Steroids Archives - Revista Brasileira de Ginecologia e Obstetrícia
Summary
Revista Brasileira de Ginecologia e Obstetrícia. 2010;32(9):447-453
DOI 10.1590/S0100-72032010000900006
PURPOSE: to evaluate the concentration of steroid hormones in follicular fluid (FF) of small (10-14 mm) and large (> 18 mm) follicles of women with polycystic ovary syndrome (PCOS) submitted to controlled ovarian hyperstimulation (COH) and in vitro fertilization (IVF) cycles. METHODS: a case-control study was conducted on 13 infertile women with PCOS (17 cycles) and 31 infertile women due to male factor - Control Group (31 cycles). FF was aspirated individually and divided into four groups: G1 (FF of small follicles of the Control Group), G2 (FF of small follicles of the PCOS group), G3 (FF of large follicles of the Control Group) and G4 (FF of large follicles of the PCOS group). Estrogen, progesterone and β-hCG were determined by chemiluminescence, and testosterone and androstenedione by radioimmunoassay. The unpaired t-test was used to compare the hormone determinations in the FF of the PCOS and Control Groups, and the four groups were compared by ANOVA. Fisher's exact test was used to compare the pregnancy rates. RESULTS: the small follicles of the two groups had lower progesterone levels (8,435±3,305 ng/mL) than large follicles (10,280±3,475 ng/mL), p-value <0.01. The progesterone levels of all follicles of group PCOS (8,095±4,151 ng/mL) were lower than Control (9,824±3,128 ng/mL), p-value =0.03. Testosterone differed between G1 (326.6±124.4 ng/dL) and G3 (205.8±98.91 ng/dL), p-value <0.001, and between G3 (205.8±98.91 ng/dL) and G4 (351.10±122.1ng/dL), p-value <0.001. Small follicles had higher testosterone levels (508.9±266 ng/dL) than large follicles (245.10±123 ng/dL), p-value <0.0001. The pregnancy rates did not differ between the PCOS (5/13, 38.5%) and the Control groups (9/31, 40.9%), p-value =072. CONCLUSIONS: women with PCOS had high testosterone concentrations in the FF, regardless of the stage of follicle development, and reduced progesterone levels, suggesting that paracrine factors may inhibit the secretion of the latter by follicular cells. The pregnancy rates showed that treatment with COH and IVF is a good option for women with infertility secondary to PCOS.
Summary
Revista Brasileira de Ginecologia e Obstetrícia. 2010;32(9):447-453
DOI 10.1590/S0100-72032010000900006
PURPOSE: to evaluate the concentration of steroid hormones in follicular fluid (FF) of small (10-14 mm) and large (> 18 mm) follicles of women with polycystic ovary syndrome (PCOS) submitted to controlled ovarian hyperstimulation (COH) and in vitro fertilization (IVF) cycles. METHODS: a case-control study was conducted on 13 infertile women with PCOS (17 cycles) and 31 infertile women due to male factor - Control Group (31 cycles). FF was aspirated individually and divided into four groups: G1 (FF of small follicles of the Control Group), G2 (FF of small follicles of the PCOS group), G3 (FF of large follicles of the Control Group) and G4 (FF of large follicles of the PCOS group). Estrogen, progesterone and β-hCG were determined by chemiluminescence, and testosterone and androstenedione by radioimmunoassay. The unpaired t-test was used to compare the hormone determinations in the FF of the PCOS and Control Groups, and the four groups were compared by ANOVA. Fisher's exact test was used to compare the pregnancy rates. RESULTS: the small follicles of the two groups had lower progesterone levels (8,435±3,305 ng/mL) than large follicles (10,280±3,475 ng/mL), p-value <0.01. The progesterone levels of all follicles of group PCOS (8,095±4,151 ng/mL) were lower than Control (9,824±3,128 ng/mL), p-value =0.03. Testosterone differed between G1 (326.6±124.4 ng/dL) and G3 (205.8±98.91 ng/dL), p-value <0.001, and between G3 (205.8±98.91 ng/dL) and G4 (351.10±122.1ng/dL), p-value <0.001. Small follicles had higher testosterone levels (508.9±266 ng/dL) than large follicles (245.10±123 ng/dL), p-value <0.0001. The pregnancy rates did not differ between the PCOS (5/13, 38.5%) and the Control groups (9/31, 40.9%), p-value =072. CONCLUSIONS: women with PCOS had high testosterone concentrations in the FF, regardless of the stage of follicle development, and reduced progesterone levels, suggesting that paracrine factors may inhibit the secretion of the latter by follicular cells. The pregnancy rates showed that treatment with COH and IVF is a good option for women with infertility secondary to PCOS.
Summary
Revista Brasileira de Ginecologia e Obstetrícia. 2007;29(11):593-601
DOI 10.1590/S0100-72032007001100008
There is evidence that estrogen, progesterone and testosterone have modulatory effects over both cellular and humoral immune responses. These effects occur via immune-neuroendocrine interactions, involving the pituitary, gonadal steroids, thymic hormones, and the presence of specific receptors and messengers. These immune responses may be altered during pregnancy, gonadectomy, menopause and hormone therapy. Estrogen depresses the cellular immunity, suppresses the natural killer cell activity and increases the production of antibodies. Progesterone/progestogen suppresses the cellular immune system. Androgens, after metabolization in estrogens, might stimulate the humoral immune response. Hormone therapy is still broadly used in post-menopause women with the purpose of decreasing climacteric symptoms, as well as preventing genital atrophy and bone loss. Its use to attenuate the risk of cardiovascular and neurodegenerative diseases remains in debate. A few studies have been carried out to examine the effect of post-menopause hormone therapy on the immune system. There is evidence that the hypoestrogenic state, following menopause, could result in less resistance to infections. The present review examines the interaction between sexual steroids and the immune system and, based on epidemiological and clinical studies, evaluates the effects of hormone therapy on the immune responses. It was concluded that the hormone therapy normalizes the cellular immune response in post-menopausal women.
Summary
Revista Brasileira de Ginecologia e Obstetrícia. 2007;29(11):593-601
DOI 10.1590/S0100-72032007001100008
There is evidence that estrogen, progesterone and testosterone have modulatory effects over both cellular and humoral immune responses. These effects occur via immune-neuroendocrine interactions, involving the pituitary, gonadal steroids, thymic hormones, and the presence of specific receptors and messengers. These immune responses may be altered during pregnancy, gonadectomy, menopause and hormone therapy. Estrogen depresses the cellular immunity, suppresses the natural killer cell activity and increases the production of antibodies. Progesterone/progestogen suppresses the cellular immune system. Androgens, after metabolization in estrogens, might stimulate the humoral immune response. Hormone therapy is still broadly used in post-menopause women with the purpose of decreasing climacteric symptoms, as well as preventing genital atrophy and bone loss. Its use to attenuate the risk of cardiovascular and neurodegenerative diseases remains in debate. A few studies have been carried out to examine the effect of post-menopause hormone therapy on the immune system. There is evidence that the hypoestrogenic state, following menopause, could result in less resistance to infections. The present review examines the interaction between sexual steroids and the immune system and, based on epidemiological and clinical studies, evaluates the effects of hormone therapy on the immune responses. It was concluded that the hormone therapy normalizes the cellular immune response in post-menopausal women.