The effects of long term fadrozole hydrochloride treatment in patients with advanced stage breast cancer.

Fadrozole hydrochloride at a dose of 2 mg b.i.d. has been shown to be an effective aromatase inhibitor in advanced stage breast cancer patients as determined by its ability to significantly suppress endogenous estrogen biosynthesis over a 12-week period. Continued suppression of circulating estrogen levels over a prolonged period has not yet been examined in published reports. In this study, we report the extended use of fadrozole hydrochloride at a maintenance dose of 2 mg b.i.d. in a cohort of 11 patients extending to 973 days of therapy. Results show that the degree of suppression of plasma and urinary estrogens was maintained in all patients throughout the extended period of drug use. Continued estradiol suppression of over 50% or greater from baseline was observed, as was continued suppression of estrone to over 80% from baseline. Cortisol determinations after 9 months of treatment showed no suppression from baseline. The aldosterone values and responses to cortrosyn stimulation continued to be suppressed as first noted following the initial 3 months of the core clinical trial. Objective tumor response noted in the core clinical trial did not change until disease progression. These findings suggest that fadrozole hydrochloride maintains its ability to suppress the aromatase enzyme during long term use. No observable escape from suppression of plasma and urinary estrogens occurred during prolonged treatment.

Specificity of low dose fadrozole hydrochloride (CGS 16949A) as an aromatase inhibitor.

CGS 16949A (fadrozole hydrochloride), a potent cytochrome P450-mediated steroidogenesis inhibitor, blocks aromatase at low doses, but other biosynthetic steps at higher concentrations. Recent studies demonstrated inhibition of C11-hydroxylase, corticosterone methyloxidase-II, and deoxycorticosterone to corticosterone conversion with this agent at some-what higher concentrations than those required for blockade of aromatase. Based upon phase I studies, we postulated that relatively selective inhibition of aromatase might be possible if sufficiently low doses of CGS 16949A were used. A phase II study in 54 postmenopausal women with metastatic breast cancer examined the effects of low dose CGS 16949A on estrogen, mineralocorticoid, and glucocorticoid secretion. Two dose schedules and two dose levels were chosen based upon our prior dose escalation protocol study. Plasma estrone, estradiol, and estrone sulfate as well as urinary estrone and estradiol fell equally with 1.8-4 mg CGS 16949A given either on a twice daily or three times daily dose schedule. Isotopic kinetic studies demonstrated an 84% decrease in the rate of conversion of androstenedione to estrone to 0.40 +/- 0.07% (patients receiving 1.8-4 mg CGS 16949A daily). With these three regimens, basal levels of aldosterone and cortisol did not change significantly over a 12-week period of observation. Clinical examination, plasma electrolytes, and urinary sodium/potassium ratios suggested no biological evidence of mineralo-corticoid deficiency. ACTH-stimulated cortisol concentrations, however, were blunted at each dose level compared to pretreatment values. Nonetheless, peak responses exceeded 550 nmol/L, or a basal to peak difference of 190 nmol/L or greater, in 97% of instances. This probably reflected inhibition of C11-hydroxylase, since basal and ACTH-stimulated levels of 11-deoxycortisol were increased in response to CGS 16949A. Androstenedione and 17 alpha-hydroxyprogesterone also exhibited an upward trend in response to drug treatment. ACTH-stimulated aldosterone levels were blunted to a greater extent than those of cortisol, probably as a reflection of corticosterone methyloxidase type II blockade. Overall, the results suggest that CGS 16949A, at doses of 1.8-2 mg daily, blocks aromatase effectively and does not produce clinically important inhibition of cortisol or aldosterone biosynthesis. Thus, this agent can probably be used safely without glucocorticoid or mineralocorticoid supplementation.

Initial clinical trial of the macrophage activator muramyl tripeptide-phosphatidylethanolamine encapsulated in liposomes in patients with advanced cancer.

A phase I clinical trial of the macrophage activator, muramyl tripeptide-phosphatidylethanolamine has been carried out in 37 patients (47 courses) at doses of 0.01-6.0 mg/m2 intravenously twice weekly for 4 weeks. Activation of peripheral blood monocytes and drug toxicity were used as the parameters to monitor the trial. Toxicity was acute systemic responses of fever, chills, and hypertension without a clear dose response. No major organ-related toxicity was seen. A dose of 4.0 mg/m2 biweekly produced activation of blood monocytes; a dose of 6.0 mg/m2 produced inhibition. There was one complete response of 3 months duration in a patient with renal cell carcinoma with pulmonary metastases. The optimum dose for phase II studies is in the range of 1-4 mg/m2 twice weekly for 4 weeks, a dose that is well tolerated.

A phase I trial of CGS 16949A. A new aromatase inhibitor.

CGS 16949A is a new, nonsteroidal competitive inhibitor of the aromatase enzyme. In this Phase I trial, 16 heavily pretreated postmenopausal patients with metastatic breast cancer were treated with escalating doses of CGS 16949A from 0.6 to 16 mg total daily oral dose. No hematologic, biochemical, or significant clinical toxicity was encountered. Endocrinologic and pharmacologic data were available from 12 of these patients. Maximum inhibition of estrogen biosynthesis was observed at a dose of 2 mg CGS 16949A daily. At this dose, the inhibition of estrogen biosynthesis was equivalent to 1000 mg aminoglutethimide (AG). The fall in plasma and urinary estrogens without a concomitant drop in androgens confirmed the specific blockade of aromatase activity. At doses of 4 to 16 mg daily, CGS 16949A appeared to inhibit the C21-hydroxylase enzyme as well. The t1/2 of CGS 16949A in the circulation was 10.5 hours. Of 16 evaluable patients there were two partial responses and seven patients with stable disease.

Hypercalcemia in malignant disease.

Hypercalcemia is a common and serious complication of neoplastic disease. It may occur in association with a variety of tumors and usually indicates a lack of tumor control. Early symptoms are nonspecific, involving several organ systems in a syndrome that may progress rapidly to death. The pathophysiology of hypercalcemia is complex and not fully understood. Research continues on local mechanisms of bone destruction at sites of bone metastases and the identification of humoral tumor-derived osteolytic factors. The therapeutic approach to hypercalcemia should be sequential, dictated more by clinical symptoms than by absolute calcium levels. The diversity of measures and agents used in the therapy of hypercalcemia of malignancy reflects the multiple mechanisms involved. The therapeutic maneuvers outlined usually yield temporary success and must be accompanied by specific antitumor therapy, the ultimate treatment for the hypercalcemia of neoplastic disease.