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Gynecomastia: Etiology, Diagnosis, And Treatment Gynecomastia: Etiology, Diagnosis, And Treatment
Male breast development occurs in an analogous fashion to female breast development. At puberty in the female breast, complex hormonal interplay occurs resulting in... Gynecomastia: Etiology, Diagnosis, And Treatment

Anabolic Steroid Induced Gynecomastia

by H. Hajdo Everything you need to know about gyno.BREAST DEVELOPMENT

Male breast development occurs in an analogous fashion to female breast development. At puberty in the female breast, complex hormonal interplay occurs resulting in growth and maturation of the adult female breast.

In early fetal life, epithelial cells, derived from the epidermis of the area programmed to later become the areola, proliferate into ducts, which connect to the nipple at the skin’s surface. The blind ends of these ducts bud to form alveolar structures in later gestation. With the decline in fetal prolactin, placental estrogen and progesterone at birth, the infantile breast regresses until puberty (13).

During thelarche, the initial clinical appearance of the breast bud, growth and division of the ducts occur, eventually giving rise to club-shaped terminal end buds, which then form alveolar buds. Approximately a dozen alveolar buds will cluster around a terminal duct, forming the type 1 lobule. Eventually, the type 1 lobule will mature into types 2 and 3 lobules, called ductules, by increasing its number of alveolar buds to as many as 50 in type 2 and 80 in type 3 lobules. The entire differentiation process takes years after the onset of puberty and, if pregnancy is not achieved, may never be completed (38).

HORMONAL REGULATION OF BREAST DEVELOPMENT

The initiation and progression of breast development involves a coordinated effort of pituitary and ovarian hormones, as well as local mediators (see Figure).

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ESTROGEN, GH AND IGF-1, PROGESTERONE, & PROLACTIN

Estrogen and progesterone act in an integrative fashion to stimulate normal adult female breast development. Estrogen, acting through its ER a receptor, promotes duct growth, while progesterone, also acting through its receptor (PR), supports alveolar development (13). This is demonstrated by experiments in ER a knockout mice which display grossly impaired ductal development, whereas the PR knockout mice possess significant ductal development, but lack alveolar differentiation (25,6).

Although estrogens and progestogens are vital to mammary growth, they are ineffective in the absence of anterior pituitary hormones (13). Thus, neither estrogen alone nor estrogen plus progesterone can sustain breast development without other mediators, such as GH and IGF-1, as confirmed by studies involving the administration of estrogen and GH to hypophysectomized and oophorectomized female rats, which resulted in breast ductal development. The GH effects on ductal growth are mediated through stimulation of IGF-1. This is demonstrated by studies of estrogen and GH administration to IGF-1 knockout rats that showed significantly decreased mammary development when compared to age-matched IGF-1- intact controls. Combined estrogen and IGF-1 treatment in these IGF-1 knockout rats restored mammary growth. (21, 36). In addition, Walden et al. demonstrated that GH-stimulated production of IGF-1 mRNA in the mammary gland itself, suggesting that IGF-1 production in the stromal compartment of the mammary gland acts locally to promote breast development (43). Furthermore, other data indicates that estrogen promotes GH secretion and increased GH levels, stimulating the production of IGF-1, which synergizes with estrogen to induce ductal development.

Like estrogen, progesterone has minimal effects in breast development without concomitant anterior pituitary hormones; again indicating that progesterone interacts closely with pituitary hormones. For example, prolonged treatment of dogs with progestogens such as depot medroxyprogesterone acetate or with proligestone caused increased GH and IGF-1 levels, suggesting that progesterone may also have an effect on GH secretion (29). In addition, clinical studies have correlated maximal cell proliferation to specific phases in the female menstrual cycle. For example, maximal proliferation occurs not during the follicular phase when estrogens reach peak levels and progesterone is low (less than 1 ng/mL[3.1nmol}), but rather, it occurs during the luteal phase when progesterone reaches levels of 10-20 ng/mL (31- 62nmol) and estrogen levels are two to three times lower than in the follicular phase (38). Furthermore, immunohistochemical studies of ER and PR showed that the highest percentage of proliferating cells, found almost exclusively in the type 1 lobules, contained the highest percentage of ER and PR positive cells (38). Similarly, there is immunocytological presence of ER, PR, and androgen receptors (AR) in gynecomastia and male breast carcinoma. ER, PR and AR expression was observed in 100% (30/30) of gynecomastia cases (37). Given these data and the fact that PR knockout mice lack alveolar development in breast tissue, it appears as if progesterone, analogous to estrogen, may increase GH secretion and act through its receptor on mammary tissue to enhance breast development, specifically alveolar differentiation (25, 16).

Prolactin is another anterior pituitary hormone integral to breast development. Prolactin is not only secreted by the pituitary gland but may be produced in normal mammary tissue epithelial cells and breast tumors. (39, 23). Prolactin stimulates epithelial cell proliferation only in the presence of estrogen and enhances lobulo-alveolar differentiation only with concomitant progesterone.

ANDROGEN AND AROMATASE

Estrogen effects on the breast may be the result of either circulating estradiol levels or locally produced estrogens. Aromatase P450 catalyzes the conversion of the C19 steroids, androstenedione, testosterone, and 16-a-hydroxyandrostenedione to estrone, estradiol-17b and estriol. As such, an overabundance of substrate or an increase in enzyme activity can increase estrogen concentrations and thus initiate the cascade to breast development in females and males. For example, in the more complete forms of androgen insensitivity syndromes in genetically male (XY) patients, excess androgen aromatizes into estrogen resulting in not only gynecomastia, but also a phenotypic female appearance. Furthermore, the biologic effects of over expression of the aromatase enzyme in female and male mice transgenic for the aromatase gene result in increased breast proliferation. In female transgenetics, over expression of aromatase promotes the induction of hyperplastic and dysplastic changes in breast tissue. Over expression of aromatase in male transgenics caused increased mammary growth and histologic changes similar to gynecomastia, an increase in estrogen and progesterone receptors and an increase in downstream growth factors such as TGF-beta and bFGF (15). Thus, although androgens do not stimulate breast development directly, they may do so if they aromatize to estrogen. This occurs in cases of androgen excess or in patients with increased aromatase activity.

PHYSIOLOGIC gynecomastia gynecomastia, breast development in males, can occur normally during three phases of life. The first occurs shortly after birth in both males and females. This is caused by the high levels of estradiol and progesterone produced by the mother during pregnancy, which stimulates newborn breast tissue. It can persist for several weeks after birth and can cause mild breast discharge called “witch’s milk” (38).

Puberty marks the second situation in which gynecomastia can occur physiologically. In fact, up to 60% of boys have detectable gynecomastia by age 14. Although it is mostly bilateral, it can occur unilaterally, and usually resolves within 3 years of onset (38). Interestingly, in early puberty, the pituitary gland releases gonadotropins in order to stimulate testicular production of testosterone mostly at nighttime. Estrogens, however, rise throughout the entire day. Some studies have shown that a decreased androgen to estrogen ratio exists in boys with pubertal gynecomastia when compared with boys who do not develop gynecomastia (30). Furthermore, another study showed increased aromatase activity in the skin fibroblasts of boys with gynecomastia. Thus, the mechanism by which pubertal gynecomastia occurs may be due to either decreased production of androgens or increased aromatization of circulating androgens, thus increasing the estrogen to androgen ratio (26).

The third age range in which gynecomastia is frequently seen is during older age (>60 years). Although the exact mechanisms by which this can occur have not been fully elucidated, evidence suggests that it may result from increased peripheral aromatase activity secondary to the increase in total body fat, coupled with mild hypogonadism associated with aging. For instance, investigators have shown increased urinary estrogen levels in obese individuals, and have demonstrated aromatase expression in adipose tissue (32). Thus, like the gynecomastia of obesity, the gynecomastia of aging may partly result from increased aromatase activity, causing increased circulating estrogen levels (7). Moreover, not only does total body fat increase with age, but there may be an increase in aromatase activity in the adipose tissue already present, increasing circulating estrogens even further. Lastly, SHBG increases with age in men. Since SHBG binds estrogen with less affinity than testosterone, the bioavailable estradiol to bioavailable testosterone ratio may increase in the obese older male.

PATHOLOGIC gynecomastia INCREASED ESTROGEN

Since the development of breast tissue in males occurs in an analogous manner to that in females, the same hormones that affect female breast tissue can cause gynecomastia. The testes secrete only 6-10 mg of estradiol and 2.5 mg of estrone per day. Since this only comprises a small fraction of estrogens in circulation (i.e. 15% of estradiol and 5% of estrone), the remainder of estrogen in males is derived from the extraglandular aromatization of testosterone and androstenedione to estradiol and estrone, respectively (27). Thus, any cause of estrogen excess from overproduction to peripheral aromatization of androgens can initiate the cascade to breast development.

TUMORS

Testicular tumors can lead to increased blood estrogen levels by: estrogen overproduction; androgen overproduction with aromatization in the periphery to estrogens; and by ectopic secretion of gonadotropins which stimulate otherwise normal Leydig cells. Tumors causing an overproduction of estrogen represent an unusual but important cause of estrogen excess. Examples of estrogen-secreting tumors include: Leydig cell tumors, Sertoli cell tumors, granulosa cell tumors and adrenal tumors.

Interstitial cell tumors, or Leydig cell tumors constitute 1%-3% of all testis tumors. Usually, they occur in men between the ages of 20 and 60, although up to 25% of them occur prepubertally. In prepubertal cases, isosexual precocity, rapid somatic growth, and increased bone age with elevated serum testosterone and urinary 17-ketosteroid levels are the presenting features. In adults, elevated estrogen levels coupled with a palpable testicular mass and gynecomastia may develop. Though mostly benign, Leydig cell tumors may be malignant and metastasize to lung, liver, and retroperitoneal lymph nodes (34, 14).

Sertoli cell tumors comprise less than 1% of all testicular tumors and occur at all ages, but one third have occurred in patients less than 13 years, usually in boys under 6 months of age. Although they arise in young boys, they usually do not produce endocrinologic effects in children. Again, the majority are benign, but up to 10% are malignant. gynecomastia occurs in one third of cases, presumably due to increased estrogen production (34).

Granulosa cell tumors, which occur very rarely in the testes, can also overproduce estrogen. In fact, only eleven cases have been reported with gynecomastia as a presenting feature in half of them (28).

Germ cell tumors are the most common cancer in males between the ages of 15 and 35. They are divided into seminomatous and nonseminomatous subtypes and include embryonal carcinoma, yolk sac carcinoma, choriocarcinoma and teratomas. Elevated alpha fetoprotein (AFP) and b HCG function as reliable markers in some tumors. As a result of the increased b HCG, acting analogously to LH to stimulate the Leydig cell LH receptor, testicular estrogen production is also increased, which, in turn, can cause gynecomastia. Although germ cell tumors generally arise in the testes, they can also originate extra-gonadally, specifically in the mediastinum. These extragonadal tumors also possess the capability of producing b HCG, but they must be differentiated from a multitude of other tumors such as large cell carcinomas of the lung which can synthesize ectopic b HCG (31).

Some neoplasms that overproduce estrogens also possess aromatase overactivity. Sertoli Cell tumors in boys with Peutz-Jegher syndrome, an autosomal dominant disease characterized by pigmented macules on the lips, gastrointestinal polyposis and hormonally active tumors in males and females, for instance, have repeatedly demonstrated aromatase overactivity, resulting in gynecomastia, rapid growth and advanced bone age as presenting features (18, 44, 10). Feminizing Sertoli cell tumors with increased aromatase activity can also be seen in the Carney complex, an autosomal dominant disease characterized by cardiac myxomas, cutaneous pigmentation, adrenal nodules and hypercortisolism. Other than sex-cord tumors, fibrolamellar hepatocellular carcinoma has also been shown to possess ectopic aromatase activity, causing severe gynecomastia in a 17-year-old boy (2). Furthermore, adrenal tumors can secrete excess dehydroepiandrosterone (DHEA), DHEA-sulfate (DHEAS) and androstenedione which can then be aromatized peripherally to estradiol.

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NON-TUMOR CAUSES OF ESTROGEN EXCESS

INCREASED AROMATASE ACTIVITY

Besides tumors, other conditions have been associated with excessive aromatization of testosterone and androgens to estrogen, which results in gynecomastia. For instance, a familial form of gynecomastia has been discovered, in which affected family members have an elevation of extragonadal aromatase activity (5). As stated, obesity may cause estrogen excess through increased aromatase activity in adipose tissue. Furthermore, hyperthyroidism induces gynecomastia through several mechanisms, including increased aromatase activity (38).

DISPLACEMENT OF ESTROGENS FROM SHBG

Another cause of gynecomastia from estrogen excess includes steroid displacement from sex-hormone binding globulin (SHBG). SHBG binds androgens more avidly than estrogen. Thus, any condition or drug that can displace steroids from SHBG, will more easily displace estrogen, allowing for higher circulating levels of estrogen. Drugs can cause gynecomastia by numerous mechanisms besides displacement from SHBG. These drugs and their mechanisms will be addressed in a subsequent section.

DECREASED TESTOSTERONE AND ANDROGEN RESISTANCE

Breast development requires the presence of estrogen. Androgens, on the other hand oppose the estrogenic effects. Thus, an equilibrium exists between estrogen and androgens in the adult male to prevent growth of breast tissue, whereby either an increase in estrogen or a decrease in androgen can tip the balance toward gynecomastia. Increased estrogen levels will increase glandular proliferation by several mechanisms. These include direct stimulation of glandular tissue and by suppressing LH, therefore decreasing testosterone secretion by the testes and exaggerating the already high estrogen to androgen ratio.

Besides increased estrogen production, decreased testosterone levels can cause an elevation in the estrogen to androgen ratio, producing gynecomastia. Primary hypogonadism, with its reduction in serum testosterone and increased serum LH levels increases testicular estradiol production and is associated with an increased estrogen to androgen ratio. Klinefelter’s syndrome, occurring in 1 in 500 males who possess an XXY karyotype and primary testicular failure, features gynecomastia as well, again presumably secondary to decreased testosterone production, compensatory increased LH secretion, overstimulation of the Leydig cells and relative estrogen excess. In addition, any acquired testicular disease resulting in primary hypogonadism such as viral and bacterial orchitis, trauma, or radiation can also promote gynecomastia by the same mechanisms (27). Lastly, enzyme deficiencies in the testosterone synthesis pathway from cholesterol also result in depressed testosterone levels and hence a relative increase in estrogen. Deficiency of 17-oxosteroid reductase, the enzyme that catalyzes the conversion of androstenedione to testosterone and estrone and estrone to estradiol, for example, will cause elevation in estrone and androstenedione, which is then further aromatized to estradiol (7).

Secondary hypogonadism, if severe enough, results in low serum testosterone and unopposed estrogen effect from increased conversion of adrenal precursors to estrogens (27). Thus, patients with Kallmann’s syndrome, a form of congenital secondary hypogonadism with anosmia, also develop gynecomastia. In fact, hypogonadism from whatever cause constitutes most cases of gynecomastia.

The androgen resistance syndromes, including complete and partial testicular feminization (e.g. Reifenstein’s syndrome) are characterized by gynecomastia and varying degrees of pseudohermaphroditism. Kennedy Syndrome, a neurodegenerative disease, is also associated with decreased effective testosterone due to a defective androgen receptor (38). The gynecomastia is the combined result of decreased androgen responsiveness at the breast level and increased estrogen levels as a result of elevated androgen precursors of estradiol and estrone. As such, androgens in these diseases are not recognized by the peripheral tissues including the breast and pituitary. Androgen resistance at the pituitary results in elevated serum LH levels and increased circulating testosterone. The increased serum testosterone is then aromatized peripherally, promoting gynecomastia. Thus, gynecomastia is the result of increased estradiol levels which arise due to unopposed androgen unresponsiveness.

OTHER DISEASES

Other disease states have also resulted in gynecomastia.

Men with end stage renal disease may have reduced testosterone, and elevated gonadotropins. This apparent primary testicular failure may then lead to increased breast development (16).

The gynecomastia of liver disease, particularly cirrhosis, does not have a clear etiology. Some have speculated that the gynecomastia is the result of estrogen overproduction, possibly secondary to increased extraglandular aromatization of androstenedione, which may have decreased hepatic clearance in cirrhotics. However, testosterone administration to cirrhotics causes a rise in estradiol, but decreases the prevalence of gynecomastia (11, 3, 33). Therefore, although the association of gynecomastia with liver disease is apparent, current data are conflicting and the mechanism by which this occurs remains unclear.

As previously stated, thyrotoxicosis is associated with gynecomastia. Patients often have elevated estrogen which may result from a stimulatory effect of thyroid hormone on peripheral aromatase. Testosterone may also be increased possibly due to thyroid-hormone-stimulated increase in SHBG, as free testosterone is usually normal. Since SHBG binds testosterone more avidly than estradiol, there is a higher ratio of free estradiol to free testosterone. Thus, with normal testosterone and increased estrogen, there is an elevated estrogen to testosterone ratio. In addition, LH is also increased, which may also stimulate testicular estrogen synthesis (16, 9). gynecomastia can also follow spinal cord disorders. Most patients with spinal cord disorders display depressed testosterone levels and, in fact, can develop testicular atrophy with resultant hypogonadism and infertility. Some have speculated that this may result from recurrent urinary tract infections, increased scrotal temperature, and a neuropathic bladder, which ultimately cause acquired primary testicular failure. The exact mechanism, however, remains elusive (17).

Refeeding gynecomastia refers to breast development in men recovering from a malnourished state (13). Although most cases regress within seven months, the etiology of this phenomenon has not been fully elucidated.

HIV patients can also develop gynecomastia. There is a high incidence of androgen deficiency due to multifactorial causes, including primary and secondary hypogonadism (27).

DRUGS

A significant percentage of gynecomastia is caused by medications or exogenous chemicals that result in increased estrogen effect. This may occur by several mechanisms: 1) they possess intrinsic estrogen-like properties, 2) they increase endogenous estrogen production, or 3) they supply an excess of an estrogen precursor (e.g. testosterone or androstenedione) which can be aromatized to estrogen. Examples of drugs that cause gynecomastia are listed in Tables 2 and 3. Contact with estrogen vaginal creams, for instance, can elevate circulating estrogen levels. These may or may not be detected by standard estrogenic qualitative assays. An estrogen-containing embalming cream has been reported to cause gynecomastia in morticians (4, 12). Recreational use of marijuana, a phytoestrogen, has also been associated with gynecomastia. It has been suggested that digitalis causes gynecomastia due to its ability to bind to estrogen receptors (16, 35). The appearance of gynecomastia has been described in body builders and athletes after the administration of aromatizable androgens. The gynecomastia was presumably caused by an excess of circulating estrogens due to the conversion of androgens to estrogen by peripheral aromatase enzymes (8).

Drugs and chemicals that cause decreased testosterone levels either by causing direct testicular damage, by blocking testosterone synthesis, or by blocking androgen action can produce gynecomastia. For instance, chemotherapeutic drugs, such as alkylating agents, cause Leydig cell and germ cell damage, resulting in primary hypogonadism. Flutamide, an anti-androgen used as treatment for prostate cancer, blocks androgen action in peripheral tissues, while cimetidine blocks androgen receptors. Ketoconazole, on the other hand, can inhibit steroidogenic enzymes required for testosterone synthesis. Spironolactone causes gynecomastia by several mechanisms. Like ketoconazole, it can block androgen production by inhibiting enzymes in the testosterone synthetic pathway (i.e. 17a hydroxylase and 17-20-desmolase), but it can also block receptor-binding of testosterone and dihydrotestosterone (40). In addition to decreasing testosterone levels and biologic effects, spironolactone also displaces estradiol from SHBG, increasing free estrogen levels. Ethanol increases the estrogen to androgen ratio and induces gynecomastia by multiple mechanisms as well. Firstly, it is associated with increased SHBG, which decreases free testosterone levels. Secondly, it increases hepatic clearance of testosterone, and thirdly, it has a direct toxic effect on the testes themselves (27). Unfortunately, besides the drugs stated, a multitude of others cause gynecomastia by unknown mechanisms (Table 3).

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Table 3. Drugs that cause gynecomastia by uncertain mechanisms:
Cardiac and antihypertensive medications:
Calcium channel blockers (verapamil, nifedipine, diltiazem)
ACE Inhibitors (captopril, enalapril
b blockers
Amiodarone
Methyldopa
Reserpine
Nitrates

Psychoactive drugs:
Neuroleptics
Diazepam
Neuroleptics
Diazepam
Phenytoin
Tricyclic antidepressants
Haloperidol
Drugs for infectious diseases:
Indinavir
Isoniazid
Ethionamide
Griseofulvin

Drugs of Abuse:
amphetamines

Other:
Theophylline
Omeprazole
Auranofin
Diethylpropion
Domperidone
Penicillamine
Sulindac
Heparin

MALE BREAST CANCER

Male breast cancer is rare and comprises only 0.2 percent of all male cancers. Although uncommon, it has been associated with gynecomastia and necessitates inclusion in the differential diagnosis. Other risks include Klinefelter’s syndrome, exogenous estrogen exposure, family history, and testicular disorders. It is unclear if these are specific risks for breast cancer are linked to the stimulatory process responsible for gynecomastia. New evidence suggests obesity and consumption of red meat may also raise the risk for the development of male breast cancer (19).

PATIENT EVALUATION

HISTORY AND PHYSICAL EXAMINATION

At presentation, all patients require a thorough history and physical exam. Particular attention should be given to medications, drug and alcohol abuse, as well as other chemical exposures. Symptoms of underlying systemic illness, such as hyperthyroidism, liver disease, or renal failure should be sought. Furthermore, the clinician must recall neoplasm as a possible etiology and should establish the duration and timing of breast development. Obviously, rapid breast growth that has occurred recently is more concerning than chronic gynecomastia. Additionally, the clinician should inquire about fertility, erectile dysfunction and libido to rule out hypogonadism, either primary or secondary, as a potential cause.

In our experience, the breast examination is best performed with the patient supine and with the examiner palpating from the periphery to the areola. The glandular mass should be measured in diameter. gynecomastia is diagnosed by finding subareolar breast tissue of 2 cm in diameter or greater. Malignancy is suspected if an immobile firm mass is found on physical examination. Skin dimpling, nipple retraction or discharge, and axillary lymphadenopathy further support malignancy as a possible diagnosis.

A thorough testicular exam is essential. Bilaterally small testes imply testicular failure, while asymmetric testes or a testicular mass suggest the possibility of neoplasm. Visual field impairment may suggest pituitary disease. Physical findings of underlying systemic conditions such as thyrotoxicosis, HIV disease, liver, or kidney failure should also be assessed.

LABORATORY EVALUATION

All patients who present with gynecomastia should have serum testosterone, estradiol, LH and b HCG measured. Further testing should be tailored according to the history, physical examination and the results of these initial tests. An elevated b HCG or a markedly elevated serum estradiol suggests neoplasm and a testicular ultrasound is warranted to identify a testicular tumor, keeping in mind, however, that other non-testicular tumors can also secrete b HCG. A low testosterone level, with an elevated LH and normal to high estrogen level indicates primary hypogonadism. If the history suggests Klinefelter’s Syndrome, then a karyotype should be performed for definitive diagnosis. Low testosterone, low LH and normal estradiol levels imply secondary hypogonadism, and hypothalamic or pituitary causes should be sought. If testosterone, LH and estradiol levels are all elevated, then the diagnosis of androgen resistance should be entertained. Liver, kidney and thyroid function should be assessed if the physical examination suggests liver failure, kidney failure, or hyperthyroidism, respectively. Furthermore, if examination of breast tissue suggests malignancy, a biopsy should be performed. This is of particular importance in patients with Klinefelter’s syndrome, who have an increased risk of breast cancer.

TREATMENT

Treatment of the underlying endocrinologic or systemic disease that has caused gynecomastia is mandatory. Testicular tumors, such as Leydig cell, Sertoli cell or granulosa cell tumors should be surgically removed. In addition to surgery, germ cell tumors are further managed with chemotherapy involving cisplatin, bleomycin and either vinblastine or etoposide (34, 14). Should underlying thyrotoxicosis, renal or hepatic failure be discovered, appropriate therapy should be initiated. Medications that cause gynecomastia should also be discontinued whenever possible based on their role in management of the underlying condition. Of course, if a breast biopsy indicates malignancy, then mastectomy should be performed.

If no pathologic abnormality is detected, then appropriate treatment is close observation. A careful breast exam should be done initially every 3 months until the gynecomastia regresses or stabilizes, after which a breast exam can be performed yearly. It is important to remember that some cases of gynecomastia, especially that which occurs in pubertal boys, can resolve spontaneously.

MEDICAL TREATMENT

If the gynecomastia is severe, does not resolve, and does not have a treatable underlying cause, some medical therapies may be attempted. These include testosterone, dihydrotestosterone, danazol, clomiphene citrate, tamoxifen and the aromatase inhibitor testolactone. Testosterone treatment of hypogonadal men with gynecomastia often fails to produce breast regression once gynecomastia is established. Unfortunately, testosterone treatment may actually produce the side effect of gynecomastia by being aromatized to estradiol. Thus, although testosterone is used to treat hypogonadism, its use to specifically counteract gynecomastia is limited (42). Dihydrotestosterone, a non-aromatizable androgen, has been used in patients with prolonged pubertal gynecomastia with good response rates (22). Since dihydrotestosterone is given either intramuscularly or percutaneously, this may restrict its usefulness. Danazol, a weak androgen that inhibits gonadotropin secretion, resulting in decreased serum testosterone levels, has been studied in a prospective placebo-controlled trial, whereby gynecomastia resolved in 23 percent of the patients, as opposed to 12 percent of the patients on placebo (20). Unfortunately, undesirable side effects including edema, acne, and cramps have limited its use (27). Investigators have reported a 64 percent response rate with 100 mg/day of clomiphene citrate, a weak estrogen and moderate antiestrogen (24). Lower doses of clomiphene have shown varied results, indicating that higher doses may need to be administered, if clomiphene is to be attempted. tamoxifen, also an antiestrogen, has been studied in 2 randomized, double-blind studies in which a statistically significant regression in breast size was achieved, although complete regression was not documented (1). One study compared tamoxifen with danazol in the treatment of gynecomastia. Although patients taking tamoxifen had a greater response with complete resolution in 78 percent of patients treated with tamoxifen, as compared to only a 40 percent response in the danazol-treated group, the relapse rate was higher for the tamoxifen group (41). Although complete breast regression may not be achieved and a chance of recurrence exists with therapy, tamoxifen, due to relatively lower side effect profile, may be a more reasonable choice when compared to the other therapies. If used, tamoxifen should be given at a dose of 10 mg twice a day for at least 3 months (27). An aromatase inhibitor, testolactone, has also been studied in an uncontrolled trial with promising effects (45). Further studies must be performed on this drug before any recommendations can be established on its usefulness in the treatment of gynecomastia.

SURGICAL TREATMENT

When medical therapy is ineffective, particularly in cases of longstanding gynecomastia, or when the gynecomastia interferes with the patient’s activities of daily living, then surgical therapy is appropriate. This includes removal of glandular tissue coupled with liposuction, if needed. In our experience, uses of delicate cosmetic surgical techniques are warranted to prevent unsightly scarring.

SUMMARY

In summary, gynecomastia is a relatively common disorder. The causes of its development range vastly from benign physiologic processes to rare neoplasms. Thus, in order to properly diagnose the etiology of the gynecomastia, the clinician must understand the hormonal factors involved in breast development. Parallel to female breast development, estrogen, along with GH and IGF-1 is required for breast growth in males. Since a balance exists between estrogen and androgens in males, any disease state or medication that can increase circulating estrogen or decrease circulating androgen, causing an elevation in the estrogen to androgen ratio, can induce gynecomastia. Due to the diversity of possibly etiologies, including neoplasm, performing a careful history and physical is imperative. Once gynecomastia has been diagnosed, treatment of the underlying cause is warranted. If no underlying cause is discovered, then close observation is appropriate. If the gynecomastia is severe, however, medical therapy can be attempted and if ineffective, glandular tissue can be removed surgically.

References:

1. Alagaratnam TT: Idiopathic gynecomastia treated with tamoxifen; a preliminary report. Clin Ther 9:483-7, 1987

2. Agarwal VR, Takayama K, Van Wyk JJ, Sasano H, Simpson ER, Bulun SE: Molecular Basis of Severe gynecomastia Associated with Aromatase Expression in a Fibrolamellar Hepatocellular Carcinoma. Journal of Clinical Endocrinology and Metab 83(5): 1797-1800, 1988

3. Bahnsen M, Gluud C, Johnsen SG: Pituitary-testicular Function in Patients with Alcoholic Cirrhosis of the Liver. European Journal of Clinical Investigation 11: 473-479, 1981.

4. Bhat N, Rosato E, Gupta P: gynecomastia in a mortician: A case report. Acta Cytol 34:31, 1990.

5. Berkovitz GD, Guerami, Brown TR, MacDonald PC Migeon CJ: Familial gynecomastia with Increased Extraglandular Aromatization of Plasma Carbon 19-Steroids. Journal of Clinical Investigation 75: 1763-1769, 1985.

6. Bocchinfuso WP, Korach KS: Mammary Gland Development and Tumorigenesis in Estrogen Receptor Knockout Mice. Journal of Mammary Gland Biology and Neoplasia 90: 323-334, 1997.

7. Braunstein: Aromatase and gynecomastia. Endocrine-Related Cancer 6: 315-324, 1999.

8. Calzada L, Torres-Calleja JM, Martinez N: Measurement of Androgen and Estrogen Receptors in Breast Tissue from Subjects with Anabolic Steroid-Dependent gynecomastia. Life Sciences 69 (2110): 1465-1479.

9. Chan WB, Yeung VT, Chow CC, So WY, Cockram CS: Gynaecomastia as a Presenting Feature of Thyrotoxicosis. Postgraduate Medical Journal 75(882): 229-231, 1999.

10. Coen P, Kulin H, Ballantine T, Zaino r, Frauenhoffer E, Boal D, Inkster S, Brodie A, Santen R: An Aromatase-Producing Sex-cord Tumor Resulting in Prepubertal gynecomastia. New England Journal of Medicine 324 (5): 317-22, 1991.

11. Edman DC, Hemsell DL, Brenner PF: Extraglandular Estrogen Formation in Subjects with Cirrhosis. Gastroenterology 69: 819, 1975.

12. Finkelstein J, McCully W, MacLaughlin D, et al.: The mortician’s mystery: gynecomastia and reversible hypogonadotropic hypogonadism in an embalmer. N Eng J Med 319:961, 1988.

13. Franz A, Wilson J: Williams Textbook of Endocrinology ninth edition, 877-885, 1998.

14. Gana BM: Leydig Cell Tumor, British Journal of Urology 75(5): 676-8, 1995.

15. Gill K, Kirma N, Tekmal RR: Overexpression of Aromatase in Transgenic Male Mice Results in the Induction of gynecomastia and other Biochemical Changes in Mammary Gland. Journal of Steroid Biochemistry and Molecular Biology 77(1):13-18, 2001.

16. Glass AR: gynecomastia. Endocrinology and Metabolism Clinics of North America. 23(4): 825-837, 1994.

17. Herito RJ, Dankner R, Berezin M, Zeilig G, Ohry A: gynecomastia Following Spinal Cord Disorder. Archives of Physical Medicine and Rehabilitation 78(5): 534-537, 1997.

18. Hertl MC, Wiebel J, Schafer H, Willig HP, Lambrecht W. Feminizing Sertoli Cell Tumors Associated with Peutz-Jeghers Syndrome: An Increasingly Recognized Cause of Prepubertal gynecomastia. Plastic Reconstructive Surgery 102(4):1151-57, 1998.

19. Hsing A, McLaughlin J, Cocco p, Chen H, Fraumeni JF: Risk factors for male breast cancer. Cancer Causes and Control 9; 269-275, 1998.

20. (Jones DJ, Holt SD, Surtees P, et al: A comparison of danazol and placebo in the treatment of adult idiopathic gynaecomastia: results of a prospective study in 55 patients. Ann R Coll Surg Engl, 72:296-8, 1990.)

21. Kleinberg DL, Feldman M, Ruan W: IGF-1: An Essential Factor in Terminal End Bud Formation and Ductal Morphogenesis. Journal of Mammary Gland Biology and Neoplasia 5(1):7-17, 2000.

22. Kuhn JM, Roca R, Laudat MH, et al: Studies on the treatment of idiopathic gynecomastia with percutaneous dihydrotestosterone. Clin Endo 19: 513-20, 1983.)

23. LeProvost F, Leroux, C, Martin P Gaye P, Djiane, J, Prolactin Gene Expression in Ovine and Caprine Mammary Gland, Neuroendocrinology 60: 305-313, 1994.

24. Leroith D, Sobel R, Glick SM: The effect of clomiphene citrate on pubertal gynaecomastia. Acta Endocrinol (copenh). 95:177-80, 1980.

25. Lubahn, DB, Moyer JS, Golding TS: Alteration of Reproductive Function but not Prenatal Sexual Development after Insertional Disruption of the Mouse Estrogen Receptor Gene. Proc Soc Natl Acad Sci USA 90:11162-11166, 1993.

26. Mahoney CP: Adolescent gynecomastia. Differential Diagnosis and Management. Pediatric Clinics of North America 37(6): 1389-1404, 1990.

27. Mathur R, Braunstein: Gynecomastia: Pathomechanisms and Treatment Strategies. Hormone Research 48:95-102, 1997.

28. Matoska J, Ondrus D, Talerman A: Malignant Granulosa Cell Tumor of the Testes Associated with gynecomastia and LongSurvival. Cancer 69(7): 1769-72, 1992.

29. Mol JA, Van Garderen E, Rutteman GR, Rijnberk A: New Insights in the Molecular Mechanism of Progestin-induced Proliferation of Mammary Epithelium: Induction of the Local Biosynthesis of Growth Hormone in the Mammary Gland of Dogs, Cats, and Humans. Journal of Steroid Biochemistry and Molecular Biology 57 (1-2): 67-71, 1996.

30. Moore DC, Schlaepfer, LP, Sizonenko PC: Hormonal Changes During Puberty: Transient Pubertal Gynecomastia; Abnormal Androgen-Estrogen Ratios. Journal of Clinical Endocrinology and Metabolism 58:492-499, 1984.

31. Moran CA, Suster S: Primary Mediastinal Choriocarcinoma: A Clinicopathologic and Immunohistochemical Study of Eight Cases. American Journal of Surgical Pathology 21(9): 1007-1012, 1997.

32. Niewoehner CB, Nuttall FQ: gynecomastia in Hospitalized Male Population. American Journal of Medicine 77: 633-638, 1984.

33. Olivo J, Gordon GG, Raifi F: Estrogen Metabolism in Hyperthyroidism and in Cirrhosis of the Liver. Steroids 26: 47-56, 1975.

34. Richie J: Campbell’s Urology 7th Edition, 2439-2443, 1998.

35. Rifka SM, Pita JC, Vigersky RA, et al. Interaction of digitalis and spironolactone with human sex steroid receptors. J Clin Endocrinol Metab 1977; 46:228-244.

36. Ruan W, Kleinberg DL: Insulin-like Growth Factor I is Essential for Terminal End Bud Formation and Ductal Morphogenesis during Mammary Development. Endocrinology 140(11): 5075-81, 1999.

37. Sasano H, Kimura m, Shizawa s, Kimura N, Nagua H, Aromatase and Steroid Receptors in gynecomastia and Male Breast Carcinoma: an Immunohistochemical Study. Journal of Clinical Endocrinology and Metabolism 81 (8): 3063-7, 1996.

38. Santen R: Endocrinology fourth edition vol. 3: 2335-2341, 2001

39. Steinmetz R, Grant A, Malven, P: Transcription of Prolactin Gene in Milk Secretory Cells of the Rat Mammary Gland. Journal of Endocrinology 36: 305-313,1993.

40. Thompson DF, Carter J: Drug-induced gynecomastia. Pharmacotherapy 13(1): 37-45, 1993.

41. Ting AC, Chow LW, Leung YF: Comparison of tamoxifen with danazol in the management of idiopathic gynecomastia. Am Surg 66(1):38-40, 2000.

42. Treves N: Gynecomastia: the origins of mammary swelling in the male: and analysis of 406 patients with breast hypertrophy, 525 with testicular tumors, and 13 with adrenal neoplasms. Cancer 11: 1083-102, 1958.

43. Walden PD, Ruan W, Feldman M, Kleinberg DL: Evidence that the Mammary Fat Pad Mediated the Action of Growth Hormone in Mammary Gland Development, Endocrinology 139 (2): 659-62, 1998

44. Young S, Gooneratne S. Straus FH 2nd, Zeller WP, Bulun SE, Rosenthal IM: Feminizing Sertoli Cell Tumors in Boys with Peutz-Jehgers Syndrome. American Journal of Surgical Pathology 19 (1):50-58, 1995.

45. Zachmann M, Eiholzer U, Muritano M, et al: Treatment of pubertal gynaecomastia with testolactone. Acta Endocrinol supple (copenh) 279:218-26, 1986.

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