1 Centre for Neuroendocrinology, University College London, London, UK, 2 ANZAC Research Institute, University of Sydney, Sydney, Australia, 3 Universität zu Köln, Köln, Germany, 4 Westfälische Wilhelms-Universität, Münster, Germany, 5 Sheba Medical Center, Tel Hashomer, Israel, 6 NV Organon, Oss, The Netherlands and 7 Rambam Medical Center, Haifa, Israel
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Abstract |
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Introduction |
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FSH is used for clinical treatment of both female and male infertility. Protocols for the induction of follicular development in women and spermatogenesis in men commonly rely on multiple injections of FSH preparations (
Schaison et al.1993; Out et al.1999
). The availability of longer-acting FSH would thus allow the development of new, more convenient treatment regimens. Site-directed mutagenesis and gene transfer techniques have been used to develop such a novel form of FSH, which was designated FSH-CTP (Org 36286). This potentially long-acting recombinant human FSH contains the
-subunit of human FSH and a hybrid ß-subunit, which is composed of the ß-subunit of human FSH and the CTP part of the ß-subunit of HCG.
Preclinical pharmacokinetic studies in dogs have demonstrated a prolonged half-life (~ two times longer) of FSH-CTP compared to that of normal recombinant human FSH (Org 32489, Puregon®). Furthermore, the in-vivo bioactivity of FSH-CTP, as assessed in the ovarian weight augmentation assay (classical Steelman-Pohley test) (Wang, 1988) was also found to be at least two times higher than the in-vivo bioactivity of Puregon (unpublished observations).
The present study is the first in which FSH-CTP has been administered to humans. The three-dimensional structure of this new compound is foreign to humans, and therefore possible antigenicity of FSH-CTP was of special consideration. To avoid complications raised by formation of cross-reactive antibodies against native FSH or HCG, this study was performed in hypogonadotrophic hypogonadal male subjects.
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Materials and methods |
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The mean age (± SD) of all subjects was 45 (± 7) years. Mean height was 176 (± 7) cm, and the mean weight was 81.7 (± 13.7) kg. The mean BMI was 26.4 (± 3.3) kg/m2. For both LH and FSH the median concentrations were 0.5 IU/l. For eight subjects (61.5%), the cause of hypogonadism was hypothalamus-related and for the other five subjects the cause was pituitary related.
Design of the study
The study was designed as a phase I, non-blind, multi-centre study in which the safety, pharmacokinetics, and pharmacodynamics of FSH-CTP were studied in hypogonadotrophic hypogonadal male subjects. The trial protocol was approved by the Independent Ethics Committee (IEC) of each trial centre.
After written informed consent was obtained, the subject's general medical history including his andrological history and drug history were obtained. The subjects included were fully aware of the fact that antibody formation, resulting from FSH-CTP treatment, could impair future infertility treatment. Before any of the included subjects were enrolled, antibody levels against FSH-CTP and CHO cell-derived proteins were measured to prevent occurrence of secondary antibody responses. Following inclusion in the study, subjects received four single s.c. injections of FSH-CTP (solution for injection: 15 µg FSH-CTP in 0.5 ml, NV Organon, The Netherlands) with an interval of ~4 weeks. Subjects were admitted to the clinic in the morning of each day of injection. Prior to and after each injection, blood was collected for the assessment of anti-FSH-CTP and anti-CHO cell or culture supernatant-derived protein antibodies, the concentration of FSH-CTP in serum, to study pharmacokinetics or serum testosterone, inhibin-B, and oestradiol concentrations to study the pharmacodynamics. The assessment schedule is presented in
Table
I.
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Antibody levels against FSH-CTP were assessed before and during the study, using a radio-immunoassay based on the formation of an immune complex between the serum-derived specific antibody and [125 I]-labelled FSH-CTP. Due to an absence of human antibodies, murine monocolonal antibodies were used as positive controls.
FSH-CTP was produced by CHO-cells transfected with the genes encoding the - and ß-subunits of human FSH and the CTP-part from human chorion gonadotrophin and purified from CHO cell culture supernatant. Residual CHO cell-derived proteins that are present in minute quantities may cause an immune response in subjects treated for infertility with FSH-CTP. To determine the presence of anti-CHO antibodies in human serum after FSH-CTP administration, CHO proteins were coated on 96-well microplates and incubated with human serum samples. When anti-CHO antibodies are present in a human serum sample, these antibodies bind to the coated CHO proteins. The bound human anti-CHO antibodies were detected by goat anti-human immunoglobulin coupled to horse radish peroxidase (GaH Ig HRP).
Routine biochemical and haematological parameters as well as urine analysis were assessed at screening, 24 h after each administration of FSH-CTP, and at the post-treatment visit.
As the injection of FSH-CTP was given s.c., the injection site (i.e. the abdominal wall around the umbilicus) was examined. Monitoring of the injection site was performed 1 and 24 h after each FSH-CTP injection by the person who administered the study drug. If possible, the same person administered the study drug and monitored the injection site of a subject throughout the whole study. Redness, itching, swelling, pain, and bruising were scored as either none, mild, moderate, or severe reflecting the maximal intensity as experienced by the subject.
FSH-CTP concentrations
FSH-CTP serum concentrations were analysed using an enzyme immunoassay (EIA) without sample purification. In this assay, an antibody, which recognizes the c1 epitope on hFSH (INN-hFSH, Immunological Diagnostics, Austria) was used to coat the 96 well plates. After incubation with serum samples, bound FSH-CTP was detected colourimetrically using biotin-coupled anti-ß-HCG monoclonal antibodies (Organon Teknika, Boxtel, The Netherlands), streptavidine coupled to horse-radish peroxidase, and tetramethylbenzidine (TMB) substrate. This assay was developed and validated by NV Organon (Oss, The Netherlands). Calibration curves for FSH-CTP were constructed using 4-parameter-logistic regression. In each analysis series quality control (QC), consisting of human serum, spiked with known quantities of FSH-CTP was analysed. The coefficient of variation (CV) of duplicate determinations did not exceed 20%. The lower limit of quantitation (LLOQ) was 0.079 ng/ml. Selectivity and specificity of the assay were as follows: selectivity: the results of five blank female and six blank male serum samples were below LLOQ. One female blank serum sample contained 0.100 ng FSH-CTP/ml. Specificity: No significant interference could be detected with related and endogenous compounds (i.e. -FSH-CTP, ß-FSH-CTP, recFSH, HCG, hTSH, and hLH + hFSH). Only
-FSH-CTP showed some cross-reactivity (~0.5%). All spiked FSH-CTP serum concentrations were within 80120% limits (12.619.0 ng/ml) of the nominal concentration (15.8 ng/ml).
Measurement of serum hormone concentrations
Measurement of FSH and LH at screening were performed by the laboratory of each participating centre using their standard methods.
Inhibin B in human serum was denaturated (using sodium dodecyl sulphate, SDS at 100°C), oxidised (hydrogen peroxide), and subsequently analysed using an adapted enzyme immunoassay as previously described (Robertson et al.1996). The detection limit of this assay was 15.6 pg/ml and the CV for duplicate determinations did not exceed 20%. Testosterone and oestradiol serum concentrations were determined by Analytisch Biochemisch Laboratorium b.v. (Assen, The Netherlands) using a time-resolved fluoroimmuno assay (Autodelfia®; Delfia; Wallac Oy, Turku, Finland). The lower limit of quantitation of oestradiol concentrations in serum was 13.6 pg/ml and for testosterone the detection limit was 0.140 ng/ml. The CV of quality controls was <5% for both the oestradiol and testosterone assays.
Statistical and analytical methods
The statistical analysis of the pharmacokinetic parameters was carried out using a paired t
-test on log-transformed parameters and a non-parametric signed-rank test on tmax. All analyses were performed using SAS Version 6.08 or higher. For pharmacodynamic parameters (testosterone, oestradiol and inhibin-B) only descriptive statistics are presented.
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Results |
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Of the subjects that were included, the hypogonadotrophic hypogonadal status was a result of a hypothalamic dysfunction in eight subjects (five idiopathic hypogonadotrophic hypogonadisms and three Kallmann syndromes) and for five subjects this status was caused by dysfunctioning of the pituitary gland (four pituitary tumours and one traumatic lesion of the pituitary gland).
For the safety analysis, data from all 13 subjects was used whereas for the pharmacodynamics and pharmacokinetics analysis, data from ten subjects was used. Three subjects were excluded from the pharmacodynamics and kinetics analysis due to measurable concentrations of FSH-CTP before the first dose was administered, which was probably caused by non-specific interference of serum proteins (see Materials and methods section for the specificity and selectivity of the assay used). In two out of these three subjects, no dose response after FSH-CTP administration was observed at all, in one subject with a positive read-out at t = 0 h a dose response was observed, which peaked at 30 h post administration.
Safety and local tolerance
The safety analysis was performed on all subjects that received at least one injection with the investigated compound. No safety data were excluded from the analysis. In all samples analysed, no anti-FSH-CTP or anti-CHO antibodies were found.
Three subjects (23.1%) experienced a total of five adverse events (maximum intensity): `skin disorder' (mild), `periodontal destruction' (moderate), `abdominal pain' (mild), and twice `inflicted injury' (mild), none of which was considered drug-related.
All haematology parameters were within the safety limits and no clinically relevant shifts were reported for haematological and biochemical parameters. No clinically significant findings were found at the general medical examination of the post-treatment assessment.
The number of subjects with local tolerance symptoms during the entire treatment period and after the first and last injection of FSH-CTP is given in
Table
II. All reported reactions had a mild intensity.
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Pharmacodynamics
Following the first injection with FSH-CTP, a clear rise in serum inhibin-B concentrations was observed, which returned to baseline concentration before the next injection was given (on average 4 weeks later, Figure 2). Similar effects on inhibin-B serum concentrations were obtained after the third injection with FSH-CTP. The time to reach the maximal concentration of inhibin-B (~144 h) was longer than for FSH-CTP (~46 h). Following administration of FSH-CTP hardly any changes were observed in serum testosterone or oestradiol concentrations. Descriptive statistics on serum testosterone, oestradiol and inhibin-B concentrations are presented in
Table
IV
and
Figure
2
.
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Discussion |
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The new compound FSH-CTP contains the -subunit of human FSH and a hybrid ß-subunit, which is composed of the ß-subunit of human FSH and the C-terminal part of the ß-subunit of HCG. This part of HCG contains four O-linked oligosacharides (
Feng et al.1995
).
It was hypothesised that the extension of the ß-subunit could prolong the half-life of FSH-CTP. In agreement herewith, in the current study, the elimination half-life (t) of FSH-CTP in humans was 94.7 ± 26.2 h, which is ~23 fold longer than the t
of recombinant human FSH. The elimination half-life of recombinant human FSH has been shown to be ~34 h ± 5 h in pituitary suppressed females (33 h ± 4 h using Puregon®Pen) (Voortman et al.1999
). Elimination half-life of recombinant human FSH in a multiple rising dose study in men with hypogonadotrophic hypogonadism was shown to be 48 ± 5 h (Mannaerts et al.1996
).
The three-dimensional structure of this new compound is foreign to humans, and therefore possible antigenicity of FSH-CTP was of special consideration. To avoid complications raised by formation of antibodies against native FSH, this study was performed in hypogonadotrophic hypogonadal male subjects. However, neither anti-FSH-CTP nor anti-CHO antibodies were found in any analysed samples. Furthermore, measurement of local tolerance demonstrated that s.c. administration of FSH-CTP is well tolerated and no increase in intensity of injection-site responses was observed after repeated exposure to FSH-CTP. Finally, no subjects discontinued due to adverse events. Based on these data, it can be concluded that use of FSH-CTP is safe and well tolerated.
Analysis of the mean serum FSH-CTP concentrations after the first injection demonstrated that these concentrations were slightly lower than observed after the third injection. The discrepancy between the first and third injection with FSH-CTP is shown by a statistically significant difference in AUC0-tfix
and Cmax, albeit that the absolute differences are very small and further research is required to demonstrate the relevance of this observation. When compared with recombinant human FSH, absorption of FSH-CTP appeared to be slow with peak concentrations being reached on average 46 ± 18 h after injection. Recombinant FSH reaches maximal serum concentrations by 13 ± 6 h after s.c. injection in females (Voortman et al.1999).
To determine pharmacodynamic properties of FSH-CTP, serum testosterone, oestradiol and inhibin-B concentrations were determined. Inhibin-B has been extensively shown to be the physiologically relevant form of inhibin in men (Anawalt et al.1996). In this study it was shown that the dose of FSH-CTP used caused a rise in inhibin-B concentrations, which returned to baseline concentrations within 4 weeks. This observation is in agreement with recent evidence showing that treatment of oligozoospermic males with FSH increases inhibin-B plasma concentrations (Foresta et al.1999
). Furthermore, the bioactivity of recombinant FSH in hypogonadotrophic hypogonadal male subjects was also reflected by increased inhibin-B levels upon multiple rising doses (Mannaerts et al.1996
). Hardly any changes were observed in serum testosterone or oestradiol concentrations after injection of FSH-CTP. In agreement herewith, serum concentrations of LH, testosterone, androstenedione and oestradiol remained unchanged after administration of increasing doses of recombinant human FSH to male subjects (Mannaerts et al.1996
).
In conclusion, use of FSH-CTP is safe and does not lead to detectable formation of antibodies. This is a promising new compound for development of new, more convenient regimens for the treatment of male and female infertility.
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Acknowledgements |
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Notes |
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*For participant details see Acknowledgements section
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References |
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Boime, I. and Ben-Menahem, D. ( 1999) Glycoprotein hormone structure-function and analog design. Recent Prog. Horm. Res., 54, 271288.[Medline]
Damewood, M.D., Shen, W., Zacur, H.A. et al. (1989) Disappearance of exogenously administered human chorionic gonadotropin. Fertil. Steril., 52, 398400.[ISI][Medline]
Feng, W., Huth, J.R., Norton, S.E. et al. (1995) Asparagine-linked oligosaccharides facilitate human chorionic gonadotropin beta-subunit folding but not assembly of prefolded beta with alpha. Endocrinology, 136, 5261.[Abstract]
Foresta, C., Bettella, A., Rossato, M. et al.
(1999) Inhibin B plasma concentrations in oligozoospermic subjects before and after therapy with follicle stimulating hormone. Hum. Reprod., 14, 906912.
Mannaerts, B., Fauser, B., Lahlou, N. et al. ( 1996) Serum hormone concentrations during treatment with multiple rising doses of recombinant follicle stimulating hormone (Puregon) in men with hypogonadotropic hypogonadism. Fertil. Steril., 65, 406410.[ISI][Medline]
Moyle, W.R., Myers, R.V., Wang, Y. et al. (1998) Functional homodimeric glycoprotein hormones: implications for hormone action and evolution. Chem. Biol., 5, 241254.[ISI]
Out, H.J., Bennink, H.J. and de Laat, W.N. ( 1999) What are the clinical benefits of recombinant gonadotrophins?: the development of recombinant FSH (Puregon®: a scientific business. Hum. Reprod., 14, 21892190.
Robertson, D., Burger, H.G., Sullivan, J. et al. (1996) Biological and immunological characterization of inhibin forms in human plasma. J. Clin. Endocrinol. Metab., 81, 669676.[Abstract]
Saal, W., Glowania, H.J., Hengst, W. et al. (1991) Pharmacodynamics and pharmacokinetics after subcutaneous and intramuscular injection of human chorionic gonadotropin. Fertil. Steril., 56, 225229.[ISI][Medline]
Schaison, G., Young, J., Pholsena, M. et al. ( 1993) Failure of combined follicle-stimulating hormone-testosterone administration to initiate and/or maintain spermatogenesis in men with hypogonadotropic hypogonadism. J. Clin. Endocrinol. Metab., 77, 15451549.[Abstract]
Voortman, G., van de Post, J., Schoemaker, R.C. et al. ( 1999) Bioequivalence of subcutaneous injections of recombinant human follicle stimulating hormone (Puregon® by Pen-injector and syringe. Hum. Reprod., 14, 16981702.
Wang, C. (1988) Bioassays of follicle stimulating hormone. Endocr. Rev., 9 , 374377.[Abstract]
Submitted on November 20, 2000; accepted on March 27, 2001.