1 II Department of Obstetrics and Gynaecology, University of Milano, Milano, 2 IRCCS Istituto Auxologico Italiano and 3 Reproductive Centre, Ospedale di Reggio Emilia, Italy
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Abstract |
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Key words: endometrioma/endometrium/follicular fluid/peritoneal fluid
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Introduction |
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Notwithstanding the aetiopathogenetic model considered, there are only few and limited observations regarding the role played by the ovulatory ovarian activity in the development of endometriotic cysts (Bahtiyar et al., 1998). In this study, we postulate that ovarian follicles may be involved in the pathogenesis of endometrioma, at least in promoting their growth. To investigate this hypothesis, we evaluated the ability of follicular fluid to stimulate endometrial and endometriotic cell proliferation in vitro.
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Materials and methods |
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Follicular fluid
Follicular fluids were obtained from 12 women undergoing IVF and embryo transfer procedures at the Reproductive Centre, Reggio Emilia Hospital for tubal factor or male infertility. In these women a preliminary laparoscopy ruled out the presence of endometriosis. A standard IVF protocol was used as described elsewhere (Viganò et al., 1998). Briefly, these women were pretreated with gonadotrophin-releasing hormone analogue (buserelin acetate, Suprefact; Hoechst, L'Aquila, Italy) started in the mid-luteal phase of the preceding cycle and continued for 14 days. Follicle-stimulating hormone (FSH, Metrodin, Serono Laboratories, Inc., Rome, Italy) was started thereafter with dose variations depending on individual responses. Follicular development was monitored by daily measurements of serum oestradiol and by ultrasonographic measurements of follicle diameter. Human chorionic gonadotropin (HCG, 10 000 IU, Profasi; Serono Laboratories, Inc.) was administered when the size of at least two leading follicles reached 15 mm or serum oestradiol levels >1 nmol/mature follicle. Transvaginal ultrasound-guided oocyte retrieval was performed 36 h later and the contents of visible follicles were aspirated. Care was taken to select only follicular fluids that were clear, non-bloody and that did not contain flushing medium. Oocytes were identified and separated. The follicular aspirates obtained were centrifuged at 800 g for 10 min at room temperature to separate them from cells and then stored at 20°C. At the time of experiment, samples were thawed and pooled. 17-ß-Oestradiol and progesterone concentrations of the pools were measured. Overall, three different pools were obtained using follicular fluids from at least three different women for each pool.
Peritoneal fluid
Samples of peritoneal fluid were collected at the time of laparoscopy from 38 women who, on the basis of the laparoscopic diagnosis, were divided into the following three groups: endometriosis stage III (12 women), endometriosis stage IIIIV (12 women) and controls (14 women). All the women were in early follicular or late luteal phase of the menstrual cycle in order to avoid contamination of follicular fluid into peritoneal fluid. No woman had received hormones for at least 3 months. In the control group, laparoscopic examination demonstrated normal pelvic organs in four cases, pelvic adhesions in two cases, benign ovarian pathology in six cases and benign uterine pathology in two cases. Peritoneal fluid samples were centrifuged at 800 g for 10 min at room temperature to separate them from cells and then stored at 20°C. At the time of experiment, samples were thawed and pooled. Each pool was established so that an equal number of early follicular and late luteal phase samples were used. 17-ß-Oestradiol and progesterone concentrations of the pools were measured. Overall, three different pools of peritoneal fluid for each of the three groups of women were obtained.
Collection, isolation and culture of endometrium and endometriotic cyst
Samples of uterine endometrium were obtained at the time of laparoscopy using an endometrial biopsy curette from 11 proliferative phase women affected by benign ovarian pathology but without evidence of endometriosis. Moreover, six samples of ovarian endometriotic cysts were obtained from six proliferative phase women affected by endometriosis stage IIIIV. Histopathological examination confirmed the endometriotic character of the cysts and both the phase of the menstrual cycle and the absence of pathological conditions of the endometria. Endometriotic cysts were excised at operation, biopsied and endometriotic tissue was dissected from underlying parenchyma. In previous studies, we have successfully established and employed endometrial cell cultures from endometrial samples and from endometriotic cysts biopsies (Viganò et al., 1993, 2000
; Somigliana et al., 1996
; Di Blasio et al., 1997
). Briefly, tissues were gently minced into small pieces (12 mm3) and washed in fresh medium to remove mucus or debris. Thereafter, they were incubated for 2 h at 37°C in a shaking water bath in 10 ml Ham's F-10 (BioWhittaker, PBI International, Milan, Italy) containing 0.2% collagenase (Boehringer-Mannheim Biochemicals, Milan, Italy). After several washings, the cell suspension was digested in a 0.05% trypsin solution for 35 min. Cells, which represent a mixture of both stromal and epithelial components, were washed twice in Ham's F-10 supplemented with 10% fetal calf serum (FCS; Flow Laboratories, Opera, Milan, Italy) and antibiotics and counted using a Cell Counter (Seac, Milan, Italy). Specifically, ~50 000100 000 cells/well were allowed to adhere selectively to 24-well tissue culture plates and cultured in 1 ml of Ham's F-10 with 10% FCS, 2 mmol/l L-glutamine, antibiotics and 2.5 µg/ml fungizone in a humidified atmosphere of 95% air and 5% CO2 at 37°C.
Proliferation assay
Duplicates of endometrial and endometriotic cells cultures established at day 1 were allowed to proliferate in eight different medium conditions from day 0:
For each of these conditions, control medium was represented by Ham's F-10 with 10% charcoal stripped (steroid depleted) calf serum (Sigma) added with the corresponding concentration of 17-ß-oestradiol and progesterone (Sigma) (Table I). Steroids were dissolved in ethanol as concentrated stocks. The final ethanol concentration was below 0.1% in all media. Content of 17-ß-oestradiol in follicular fluid pools ranged between 2.2x106 and 3.5x106 pg/ml, whereas progesterone concentration was between 10x106 and 14x106 pg/ml. Levels of 17-ß-oestradiol and progesterone in pools of peritoneal fluids ranged between 300 and 640 pg/ml and between 18x103 and 31x103 pg/ml respectively. All media were supplemented with 2 mmol/l L-glutamine, antibiotics and 2.5 µg/ml fungizone and changed every other day. After 8 days of treatment, cells were harvested by a 10 min incubation in 0.05% trypsin-0.02% EDTA solution and counted using a Cell Counter (Seac).
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Results |
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Discussion |
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Peritoneal fluid contains many growth factors and cytokines which have been advocated to be involved in the implantation and growth of ectopic endometrial fragments (Koutsilieris et al., 1991). Interestingly, it has been reported that the peritoneal fluid of women with endometriosis would induce an increase in endometrial stromal cells proliferation (Surrey and Halme, 1990
). However, results from other studies on this subject are conflicting (Meresman et al., 1997
; Overton et al., 1997
). In the present study, we failed to detect an increased ability to stimulate endometrial cells proliferation using peritoneal fluids from women with endometriosis. However, this topic was not the main objective of our experimental design and we cannot exclude that increasing the number of peritoneal fluid pools tested would lead to some differences. Indeed, the central purpose of this study was to evaluate the ability of follicular fluid to affect endometrial and endometriotic cell proliferation. To this specific aim, comparison with peritoneal fluid was established, since this milieu is a well-known mitogenic source for endometrial cells (Koutsilieris et al., 1991
). In this contest, results from our study suggest that follicular fluid may represent an extremely favourable environment for endometrial and endometriotic cells growth. Indeed, a marked and statistically significant enhanced ability to stimulate proliferation of these cells was observed using follicular fluids obtained from partially luteinized follicles.
Our study also implies that the follicular fluid-mediated induction of endometrial cell proliferation is not merely due to steroid hormones. Indeed, the control media used in this study did actually contain a concentration of steroid hormones similar to the experimental conditions tested. Therefore, other factors present in follicular fluid may be responsible for this effect. In particular, growth factors such as vascular endothelial growth factor (Lee et al., 1997), insulin-like growth factors I and II (VanDessel et al., 1996
), steroidogenesis-inducing protein (Khan et al., 1997
) and tumour necrosis factor-
(Punnonen et al., 1992
) and cytokines such as interleukin (IL)-1 (Chen et al., 1995
), IL-6 (Buyalos et al., 1992
), IL-8 (Arici et al., 1996
), monocyte chemotactic protein-1 (Arici et al., 1997b
), leukaemia inhibiting factor (Arici et al., 1997a
), as well as prostaglandins have been detected in follicular fluid. Interestingly, direct evidences of interaction between growth factors and sex steroids in the regulation of endometrial stromal cell growth have been reported (Irwin et al., 1991
). However, factors and molecular interactions that are responsible for the ability of follicular fluid to increase endometrial stromal cell proliferation markedly were not further investigated herein, and are beyond the scope of the present study. Exciting new insights might be drawn from future investigations in this field.
Our results are generally in keeping with those from Bahtiyar et al. in terms of reported ability of follicular fluid to stimulate endometrial cell growth (Bahtiyar et al., 1998). Moreover, in that study follicular fluid from women with endometriosis was shown to induce an increased cell proliferation than that obtained using follicular fluid from women without the disease. It should, however, be noted that these authors failed to evaluate the mitogenic ability of follicular fluid relative to other milieus and did not investigate whether this effect was merely steroid-dependent. Interestingly, they postulated that repetitive release of follicular content into the peritoneal fluid at the time of ovulation may play a role in the growth of peritoneal ectopic endometrial implants. Although this hypothesis might have some relevance, it is tempting to speculate that ovarian follicles may be also involved in the growth of ovarian endometriomas. At present, endometriotic cyst formation could probably not be explained by a unique aetiopathogenetic model and this has undoubtedly complicated the research on this topic. Nevertheless, there is a small amount of compelling evidence to support a possible role of ovarian follicles in the pathogenesis of these cysts. First, Nezhat et al. found that some large endometriomas also had histological characteristics of luteal or follicular ovarian cysts suggesting that these lesions may develop as a result of secondary involvement of functional ovarian cysts (Nezhat et al., 1992
). Moreover, very recently, Jain and Dalton showed by serial transvaginal tracking of ovarian follicles that a chocolate cyst can develop from an ovarian follicle (Jain and Dalton, 1999
). In each of the 12 cases reported by these authors, the diagnosis was successively confirmed laparoscopically.
In conclusion, our findings suggest that follicular fluid may be important in the pathogenesis of endometriomas. Results from experimental and clinical future investigations are mandatory to verify this hypothesis. If the role of the follicular fluid would be confirmed, our ability to prevent, diagnose and treat endometriomas could be improved.
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Notes |
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References |
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Submitted on November 30, 2000; accepted on March 1, 2001.