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This chapter should be cited as follows:
Schickedanz, A, Kalro, B, et al, Glob. libr. women's med.,
(ISSN: 1756-2228) 2008; DOI 10.3843/GLOWM.10297
This chapter was last updated:
November 2008

Bleeding Problems in Midlife



Abnormal uterine bleeding (AUB) is one of the most common presenting complaints encountered in a gynecologist’s office or primary care setting. An estimated 60% of visits to a physician’s office are from women seeking treatment for menstrual problems. Unpredictable and unscheduled bleeding often lead to psychological, medical, and sexual problems requiring pharmacologic and surgical interventions. Hysterectomy is the second most common surgery performed in the United States, with 500,000–600,000 hysterectomies performed per annum at a cost of over $ 2 billion.1 Forty percent of women over the age of 55 years have undergone a hysterectomy,2 about 22% having been performed for AUB.3 The intent of this chapter is to review the etiology, evaluation, diagnosis, and medical and surgical management of AUB in women during midlife.

Dysfunctional uterine bleeding (DUB) is defined as AUB with no demonstrable organic genital or extragenital cause. More than 50% of hysterectomies performed for excessive blood loss have no abnormal pathologic evaluation.4  The diagnosis of DUB is often one of exclusion, and it is common at extremes of reproductive life when anovulatory cycles and luteal insufficiency are more prevalent.

The causes for AUB are listed in Table 1. AUB can be associated with ovulatory and anovulatory cycles. Bleeding disorders associated with ovulatory cycles include heavy or prolonged bleeding and intermenstrual bleeding, whereas women with the anovulatory cycles often experience irregular, unpredictable, and variable amounts of bleeding. Luteal phase insufficiency may manifest as shorter intervals between cycles. In addition, there are iatrogenic causes, structural lesions, systemic diseases, and endocrinopathies that may lead to AUB.


Table 1. Differential diagnosis of abnormal uterine bleeding

Reproductive Tract



Polyps (cervical or endometrial)


Infection (pelvic inflammatory disease, endometritis, tuberculus endometritis)



Foreign Body


Spontaneous abortion

Gestational trophoblastic disease

Ectopic pregnancy



Oral contraceptives

Intrauterine device



Hormone replacement therapy

Psychotropic agents


Hypothyroidism and hyperthyroidism


Functional hypothalamic amenorrhea

Chronic illness

Eating disorders


Excessive exercise

Congenital adrenal hyperplasia

Polycystic ovarian syndrome


Premature ovarian failure/premature menopause


Systemic Disease

Liver disease

Coagulation disorders

Renal failure




Abnormal uterine bleeding includes a spectrum of bleeding disorders including menorrhagia (heavy or prolonged periods), metrorrhagia (irregular periods at frequent intervals), menometrorrhagia (heavy or prolonged periods occurring at irregular intervals), polymenorrhea (regular periods at frequent intervals) oligomenorrhea (infrequent periods), amenorrhea (absent menstrual periods), intermenstrual bleeding (bleeding between periods), and postcoital bleeding (bleeding after intercourse).5 Disorders that cause abnormal uterine bleeding can present anywhere along the spectrum.   

Menorrhagia, or hypermenorrhea, is defined as excessive menstrual bleeding and is usually associated with ovulatory cycles. The prevalence of menorrhagia in the general population is approximately 9–11%. About 5% of women between ages 30 and 49 years consult their general practitioners, and 12% of referrals to the gynecologist are for menorrhagia.6 For diagnostic purposes, menorrhagia is defined as objective blood loss exceeding 80 mL/cycle7 or menses lasting longer than seven days, although the term is often used more generally to describe excessive bleeding as perceived by the patient. Quantifying the amount of menstrual loss objectively is impractical and unnecessary.7, 8, 9 Typically, one has to rely on the patient’s subjective complaint and proceed with evaluation. Subjective assessment of bleeding by patients is often inaccurate. Reported pad counts may markedly differ between patients.4 In addition, fluid loss may not accurately reflect blood loss, as cervical and vaginal secretions may make up a large proportion of menstrual fluid.10 It has been estimated by spectrophotometric methods that the average loss during a menstrual period is approximately 40 mL. Several laboratory techniques have been described attempting to quantify blood loss, but it is a cumbersome and time-consuming process.11, 12, 13, 14 Blood loss in excess of 80 mL/cycle significantly increases a woman’s risk for iron deficiency anemia.

Many of the disorders causing menorrhagia may also present with metrorrhagia or a combination of heavy and frequent irregular periods (menometrorrhagia). In addition, intermenstrual bleeding (IMB) is commonly associated with the use of combined oral contraceptive pills (COCs). This type of breakthrough bleeding (BTB) often occurs during the first few months of use and usually resolves thereafter. Both continuous and cyclic regimens of COC administration have been associated with BTB. Causes include missed pills, drug interactions with anticonvulsants, rifampicin, and certain antibiotics, but BTB most commonly results from an imbalance between the estrogen and progestin that makes the endometrial lining unstable or fragile. Therefore, changing the formulation to a higher or lower dose of estrogen or a different progestin may be required to resolve the BTB. It is also important to counsel patients to take their pills daily and at approximately the same time everyday so as to not trigger “withdrawal bleeding.” IMB may be a manifestation of endometritis and may also result from structural lesions such as endometrial polyps or submucosal fibroids. Postcoital bleeding usually indicates cervical or vaginal lesions that may be either benign or malignant. Causes include cervical ectopy and polyps, cervicitis, cervical malignancy, vaginal lacerations, postmenopausal atrophic vaginitis, and vaginal neoplasms.


Fibroids, also known as leiomyomas, are a common incidental finding. They may be identified in up to 20–30% of women during their reproductive years,15 and their peak incidence is in the early perimenopause at approximately age 44 years.16 They are composed of fibrous connective tissue and smooth muscle and are classified according to their location. They may be within the myometrium (intramural), may be within the endometrial cavity (submucosal), or may protrude into the abdominal cavity (subserosal); a single fibroid often extends into more than one location. Ninety-five percent of fibroids are intramural or subserosal; fewer than 5% are submucosal or cervical in location.17 African-American women have a threefold to ninefold greater incidence of these tumors than do Caucasians.15 In a study evaluating 1.7 million hysterectomies performed for reasons other than fibroids, more than a third of the uteri contained fibroids.17 About a third of all hysterectomies performed in the United States are for symptoms resulting from leiomyomas.18 AUB is the most common symptom associated with fibroids, but their discovery during evaluation may also be incidental. Usually, larger fibroids that cause overall uterine enlargement, or submucosal fibroids that encroach on or lie in close proximity to the endometrial cavity, are more likely to be associated with excessive or irregular bleeding. Fibroids are hormone-dependent and tend to regress, with or without calcification, during the menopausal years as estrogen levels decline. With increasing use of hormone replacement therapy (HRT), fibroids tend not to regress and can cause AUB patterns in postmenopausal women. Individuals from certain ethnic backgrounds and families exhibit a genetic predisposition to fibroid formation.19


Adenomyosis is defined by the presence of endometrial glands and stroma surrounded by reactive and hypertrophic myometrium.20 Most cases of adenomyosis are diagnosed between 40 and 50 years of age, but true prevalence is difficult to establish due to wide variations in diagnosis by pathologists. The most frequent symptom associated with adenomyosis is menorrhagia.20 Metrorrhagia can also be seen in up to 20% of patients.20 The etiology of abnormal uterine bleeding in these patients is not well understood. Possible mechanisms include impaired contractility and compression as well as dysfunction of prostaglandins.20 In addition to the association of abnormal uterine bleeding and adenomyosis, there is also a high prevalence of associated pathology within the uterus. Up to 80% of adenomyotic uteri contain fibroids, polyps, hyperplasia, or cancer.20

Endometrial Polyps

Polyps of the endometrium are a notorious and common cause of irregular bleeding in both perimenopausal and menopausal women. The etiology of polyps is poorly understood, but hormones, particularly unopposed estrogen exposure and tamoxifen treatment, may play a role in their pathogenesis. Interestingly, but not surprisingly, obese women have been reported to have a higher incidence of polyps, perhaps secondary to a relatively hyperestrogenic milieu that results from peripheral aromatization of androgens to estrogens in adipose tissues or from increased insulin. Polyps in middle-aged women tend to be benign, but they should not be ignored in the presence of symptoms. Two morphologic types of endometrial polyps have been identified in the reproductive age group. The hyperplastic type arises from the basal layer and is dependent on estrogens but not progestogens for stimulation. The second type of polyp consists of a glandular component that responds to cyclic hormonal changes, and its morphology resembles that of the surrounding endometrium. Late menopause, owing to longer duration of exposure to estrogens, has been implicated as a risk factor for development of endometrial polyps. The majority of polyps in the postmenopausal years are atrophic with fibrotic transformation of the stroma that may explain incomplete removal by curettage and offer one explanation for their persistence or recurrence in such women.21 It is likely that with increasing use of HRT, the incidence of endometrial polyps will rise. Menorrhagia may occur in approximately 12% of women with endometrial polyps;22 the mechanism responsible is unknown. Reslova and colleagues studied a cohort of 245 pre- and postmenopausal women with endometrial polyps and observed AUB in 44% of postmenopausal and 82% of premenopausal women;21 8% were taking tamoxifen as treatment for breast cancer.

Anovulatory Bleeding

Bleeding problems associated with anovulatory cycles are often encountered at the extremes of reproductive life, during the perimenarchial and perimenopausal years. The character, amount, and duration of bleeding are typically unpredictable. This type of bleeding pattern results from a disordered endometrium as a consequence of anovulation and unopposed estrogen effects, and absence of the stabilizing influence of progesterone. Anovulatory bleeding increases the risk of endometrial hyperplasia, particularly in perimenopausal women, owing to the relative increase in ovarian estrogen production and relative decrease in progesterone production characteristic of the aging ovary.

Numerous endocrine dysfunctions can cause abnormal uterine bleeding as a result of anovulation. Polycystic ovary syndrome, hyperprolactinemia, hyperthyroidism and hypothyroidism, uncontrolled diabetes, Cushing’s syndrome, growth hormone excess, adrenal hyperplasia, and rarely, androgen-secreting tumors of the ovary and adrenal gland, can be associated with anovulatory menstrual cycles. Medications associated with anovulation include the progesterone only pill (the “mini-pill”), major tranquilizers, tricyclic antidepressants, and heroin use, although the latter is more often associated with amenorrhea.23 Systemic illnesses such as liver and renal disease may also suppress central rhythms of gonadotropin-releasing hormone (GnRH) secretion and result in disorganized patterns of follicle-stimulating hormone (FSH) or luteinizing hormone (LH) release and ovarian stimulation, or adversely affect estrogen metabolism with the end result of luteal phase deficiency or anovulation, although at this stage they are usually fairly advanced. Women with chronic renal failure have low estrogen levels and are often amenorrheic secondary to uremia. Menses often resume following dialysis and improvement of uremia. Vigorous exercise regimens, eating disorders, obesity, and stressful life events or lifestyle with secondary disruption of the hypothalamic-pituitary-ovarian axis, can also be associated with anovulation.

Tamoxifen-Induced Endometrial Effects

Tamoxifen, a selective estrogen receptor modulator, is a triphenylethylene derivative that has been used to treat women with breast cancer for over 25 years. It appears to be well tolerated with few adverse effects. However, its prolonged use has been associated with significant uterine abnormalities, both benign and malignant. Tamoxifen was initially thought to possess antiestrogenic properties exclusively, but observations in postmenopausal women have revealed that it exerts estrogen-like effects on genital tract tissues and the endometrium.24, 25, 26, 27 Although the majority of information available derives primarily from experience with tamoxifen use in postmenopausal women, increasing information now relates to the effects of tamoxifen in premenopausal women. Tamoxifen-related effects on the endometrium affect large numbers of women. The magnitude of this affect is likely to increase as indications for tamoxifen extend to healthy high-risk women.28

The endometrial effects of tamoxifen are largely proliferative and vary from benign polyps29, 30, 31, 32, 33, 34 and hyperplasia to frank endometrial malignancy.32, 33, 34, 35, 36 These effects appear to be more pronounced in postmenopausal women than in premenopausal women.29, 30Tamoxifen-treated endometrium is difficult to biopsy with poor tissue yield despite ultrasound and hysteroscopic evidence of thickened and abnormal endometrium.37 Microscopic examination reveals tamoxifen-induced diffuse endometrial thickening with dilated cystic glands of endometrial origin.38 Focally, the glandular epithelium displays mitotic activity with mucinous, clear cell, oxyphilic, and other epithelial metaplasias often noted. The endometrial stroma is characteristically fibrotic with occasional stromal mitosis, structural characteristics that might explain the difficulty that may be encountered when attempting to obtain a satisfactory biopsy specimen.38, 39, 40

Postmenopausal women on tamoxifen are seven times more likely to develop endometrial polyps than those not taking tamoxifen.31, 33 Tamoxifen-induced polyps have distinct macroscopic and microscopic features with background endometrial hyperplasia.38, 41, 42 Polyps may undergo ulceration, infarction, and occasional myxoid change and may be mistaken for malignancy. The prevalence of endometrial cancer in tamoxifen-induced endometrial polyps is significantly higher than in polyps that develop in women not exposed to the drug.38, 41, 43

It is now well established that tamoxifen use is associated with increased risk of endometrial cancers, including rare invasive varieties such as uterine leiomyosarcoma, endometrial stromal sarcoma, and malignant mixed müllerian tumor.44, 45, 46, 47 The pathologic features of tamoxifen-induced endometrial cancer are not well understood. Whereas some studies have suggested they are most likely to be high-grade endometrioid adenocarcinomas or histologic subtypes associated with a poor prognosis,34, 48, 49 others have concluded that the majority of tamoxifen-induced endometrial cancers are well differentiated and less aggressive than those that develop in women not exposed to the drug.46, 50, 51

Raloxifene, a similar selective estrogen receptor modulator, is currently indicated in the prevention and treatment of osteoporosis. Studies have also shown a decrease in breast cancer due to its similar antagonistic affects on breast tissue. In contrast to tamoxifen, raloxifene has purely antagonistic affects on the endometrium. It has not been shown to increase endometrial thickness or cause endometrial proliferation in healthy postmenopausal women.52


Perimenopause is the time interval between declining ovarian function and the complete cessation of ovarian function. The age of onset and duration of this transition varies greatly and is unpredictable. As defined by the World Health Organization, the early perimenopause is marked by the onset of a break in regular menstrual cyclicity in a previously normally cycling woman who experiences no more than 3 months of amenorrhea. In the late perimenopause, women often experience amenorrhea for 3–11 months. Amenorrhea lasting 12 months or longer is classically defined as menopause. The perimenopausal transition can begin as early as 10 years prior to menopause. Fewer than 10% of women experience abrupt cessation of menses prior to the menopause without prior irregularity of menstrual cycles.53 Menstrual changes appear to be the most common symptom of the perimenopause, with 90% of women experiencing more frequent or less frequent periods, missed periods, or a variation in menstrual flow. Often, in the early perimenopause, there is shortening of the follicular phase with little change in luteal phase duration, resulting in shorter cycles spanning 21–24 days. However, ovulation still occurs and pregnancy is therefore possible. Contraception is often overlooked in this age group, with a significant number of unintended pregnancies being the consequence. Once oligo-ovulation sets in, menstrual cycle length typically increases and FSH levels increase progressively. Ovarian aging is associated with declining sensitivity and responsiveness to FSH and LH, with resultant perturbations in estrogen levels and anovulatory cycles. Estrogen levels are typically higher than in ovulatory cycles and exhibit wide fluctuations, with concentrations ranging from as high as 700 pg/mL to as low as 20 pg/mL heralding the waxing and waning ovarian function. Endometrial stimulation from unopposed fluctuating estrogen exposure results in a vascular and friable endometrium that bleeds intermittently and sloughs at unpredictable intervals.

Intrauterine and ectopic pregnancy are important considerations in formulating the differential diagnosis in a perimenopausal woman who presents with an AUB pattern. Idiopathic hyperprolactinemia was frequently observed in one study of premenopausal women presenting with bleeding problems. The role of prolactin per se in inducing AUB in such women is not clear, but it was an interesting observation worthy of note.54 Women in the study were not screened for thyroid disease; hypothyroidism is fairly common in this age group, and elevated thyroid-stimulating hormone (TSH) levels often result in mild elevations in serum prolactin concentrations.


Ovarian follicular depletion and the concomitant decline in ovarian estradiol production results in menopause. In developed nations, the average age of menopause is approximately 51 years. The increasing use of HRT in menopausal women for relief of vasomotor symptoms in the short term, and for potential long-term benefits on bone and the brain, has led to the increased incidence of bleeding problems in this age group. Typically, a cyclic regimen of progestational agents with continuous estrogen replacement induces regular withdrawal bleeding at the end of progestin/progesterone exposure and continuous combined estrogen/progestin treatment regimens result in amenorrhea. Most women prefer not to continue experiencing cyclic bleeding indefinitely, and opt for the latter.

New-onset or persistent bleeding patterns that differ from the expected pattern, whether on or off HRT, warrant evaluation to exclude endometrial pathology. AUB patterns are common in the initial months of HRT use with both cyclic and combined continuous treatment regimens. Prolonged unopposed estrogen use in women with intact uteri significantly increases the risk of endometrial hyperplasia, a precursor of endometrial cancer,55 necessitating regular endometrial surveillance. Inadequate progestogen exposure in cyclic treatment regimens could also increase the risk of hyperplasia. Awareness of bleeding patterns on HRT is therefore critical and avoids both excessive and inadequate evaluation.

Lesions such as endometrial polyps and fibroids, in particular submucosal fibroids, can pose a problem in menopausal women on HRT. Townsend and coworkers56 evaluated a series of postmenopausal women with persistent bleeding problems on or off HRT, and found that 90% had either polyps or submucous fibroids.

Thyroid Disorders

Thyroid disease is more common in women in their midlife years and 2–5% of women exhibit clinical disease. Thyroid antibodies are present in about 5% of women. The American College of Physicians recommends that all women over age 50 years be screened for thyroid disorders every 2– 5years by obtaining a baseline TSH. Subclinical or frank hypothyroidism can present with easy bruising and metrorrhagia or menorrhagia57, 58, 59 that usually resolves with thyroid replacement therapy within 3–6 months.60 Hypothyroidism has protean clinical manifestations, one of which is a von Willebrand–like bleeding disorder.61 Also, hypothyroidism alters steroid metabolism and clearance, making endometrial dysfunction more likely.62 Menorrhagia is considered an early manifestation of hypothyroidism and generally responds to thyroxine replacement.  In a cohort study of 171 hypothyroid patients, 76.6% had regular cycles and 23.4% had irregular periods (most commonly oligomenorrhea and menorrhagia). In controls, only 8.4% had irregular cycles. This study demonstrated that hypothyroidism may be less frequently associated with menstrual disturbance than previously described, but still shows significantly increased AUB than seen in euthyroid women. 63

Endometrial Malignancy

Endometrial cancer is the most common gynecologic malignancy in women in the United States. Risk factors include obesity, nulliparity, late menopause, tamoxifen use, diabetes (more so with inadequate glycemic control), and unopposed estrogen exposure. The average age for adenocarcinoma appears to be the 6th decade, but about 20–25% of endometrial cancers are diagnosed before menopause.64 AUB is often the initial presenting symptom. Endometrial evaluation should therefore be considered, particularly in women with anovulatory menstrual cycles. Women with hyperplasia without cytologic atypia are at low risk for endometrial cancer. In contrast, women with hyperplasia and atypia have a 23% likelihood of developing endometrial cancer in the next decade.65

Fallopian tube malignancies are rare, but can present as abnormal vaginal bleeding during the 5th and 6th decades.66, 67 Many other cancers of the genital tract may present with abnormal bleeding. Although extremely rare, leiomyosarcoma, malignant melanoma of the vagina, primary cervical lymphoma, malignant mixed mullerian tumor of the cervix, placental site trophoblastic tumor, and primary primitive neuroectodermal tumor of the uterus have all presented with AUB.

Inherited Bleeding Diathesis

The hemostatic mechanisms that control menstrual bleeding are complex and involve constriction of endometrial arterioles and/or myometrial arteries and the formation of platelet and fibrin hemostatic plugs within endometrial vessels. Therefore, any process that disrupts either mechanism can result in menorrhagia.68, 69, 70, 71 Other factors such as tissue regeneration, prostaglandins (PGs), inflammation, and myometrial contractility also influence the amount of blood loss. Coagulopathies are generally uncommon, but may occasionally manifest as menorrhagia, usually at menarche.

In a cohort study of 115 women with menorrhagia, 47% of women were found to have hemostatic abnormalities including platelet dysfunction, von Willebrand's disease, and coagulation factor deficiencies. Interestingly, adolescents and perimenopausal-age women were equally as likely to have  hemostatic abnormalities.72 This series suggests that all women with an extensive history of menorrhagia should be evaluated for a possible bleeding diathesis. 

In 1926, von Willebrand first described a family with a bleeding disorder in which the index patient died during a menstrual period. Von Willebrand’s disease (vWD), a condition characterized by defective platelet adhesion and factor VIII deficiency, is the most common bleeding disorder and affects approximately 1% of the population. Menorrhagia dating from menarche predicts an inherited bleeding disorder in 65% of women with vWD and in 67% of women with factor XI deficiency.6 In a retrospective survey, a pictorial bleeding assessment chart revealed menorrhagia in 74% of patients with vWD, in 57% of hemophilia A or B carriers, and in 57% of patients with factor XI deficiency, compared with 29% of controls.6 As the concentration of von Willebrand factor (vWF) tends to increase with age, the severity of bleeding disorders decreases as does the prevalence of menorrhagia.73 Menorrhagia can be a valuable predictor of bleeding disorders.74

A family history of excessive menstrual blood loss or other bleeding disorders is often helpful and prompts evaluation. However, milder forms can often go undiagnosed. Apart from the medical implications, menorrhagia can pose a social problem for women in today’s society and can adversely affect their quality of life. Other hematologic causes for AUB include thrombocytopenia, idiopathic or secondary to leukemia, and aplastic anemia.



Important considerations when eliciting a history include age at onset, nature, and duration of AUB pattern, gynecologic and obstetric history, sexual and contraceptive history, use of medications, symptoms suggestive of endocrinopathies, chronic medical illness, coagulopathies, excessive exercise and stress patterns, and eating disorders. A careful family history is also important.

General Examination

General examination for physical evidence of systemic diseases, endocrine disorders, signs of hirsutism or virilization, galactorrhea, and coagulopathies is vital. A pelvic examination is essential to exclude the possibility of infections and to detect an obvious pelvic lesion.

Diagnostic Tests

The diagnostic evaluation of AUB in premenopausal women can be more challenging than in postmenopausal women. Identifying the cause for AUB is essential in planning appropriate treatment. Having excluded bleeding disorders and pregnancy, endocrine abnormalities account for most cases. Other causes include endometritis, endometrial polyps, and submucous fibroids. Evaluation is guided by patient’s age and history. Gonadotropin levels (FSH, LH), sex steroid hormone levels (estrogen, progesterone, and androgens), thyroid function tests, a prolactin level, complete blood count, platelet count, coagulation profile, and pregnancy test are useful initial tests.


Endometrial monitoring can be achieved by various means with varying degrees of invasiveness and risk. Listed in the following sections are methods in current use, including their advantages, risks, and limitations.

Transvaginal Ultrasonography

Transvaginal ultrasonography (TVUS) is a noninvasive and relatively inexpensive method for direct assessment of endometrial thickness and certain anatomic features of the pelvic organs. It does not require a distended bladder, is well tolerated by patients, and has a diagnostic sensitivity of greater than 90% in experienced hands.75, 76 Despite a smaller field of view when compared with transabdominal ultrasound examination, the higher resolution of TVUS permits better tissue characterization.77, 78 The proximity of the vaginal transducer to the pelvic organs allows good definition of endometrial thickness and architecture. The endometrium may be homogeneous or inhomogeneous with localized cystic or other features. An obese body habitus, low level of operator skill, and low signal-to-noise ratio pose limitations on the usefulness of this method. Several studies have documented the usefulness of TVUS as a diagnostic tool prior to proceeding with more invasive procedures such as endometrial biopsy (EMB) and hysteroscopy.79 In postmenopausal women, endometrial thickness and morphology are useful parameters for identifying those who require endometrial tissue sampling.76 As many as 30–40% of dilation and curettage (D&C) procedures performed for evaluation of the endometrium can be avoided by first evaluating the endometrium with TVUS.80, 81

TVUS is slightly less useful in premenopausal women because endometrial thickness and architecture vary widely across the menstrual cycle. These parameters are therefore less reliable indices of pathology, and interpretation is more difficult for the less skilled or experienced operator. In one retrospective study of premenopausal women who underwent an EMB, D&C, or hysterectomy for DUB, ultrasound findings of a thickened endometrium correlated well with pathologic findings of polyps and submucosal fibroids.82

In postmenopausal women, an endometrial thickness of 4–5 mm or less excludes significant endometrial pathology with a positive predictive value of 87.3% and sensitivity of 90%.83, 84, 85, 86 Three-dimensional ultrasonography with Doppler velocimetry appears to be more effective for differentiating certain types of fallopian tube carcinomas from adnexal lesions.87, 88, 89, 90

Adenomyosis causes blurring of endomyometrial interface, subendometrial linear striations, echogenic nodules, asymmetric myometrial thickness, and myometrial cysts on TVUS.91 MRI is considered the most sensitive diagnostic study for adenomyosis especially in patients with associated leiomyomata.91


Introduction of sterile saline solution into the uterine cavity and simultaneous TVUS can clearly identify the size and location of any intracavitary lesion and has proved to be an extremely useful diagnostic technique.92 Sonohysterography (SHG) is being applied in the evaluation of AUB in women with increasing frequency. TVUS can detect a thickened endometrial lining but has limitations in that it cannot, by itself, exclude the presence of an intracavitary lesion such as a polyp or a fibroid within the thickened or asymmetric endometrial “stripe.” A study of asymptomatic postmenopausal women seeking HRT revealed a high incidence of intracavitary pathology as detected by SHG. Intracavitary lesions were more prevalent (63.6%) in those with a thick endometrial stripe on TVUS, but were also noted in 36.8% of those with a normal endometrial thickness.93 The authors concluded that a 5-mm or smaller endometrial stripe on TVUS was useful for excluding endometrial hyperplasia but could not exclude an endometrial polyp.

SHG has proved to be as effective as hysteroscopy and superior to hysterosalpingography (HSG) and TVUS for diagnosis of intrauterine anatomic lesions (see later). In one series, saline solution SHG avoided as many as 50% of hysteroscopies performed.94 In women with endometrial cancer, intraperitoneal spread of endometrial cancer cells following SHG or HSG is a concern but is debatable. In one series, survival rates were similar in patients with endometrial carcinoma who had intraperitoneal spill from a preoperative HSG to those in women who did not.95 The timing of SHG in relation to menstrual flow does not appear to be as important in postmenopausal women as it is in premenopausal women. In menstruating women with predictable cyclicity, mid and late luteal phase SHG has a higher false-positive rate (27%) for detection of structural endometrial lesions than does SHG in the early and mid follicular phase (0%).96 Premenopausal women with AUB have a higher incidence of polyps (33% versus 10%), intracavitary myomas (21% versus 1%), and intramural myomas (58% versus 13%) when compared with asymptomatic age-matched women.97

The addition of 3D views during SHG increases sensitivity of SHG alone. Recently, 3D hysterosonography (3-DHS) has been compared to diagnostic hysteroscopy in women with abnormal uterine bleeding. In this study, 242 women with abnormal uterine bleeding underwent 3-D hysterosonography and hysteroscopy. The sensitivity and specificity of 3D hysterosonography was 93.5% and 99.4%, respectively, with a positive predictive value of 98.6% and a negative predictive value of 97%. In comparison, the sensitivity and specificity of hysteroscopy was 98.7% and 99.4%, respectively, with a PPV of 98.7% and a NPV of 99.4%.98


HSG is another technique used to evaluate the uterine cavity, but it is now used less frequently for this purpose. Although it remains the gold standard for evaluating fallopian tube patency, other methods have gained popularity over HSG for the evaluation of the uterine cavity. Studies comparing HSG with SHG and hysteroscopy have documented that the latter two techniques yield more information than does HSG.99, 100, 101


Although the technique of visualizing the uterine cavity was introduced over a century ago, hysteroscopy has gained popularity only over the last two decades. The first hysteroscopy was performed in 1869, when Pantaleoni attempted to visualize the uterine cavity with a lead pipe and candle.102 Improvement in optics, video monitoring systems, distention media, and smaller telescope size have made hysteroscopy a safe, popular, and acceptable method of directly visualizing and assessing the uterine cavity. AUB appears to be the most common indication for a diagnostic hysteroscopy.103 However, only 28% of gynecologists perform office hysteroscopies.104 Most diagnostic hysteroscopies are performed with the patient under anesthesia, increasing the patient’s risk from anesthesia and at an increased cost. Widrich and associates performed outpatient office hysteroscopies on pre- and postmenopausal women without anesthesia; their findings correlated well with those from SHG performed immediately before, and procedures were generally well tolerated.105

Hysteroscopy is best performed immediately after a menstrual period in the early proliferative phase for optimal visualization of the endometrial surface and any lesions that may be present. Light anesthesia is required and paracervical block with a local anesthetic and vasopressin provides both vasoconstriction during the procedure and postoperative pain relief. Complications are rare in experienced hands, but include infection, bleeding, and risk of uterine perforation. Advantages include direct visualization of the endometrium and endocervix, detection of minute focal lesions, and the ability to perform directed biopsies. In women with AUB, Loffer showed that hysteroscopy alone had better diagnostic accuracy than a routine D&C and that, when the two were combined, diagnostic specificity was 100%.106 The majority of lesions that escape detection by a routine D&C are endometrial polyps and submucous fibroids.107

Even in experienced hands, false-positive identification of endometrial pathology during hysteroscopy can be as high as 20%. An EMB at the time of a hysteroscopy increases the diagnostic accuracy to 100% for diagnosis of endometrial neoplasia and its precursors.108 Although hysteroscopy appears superior to HSG, TVUS, and endometrial sampling for diagnosis of uterine intracavitary lesions,109 it is invasive, more expensive, usually requires anesthesia, and carries risks. Hysteroscopy should therefore not be the initial choice for evaluation, but should be reserved for those patients whose initial workup does not establish a diagnosis and those who require further evaluation with D&C.

Endometrial Sampling

In the early 1900s, EMB became an accepted gynecologic office procedure and was performed in certain instances without anesthesia. It is now a safe, quick, convenient, well-tolerated, and inexpensive diagnostic office procedure often employed to evaluate the endometrium in women with AUB. Relative contraindications to this procedure include profuse bleeding and coagulopathy. Various sampling devices have been described and compared over the years. The Pipelle aspiration canula is a safe, rapid, and inexpensive method of obtaining endometrial tissue for evaluation.110 Several studies have compared the efficacy of the Pipelle sampler with the Novak biopsy instrument, Vabra aspirator, and D&C.111, 112, 113, 114 An adequate endometrial tissue specimen was obtained with the Pipelle in 85–95% of premenopausal women and approximately 80% of postmenopausal women. Results from sampling with the Novak and Vabra devices were comparable. Nondirected EMB alone is not adequate for determining the cause of AUB and can fail to detect polyps and fibroids.115, 116 Although still useful, EMB is further limited by an inability to identify abnormalities outside the endometrial cavity (adenomyosis, intramural fibroids).117

Among women presenting with AUB, 30–50% will have benign anatomic pathology such as polyps, myomas, endometrial hyperplasia, or adenomyosis. Fewer than 1% of women under the age of 50 years, and 10–15% of those over age 50 years, will have a malignancy.118, 119 In approximately 50% of women, bleeding is dysfunctional in nature, and surgical intervention in all women with AUB is therefore unnecessary.

Dilation and curettage

Operative D&C was first introduced in 1843 by Recamier in the pre-antiseptic era and was fraught with complications, including death.120 At one time, D&C was the most common diagnostic and therapeutic surgical procedure performed in the world. Today, after several decades of experience, D&C is a relatively safe procedure. Complications include perforation, infection, postoperative intrauterine adhesions, tubal damage, and infertility, the latter two being more relevant for younger women. D&C is several times more costly than office EMB and is associated with a higher risk of complications.121 D&C should therefore not be routine practice. Rather, it should be reserved for specific circumstances such as cervical stenosis in which it may be the preferred method of sampling the endometrium. The amount of endometrial surface sampled by D&C is less than 15%, the prevalence of cervical stenosis that precludes office EMB is approximately 4–10%,122 and D&C requires anesthesia.

Both D&C and office EMB have sampling limitations and both are blind procedures.123 A hysteroscope-directed biopsy provides more information than D&C alone.109, 124


More than 50% of the estimated 650,000 hysterectomies performed annually in the United States are for AUB, at a cost in excess of $1.5 billion. Nearly half of the uteri removed are without disease, indicating the need for less invasive therapies. It is estimated that four of every five women treated for ovulatory menorrhagia will have no anatomic lesion, and over a third of hysterectomies performed for this indication reveal no pathology.125 A thorough understanding of the physiology of the normal menstrual cycle and of the etiology and pathogenesis of AUB during the various stages of reproductive life and beyond is essential in formulating a management plan and selecting the most appropriate treatment strategy.

Management options include medical and surgical measures. Anatomic lesions, including polyps and submucous fibroids, usually require surgical intervention such as hysteroscopy with or without D&C. Other structural anomalies such as adenomyosis and intramural leiomyomas may respond to medical interventions. Menorrhagia, anovulatory bleeding, and perimenopausal bleeding disorders can be treated medically before resorting to more invasive surgical procedures.


Cyclooxygenase Inhibitors

The endometrium produces prostaglandins throughout the menstrual cycle but more so in the late luteal and menstrual phases when systemic and local progesterone levels are declining. Phospholipases convert fatty acid precursors to arachidonic acid, which is subsequently converted to PGs by cyclooxygenases.126 Endometrial phospholipases are abundant, particularly in the luteal phase when PGF, a potent vasoconstrictor, predominates in the glandular epithelium.127, 128 PGE2 and PGI2 (prostacyclin) have vasodilating properties and are found in the stromal cells129 and superficial endometrium,130, 131 respectively. Greater amounts of PGI2132 and higher ratios of PGE2:PGF have been observed in women with menorrhagia than in women with normal volumes of menstrual blood loss.131, 133

The role of PGs in mediating menstrual blood loss provides the rationale for treatment of menorrhagia associated with ovulatory cycles with cyclooxygenase inhibitors such as nonsteroidal anti-inflammatory drugs (NSAIDs). In the 1970s and early 1980s, mefenamic acid and flufenamic acid were observed to be effective in decreasing menstrual blood loss in ovulatory menorrhagia. Since then, other NSAIDs, including diclofenac, flurbiprofen, ibuprofen, indomethacin, naproxen, and naproxen sodium have been used for the same purpose. The Cochrane Review observed that when compared with placebo, mean blood loss was decreased by treatment with NSAIDs in five of the seven randomized controlled trials (RCTs) examined.134 Subjective perceptions of reduced menstrual blood loss have also been documented in placebo-controlled trials.135, 136 All NSAIDs studied to date appear equally efficacious, and there is no evidence to indicate that any one is superior to others. The typical treatment regimen involves starting medication on the first day of flow and continuing for approximately five days or until cessation of menses. Doses of mefenamic acid and naproxen prescribed are 250–500 mg two to four times per day; ibuprofen can be used in doses up to 600–1200 mg/day.

NSAIDs have also been studied in abnormal uterine bleeding associated with hormonally induced bleeding. In a double-blind, placebo-controlled study of valdecoxib and placebo for controlling irregular uterine bleeding in depot-medroxyprogesterone acetate (DMPA) users, the number of subjects whose bleeding was stopped during the first week was significantly higher in the valdecoxib group than in the placebo group (77.3% vs. 33.3%, p<.01) suggesting that NSAIDS may also be effective in control of irregular bleeding in DMPA users. 137

Antifibrinolytic Agents

Fibrinolysis is an important physiologic process by which a vascular clot is broken down. This process is mediated by activation of plasminogen by a group of enzymes called plasminogen activators (PAs) to yield plasmin. Pathologic processes that increase local fibrinolytic activity may increase menstrual loss. Women with ovulatory menorrhagia have higher levels of PAs.138, 139 PA inhibitors such as tranexamic acid have been shown to decrease menstrual blood loss by approximately 60% in women with increased endometrial PA activity.140, 141 Interestingly, women taking tranexamic acid in one study experienced a 45% decrease in menstrual flow, whereas those taking norethisterone during the luteal phase experienced a 20% increase in menstrual loss.142 Tranexamic acid also appears to be more effective than NSAIDs in this respect.143, 144

In North America, antifibrinolytics are rarely used owing to concerns about their adverse effects–including gastrointestinal side effects and possible increased risk of thromboembolism–and poor marketing by pharmaceutical companies for lack of a patent.145


High-dose parenteral estrogens have been used effectively to treat acute episodes of excessive uterine bleeding.146, 147 Although estrogen does promote rapid endometrial regrowth over denuded epithelial surfaces, the exact mechanism responsible for the effectiveness of parenteral estrogen is not clearly understood. When such treatment is ineffective, D&C may be required to control bleeding. Parenteral estrogens have no place in the long-term management of bleeding disorders. When there are contraindications to estrogen treatment (smoking, history of thromboembolism), high-dose progestational agents can be used,148 although there are no RCTs to support their effectiveness.

Progestational Agents

Progestins have been used for decades in the treatment of DUB. However, the agent, route of administration, and dosing schedule have varied widely. In the United States, medroxyprogesterone acetate (MPA) is popular, whereas norethindrone is more widely used in other countries. Most of the world’s literature addresses the use of norethindrone. Not surprisingly, progestins appear to be more effective for the treatment of DUB than for AUB associated with anatomic lesions or menorrhagia. When compared with placebo, danazol, NSAIDs, the progesterone-containing intrauterine device (IUD), and antifibrinolytics, the effects of oral progestins range from none to an increase in menstrual loss in women with menorrhagia.134, 142, 149, 150

Continuous systemic dosing may be more effective for women with ovulatory menorrhagia than cyclic progestin therapy, but to be most effective, the dose must be sufficient to suppress ovarian cyclicity. Partial ovarian suppression may desynchronize endometrial development and result in more rather than less bleeding. Studies of depo-MPA used for contraceptive indications have observed that approximately 80% of treated women are amenorrheic by the end of the first year, but it is important to remember that such studies were not designed to evaluate the efficacy of depo-MPA in women with excess menstrual loss.151 Incidentally, 50% of women using depo-MPA for contraception experienced irregular bleeding during the first year. Prolonged irregular bleeding in Norplant users accounts for the high rate of discontinuation of therapy. Runic and colleagues observed fragile capillaries and increased tissue factor expression at sites of endometrial bleeding in hysteroscopically directed EMB specimens in women using Norplant, when compared with specimens obtained from nonbleeding sites.152

Progestin Intrauterine Contraceptive Device

IUDs have been used for decades for contraception. The concept of using an IUD impregnated with a progestational agent to deliver continuous local progestin therapy is not a novel one and studies were first published in the early 1980s.153 However, only recently has this approach gained popularity in the treatment of AUB. Menstrual blood loss three months after insertion of a progestin IUD was reduced by 94% from baseline, compared with an 87% reduction observed in women treated with norethindrone.154 Despite comparative decreases in blood loss, women who received the IUD more often chose to continue treatment. The progestin IUD rivals surgical endometrial resection in its efficacy for reducing blood loss and achieving amenorrhea.155 In a group of women awaiting hysterectomy for DUB, 41 of 50 treated with the progestin IUD elected not to proceed with surgery.156 Another study from Sweden reported similar results.157

Administering progestational agents via a local route to the endometrium is logical and offers advantages to the patient because systemic progestins may have undesirable effects on lipids and the central nervous system, the latter being the most frequent reason for poor compliance. Although an IUD insertion is somewhat invasive, the long-term benefits, efficacy and reduced need for hysterectomy, appear to justify its use. Interestingly, the cost of an IUD that is effective for five years is comparable with that of oral progestin treatment for the same length of time. Moreover, progestin IUDs are associated with low risks of ectopic pregnancy and pelvic inflammatory disease,158, 159 and therefore offer further advantages to ovulatory women.

In the United States, the only currently available progestin IUD contains levonorgestrel, is marketed under the name Mirena, and is effective for five years. The plastic T-shaped frame of Mirena contains 52 mg of levonorgestrel impregnated in its vertical stem of polydimethylsiloxane, of which approximately 20 μg is released each day. The drug is distributed in silicone fluid with a rate-limiting membrane that allows slow diffusion of the drug into the endometrium. The device is also impregnated with barium sulfate that renders it radiopaque.160 Plasma levels of levonorgestrel with the system in place are negligible when compared with those in women receiving treatment with a progestin-only pill (POP), Norplant, or a combined oral contraceptive.161, 162, 163, 164 Systemic progestational side effects are rare, and there is no demonstrable effect on the hypothalamic-pituitary-ovarian axis.165, 166

Combined Estrogen and Progestin Preparations

Combination estrogen and progestin preparations include combined oral contraceptives (COC), contraceptive patches, and vaginal contraceptive rings. These methods can be used cyclically to provide a regular predictable bleeding pattern, or may be used continuously to reduce overall episodes of bleeding. Progestins in combination medication cause endometrial atrophy and the estrogen supports the endometrium to reduce intermenstrual bleeding.4 The advantages of using combined estrogen and progesterone therapy include effectiveness, predictability, contraceptive effect, and reduced withdrawal bleeding episodes, while disadvantages include the need for strict daily use and systemic side effects.167 Additionally, hormonal combinations may be less effective in treating structural lesions such as polyps and submucosal fibroids. COCs are commonly used to treat menorrhagia, and significantly reduce blood loss comparable with that of NSAIDs and danazol.168 Although commonly used, a Cochrane review found no significant difference between groups treated with COCs, mefenamic acid, low dose danazol or naproxen. This review found insufficient evidence to determine the effectiveness of COCs in the treatment of menorrhagia.169


Danazol, a synthetic derivative of testosterone, has been used to treat DUB effectively, the proposed mechanisms of action being suppression of ovulation, decreased ovarian production of estradiol, and direct effects on estrogen receptors in the endometrium. Chimbara and colleagues demonstrated that higher doses were more effective than lower doses in treating ovulatory menorrhagia.170 However, the androgenic and often persistent side effects, including oily skin, acne, weight gain, and deepening of voice, have limited its use.

Gonadotropin-Releasing Hormone Agonists

GnRH agonists down-regulate and desensitize the anterior pituitary, thereby reducing gonadotropin synthesis and release and inducing a reversible hypogonadal state. Agonists have been used effectively for treatment of bleeding disorders, particularly those associated with leiomyomas and adenomyosis.171, 172 Both total uterine volume and myoma volume decrease; the extent of shrinkage is significant but highly variable. Within months after cessation of therapy, uterine and myoma volumes return to pretreatment levels.173 Consequently, GnRH agonists are used primarily as a preoperative adjunct to control bleeding and reduce the size of myomas and the uterus, facilitate subsequent surgery, and reduce the need for blood transfusion.

Antiprogestational Agents

The antiprogestational class of agents, although used primarily as abortifacients, has also been shown to significantly reduce fibroid volume without affecting circulating gonadotropin or gonadal steroid levels,174 achieving amenorrhea in all women. Mifepristone (RU-486) has been available in Europe for many years, but has been approved for use as an early first trimester abortifacient in the United States only recently. Its use for the treatment of menorrhagia remains largely unexplored.

Gonadotropin-Releasing Hormone Antagonists

GnRH antagonist agents are used primarily in patients undergoing ovulation induction, but they may have a potential role in the treatment of bleeding disorders in the future. Currently, GnRH antagonists are considerably more expensive than GnRH agonists and are not available in depot form, making them impractical for use in the management of bleeding disorders.


Progestational Agents

Cyclic progestin administration in perimenopausal women with anovulatory cycles can be extremely effective.175, 176 Such treatment also effectively prevents the endometrial consequences of otherwise unopposed estrogen stimulation. The progestin-only pill (POP) may offer an alternative approach to providing both contraception and endometrial protection, but continuous progestin treatment can induce BTB by promoting overexpression of tissue factors and increased vascular fragility in the endometrium.152 There is also concern that continuous systemic progestin treatment may be detrimental to maintenance of bone mass in the long term. In women who present with complaints of mood changes or depression during the perimenopausal transition or who have a prior history of depression or severe premenstrual syndrome (PMS), it is important to exercise caution when prescribing hormonal treatment because they may not tolerate progestin therapy or progestin-dominant COCs. Progestins are also likely to aggravate insulin resistance in susceptible individuals.177

Oral micronized progesterone appears to be better tolerated than synthetic progestins, with fewer mood and PMS-like symptoms. The most common reported side effects are fatigue, sedation, and dizziness. Micronization decreases particle size, enhances dissolution, prolongs the half-life of progesterone, and decreases its breakdown in the gastrointestinal tract. Progesterone can be administered orally, topically, intravaginally, or intramuscularly, the former three being the most popular routes for HRT.

As with the treatment of menorrhagia, the levonorgestrel-releasing intrauterine system (LNG-IUS) has proven to be an effective method for delivery of progesterone in perimenopausal women. Efficacy studies of the LNG-IUS during estrogen replacement therapy in perimenopausal women show suppression of endometrial proliferation with resultant amenorrhea as well as resolution of vasomotor symptoms and high levels of patient compliance. 178

Combined Oral Contraceptives

Combined oral contraceptives (COCs) suppress ovarian function and thereby provide contraception. Ovarian suppression is useful in other contexts as well. COC use is advocated in perimenopausal women to eliminate the highly dynamic and fluctuating hormone levels that characterize the perimenopausal years. COCs may be used to avoid vasomotor symptoms associated with transient declines in circulating estrogen levels that typically occur in the perimenopause or to temper worsening mood changes. In addition to cycle regulation, they also provide safe and effective contraception for women who are at risk of spontaneous ovulation and pregnancy. Pregnancy is often undesirable in this age group and can be fraught with complications, including an increased risk of chromosomal abnormalities and spontaneous abortion. Other benefits of COCs include conservation of bone mass, decrease in benign breast disease, reduced risk for ovarian and endometrial cancer, and reduced need for surgical sterilization procedures. COCs also reduce the need for invasive surgical procedures such as hysteroscopies, D&Cs, endometrial ablations, and hysterectomies for persistent AUB due to hormone dysregulation. It is important to exercise caution when using OCs in smokers, hypertensive women, and those who may harbor an unrecognized thrombophilia. Women on COCs may experience BTB and may require an alternate formulation. It is interesting to note that the risk of BTB during treatment with COCs is twofold higher in smokers than in nonsmokers.179

The pill is not a panacea for all women. It may not be easy to convince a woman who has previously experienced side effects on the pill to try another formulation. In older women, prudence dictates the use of preparations containing 20 μg or less ethinyl estradiol to avoid unwanted side effects and risks such as venous thromboembolism. Standard doses of estrogens and progestogens used in conventional HRT are relatively ineffective in suppressing the hypothalamic-pituitary-ovarian axis and may aggravate the underlying hormone chaos.

COCs can be used in cyclic or continuous fashion.180 Some women feel more secure having regular monthly cycles. Others prefer having less frequent menses or none at all. It is therefore important to educate and counsel patients carefully to allow them to select their preferred regimen. Women in this age group generally are very receptive to this approach and find this concept attractive. The two regimens are interchangeable if one is not well tolerated by the patient. The continuous combined regimen is often associated with some BTB in the initial months of use. Abdominal bloating, breast tenderness, weight gain, and loss of libido can be associated with COC use and may hinder compliance.

COCs and progestins have a very limited role in treating women with AUB that is associated with structural abnormalities, such as polyps and submucous fibroids, although there is no evidence that their use makes matters worse.

Endometrial Hyperplasia

Unopposed estrogen effects on the endometrium include endometrial hyperplasia that may be simple or complex in histologic pattern. Complex hyperplasia may be observed with or without associated cytologic atypia. The presence of atypia increases the risk for endometrial cancer. Risk for developing endometrial carcinoma is approximately 25% in patients with atypia, but only 2% in patients without atypia.181 Hyperplasia without atypia can be treated with higher doses of progestins with a repeat EMB 4–6 months after initiation of treatment to ensure that the abnormality has resolved. Hyperplasia with atypia is best treated surgically. Persistence of atypia has been demonstrated in as many as 50% of women despite treatment with high doses of progestational agents.182


Endoscopic Surgery

Hysteroscopy is a useful diagnostic and therapeutic tool for patients with and without intracavitary lesions. Diagnostic hysteroscopy can be performed as an office procedure without anesthesia. Most gynecologists, however, prefer to perform this procedure with the patient under anesthesia, particularly if they plan to biopsy or excise polyps/fibroids.

Polyps are usually pedunculated, vary in size, and can be excised by twisting and avulsion with a grasping forceps. Sessile polyps are best excised by D&C or monopolar loop excision under direct hysteroscopic visualization.

Hysteroscopic treatment of fibroids depends on the size, number, nature, and location of lesions. Small pedunculated submucosal fibroids can be excised by techniques similar to those described for polyps. Larger pedunculated fibroids or fibroids having an intramural component that does not extend deeply into the myometrium require resection with a loop electrode. For fibroids with a deeper intramural component, laparoscopic guidance during hysteroscopic resection is advisable.

In women with unexplained menorrhagia and normal endometrial histology, an endometrial ablation can be considered using electrosurgical or laser energy systems. With improvement in fiberoptic and video monitoring techniques, the safety and efficacy of distention media, operative equipment, and energy systems, this procedure is relatively safe in experienced hands. Transcervical endometrial resection was first described in 1981 by Goldrath who used the neodymium:yttrium-aluminum-garnet (Nd:YAG) laser energy system. Laser energy systems vary in their depth penetration, extent of endometrial destruction, beam scatter, and absorption by distention media. Amenorrhea and complication rates vary widely and are largely operator and technique dependent. Initial reports were encouraging, with over 90% initial eumenorrhea or amenorrhea rates,183, 184 but longer follow-up studies revealed increasing failure rates requiring additional surgery.185 Failure rates vary between 5% and 10%. Other techniques for endometrial ablation followed, including the resectoscope and rollerball electrocautery. Since 1997, five global endometrial ablation devices (GEA) have been approved for treatment of menorrhagia. These techniques allow the surgeon to treat the entire endometrium through a more automated process rather than in sections as had been previously performed.186 Currently available methods include thermal balloon, circulated hot fluid, cryotherapy, bipolar radiofrequency electrosurgery, and microwave energy.186 Contraindications to GEA include desire for future pregnancy, malignant or premalignant changes of the uterus, untreated pelvic inflammatory disease or endometrial infection, hydrosalpinx, history of classical cesarean delivery or transmural myomectomy, uterine anomaly, and intrauterine device in place.186 In addition, each ablation technique has specific limitations on cavity size and extent of uterine pathology.186 Endometrial sampling should be performed to exclude malignancy before ablation and pretreatment of the endometrium with GnRH agonists may also be recommended.186 Several cases of endometrial adenocarcinoma have been reported in women who have previously undergone endometrial ablation.187 Therefore, any subsequent HRT should include progestogens to prevent endometrial hyperplasia in residual islands of functional endometrium, even in amenorrheic women. Complications of the procedure include cervical trauma during dilation, particularly with a stenotic cervix, uterine perforation with or without trauma to other intra-abdominal organs, excessive bleeding, infection, air embolism, fluid and electrolyte disturbances, and those that may be associated with laser and electrosurgical instruments or anesthesia. Late complications include hematometra, recurrence of bleeding problems, retrograde menstruation, and pelvic pain.

Laparoscopic or conventional myomectomy by laparotomy is an option for women with large fibroids causing menorrhagia. The size and location of myomas often dictate the surgical approach. Myomectomies are more frequently performed in women of reproductive age who wish to conserve their fertility and in those who prefer not to undergo a hysterectomy for cultural or other reasons. Postoperative recurrence and adhesions can pose subsequent problems.

Uterine artery embolization of symptomatic myomas can avoid the need for a surgical procedure. However, this procedure requires a highly skilled and experienced interventional radiologist. This procedure consists of injecting embolic agents into the uterine arteries. Normally, polyvinyl alcohol particles or tris-acryl gelatin microspheres are used to decrease bilateral uterine artery flow.188 Ischemia of fibroids leads to necrosis and shrinkage, while the normal myometrium survives.188 A review of available literature reports a 50–60% reduction in fibroid size and 85–95% reliefof symptoms following UAE.188 Adverse events associated with UAE include postoperative ischemic pain,  vaginal expulsionof an infarcted fibroid, treatment failure with need for subsequent surgery, chronic vaginal discharge from retained fibrotic tissue, intrauterine infection, and rarely sepsis. 188 The evidence does not support performing UAE in women that desire future fertility.


Hysterectomy is the second most commonly performed surgical procedure in the United States. Approximately half a million hysterectomies are performed annually, at a cost of approximately $5 billion. Between 1988 and 1990, the overall hysterectomy rate was 56.8 per 10,000 women.189 Women in the United States are twice as likely as British women and four times more likely than Swedish women to undergo a hysterectomy. Women who fail to respond to conservative measures clearly need and will benefit from a hysterectomy. Satisfaction rates following surgery, immediate and long term, vary widely and largely depend on the indication for surgery.

Hysterectomies can be performed via the vaginal, abdominal, or laparoscopic route. Appropriate patient selection is essential to reduce the risk of complications. In women who undergo hysterectomy for benign indications, the overall mortality rate is approximately 6 per 10,000, and is 3 per 10,000 in those under age 45 years. In one series, the perioperative death rate was 0.1% for abdominal hysterectomy and 0.2% for vaginal hysterectomy.190 Complications include wound or urinary tract infection, injury to intra-abdominal organs (bladder, ureter, intestines, rectum), and hemorrhage. Laparoscopically assisted vaginal hysterectomy and total laparoscopic hysterectomy are gaining popularity and involve a shorter duration of hospital stay. Cost differences between laparoscopic and traditional approaches can be an issue and vary widely between hospitals and providers.


AUB is a frequently encountered presenting complaint in perimenopausal and postmenopausal women, and accounts for a substantial proportion of office visits and gynecologic procedures. The etiology of AUB is varied. Establishing a diagnosis often takes time and requires specific procedures to exclude neoplasms and frank malignancies. Treatment options are many, and choice depends on patient preference and the underlying cause(s). Counseling and education on the various medical and surgical options available, and their side effects, are essential to ensure compliance and successful treatment. Given the many effective medical therapies available, surgery should be reserved for those who cannot tolerate or fail to respond to medical therapy and those whose pathology is not amenable to medical treatment.



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