Effects of estradiol alone or in combination with cyproterone acetate on carotid artery pulsatility index in postmenopausal women

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Effects of estradiol alone or in combination with cyproterone acetate on carotid artery pulsatility index in postmenopausal women Vincenzo De Leo a,*, Antonio la Marca a, Roberto Orlandi c, Donatella Crippa c, Carlo Setacci b, Felice Petraglia a a

Department of Pediatrics, Obstetrics and Reproductive Medicine, Section of Obstetrics and Gynecology, Siena, Italy b Chair of Vascular Surgery, University of Siena, Siena, Italy c Shering Medical Department, Milan, Italy Received 24 September 2002; received in revised form 25 March 2003; accepted 17 April 2003

Abstract Ojectives: The incidence of cardiovascular disease (CVD) increases dramatically with the loss of ovarian function. Observational studies indicate that the risk of CVD may be reduced by up to 50% in postmenopausal women who take estrogen replacement therapy. Estrogen therapy reduces internal carotid artery pulsatility index (PI). The improvement in carotid PI following HRT has been proposed as a marker of the cardioprotective effect of estrogen therapy. Cyclical progesterone addition to ERT partially antagonizes the reduction on the carotid artery PI. As progesterone, androgens has been shown to decreases arterial vasodilatation and carotid PI. To our knowledge no information is available regarding the effect of CPA addition on the carotid artery PI in women taking estrogen replacement therapy. Methods: We recruited a total of 30 women in postmenopause for at least 12 months and were in good health. Fifteen women were postmenopausal following surgical bilateral oophorectomy for benign condition. Fifteen postmenopausal women received estradiol valerate for 21 days and CPA (1 mg) for 10 days for 3 months (Group E/CPA). Ovarectomized women (n /15) received estradiol hemihydrate (2 mg) for 3 months (Group E). The main factor investigated was PI, an indicator of impedence to blood flow down stream. Doppler US were performed before the start and at the end of the therapy. Results: The mean reductions respect to basal values were 11.5% in women treated with E and 10.8% in women treated with E/CPA. No significant difference was found between treatment values. Conclusions: The results of the present study demonstrate that cyproterone acetate addition to E do non-antagonize the effect of estrogen on carotid artery PI. The present study demonstrate that both estradiol hemihydrate and estradiol valerate plus cyproterone acetate lead to similar improvement in carotid artery; through this mechanism both treatments could potentially reduce the incidence of cerebrovascular disease in postmenopausal women. # 2003 Elsevier Ireland Ltd. All rights reserved. Keywords: Estradiol; Cyproterone acetate; Carotid artery pulsatility index

* Corresponding author. Present address: Institute of Obstetrics and Gynecology, University of Siena, Policlinico Le Scotte, Viale Bracci, 53100 Siena, SI, Italy. Tel.: /39-0577-23-3465; fax: /39-0577-23-3464. E-mail address: [email protected] (V. De Leo). 0378-5122/03/$ - see front matter # 2003 Elsevier Ireland Ltd. All rights reserved. doi:10.1016/S0378-5122(03)00192-0

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1. Introduction Cardiovascular disease (CVD) is the leading cause of death in women in the western world. The incidence of CVD increases dramatically with the loss of ovarian function. Ovarian hormones have anti-atherogenic properties influencing all steps in the development of atherosclerosis: accumulation of cholesterol in the arterial wall, arterial smooth muscle cell proliferation platelet aggregation, collagen production and act as a vasoactive substance [1
/6]. Observational studies indicate that the risk of CVD may be reduced by up to 50% in postmenopausal women who take estrogen replacement therapy. Only 30
/50% of this reduction is considered due to the beneficial changes in serum lipid profile following estrogen therapy [7,8]. Estrogen reduces vascular resistance and act as a vasodilator in vitro [9]. In women estrogen modulates blood flow in arterial distracts such as vagina, uterine and carotid vessels as well as coronary arteries [1,2]. Downstream resistance to flow estimated as arterial pulsatility index (PI), increases with time from menopause [10]. Estrogen therapy reduces internal carotid artery PI [10
/17]. The improvement in carotid PI following HRT has been proposed as a marker of the cardioprotective effect of estrogen therapy [10
/17]. Progesterone has been shown to antagonize the vasodilatation caused by estradiol in the animal model [18]. Cyclical progesterone addition to ERT partially antagonizes the reduction on the carotid artery PI [19]. As progesterone, androgens has been shown to decreases arterial vasodilatation and carotid PI. In menopausal women, androgen supplementation during HRT partially contrast the beneficial effects of estrogen on cerebral blood flow [20]. Both dydrogesterone and norethisterone partially antagonized the reduction in the carotid artery PI in postmenopausal women of estrogen replacement therapy [19]. Recent reviews demonstrated that the type of progestogen detained differential effect of HRT. On lipid and lipoprotein levels, the least antagonism was seen with medrogestone, progesterone and cyproterone acetate. High antagonistic effect was observed with medroxyprogesterone acetate norgestrel and nor-

ethindrone [21
/27]. Due to low antagonistic effect of CPA on estrogen action, the association of estradiol valerate and cyproterone acetate has been widely prescribed to postmenopausal women. To our knowledge no information is available regarding the effect of CPA addition on the carotid artery PI in women taking estrogen replacement therapy.

2. Methods We recruited a total of 30 women. Institution review board approval for the study was obtained. The women had all been in postmenopause for at least 12 months and were in good health. Fifteen women were postmenopausal following surgical bilateral oophorectomy for benign condition. None had taken thyroid hormones, steroids or SERMS in the previous 12 months. Women with known CVD where excluded lipids and blood pressure were in the normal range for all women, 15 postmenopausal women received estradiol valerate for 21 days and CPA (1 mg) for 10 days (Climen, Schering AG) for 3 months (Group E/ CPA). Ovarectomized women (n /15) received estradiol hemihydrate (2 mg) for 3 months (Estrofem, Novonordisk) (Group E). All women were asked to not change their physical activity. No significant differences were found between baseline characteristics between the two groups (Table 1). The main factor investigated was PI, an indicator of impedence to blood flow down stream. Table 1 Demographic details of the study population

Age (year) BMI (kg/ht2) FSH (IU/l) E2 (pg/ml) Tc (mg/dl) LDLc (mg/dl) HDLc (mg/dl) TG (mg/dl) Carotid PI

E/CPA (n/15)

E (n/15)

529/3 279/4.4 589/8 159/4 2259/53 1389/29 659/17 1109/23 0.989/0.1

559/4 269/5.2 619/9 159/5 2189/46 1359/27 629/16 1059/21 0.979/0.1

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Doppler US were performed before the start and at the end of the therapy. The equipment used was a HP Sonos 5500 with a linear 5-MHz probe. Each women rested for 5 min in the supine position before readings were taken. The common carotid arteries and the proximal parts of the internal and external carotid artery were identified. PI was the mean of three consecutive recordings from internal carotid artery. Serum cholesterol, triglycerides, HDL- and LDL-cholesterol (calculated using the Friedewald’s formula) were assessed at baseline and every 4 weeks of treatment for both groups.

3. Statistical analysis The results were expressed as means and standard deviations. Statistical analysis was performed by the t-test for paired and unpaired data. Statistical significance was set at P B/0.05.

4. Results Baseline values of carotid artery PI prior to the treatments were compared and no significant differences were found (Table 1). As shown in the Fig. 1, 3 months of both treatments were followed by a significant reduction in carotid artery PI. The mean reductions respect to basal values were 11.5% in women treated with E and 10.8% in

Fig. 1. Significant reduction in carotid PI after 3 months of therapy with E/CPA (circle) or E alone (square).

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women treated with E/CPA. No significant difference was found between treatment values. Baseline levels of serum cholesterol, triglycerides, HDL- and LDL-cholesterol were similar in the two groups. Serum cholesterol concentrations fell by 4.5% in group E (P B/0.05) and by 3.4% in group E/CPA (P B/0.05). HDL concentrations did not change significantly at the end of treatment in both groups. For triglycerides, significant increases (P B/0.05) from baseline were observed in both groups at most of the time points studied (59/ 1 and 6.29/1.3% for E/CPA and E, respectively). LDL concentrations significantly decreased (P B/ 0.05) from baseline in both groups at most of the time points studied (/69/2 and /89/3% for E/ CPA and E, respectively). The LDL/HDL ratio fell by 10% in both groups (P B/0.01) (Fig. 2).

5. Discussion Doppler US is the most accurate non-invasive method to evaluate vascular impedence. PI reflects vascular impedence to distal flow with respect to the point of measurement. Because PI represents distal resistance and vascular compliance, modifications in PI reflect a parallel effect on heart load and hence on heart function. Estradiol alone induced a 11.5% reduction in PI after 3 months of therapy, which is similar to the reduction reported in literature [16,28]. Estradiol increases blood flow in reproductive tissues and lead to relaxation of smooth muscle cells of vessels such as coronary arteries [29
/31]. The increase in arterial PI occurring in women after menopause seems to be due to reduced vascular compliance and increased vascular resistance. Estrogen administration leads to reduction in PI. It has been reported that in suspension of therapy, PI returns to pre-treatment values in 6 month, suggesting a causal relationship between sex steroids and vascular tone [32]. The results of the present study demonstrate that cyproterone acetate addition to estradiol do non-antagonize the effect of estrogen on carotid artery PI. A recent study demonstrated an unfavorable affect of other progestogens, namely dydrogesterone and norethisterone on carotid

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Fig. 2. Percentage modifications in lipids after 3 months of therapy with E/CPA (black columns) or E alone (grey columns).

artery PI [19]; others found no effect when medroxyprogesterone acetate was administered [33]. Progestogens have been showed to exert differential effect on lipids and lipoproteins [34], similarly the type of progestogen may differentially affect the beneficial action of estradiol on vascular tone. Estrogen replacement therapy has been shown to reduce the risk of coronary disease [35]. The most probable mechanism of this effect is the modification of lipid profiles [36]. Estradiol is reported to decrease serum triglycerides and total, LDL- and HDL-cholesterol [37]. The administration of a progestin to protect the endometrium reduces the positive effects of estradiol on lipid profiles. However, this reduction depends on dose and the androgenicity of the progestin [34]. The results of our study show that protocols with estradiol valerate and cyproterone acetate have favorable effects on serum lipids. Changes in plasma levels of cholesterol, HDL, LDL, and triglycerides were not significantly different in the two groups. The positive effect of E/CPA association is due to the very low dose of cyproterone acetate. The dose of 1 mg for only 12 days per month is able to prevent estrogen induced endometrial hyperplasia without antagonize the beneficial effect of estradiol. Furthermore cyproterone is an antiandro-

genic progestin which is followed by a positive effect on frequent menopausal disturbances of skin such as hirsutism. In conclusion the present study demonstrate that both estradiol hemihydrate and estradiol valerate plus cyproterone acetate lead to similar improvement in carotid artery; through this mechanism both treatments could potentially reduce the incidence of cerebrovascular disease in postmenopausal women.

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