A dose response evaluation of delta-1-testololactone in advanced breast cancer

Additive endocrine therapy for advanced breast cancer - back to the future

While novel endocrine treatment options have been implemented in the advanced - as well as adjuvant setting, recent results suggest a place for "old-fashioned" additive treatment with estrogens in advanced breast cancer. This paper reviews the biological rationale for endocrine therapy in general and additive treatment with estrogens in particular. The finding that patients becoming resistant to treatment with aromatase inhibitors may subsequently respond to estrogen therapy adds important information to our understanding of therapy resistance in general. Moreover, the return of a therapeutic option abandoned more than 20 years ago, now to be used in a different sequential setting, suggests a critical examination whether there may be other conventional treatment options still earning a place as treatment in advanced disease as well. While ablative therapies including surgical oophorectomy, hypophysectomy and adrenalectomy are not candidate treatment options due to morbidity, there are additive treatment options apart from estrogen therapy that may be considered. Androgens administered at therapeutic doses are not feasible for toxicity reasons; yet, the potential of adding androgens in small doses as adjuvant to aromatase inhibitors should be further explored. Whether patients become resistant to other treatment options may still benefit from megestrol acetate, remains to be explored.

Aromatase inhibition: translation into a successful therapeutic approach

The development of the novel third-generation aromatase inhibitors and inactivators for breast cancer treatment is one of the most successful contemporary achievements in cancer therapy. Parallel to studies evaluating toxicity and clinical efficacy in metastatic disease, the endocrine effects of multiple compounds were evaluated, leading to the identification of the highly potent third-generation aromatase inhibitors based on estrogen deprivation and aromatase inhibition in vivo. Thus, translational studies have been of vital importance identifying the unique characteristics of these compounds. Whereas first- and second-generation aromatase inhibitors inhibit estrogen synthesis in vivo by up to 90%, the third-generation compounds anastrozole, exemestane, and letrozole were found to cause > or =98% aromatase inhibition. This article summarizes and discusses the "translational research" that provided the background for the implementation of the third-generation aromatase inhibitors and inactivators into large clinical trials. The need for future translational research exploiting the mechanisms of resistance to these compounds for future improvement of endocrine therapy is emphasized.

Aromatase inhibitors and inactivators for breast cancer therapy

Aromatase inhibitors and inactivators are increasingly important to the therapy of advanced breast cancer in postmenopausal women. These compounds are also currently being evaluated in the adjuvant setting and may have potential in breast cancer prevention. In addition to the recent clinical results, experimental research with development of aromatase 'knockout' mice as well as certain clinical observations in individuals lacking this enzyme have deepened our understanding of estrogens outside of the field of reproduction. Such information should help us to further develop this type of therapy in breast cancer and, in particular, extend our understanding of the lack of complete cross-resistance between aromatase inhibitors and inactivators. Clinically, third-generation aromatase inhibitors and inactivators have shown superiority compared with conventional treatment in advanced postmenopausal breast cancer with respect to second-line (tamoxifen failures) as well as first-line therapy. The fact that tamoxifen is noncurative in metastatic disease but improves long-term survival in the adjuvant setting suggests that even modest improvements in therapy of advanced disease may be translated into survival benefits in patients with early disease. In addition, these novel compounds with lack of complete cross-resistance extend the scope of using sequential treatment options to maximise the duration of optimal endocrine therapy in metastatic breast cancer disease.

Pharmacological profiles of exemestane and formestane, steroidal aromatase inhibitors used for treatment of postmenopausal breast cancer

Steroidal aromatase inhibitors like formestane and exemestane are useful drugs for endocrine treatment of postmenopausal breast cancer. In addition, these drugs should be considered valuable probes to explore the biology of breast cancer with particular emphasis on possible relations between the degree of estrogen suppression and clinical efficacy and the possible role of intratumor estrogen synthesis. The fact that steroidal and non-steroidal aromatase inhibitors bind to different parts of the aromatase enzyme suggests these drugs may act in concert aggravating plasma estrogen suppression. Thus, use of a steroidal and a non-steroidal aromatase inhibitors in concert may be one way to improve breast cancer treatment and may also provide important information to a better understanding of the dose-response relationship between estrogen suppression and clinical effects. Further, the finding that patients progressing on non-steroidal aromatase inhibitors may respond to formestane as well as exemestane suggests these drugs may have differential effects, probably on the aromatization in the tumor tissue. Further studies are warranted to explore the influence of steroidal and non-steroidal aromatase inhibitors on intratumor aromatase activity and intratumor estrogen concentrations and to correlate these findings to intratumor drug concentrations. The findings that steroidal aromatase inhibitors may have clinical effects in patients progressing on treatment with the non-steroidal aromatase inhibitor aminoglutethimide is challenging, and suggest further studies to evaluate possible benefits of using different novel aromatase inhibitors in concert or sequence.

First generation aromatase inhibitors--aminoglutethimide and testololactone

Aminoglutethimide and testololactone may be considered the first generation aromatase inhibitors for the endocrine treatment of breast carcinoma. Initially, both of these agents were designed and used clinically based on different concepts of their mechanisms of action. Only later were they both demonstrated to inhibit aromatase. Curiously, testololactone was earlier and more widely used than aminoglutethimide in treating advanced breast carcinoma. The discovery of the peripheral aromatase inhibition as the proper mechanism of action was delayed for both the agents but was relatively more timely for aminoglutethimide. Paradoxically, the clinical use of testololactone has become already obsolete since its true mechanism of action was discovered. Aminoglutethimide is still the most widely used aromatase inhibitor in treating advanced breast carcinoma. Due to the initial misinterpretation of its mechanism of action, aminoglutethimide was used for a long time at a relative high daily dose, always combined with hydrocortisone. Subsequent phase II and then randomized phase III studies demonstrated an equivalent efficacy using half (500 mg) of the previous conventional daily dose (1000 mg), with hydrocortisone. Very recently, a randomized clinical trial demonstrated that administering this lower dose without hydrocortisone did not significantly decrease the clinical efficacy. By decreasing the dose of aminoglutethimide, the incidence of side effects has been reduced. So, the last paradoxical aspect of the aminoglutethimide story is that this agent seemed initially very toxic but finally, with the new schedules, shows a very low toxicity profile, especially after the first few weeks of treatment.

Deflazacort and Fluoximesterone in Advanced, Pretreated Breast Cancer

A very simple, low dose, orally administered regime (10 to 15 mg of fluoximesterone + 6 mg of deflazacort daily for periods of 1 to several months) resulting in mild-acceptable toxicity (essentially some weight gain) determined subjective improvement In 2/3 of 34 evaluable patients (out of 36 treated) and an objective measurable tumor reduction in 1/3, although most patients had been previously treated with chemotherapy and hormone treatment and proved primarily or secondarily refractory. The receptor status at the beginning of fluoximesterone + deflazacort treatment was not known, except in one negative-receptor patient, who responded to the combination after becoming resistant to tamoxifen (see photo). In some patients the condition of hormone refractoriness would suggest a no-treatment policy, but a trial with this regime is always convenient as it may improve both duration and quality of life.

Aminoglutethimide enzyme induction: pharmacological and endocrinological implications

Aminoglutethimide is an aromatase inhibitor that is successfully used for endocrine treatment of advanced breast cancer. This drug also stimulates the activity of hepatic mixed-function oxidases, increasing the metabolism of several drugs, including warfarin, digitoxin, antipyrine and theophylline. It also increases the plasma clearance rate of oestrone sulphate. As this oestrogen may be an important substrate for tumour cells, stimulation of oestrone sulphate metabolism may be a component of the mechanism of action of aminoglutethimide.

Postmenopausal estrogen synthesis and metabolism: alterations caused by aromatase inhibitors used for the treatment of breast cancer

Inhibition of postmenopausal estrogen production by aromatase inhibitors is an established drug treatment modality for postmenopausal breast cancer. In this article postmenopausal estrogen disposition and the alterations caused by treatment with aromatase inhibitors are reviewed. Recent investigations have challenged the hypothesis that aromatization of androstenedione into estrone is the sole production pathway for estrogens in postmenopausal women. The finding that estrogens persist in the plasma of patients receiving aminoglutethimide treatment despite a near total inhibition of the aromatase enzyme suggests that alternative pathways for estrogen synthesis exist. While nonspecific actions of aromatase inhibitors may be disadvantageous, certain effects may also be beneficial. Recent findings that aminoglutethimide may induce estrone sulfate metabolism questions whether this "prototype" aromatase inhibitor might have a dual mechanism of action. The importance of investigating the possible influence of different aromatase inhibitors on all components of estrogen disposition is considered.

New endocrine drugs for treatment of advanced breast cancer

Current status of endocrine treatment for breast cancer is reviewed. Several new aromatase inhibitors as well as antiestrogens are being introduced for clinical trials. As different drugs within the same drug group may possess different biochemical actions, apart from being useful drugs for treatment of breast cancer, these drugs may also extend our knowledge about the endocrinology of breast cancer.

High-density lipoprotein cholesterol is not decreased if an aromatizable androgen is administered

We examined the influence of aromatization of testosterone on serum high-density lipoprotein cholesterol (HDL-C) and postheparin plasma hepatic triglyceride lipase activity (HTLA) in men. Eighteen healthy lean nonsmokers (ages, 20 to 33) were administered androgens in a weekly total dose of 280 mg for 12 weeks in one of three groups: testosterone enanthate (TE) (280 mg/wk intramuscularly [IM]); TE (280 mg/wk IM) + testolactone (TL) (250 mg orally [PO] four times daily); or methyltestosterone (MeT) (20 mg PO twice daily). Serum testosterone achieved steady state levels by 4 weeks with greater than 40 nmol/L (TE and TE + TL) and less than 15 nmol/L (MeT) while 17b-estradiol (E2) rose to greater than 250 pmol/L (TE) or remained below 70 pmol/L (TE + TL and MeT). LH fell to less than 5 U/L (TE and TE + TL) but remained unchanged with MeT. By 4 weeks, HDL-C had decreased significantly from 1.20 +/- 0.13 to 0.77 +/- 0.13 mmol/L (MeT), from 1.18 +/- 0.15 to 0.89 +/- 0.13 mmol/L (TE TL), and demonstrated no decrease in the TE group across the time course of the study. These changes were preceded by mean increases in HTLA of 102% (MeT) and 55% (TE + TL) over baseline, and no significant change with TE. The changes in HDL-C and HTLA returned to baseline within 2 weeks of steroid cessation. There were no changes in total cholesterol, triglycerides, or insulin in any group but, in the MeT group, apo AI levels decreased and low-density lipoprotein cholesterol (LDL-C) increased.(ABSTRACT TRUNCATED AT 250 WORDS)

Mechanisms of action of aminoglutethimide as endocrine therapy of breast cancer

During the last decade aminoglutethimide has been recognised as a valuable alternative in endocrine therapy for advanced breast cancer. Although some side effects do occur, most often these are initial effects which subside within a few weeks, and cessation of therapy is not usually indicated. Aminoglutethimide was originally introduced as an inhibitor of steroidogenesis in the adrenal cortex. It was soon recognised, however, that inhibition of the non-glandular aromatase, blocking the conversion of androgenic prohormones to oestrogens, was more important, resulting in decreased blood levels of oestrogens. In this review the role of aromatase inhibition as the only important aspect of the mechanism of action of aminoglutethimide is challenged. Evidence has accumulated during the last few years that aminoglutethimide is a most potent inducer of microsomal enzymes. In addition to the pharmacological implications this has (suggesting important interactions), it also points to the possibility that levels of oestrogens are decreased due to accelerated metabolism of these hormones. Based on new experimental data, and also clinical work with alternative aromatase inhibitors, it appears that the antitumour activity of aminoglutethimide may be due to both aromatase inhibition and accelerated metabolism of oestrogens. This seriously challenges the importance of aromatase inhibition alone as a strategy in endocrine therapy of breast cancer, and furthermore suggests that accelerated metabolism of key hormones is an alternative strategy to be explored.

Alterations in the metabolism of oestrogens during treatment with aminoglutethimide in breast cancer patients. Preliminary findings

In this small study, the effect of aminoglutethimide on the disposition of oestrogens in women with advanced breast cancer was investigated using bolus injections of 4-[14C]-oestradiol and 6,7-[3H]-oestrone sulphate, alone or in combination. No alterations in oestrogen disposition were seen after short term (6 hours) aminoglutethimide administration. During long term (3 weeks to 8 months) aminoglutethimide treatment mean 4-[14C]-oestradiol clearance was not changed. 14C-Oestrone sulphate AUC was reduced by 43% at a low dose of aminoglutethimide (125 mg twice daily) and by 65% at a high dose (250 mg 4 times daily) with hydrocortisone acetate 25 mg twice daily. The oestrone sulphate terminal elimination rate constant (lambda z) was concurrently increased (mean of 46 and 79%, respectively, with the 2 dosage regimens). A possible increase in oestrone sulphate clearance during long term treatment was tested for by injecting 6,7-[3H]-oestrone sulphate. These studies revealed a marked increase (mean 104%) in oestrone sulphate clearance in patients receiving the high dose aminoglutethimide schedule. Following injection of 4-[14C]-oestradiol plus 6,7-[3H]-oestrone sulphate, the fraction of 4-[14C]-oestradiol metabolised to oestrone sulphate was found to be reduced in all patients (mean 13%). A mean increase of 80% in the urinary excretion of 14C-oestriol was observed after 4-[14C]-oestradiol administration. Our results, although preliminary, suggest that aminoglutethimide is a potent inducer of aminoglutethimide metabolism, thereby producing a significant reduction in plasma bioavailability of oestrone sulphate. These effects may have a role in the action of aminoglutethimide, a finding which warrants further investigation.

Hormonal changes in postmenopausal women with breast cancer treated with trilostane and dexamethasone

Postmenopausal women with metastatic breast cancer were treated with trilostane, initially 240 mg daily increasing after 3 days to 480 mg daily and after a further three days to 960 mg daily. After 3 days at this dose dexamethasone 1 mg daily was added and this combination was continued until disease progression occurred. Partial remission was seen in 26% and stabilization of previously progressive disease in a further 13% of the first twenty-three patients studied. During therapy with trilostane alone significant increases in DHEAS, androstenedione, 17-hydroxypregnenolone, progesterone, testosterone and oestradiol were seen. A significant fall in oestrone concentration occurred at the same time. After dexamethasone was added the elevated steroid concentrations fell back to the baseline while oestrone remained depressed below this and testosterone was also significantly lowered. No change was seen in cortisol or ACTH concentration while patients were on trilostane alone but cortisol levels were undetectable after dexamethasone was added though, in most patients, ACTH remained detectable. There was no change in the ratio of delta 5:delta 4 steroids at any stage of therapy but a highly significant increase in the androstenedione: oestrone ratio was seen. We conclude that in long-term use in vivo it is difficult to demonstrate that trilostane inhibits 3 beta-hydroxysteroid dehydrogenase but it may produce inhibition of aromatase.

Low-dose aminoglutethimide in treatment of advanced breast cancer

The clinical and endocrine effects of low-dose aminoglutethimide without hydrocortisone in patients with advanced breast cancer were investigated. In a dose escalation study low-dose aminoglutethimide alone (62.5-125 mg twice daily) was as effective as conventional doses with hydrocortisone in lowering serum oestrone and oestradiol concentrations but caused minimum adrenal inhibition, as assessed by serum dehydroepiandrosterone sulphate. 11 of 57 (19%) evaluable patients had tumour regression by objective criteria on this treatment, but the frequency of side-effects was similar to that with conventional doses. Low-dose aminoglutethimide is active in the treatment of breast cancer. It appears to work by inhibition of the aromatase enzyme system in peripheral tissues rather than adrenal suppression.

Additive effects of aminoglutethimide, testololactone, and 4-hydroxyandrostenedione as inhibitors of aromatase

In vitro p450 spectral data suggested that combinations of aromatase inhibitors might produce enhanced biologic effects. If correct, two clinically available aromatase inhibitors, aminoglutethimide (AG) and testololactone (TL) could potentially be given together at lower than usual dosage with reduction of patient side effects and preservation of aromatase inhibition. Using a [3H]water aromatase assay and a placental microsomal system, AG and TL were tested individually and in combination over their respective dose response ranges. Additive effects of these two compounds were observed. Another inhibitor, 4-hydroxyandrostenedione, given with AG produced similar additive inhibition. These data provide a basis for a future trial of AG and TL in combination in patients with breast carcinoma.

Phase II study of high-dose tamoxifen (NSC-180973) in patients with disseminated malignant melanoma

Seventeen patients with disseminated malignant melanoma received a daily oral regimen of tamoxifen, 100 mg/m2. All patients had prior chemotherapy and predominantly visceral involvement. None of the patients had an objective regression and most (71%) had progressive disease at the time of first reassessment. Moderate to severe nausea occurred in 24% of patients. In the dose and schedule used in this study, tamoxifen is ineffective in patients with advanced malignant melanoma and prior chemotherapy exposure.

Inhibition of estrogen synthesis in human breast tumors by testololactone and bromoandrostenedione

The inhibition of aromatase enzyme in human breast tumors by delta 1-testololactone, testololactone, 6 alpha-bromoandrostenedione, and 6 beta-bromoandrostenedione was investigated. Estrone and estradiol synthesis from androstenedione was reduced in 3 tumor incubations by the presence of 0.13 mM delta 1-testololactone and testololactone. 6 alpha- and 6 beta-bromoandrostenedione (2.0 microM) were also shown to block estrogen synthesis in 2 tumors. Furthermore, Lineweaver-Burk plots revealed that all 4 compounds are competitive inhibitors of androstenedione aromatization. An apparent Km of the aromatase enzyme for androstenedione of 0.08 microM and a Vmax of 23 pmol of estrone synthesized/g tumor/hr were determined for one human breast tumor specimen. These results demonstrate that these aromatase inhibitors may be useful for the treatment of breast cancer.

Combined androgen and antimetabolite therapy of advanced female breast cancer. A report of the cooperative breast cancer group

A clinical trial of androgen and antimetabolite therapy of advanced female breast cancer was conducted in 110 patients by the Cooperative Breast Cancer Group. An objective regression rate of 20% was achieved in women receiving oral testolactone, 6% in patients given intravenous fluorouracil alone, and 14% when the androgen and antimetabolite were administered together. This randomized trial according to the CBCG protocol did not produce the high regression rate noted previously in a nonrandomized, nonprotocol evaluation of these drugs.