Polycystic ovary syndrome

Polycystic ovary syndrome (PCOS) is one of the most common female endocrine disorders. It is a genetic disorder that can be inherited from either parent.
PCOS produces symptoms in approximately 5% to 10% of women of reproductive age (12–45 years old) and is thought to be one of the leading causes of female subfertility.^[1][2][3]
The principal features are anovulation, resulting in irregular menstruation, amenorrhea, ovulation-related infertility, and polycystic ovaries; excessive amounts or effects of androgenic (masculinizing) hormones, resulting in acne and hirsutism; and insulin resistance, often associated with obesity, Type 2 diabetes, and high cholesterol levels. The symptoms and severity of the syndrome vary greatly among affected women.

Names

Other names for this syndrome include polycystic ovary disease, functional ovarian hyperandrogenism, Stein-Leventhal syndrome (original name, not used in modern literature), ovarian hyperthecosis and sclerocystic ovary syndrome.
The common names derive from a typical finding on medical images, called a polycystic ovary. A polycystic ovary has an abnormally large number developing eggs visible near its surface, looking like many small cysts or a string of pearls.

Definition

Two definitions are commonly used:

NIH

In 1990 a consensus workshop sponsored by the NIH/NICHD suggested that a patient has PCOS if she has ALL of the following:

1. oligoovulation
2. signs of androgen excess (clinical or biochemical)
3. other entities are excluded that would cause polycystic ovaries

Rotterdam

In 2003 a consensus workshop sponsored by ESHRE/ASRM in Rotterdam indicated PCOS to be present if any 2 out of 3 criteria are met^[4]

1. oligoovulation and/or anovulation
2. excess androgen activity
3. polycystic ovaries (by gynecologic ultrasound)

The Rotterdam definition is wider, including many more patients, notably patients without androgen excess and with other conditions that might cause polycystic ovaries. Critics say that findings obtained from the study of patients with androgen excess cannot necessarily be extrapolated to patients without androgen excess.^[5][6]
The prevalence of PCOS depends on the choice of diagnostic criteria. One community-based prevalence study using the Rotterdam criteria found that about 18% of women had PCOS, and that 70% of them were previously undiagnosed.^[7]

Signs and symptoms

Common symptoms of PCOS include

• Menstrual disorders: mostly oligomenorrhea (few menstrual periods) or amenorrhea (no menstrual periods), but other types of menstrual disorders may also occur.
• Infertility: generally resulting from chronic anovulation (lack of ovulation).
• High levels of masculinizing hormones: mostly acne and hirsutism (excess hair), but may produce hypermenorrhea (very frequent menstrual periods) or other symptoms.^[8] Approximately three-quarters of patients with PCOS (by the diagnostic criteria of NIH/NICHD 1990) have evidence of hyperandrogenemia.^[9]
• Metabolic syndrome: This appears as a tendency towards central obesity and other symptoms associated with insulin resistance. Serum insulin, insulin resistance and homocysteine levels are significantly higher in subjects having PCOS.^[10]

Diagnosis

Not all women with PCOS have polycystic ovaries (PCO), nor do all women with ovarian cysts have PCOS; although a pelvic ultrasound is a major diagnostic tool, it is not the only one. The diagnosis is straightforward using the Rotterdam criteria, even when the syndrome is associated with a wide range of symptoms.

Standard diagnostic assessments

• History-taking, specifically for menstrual pattern, obesity, hirsutism, and the absence of breast development. A clinical prediction rule found that these four questions can diagnose PCOS with a sensitivity of 77.1% (95% confidence interval [CI] 62.7%–88.0%) and a specificity of 93.8% (95% CI 82.8%–98.7%).^[11]
• Gynecologic ultrasonography, specifically looking for small ovarian follicles. These are believed to be the result of disturbed ovarian function with failed ovulation, reflected by the infrequent or absent menstruation that is typical of the condition. In a normal menstrual cycle, one egg is released from a dominant follicle - essentially a cyst that bursts to release the egg. After ovulation the follicle remnant is transformed into a progesterone-producing corpus luteum, which shrinks and disappears after approximately 12–14 days. In PCOS, there is a so called "follicular arrest", i.e., several follicles develop to a size of 5–7 mm, but not further. No single follicle reaches the preovulatory size (16 mm or more). According to the Rotterdam criteria, 12 or more small follicles should be seen in an ovary on ultrasound examination. The follicles may be oriented in the periphery, giving the appearance of a 'string of pearls'. The numerous follicles contribute to the increased size of the ovaries, that is, 1.5 to 3 times larger than normal.
• Laparoscopic examination may reveal a thickened, smooth, pearl-white outer surface of the ovary. (This would usually be an incidental finding if laparoscopy were performed for some other reason, as it would not be routine to examine the ovaries in this way to confirm a diagnosis of PCOS).
• Serum (blood) levels of androgens (male hormones), including androstenedione and testosterone may be elevated. Dehydroepiandrosterone sulfate levels above 700mcg/dL are highly suggestive of adrenal dysfunction because DHEA-S is made exclusively by the adrenal glands. ^[12] The free testosterone level is thought to be the best measure,^[13] with ~60% of PCOS patients demonstrating supranormal levels.^[9] The Free androgen index of the ratio of testosterone to sex hormone-binding globulin (SHBG) is high, is meant to be a predictor of free testosterone, but is a poor parameter for this and is no better than testosterone alone as a marker for PCOS,^[14] possibly because FAI is correlated with the degree of obesity.^[15]
• Some other blood tests are suggestive but not diagnostic. The ratio of LH (Luteinizing hormone) to FSH (Follicle stimulating hormone) is greater than 1:1, as tested on Day 3 of the menstrual cycle. The pattern is not very specific and was present in less than 50% in one study.^[16] There are often low levels of sex hormone binding globulin, particularly among obese or overweight women.

Common assessments for associated conditions or risks

• Fasting biochemical screen and lipid profile
• 2-hour oral glucose tolerance test (GTT) in patients with risk factors (obesity, family history, history of gestational diabetes) and may indicate impaired glucose tolerance (insulin resistance) in 15-30% of women with PCOS. Frank diabetes can be seen in 65–68% of women with this condition. Insulin resistance can be observed in both normal weight and overweight patients.

• Fasting insulin level or GTT with insulin levels (also called IGTT). Elevated insulin levels have been helpful to predict response to medication and may indicate women who will need higher dosages of metformin or the use of a second medication to significantly lower insulin levels. Elevated blood sugar and insulin values do not predict who responds to an insulin-lowering medication, low-glycemic diet, and exercise. Many women with normal levels may benefit from combination therapy. A hypoglycemic response in which the two-hour insulin level is higher and the blood sugar lower than fasting is consistent with insulin resistance. A mathematical derivation known as the HOMAI, calculated from the fasting values in glucose and insulin concentrations, allows a direct and moderately accurate measure of insulin sensitivity (glucose-level x insulin-level/22.5).
• Glucose tolerance testing (GTT) instead of fasting glucose can increase diagnosis of increased glucose tolerance and frank diabetes among patients with PCOS according to a prospective controlled trial.^[17] While fasting glucose levels may remain within normal limits, oral glucose tests revealed that up to 38% of asymptomatic women with PCOS (versus 8.5% in the general population) actually had impaired glucose tolerance, 7.5% of those with frank diabetes according to ADA guidelines.^[17]

Differential diagnosis

Other causes of irregular or absent menstruation and hirsutism, such as hypothyroidism, congenital adrenal hyperplasia (21-hydroxylase deficiency), Cushing's syndrome, hyperprolactinemia, androgen secreting neoplasms, and other pituitary or adrenal disorders, should be investigated. PCOS has been reported in other insulin-resistant situations such as acromegaly.

Cause

PCOS is a common inherited genetic condition. It is inherited in an autosomal dominant system with high genetic penetrance in females, meaning that each child has a 50% chance of inheriting the gene from a parent who carries the gene, and if a daughter receives the gene, then the daughter will have the disease to some extent.^[18] The gene can be inherited from either the father or the mother, and can be passed along to both sons, who are asymptomatic carriers, and daughters, who will show signs of PCOS.^[18] The exact gene that is affected has not yet been identified.^[19]

Pathogenesis

Polycystic ovaries develop when the ovaries are stimulated to produce excessive amounts of male hormones (androgens), particularly testosterone, either through 1)the release of excessive luteinizing hormone (LH) by the anterior pituitary gland, 2) through high levels of insulin in the blood (hyperinsulinaemia) in women whose ovaries are sensitive to this stimulus or 3) reduced levels of sex-hormone binding globulin resulting in increased free androgens.
The syndrome acquired its most widely used name due to the common sign on ultrasound examination of multiple (poly) ovarian cysts. These "cysts" are actually immature follicles, not cysts ("polyfollicular ovary syndrome" would have been a more accurate name). The follicles have developed from primordial follicles, but the development has stopped ("arrested") at an early antral stage due to the disturbed ovarian function. The follicles may be oriented along the ovarian periphery, appearing as a 'string of pearls' on ultrasound examination.
A majority of patients with PCOS have insulin resistance and/or are obese. Their elevated insulin levels contribute to or cause the abnormalities seen in the hypothalamic-pituitary-ovarian axis that lead to PCOS.
PCOS is characterized by a complex set of symptoms, and the cause cannot be determined for all patients. In many cases it is characterised by a complex positive feedback loop of insulin resistance and hyperandrogenism. In most cases it can not be determined which (if any) of those two should be regarded causative. Experimental treatment with either antiandrogens or insulin sensitizing agents improves both hyperandrogenism and insulin resistance. PCOS is also likely to have a genetic predisposition, and further research into this possibility is taking place. A few specific genetic defects are known accounting only for a small fraction of cases, the rest may be due to the combination of several factors.
Adipose tissue possesses aromatase, an enzyme that converts androstenedione to estrone and testosterone to estradiol. The excess of adipose tissue in obese patients creates the paradox of having both excess androgens (which are responsible for hirsutism and virilization) and estrogens (which inhibits FSH via negative feedback).^[20]
Hyperinsulinemia increases GnRH pulse frequency, LH over FSH dominance, increased ovarian androgen production, decreased follicular maturation, and decreased SHBG binding; all these steps contribute to the development of PCOS. Insulin resistance is a common finding among patients of normal weight as well as those overweight patients.
PCOS may be associated with chronic inflammation, with several investigators correlating inflammatory mediators with anovulation and other PCOS symptoms.^[21][22]
One study in the United Kingdom concluded that the risk of PCOS development was shown to be higher in lesbian women than in heterosexuals.^[23][24] It should be noted however that all the participants in this study were referred after infertility was discovered or highly suspected and conclusion made is purely conjecture. Until further studies have been conducted and the research collaborated there is no assumption that female homosexuality will increase the occurrence of PCOS.
It has previously been suggested that the excessive androgen production in PCOS could be caused by a decreased serum level of IGFBP-1, in turn increasing the level of free IGF-I which stimulates ovarian androgen production., but recent data concludes this mechanism to be unlikely.^[25]
PCOS has also been associated with a specific FMR1 sub-genotype. The research suggests that women who have heterozygous-normal/low FMR1 have polycystic-like symptoms of excessive follicle-activity and hyperactive ovarian function.^[26][27]

Management

Medical treatment of PCOS is tailored to the patient's goals. Broadly, these may be considered under four categories:

• Lowering of insulin levels
• Restoration of fertility
• Treatment of hirsutism or acne
• Restoration of regular menstruation, and prevention of endometrial hyperplasia and endometrial cancer

In each of these areas, there is considerable debate as to the optimal treatment. One of the major reasons for this is the lack of large scale clinical trials comparing different treatments. Smaller trials tend to be less reliable and hence may produce conflicting results.
General interventions that help to reduce weight or insulin resistance can be beneficial for all these aims, because they address what is believed to be the underlying cause.