Uterine fibroids are the most common gynecological disorder, classically requiring surgery when symptomatic. Although attempts at finding a nonsurgical cure date back to centuries, it is only around the middle of the last century that serious attempts at a medical treatment were carried out. Initially, both progestins and estrogen–progestin combinations have been utilized, although proof of their usefulness is lacking. A major step forward was achieved when peptide analogs of the GnRH were introduced, first those with superagonist properties and subsequently those acting as antagonists. Initially, the latter produced side effects preventing their routine utilization; eventually, this problem was overcome following the synthesis of cetrorelix. Because both types of analogs produce hypoestrogenism, their use is limited to a maximum of 6 months and, for this reason, today they are utilized as an adjuvant treatment before surgery with overall good results. Over the last decade, new, nonpeptidic, orally active GnRH-receptor blockers have also been synthesized. One of them, Elagolix, is in the early stages of testing in women with fibroids. Another fundamental development has been the utilization of the so-called selective progesterone receptor modulators, sometimes referred to as “antiprogestins”. The first such compound to be applied to the long-term treatment of fibroids was Mifepristone; today, this compound is mostly used outside of Western Countries, where the substance of choice is Ulipristal acetate. Large clinical trials have proven the effectiveness of Ulipristal in the long-term medical therapy of fibroids, although some caution must be exercised because of the rare occurrence of liver complications. All selective progesterone receptor modulators produce unique endometrial changes that are today considered benign, reversible, and without negative consequences. In conclusion, long-term medical treatment of fibroids seems possible today, especially in premenopausal women.
Background : A number of synthetic steroids are capable of modulating progesterone receptors with a spectrum of activities ranging from pure antagonism to a mixture of agonism and antagonism. The best known of these are mifepristone (RU 486), asoprisnil (J 867), onapristone (ZK 98299), ulipristal (CDB 2914), Proellex ™ (CDB 4124), ORG 33628 and ORG 31710.
The term progestogen has been widely utilized to indicate the general class of agents that includes both progesterone and its synthetic analogs, whereas the term progestin refers only to synthetic progestational steroids. The development of progestins has been influenced in a major way by the search for orally active hormonal contraceptives, since it is likely that hormonal contraceptives will continue to utilize a progestin, the only possible alternative being represented by the utilization of antiprogestins. Synthetic progestogens in clinical use today belong to three main chemical families: progesterone derivatives (progesterone, retro-progesterone, 19-norprogesterone and 17alpha-hydroxyprogesterone); gonane and 19-nortestosterone derivatives (norethisterone, levonorgestrel, desogestrel, gestodene, norgestimate); a spironolactone derivative. Biological potency of progestogens varies depending on the end-point measured, usually ovulation inhibition and endometrial transformation; with both these tests, the most active compounds are all gonane derivatives, with a potency over a 100 times that of the natural hormone. When administered in adequate doses, a progestin inhibits fertility by inhibiting ovulation. This action is mainly exerted at the hypothalamic level where, physiologically, progesterone decreases the number of LH pulses. When progestogens are delivered directly to the uterine cavity, their action seems to be purely local. It has been amply proven that--even when administered in doses that do not constantly inhibit ovulation--a progestin can still remain effective as a contraceptive by acting at the level of the cervical mucus and, at least in part, of the endometrium. Progestogens utilized today differ largely in their pharmacokinetics. In general, after intake, these compounds are rapidly absorbed and distributed so that peak serum concentrations are reached between 1 and 4 h. Third-generation progestins (desogestrel, gestodene, norgestimate) have common characteristics: a higher affinity for progesterone receptors than their predecessors, a lower affinity for androgen receptors, a higher selectivity of action, a higher central inhibitory activity, a higher potency at the level of the endometrium, and an overall metabolic neutrality, in terms of effects on lipid and carbohydrate metabolism. In general, progestins can induce two types of adverse effects: changes in lipid metabolism and bleeding irregularities. Whereas the newer compounds seem to have overcome the first of these adverse effects, the second remains untouched: to this day, proper cycle control can only be achieved with combined hormonal contraceptives.
scite is a Brooklyn-based organization that helps researchers better discover and understand research articles through Smart Citations–citations that display the context of the citation and describe whether the article provides supporting or contrasting evidence. scite is used by students and researchers from around the world and is funded in part by the National Science Foundation and the National Institute on Drug Abuse of the National Institutes of Health.
hi@scite.ai
10624 S. Eastern Ave., Ste. A-614
Henderson, NV 89052, USA
Copyright © 2024 scite LLC. All rights reserved.
Made with 💙 for researchers
Part of the Research Solutions Family.