You are in: eMedicine Specialties > Obstetrics and Gynecology > Reproductive Endocrinology and Infertility Ovarian InsufficiencyArticle Last Updated: Jan 15, 2008AUTHOR AND EDITOR INFORMATIONSection 1 of 12
  Author: Lawrence M Nelson, MD, MBA, Head of Integrative Reproductive Medicine Unit, Investigator, Reproductive Biology and Medicine Branch, National Institutes of Health Lawrence M Nelson is a member of the following medical societies: American College of Obstetricians and Gynecologists, American Society for Reproductive Medicine, Association of Professors of Gynecology and Obstetrics, Endocrine Society, and Society for Experimental Biology and Medicine Coauthor(s): Vaishali Popat, MD, MPH, Fellow in Endocrinology, National Institutes of Health Editors: Robert K Zurawin, MD, Associate Professor, Director of Fellowship Programs, Minimally Invasive Surgery, Department of Obstetrics and Gynecology, Baylor College of Medicine; Chief of Gynecology, Texas Children's Hospital; Francisco Talavera, PharmD, PhD, Senior Pharmacy Editor, eMedicine; A David Barnes, MD, PhD, MPH, FACOG, Consulting Staff, Department of Obstetrics and Gynecology, Mammoth Hospital, Mammoth Lakes, California, Pioneer Valley Hospital, Salt Lake City, Utah, Warren General Hospital, Warren, Pennsylvania and Mountain West Hospital, Tooele, Utah; Frederick B Gaupp, MD, Consulting Staff, Department of Family Practice, Assumption Community Hospital; Bryan D Cowan, MD, Professor and Chairman, Department of Obstetrics and Gynecology, University of Mississippi College of Medicine; Consulting Staff, Department of Obstetrics and Gynecology, Veterans Affairs Medical Center; Medical Director, Wiser Hospital for Women, University of Mississippi Medical Center Author and Editor Disclosure Synonyms and related keywords: premature ovarian failure, premature menopause, autoimmune ovarian failure, autoimmune oophoritis, reduced ovarian reserve, hypergonadotropic amenorrhea, menopause, perimenopause, Turner syndrome, gonadal dysgenesis, hyperprolactinemia, hypothalamic amenorrhea, polycystic ovary syndrome, Stein-Leventhal syndrome, primary amenorrhea, secondary amenorrhea, oligomenorrhea, metrorrhagia, polymenorrhea, amenorrhea INTRODUCTIONSection 2 of 12
  BackgroundThe ovary functions as an endocrine organ and as a reproductive organ. As an endocrine organ, the ovary maintains health in young women by secreting steroid hormones such as estrogens, androgens, and progesterone. The ovary also secretes glycoprotein hormones such as inhibin, activin, and follistatin. Regular and predictable menstrual cycles occur if these hormones are secreted in an orderly fashion in response to stimulation provided by the hypothalamus and pituitary. As defined by the World Health Organization, ovarian insufficiency can be caused by a primary disorder in the ovary or it can occur as a result of secondary causes. Ovarian insufficiency is considered primary if the ovary fails to function normally in response to appropriate gonadotropin stimulation provided by the hypothalamus and pituitary. Ovarian insufficiency is considered secondary if the hypothalamus and pituitary fail to provide appropriate gonadotropin stimulation. As a reproductive organ, the ovary maintains a store of oocytes. Ovulation, the release of a mature oocyte from the ovary, is dependent on the growth of ovarian follicles in response to stimulation provided by the hypothalamus and pituitary. Ovarian insufficiency is a failure of the ovary to function normally in a patient younger than 40 years, in its role either as an endocrine organ or as a reproductive organ. In patients aged 40 years or older, the expected physiologic decline of ovarian function that takes place with aging is termed perimenopause or the menopausal transition. PathophysiologyA graafian follicle is a fluid-filled cystic structure in the ovary that contains an oocyte and granulosa cells. Normal ovarian function in young women is dependent on the growth and development of graafian follicles. Graafian follicles arise and grow from a pool of microscopic structures known as primordial follicles. A store of primordial follicles is required to support normal endocrine and reproductive function of the ovary. The growing graafian follicle is the major source of estradiol production, and a mature graafian follicle must develop to permit normal ovulation. In a sense, primordial follicles can be viewed as inactive endocrine and reproductive units that are stored in the ovary for future use. Primordial follicles are composed of an oocyte surrounded by a single layer of granulosa cells. The number of primordial follicles in the human ovary peaks at approximately 7 million during the fifth gestational month. After this initial finite pool is in place, no additional primordial follicles are formed. If the expenditure of these primordial follicles is regulated properly, this initial endowment functions throughout a woman's normal reproductive life span. Menopause is defined as the permanent cessation of menses. Normal menopause takes place when the supply of functional primordial follicles is exhausted. On average, natural menopause occurs at age 50 years. Importantly, normal cyclic sex steroid production in women is linked to gamete production. When primordial follicles are depleted or fail to function, normal cyclic production of estrogen and progesterone ceases and menstruation stops. In most cases, the mechanism leading to primary ovarian insufficiency remains a mystery, even after a thorough evaluation in a clinical research setting. Primary ovarian insufficiency occurs in some patients because of ovarian follicle depletion. Premature ovarian follicle depletion can occur by 2 mechanisms, (1) due to deficiency in the number of primordial follicles present in the initial in utero endowment or (2) due to an accelerated rate of follicle atresia. For example, fetuses with a single X chromosome, as in those with Turner syndrome, develop normal ovaries with a normal complement of primordial follicles, but accelerated follicle atresia leads to ovarian insufficiency at an early age. Once the responsible genes are identified, the mechanisms of follicle depletion that lead to ovarian insufficiency will be clearer. Primary ovarian insufficiency also can occur because of follicle dysfunction. Follicle dysfunction means that primordial follicles remain in the ovary, but for some reason, they fail to function normally. Some patients with primary ovarian insufficiency have follicles remaining in the ovary that appear healthy but fail to function despite high gonadotropin levels. Ovarian autoimmunity is a well-established cause of ovarian follicle dysfunction and ovarian insufficiency. Autoimmune lymphocytic oophoritis, initially described in association with Addison disease, is characterized by intense lymphocytic infiltration found primarily in the theca interna of developing graafian follicles. In patients with this condition, primordial follicles are spared the lymphocytic attack. In rare cases, enzyme deficiencies, such as 17-20 desmolase deficiency, also can be a cause of follicle dysfunction and ovarian insufficiency. Once the genes involved in primordial follicle activation and function are identified, the mechanisms of follicle dysfunction that lead to ovarian insufficiency will be clearer. Primary ovarian insufficiency, in its fully developed form, is also known as premature ovarian failure. The term failure is problematic because some patients with this condition get pregnant subsequent to the diagnosis. Thus, the ovary has not truly failed but is more likely functioning in an intermittent and unpredictable manner. Primary ovarian insufficiency is a more accurate term.
Secondary ovarian insufficiency, a result of inadequate or inappropriate gonadotropin stimulation of the ovary, can be caused by a variety of disorders that are covered in other articles. Pituitary tumors, such as prolactinomas, are associated with hyperprolactinemia, and this can be a cause of secondary ovarian insufficiency. A pituitary adenoma secreting ACTH and causing Cushing syndrome is an important, but much less common, cause of secondary ovarian insufficiency. Cushing syndrome may present with signs of androgen excess, and thus, the disorder might be confused with polycystic ovary syndrome, late-onset congenital adrenal hyperplasia, or an androgen-producing tumor of the adrenals or ovary. The physiologic origin of the stimulus from the CNS to release gonadotropins to provide ovarian stimulation comes from the gonadotropin-releasing hormone (GnRH) pulse generator. This structure is located in the arcuate nucleus of the hypothalamus. This pulse generator requires appropriate positive regulatory signals from the CNS to function properly. Inappropriate regulatory signals from the CNS can lead to failure of the GnRH pulse generator to function properly. Failure of the GnRH pulse generator results in inadequate synthesis, storage, and secretion of pituitary gonadotropins. Secondary ovarian insufficiency can result from abnormal function of the GnRH pulse generator, even in the absence of any structural CNS abnormality, such as a tumor. Secondary ovarian insufficiency also can be a result of excessive exercise or eating disorders such as anorexia nervosa or bulimia. Stress, anxiety, and depression, as well as numerous centrally acting drugs, can disrupt normal GnRH pulse-generator function and, thus, also can be causes of secondary ovarian insufficiency. Congenital reproductive tract anomalies or Asherman syndrome can cause amenorrhea on a structural basis, but these disorders can be readily distinguished from ovarian insufficiency. Clinical Situations of Primary Ovarian Insufficiency and Premature Ovarian Failure
FrequencyUnited StatesOvert primary ovarian insufficiency affects 1 in 100 women by age 40 years. It affects 1 in 1000 women by age 30 years and 1 in 10,000 women by age 20 years. The incidence of lesser-stage primary ovarian insufficiency is not available. InternationalNo clear relationship between incidence and national origin has been demonstrated. Mortality/MorbidityDelay in diagnosis of ovarian insufficiency may have potentially serious adverse health effects, such as the development of osteopenia or osteoporosis. In addition, 2 studies have demonstrated that women who develop primary ovarian insufficiency before age 40 years have a higher risk of all-cause mortality compared to women who undergo natural menopause. One study showed a relative risk of 1.56, with a 95% confidence interval (1.07-2.27). The other study showed a relative risk of 1.95, with a 95% confidence interval (1.24-3.07). RaceNo clear relationship has been demonstrated between incidence and race. SexOvarian insufficiency obviously occurs only in women. AgePrimary ovarian insufficiency, by definition, occurs before age 40 years. CLINICALSection 3 of 12
HistoryPrimary ovarian insufficiency may develop insidiously. In a few cases, the earliest sign of primary ovarian insufficiency may be the development of vasomotor symptoms, or hot flashes, even while patients still are menstruating regularly. Usually, the earliest sign of overt endocrine insufficiency of the ovary is the development of shortened or irregular cycles. Occult and biochemical primary ovarian insufficiency generally present as unexplained infertility in a woman with regular menses. Secondary ovarian insufficiency may be caused by a variety of diverse disorders that have abnormal function of the GnRH pulse generator as a final common pathway. Chronic systemic disease, drug therapy, an eating disorder, excessive exercise, depression, or an anxiety disorder all should be considered as factors in the loss of menstrual regularity. Headache and loss of peripheral vision could be symptoms of a pituitary tumor. Galactorrhea might herald a pituitary prolactinoma. Symptoms of androgen excess, such as acne, hirsutism, or male-pattern balding, could herald polycystic ovary syndrome or stromal hyperthecosis, late-onset congenital adrenal hyperplasia, Cushing syndrome, or an androgen-secreting tumor.
PhysicalPatients with early-stage ovarian insufficiency alone have no physical findings. In overt primary ovarian insufficiency and profound secondary ovarian insufficiency, physical examination may demonstrate atrophic vaginitis resulting from an estrogen deficiency. Ovarian insufficiency comprises a continuum along a decline in ovarian function. Patients with ovarian insufficiency frequently produce estrogen intermittently and may not demonstrate physical findings of estrogen deficiency. Thus, the finding of cervical mucus upon pelvic examination does not rule out a diagnosis of ovarian insufficiency.
CausesOvarian insufficiency can develop as a result of an ovarian disorder. In this case, the clinical situation is termed primary ovarian insufficiency. Ovarian insufficiency also can develop due to inadequate ovarian stimulation coming from the hypothalamus and pituitary. In this case, the clinical situation is termed secondary ovarian insufficiency. Central ovarian insufficiency is a synonym for this condition (referring to the CNS origin of the disorder).
DIFFERENTIALSSection 4 of 12
Abdominal Abscess Androgen Excess Anorexia Nervosa Anovulation Anxiety Disorders C-17 Hydroxylase Deficiency Depression Dysfunctional Uterine Bleeding Follicle-Stimulating Hormone Abnormalities Gonadotropin-Releasing Hormone Deficiency in Adults Luteinizing Hormone Deficiency Ovarian Failure Ovarian Polycystic Disease Polyglandular Autoimmune Syndrome, Type I Polyglandular Autoimmune Syndrome, Type II Polyglandular Autoimmune Syndrome, Type III Prolactinoma
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| Drug Name | Medroxyprogesterone acetate (Provera) |
|---|---|
| Description | Progestin therapy in adolescents produces regular cyclic withdrawal bleeding until maturity of positive feedback system is achieved. Progestins stop endometrial cell proliferation, allowing organized sloughing of cells after withdrawal; typically does not stop acute bleeding episode but produces a normal bleeding episode following withdrawal. Provera tabs are 2.5 mg, 5 mg, and 10 mg. |
| Adult Dose | 10 mg/d PO 12 d each mo, usually days 1-12 of calendar month |
| Pediatric Dose | Not applicable |
| Contraindications | Documented hypersensitivity; thrombophlebitis, thromboembolic disorders, cerebral apoplexy, or patients with past history of these conditions; liver dysfunction or disease; known or suspected malignancy of breast or genital organs; undiagnosed vaginal bleeding; missed abortion; as a diagnostic test for pregnancy; known or suspected pregnancy |
| Interactions | Most interactions (eg, decreased efficiency when coadministered with aminoglutethimide, slight decreases in clearance of digoxin, increases in liver enzymes when coadministered with tamoxifen, increases in half-life of warfarin [71%]) described are at relatively high doses, which are not used for HRT |
| Pregnancy | X - Contraindicated; benefit does not outweigh risk |
| Precautions | Be alert to the earliest manifestations of thrombotic disorders (eg, thrombophlebitis, cerebrovascular disorders, pulmonary embolism, retinal thrombosis); should these occur or be suspected, discontinue immediately Discontinue pending examination if sudden partial or complete loss of vision occurs or with sudden onset of proptosis, diplopia, or migraine; if examination reveals papilledema or retinal vascular lesions, withdraw medication Perform pretreatment physical examination, including special reference to breast and pelvic organs and Papanicolaou smear Because progestogens may cause some degree of fluid retention, carefully observe conditions that can be influenced (eg, epilepsy, migraine, asthma, cardiac or renal dysfunction) In case of breakthrough bleeding, consider nonfunctional causes; in cases of undiagnosed vaginal bleeding, adequate diagnostic measures are indicated Carefully observe patients with history of psychic depression, and discontinue therapy if depression recurs to a serious degree Carefully observe in diabetes Advise pathologist of progestin therapy when relevant specimens are submitted Because of occurrence of thrombotic disorders (eg, thrombophlebitis, pulmonary embolism, retinal thrombosis, cerebrovascular disorders) in patients taking estrogen-progestin combinations and because mechanism is obscure, be alert to earliest manifestations of these disorders Only administer to women who are breastfeeding when clearly necessary because many drugs are excreted in human milk; detectable amounts of progestin have been identified in milk; effects on infant are not known |
Estrogens can be given continuously or cyclically (21 d on, 7 d off). Because no controlled studies are available to compare the efficacy and safety of one method over another, the choice of therapy should be determined after considering patient preference and physician experience. Some patients cannot tolerate estradiol patches. CEEs can be used to achieve adequate estrogenization of vaginal epithelium in young women and to maintain bone density.
| Drug Name | Ethinyl estradiol (Estinyl) |
|---|---|
| Description | Reduces the secretion of LH and FSH from the pituitary by decreasing amount of gonadotropin-releasing hormones. Use 30-35 mg ethinyl estradiol combined with any form of progesterone. Restoration of regular menstrual cycles prevents endometrial hyperplasia associated with anovulation. Improvements of hyperandrogenic effects are seen in 60-100% of women but usually require a minimum of 6-12 mo of use. A pregnancy test should be performed before initiating therapy. If the woman has had no menstrual period for 3 mo, withdrawal bleeding should be induced by administration of 5-10 mg of medroxyprogesterone acetate (Provera) daily for 10 d; then, therapy is begun with OCPs. |
| Adult Dose | 2 mg PO qd |
| Pediatric Dose | Not established |
| Contraindications | Documented hypersensitivity; thrombophlebitis, undiagnosed vaginal bleeding; cardiovascular disease, cerebrovascular disease, migraine with focal aura, known or suspected carcinoma of the breast, known or suspected estrogen dependent neoplasia, cholestatic jaundice of pregnancy or jaundice with prior pill use, acute or chronic hepatocellular disease with abnormal liver function; known or suspected pregnancy |
| Interactions | May reduce hypoprothrombinemic effects of anticoagulants; estrogen levels may be reduced with coadministration of barbiturates, rifampin, and other agents that induce hepatic microsomal enzymes; an increase in corticosteroid levels may occur when administered concurrently with ethinyl estradiol; use of ethinyl estradiol with hydantoins may cause spotting, breakthrough bleeding, and reduce contraceptive efficacy; increase in fluid retention caused by estrogen intake may reduce seizure control; antibiotics may alter GI flora and cause a reduction in absorption of oral contraceptives, which may reduce efficacy |
| Pregnancy | X - Contraindicated; benefit does not outweigh risk |
| Precautions | Exercise caution in patients diagnosed with hepatic impairment, migraine, seizure disorders, cerebrovascular disorders, breast cancer, or thromboembolic disease |
| Drug Name | Transdermal estradiol (Alora, Climara, Esclim, Vivelle-dot) |
|---|---|
| Description | Used to provide adequate estrogen for the vaginal epithelium in young women and probably maintain bone density adequately. |
| Adult Dose | Alora: 0.05, 0.075, and 0.1 mg/d applied twice weekly Climara: 0.025, 0.05, 0.075, and 0.1 mg/d applied once weekly Esclim: 0.025, 0.0375, 0.05, 0.075, 0.1 mg/d applied twice weekly Vivelle-dot: 0.037, 0.05, 0.075, 0.1 mg/d applied twice weekly |
| Pediatric Dose | Not applicable |
| Contraindications | Pregnancy; undiagnosed abnormal genital bleeding; breast cancer; estrogen-dependent neoplasia; active thromboembolic disorder; chronic liver disease; neuroophthalmologic vascular disease |
| Interactions | May decrease effect of tricyclic antidepressants and cause worsening of previously well-controlled depression, which seems to be dose-dependent and reversible with decrease or discontinuation of therapy Effects may decrease during concomitant therapy with carbamazepine and/or phenytoin, dose increase may be necessary, but estrogens may increase seizures in previously well-controlled patients with epilepsy Thyroid replacement or suppressive therapy (eg, levothyroxine, triiodothyronine) may need adjustments while patient is taking estrogens because the latter increases the sex hormone-binding globulin (SHBG), especially when administered orally, thus leaving less free T4 (active hormone) available Tobacco smoking can have antiestrogenic effect by increasing C-2 hydroxylation of estradiol molecule |
| Pregnancy | X - Contraindicated; benefit does not outweigh risk |
| Precautions | Reported endometrial cancer risk among unopposed estrogen users is approximately 2- to 12-fold greater than in nonusers and appears dependent on duration of treatment and dose; greatest risk appears associated with prolonged use (increased risks of 15- to 24-fold for 5-10 y or longer); concurrent progestin therapy may offset risk but overall health impact in premenopausal women is not known Some studies suggest possible increased incidence of breast cancer in women taking estrogen therapy at higher doses or for prolonged periods; studies focused on postmenopausal women, and conclusions may not be applicable to young women with ovarian failure; good counseling should help young women deficient in estrogen feel comfortable taking estrogens During pregnancy, is associated with increased risk of fetal congenital reproductive tract disorders and, possibly, other birth defects Two studies report 2- to 4-fold increase in risk of gallbladder disease requiring surgery in women receiving oral estrogen replacement therapy, similar to 2-fold increase previously noted in users of oral contraceptives; risk from transdermal estrogens not established Occasional blood pressure increases attributed to idiosyncratic reactions; other studies show slightly lower blood pressure among estrogen users compared to nonusers; postmenopausal estrogen use does not increase risk of stroke, but blood pressure should be monitored at regular intervals Administration may lead to severe hypercalcemia in patients with breast cancer and bone metastases; if hypercalcemia occurs, discontinue use and take appropriate measures to reduce serum calcium level Addition of a progestin to estrogens may cause adverse effects (eg, adverse effects on lipoprotein metabolism [lowering HDL and raising LDL]) that could diminish cardioprotective effect May cause adverse changes in lipoprotein metabolism compared to natural progesterone; careful assessment of each patient's cardiovascular risk factors, combined with a lipid profile, is recommended before initiating long-term hormone replacement therapy Impaired glucose tolerance seen Possible enhancement of mitotic activity in breast epithelial tissue, but epidemiological data are lacking Complete medical and family histories should be taken before initiating therapy; should be prescribed for no longer than 1 year without another physical examination being performed Studies have shown that women taking estrogen replacement therapy have hypercoagulability, primarily related to decreased antithrombin activity; effect appears dose- and duration-dependent and is less pronounced than that associated with oral contraceptive use; information on hypercoagulability in women who have had previous thromboembolic disease is insufficient Estrogen therapy may be associated with massive elevations of plasma triglycerides, leading to pancreatitis and other complications in patients with familial defects of lipoprotein metabolism Careful observation is required when conditions that might be influenced by fluid retention, resulting from estrogen use, are present (eg, asthma, epilepsy, migraine, cardiac or renal dysfunction) Certain patients may develop undesirable manifestations of estrogenic stimulation (eg, abnormal uterine bleeding, mastodynia) May be poorly metabolized in patients with impaired liver function, administer with caution Drug/lab test interactions include accelerated prothrombin time, partial thromboplastin time, and platelet aggregation time; increased platelet count; increased factors II, VII antigen, VIII antigen, VIII coagulant activity, IX, X, XII, VII-X complex, and beta-thromboglobulin; decreased levels of antifactor Xa and antithrombin III, decreased antithrombin III activity; increased levels of fibrinogen and fibrinogen activity; increased plasminogen antigen and activity Increased thyroid-binding globulin (TBG) leading to increased circulating total thyroid hormone, as measured by protein-bound iodine (PBI), T4 levels (by column or by radioimmunoassay) or T3 levels by radioimmunoassay; free T4 and free T3 concentrations are unaltered Other binding proteins may be elevated in serum, ie, corticosteroid-binding globulin (CBG), SHBG, leading to increased circulating corticosteroids and sex steroids, respectively; free or biologically active hormone concentrations are unchanged Other plasma proteins may be increased (eg, angiotensinogen/renin substrate, alpha1 antitrypsin, ceruloplasmin) Increased plasma HDL and HDL-2 subfraction concentrations, reduced LDL cholesterol concentration, increased triglyceride levels Reduced response to metapyrone test may be seen; reduced serum folate concentration Long-term continuous administration of natural and synthetic estrogens in certain animal species increases frequency of carcinomas of breast, uterus, cervix, vagina, testis, and liver Administration of any drug to women who are breastfeeding should occur only when clearly necessary because many drugs are excreted in human milk; additionally, shown to decrease quantity and quality of milk |
For further reading, see Medscape's Ob/Gyn and Women's Health.
The authors and editors of eMedicine gratefully acknowledge the contributions of previous authors, Vladimir Bakalov, MD and Carmen Pastor, MD, to the development and writing of this article.
Article Last Updated: Jan 15, 2008
