Medical Care
No specific medications are available to treat the bone manifestations of McCune-Albright syndrome (MAS). Antiresorptive agents (eg, alendronate and its congeners [bisphosphonates]) are currently in phase 2 trials at the US National Institutes of Health.
Management of growth hormone excess in the setting of MAS should be achieved using pharmacotherapeutic agents, because this is invariably the result of diffuse nodular pituitary hyperplasia rather than a single definitive adenoma. Surgical removal of adenomas, even if apparently present on radiologic testing, may be complicated by coexisting fibrous dysplasia involving the skull bones that distorts anatomical planes and increases the potential for torrential intraoperative bleeding. Irradiation of the pituitary is also not ideal given the potential risk of inducing sarcomatous degeneration in fibrous dysplasia affected bones. No systemic investigation of using focused gamma knifeβbased pituitary irradiation has been done because this condition is so uncommon.
The vast majority of patients with growth hormone excess in the setting of MAS are treated with octreotide in doses similar to those used in regular acromegaly; beginning at 50 mcg every 8 hours subcutaneously, then titrated to response based on IGF-1 and postinjection growth hormone levels to doses as high as 1,500 mcg every day. Long-acting somatostatin analogues, such as Sandostatin LAR and lanreotide, have also been used on a case-by-case basis.
High-dose dopamine agonists, including bromocriptine, cabergoline, and pergolide, have also been demonstrated to have utility either as adjuncts to somatostatin analogues or as monotherapy. They appear to have particular utility in the setting of prolactin and growth hormone cohypersecretory states suggestive of somatomammotropinomas.
Pergolide was withdrawn from the US market March 29, 2007, because of heart valve damage resulting in cardiac valve regurgitation. It is important not to abruptly stop pergolide. Health care professionals should assess patients' need for dopamine agonist (DA) therapy and consider alternative treatment. If continued treatment with a DA is needed, another DA should be substituted for pergolide
No systemic data are presently available on the utility or place of growth hormone receptor antagonists such as pegvisomant in managing MAS-associated growth hormone excess. It is not contraindicated; however, the fact that these agents do not control growth hormone levels would probably make their use as monotherapy in this setting inadvisable.
MAS is a multisystemic condition with a host of variable presentations. Management often is challenging and requires a multidisciplinary approach.
Orthopedic surgical care for multiple bony fractures and deformities plays a major role.
The endocrinologist should screen and search for various endocrinopathies that worsen the clinical presentation.
An astute primary care physician (pediatrician or internist, depending on the age of the patient) who will coordinate the various aspects of the patient's care also is necessary.
Therapy for precocious puberty is available and should be tried; however, it is still largely experimental.
Because precocious puberty in patients with MAS is gonadotrophin-independent, continuous GnRH therapy has little utility.
For female patients, the central theme is to block estrogen effects. Testolactone, a competitive aromatase inhibitor, is used for this purpose.
Preliminary data from the testolactone therapeutic trials suggest that this medication causes reduction in estradiol and estrone levels, with reduced frequency of menses and reduction in growth and bone maturation. Testolactone also may cause elevations in measured urinary 17-ketosteroid (U-17KS) and 17-hydroxysteroid (U-17OHCS) levels.
Other preliminary trials of other aromatase inhibitors, such as fadrozole and anastrazole, are underway with the goal of achieving better management of precocious puberty.
Estrogen receptor antagonists, such as tamoxifen, may have a therapeutic role but have not yet been systematically investigated.
Other pilot clinical trials also have been performed, in which antiandrogen cyproterone acetate was used to block pubertal development in young female patients, while ketoconazole was used in males.
GnRH analogues may be added to testolactone as an adjunct for treatment of precocious puberty to suppress pituitary gonadotrophin production. Depot leuprolide acetate at a dose of 7.5 mg (300-500 mcg/kg) every 28 days is a typical regimen, the dose of which can be adjusted upwards or downwards based on clinical and laboratory findings.
Adequate response to these therapies can be assessed by serial GnRH stimulation tests following 3-6 months of therapy.
Other alternative treatment options include medroxyprogesterone acetate, which is particularly useful for controlling menstrual bleeding. The preferred agent is Depo-Provera in intramuscular doses of 4-15 mg/kg monthly. No definitive clinical trials have determined the efficacy of this medication in the setting of MAS.
Adequate medical therapy for precocious puberty in males consists of both antiandrogen and antiestrogen preparations. This typically consists of a combination of spironolactone and testolactone. Alternative antiandrogens, such as ketoconazole, also may be used in a dose range of 600-800 mg daily.
Hyperthyroidism in the setting of MAS is treated with the same medication options as regular hyperthyroidism, including thionamides (eg, propylthiouracil) and methimazole.
Thyroidectomy or hemithyroidectomy is the treatment of choice for hyperthyroidism associated with a goiter in patients with MAS.
Hyperthyroidism usually occurs in the context of toxic multinodular goiter. Although radioiodine can be effective in controlling hyperthyroidism, it is a less popular treatment option because high doses or repeated administrations of radioiodine may be necessary. Obvious issues arise with regard to the safety of radioiodine in children, especially in view of the potential for the development of both benign and malignant thyroid nodules over time following radioiodine therapy.
The bony disease associated with MAS is very difficult to treat.
Some preliminary data suggest that bisphosphonates (particularly pamidronate and alendronate) may have beneficial effects on the bone disease, including reducing bone pain, reducing frequency of pathologic fractures, and slowing the evolution of the bone disease.
In patients with MAS, other identified comorbidities that may be significantly affecting the bone density in a negative way must be identified and aggressively managed. Major morbidities include (1) hypogonadism, for which appropriate hormone replacement therapy should be instituted; (2) hypophosphatemia with hyperphosphaturia, which is managed aggressively with oral phosphorus replacement; (3) hypophosphatemic rickets, which is managed with appropriate vitamin D, calcium, and phosphate repletion; and (4) hyperparathyroidism, which may be primary or secondary.
DRUG TREATMENT :
Drug Category: Aromatase inhibitors
Testolactone typically is administered at a low dose of approximately 10 mg/kg/d and increased gradually over a period of 3-4 weeks to an ultimate dose of 40 mg/kg/d. With adequate treatment response, serum estrone and estradiol levels are reduced. Patients who respond to treatment should continue therapy until the age of normal puberty or until bone age of 15-16 years, when epiphysial fusion plate has occurred. Among the potential adverse effects associated with medication use are transient abdominal cramping, diarrhea, and mild hepatic inflammation evidenced by elevated SGOT, SGPT, and GGT.
1. TESTOLACTONE : (Teslac)
Description Synthetic antineoplastic agent that is structurally distinct from the androgen steroid nucleus in possessing a 6-membered lactone ring in place of usual 5-membered carbocyclic D-ring.
Although precise mechanism by which testolactone produces clinical antineoplastic effect has not been established, its principal action is reported to be inhibition of steroid aromatase activity and consequent reduction in estrone synthesis from adrenal androstenedione, the major source of estrogen in postmenopausal women.
Based on in vitro studies, the aromatase inhibition may be noncompetitive and irreversible. This phenomenon may account for the persistence of testolactone's effect on estrogen synthesis after drug withdrawal. Despite some similarity to testosterone, testolactone has no in vivo androgenic effect. No other hormonal effects have been reported in clinical studies in patients receiving testolactone. In one study, testolactone administered orally (1000 mg/d) was reported to increase renal tubular reabsorption of calcium but had no effect on serum calcium concentration. The mechanism of hypocalciuric effect is unknown. No clinical effects of testolactone on adrenal function have been reported in humans; however, one study noted an increase in urinary excretion of 17-ketosteroids in most patients treated with 150 mg/d PO.
Typically is administered at a low dose of approximately 10 mg/kg/d and increased gradually over a period of 3-4 wk to an ultimate dose of 40 mg/kg/d. With adequate treatment response, serum estrone and estradiol levels are reduced. Patients who respond to treatment should continue therapy until the age of normal puberty or until bone age of 15-16 y when epiphysial fusion plate has occurred.
Testolactone is well absorbed from the gastrointestinal tract. It is metabolized to several derivatives in the liver, all of which preserve the lactone D-ring. These metabolites, as well as some unmetabolized drug, are excreted in the urine. No clear manifestation of androgenic, estrogenic or antiestrogenic, progestational or antiprogestational, and gonadotropinlike or antigonadotropic effects have been reported. Testolactone does not demonstrate anti-inflammatory, mineralocorticoidlike, or glucocorticoidlike properties. Available for PO administration as tabs, providing 50 mg testolactone per tab.
Adult Dose 250 mg PO qid