloff et al., 1998). The finding of unchanged inhibin B concentrations in the current study corresponds to similar results in recent trials with gestagens and androgens for male contraception (Büchter et al., 1999
; Martin et al., 2000
).
One possible explanation for the difference in the maintenance rate of gonadotrophin suppression and azoospermia in the two clinical studies might be the nature of the different androgens, testosterone versus 19-nortestosterone. Because of the different conversion rate to the 5-reduced form and the minimal metabolism to oestrogens, 19-nortestosterone has a different spectrum of biological actions compared with testosterone, and can be regarded as a selective androgen (Toth and Zakar, 1982
). The selectivity of 19-nortesterone effects on various organs was demonstrated in the current study. Administration of the GnRH antagonist to study volunteers reduced prostate volume significantly, by one-third. The rapid and pronounced suppression of prostate size has also been seen in cetrorelix-treated cynomolgus monkeys (Kamischke et al., 1997
) and, to a lesser degree, in patients with benign prostatic hyperplasia (Comaru-Schally et al., 1998
). Delayed administration of 19-nortestosterone to the cetrorelix-treated volunteers induced only minimal stimulation of prostate growth, in contrast to the significant stimulation of haemoglobin concentration and the pronounced suppression of HDL-cholesterol. Similar prostate-sparing effects have been described for other selective androgens which cannot be converted to 5-dihydrotestosterone (Cummings et al., 1998
) or oestrogens (Swerdloff and Wang, 1998
).
The lack of oestrogenic activity of 19-nortestosterone could explain the less suppressive effect on gonadotrophins in the current study. It has been shown that, in addition to a hypothalamic effect (Hayes et al., 2000; Vanderschueren and Bouillon, 2000
), oestrogens are potent inhibitors of GnRH responsiveness in the pituitary gland (Finkelstein et al., 1991
). Recently, it has also been demonstrated that the negative feedback regulation of testosterone on FSH appears to be mediated largely by aromatization to oestradiol (Hayes et al., 2001
). The additional suppressive effect of oestradiol on gonadotrophin secretion has recently been demonstrated in an experimental trial of male contraception (Handelsman et al., 2000
). Similarly, long-acting testosterone preparations plus gestagens with significant aromatization to oestrogens (such as norethisterone enanthate; Kuhnz et al., 1997
) are highly effective combinations for male contraception (Kamischke et al., 2001
).
It should be noted that the same dose of 19NT-HPP given without GnRH analogues consistently suppressed gonadotrophins (Behre et al., 1992). However, it has been shown that after cessation of GnRH antagonist administration, a rebound increase of gonadotrophins to concentrations exceeding the baseline control occurs in normal men (Behre et al., 1997
). It might be speculated that the selective androgen 19-nortestosterone is not capable of suppressing this temporarily increased activity of the pituitary gland after cessation of the GnRH antagonist (Hayes et al., 2001
), in contrast to natural testosterone which is significantly metabolized to oestradiol.
In conclusion, this first study using a modern and now (at least in some countries) clinically available GnRH antagonist for male contraception demonstrated the high efficacy of suppressing both gonadotrophins as well as spermatogenesis to azoospermia. This effective suppression could not be maintained by the selective androgen 19NT-HPP. Different testosterone preparations given at varying application intervals and doses should be tested in combination with initial administration of modern GnRH antagonists to further exploit this promising approach to hormonal male contraception.
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Acknowledgements |
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Notes |
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3 To whom correspondence should be addressed at: Institute of Reproductive Medicine of the University, Domagkstr. 11, D-48129 Münster, Germany. E-mail: nieschl{at}uni-muenster.de
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References |
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Behre, H.M. and Nieschlag, E. (1999) GnRH agonist/antagonistandrogen combinations for male contraception. In Rajalakshmi, M. and Griffin, P. D. (eds), Male Contraception: Present and Future. New Age International Publishers, New Delhi, pp. 235249.
Behre, H.M., Nashan, D. and Nieschlag, E. (1989) Objective measurement of testicular volume by ultrasonography: evaluation of the technique and comparison with orchidometer estimates. Int. J. Androl., 12, 395403.[ISI][Medline]
Behre, H.M., Nashan, D., Hubert, W. et al. (1992) Depot gonadotropin-releasing hormone agonist blunts the androgen-induced suppression of spermatogenesis in a clinical trial of male contraception. J. Clin. Endocrinol. Metab., 74, 8490.[Abstract]
Behre, H.M., Bohmeyer, J. and Nieschlag, E. (1994) Prostate volume in testosterone-treated and untreated hypogonadal men in comparison to age-matched controls. Clin. Endocrinol., 40, 341349.[ISI][Medline]
Behre, H.M., Kliesch, S., Pühse, G. et al. (1997) High loading and low maintenance doses of a gonadotropin-releasing hormone antagonist effectively suppress serum luteinizing hormone, follicle-stimulation hormone, and testosterone in normal men. J. Clin. Endocrinol. Metab., 82, 14031408.
Büchter, D., von Eckardstein, S., von Eckardstein, A. et al. (1999) Clinical trial of a non-injectable male contraceptive: transdermal testosterone and oral levonorgestrel. J. Clin. Endocrinol. Metab., 84, 12441249.
Comaru-Schally, A.M., Branna, W., Schally, A.V. et al. (1998) Efficacy and safety of luteinizing hormone-releasing hormone antagonist cetrorelix in the treatment of symptomatic benign prostatic hyperplasia. J. Clin. Endocrinol. Metab., 83, 38263831.
Cummings, D.E., Kumar, N., Bardin, C.W. et al. (1998) Prostate-sparing effects in primates of the potent androgen 7alpha-methyl-19-nortestosterone: a potential alternative to testosterone for androgen replacement and male contraception. J. Clin. Endocrinol. Metab., 83, 42124219.
Eckardstein, S.v., Simoni, M., Bergmann, M. et al. (1999) Serum inhibin B in combination with serum follicle-stimulating hormone (FSH) is a more sensitive marker than serum FSH alone for impaired spermatogenesis in men, but cannot predict the presence of sperm in testicular tissue samples. J. Clin. Endocrinol. Metab., 84, 24962501.
Finkelstein, J.S., O'Dea, L.S., Whitcomb, R.W. et al. (1991) Sex steroid control of gonadotropin secretion in the human male. II. Effects of estradiol administration in normal and gonadotropin-releasing hormone-deficient men. J. Clin. Endocrinol. Metab., 73, 621628.[Abstract]
Handelsman, D.J., Wishart, S. and Conway, A.J. (2000) Oestradiol enhances testosterone-induced suppression of human spermatogenesis. Hum. Reprod., 15, 672679.
Hayes, F.J., Seminara, S.B., Decruz, S. et al. (2000) Aromatase inhibition in the human male reveals a hypothalamic site of estrogen feedback. J. Clin. Endocrinol. Metab., 85, 30273035.
Hayes, F.J., Decrz, S., Seminara, S.B. et al. (2001) Differential regulation of gonadotropin secretion by testosterone in the human male: absence of a negative feedback effect of testosterone on follicle-stimulating hormone secretion. J. Clin. Endocrinol. Metab., 86, 5358.
Kamischke, A., Behre, H.M., Weinbauer, G.F. et al. (1997) The cynomolgus monkey prostate under physiological and hypogonadal conditions: an ultrasonographic study. J. Urol., 157, 23402344.[ISI][Medline]
Kamischke, A., Venherm, S., Plöger, D. et al. (2001) Intramuscular testosterone undecanoate and norethisterone enanthate in a clinical trial for male contraception. J. Clin. Endocrinol. Metab., 86, 303309.
Knuth, U.A., Behre, H.M., Belkien, L. et al. (1985) Clinical trial of 19-nortestosterone-hexoxyphenylpropionate (anadur) for male fertility regulation. Fertil. Steril., 44, 814821.[ISI][Medline]
Kuhnz, W., Heuner, A., Humpel, M. et al. (1997) In vivo conversion of norethisterone and norethisterone acetate to ethinyl estradiol in postmenopausal women. Contraception, 56, 379385.[ISI][Medline]
Martin, C.W., Riley, S.C., Everington, D. et al. (2000) Dose-finding study of oral desogestrel with testosterone pellets for suppression of the pituitaryesticular axis in normal men. Hum. Reprod., 15, 15151524.
Matsumoto, A.M. (1988) Is high dosage testosterone an effective male contraceptive agent? Fertil. Steril., 50, 324328.[ISI][Medline]
Nieschlag, E., Behre, H.M., Engelmann, U. et al. (2000) Male contribution to contraception. In: Nieschlag, E. and Behre, H.M. (eds), Andrology Male Reproductive Health and Dysfunction, 2nd edn. Springer-Verlag, Berlin, Heidelberg, New York, pp. 399418.
Pavlou, S.N., Brewer, K., Farley, M.G. et al. (1991) Combined administration of a gonadotropin-releasing hormone antagonist and testosterone in men induces reversible azoospermia without loss of libido. J. Clin. Endocrinol. Metab., 73, 13601369.[Abstract]
Pavlou, S.N., Herodotou, D., Curtain, M. et al. (1994) Complete suppression of spermatogenesis by co-administration of a GnRH antagonist plus a physiologic dose of testosterone (abstract no. 1324). Proceedings, 76th Annual Meeting of the Endocrinological Society, Anaheim, CA, 531.
Swerdloff, R.S. and Wang, C. (1998) Dihydrotestosterone: a rationale for its use as a non-aromatizable androgen replacement therapeutic agent. Baillières Clin. Endocrinol. Metab., 12, 501506.[ISI][Medline]
Swerdloff, R.S., Bagatell, C.J., Wang, C. et al. (1998) Suppression of spermatogenesis in man induced by Nal-Glu gonadotropin releasing hormone antagonist and testosterone enanthate (TE) is maintained by TE alone. J. Clin. Endocrinol. Metab., 83, 35273533.
Tom, L., Bhasin, S., Salameh, W. et al. (1992) Induction of azoospermia in normal men with combined Nal-Glu gonadotropin-releasing hormone antagonist and testosterone enanthate. J. Clin. Endocrinol. Metab., 75, 476483.[Abstract]
Toth, M. and Zakar, T. (1982) Relative binding affinities of testosterone, 19-nortestosterone and their 5-alpha-reduced derivatives to the androgen receptor and to other androgen-binding proteins: a suggested role of 5alpha-reductive steroid metabolism in the dissociation of `myotropic' and `androgenic' activities of 19-nortestosterone. J. Steroid Biochem., 17, 653660.[ISI][Medline]
Vanderschueren, D. and Bouillon, R. (2000) Estrogen deficiency in men is a challenge for both the hypothalamus and pituitary. J. Clin. Endocrinol. Metab., 85, 30243026.
Weinbauer, G.F., Limberger, A., Behre, H.M. et al. (1994) Can testosterone alone maintain the GnRH antagonist-induced suppression of spermatogenesis in the non-human primate? J. Endocrinol., 142, 485495.[Abstract]
World Health Organization Task Force on Methods for the Regulation of Male Fertility (1990) Contraceptive efficacy of testosterone-induced azoospermia in normal men. Lancet, 336, 955959.[ISI][Medline]
World Health Organization Task Force on Methods for the Regulation of Male Fertility (1995) Rates of testosterone-induced suppression to severe oligozoospermia or azoospermia in two multinational clinical studies. Int. J. Androl., 18, 157165.[ISI][Medline]
World Health Organization Task Force on Methods for the Regulation of Male Fertility (1996) Contraceptive efficacy of testosterone-induced azoospermia and oligozoospermia in normal men. Fertil. Steril., 65, 821829.[ISI][Medline]
Submitted on April 26, 2001; accepted on August 21, 2001.