Molecular approaches to target discovery:--evaluating targets for anti-tuberculosis drug discovery programmes.

Selection of appropriate targets for launching antituberculosis drug discovery programmes is challenging. This challenge is magnified by the limited repertoire of 'validated targets' and the paucity of clinically successful drugs. However, continued understanding of the biology of the microbe and its interaction with the host has enabled detailed evaluation of several interesting pathways and novel targets. The value of a target that is suitable for antituberculosis drug discovery needs to be defined not only in the context of its 'essentiality' for survival in vitro but also against a variety of properties relevant to activities in the drug discovery process, e.g.; selectivity, vulnerability, suitability for structural studies, ability to monitor inhibition in whole cells etc. It is also rarely feasible to obtain all the relevant information on the target prior to the launch of a discovery programme. Thus, there is a continuous confidence-building exercise on the validity of a target. Several novel approaches have enabled exploitation of the mycobacterial genome and prioritisation of putative targets; the concept of 'sterilisation' is now being evaluated not only through the availability of structurally diverse probe compounds but also by the ability to characterise metabolic pathways in vivo. The impact of the current knowledge base on the different facets of 'target validation' relevant to antituberculosis drug discovery is discussed in this article with emphasis on developing appropriate matrix systems to prioritise them. The article also discusses the influence of lead generation approaches with specific reference to antibacterial drug discovery.

Nonsteroidal progestins and antiprogestins related to flutamide.

From the dual progestin/antiandrogenic properties of certain synthetic steroids (e.g. cyproterone acetate), it was apparent that the progesterone (P) and androgen (A) receptors must have some common ligand binding features. The nonsteroidal antiandrogen (aA) hydroxyflutamide was therefore considered a possible starting point for medicinal chemistry aimed at antiprogestin (aP) activity. Various modifications to the side chain and aryl ring substituents of flutamide yielded both P and aP activity, but always coupled with varying degrees of A or aA activity. Mineralocorticoid activity was present in some structures, but glucocorticoid and antiglucorticoid activities were not detected. Species (rat, rabbit and monkey) and chiral differences presented formidable difficulties in developing simple structure activity patterns, and low ( < 1%) in vitro uterine receptor binding belied in vivo potency of some aPs. One of the most active aPs, ZM172406, the R enantiomer of ZM150271, N-(3-chloro-4-cyanophenyl)-3,3, 3-trifluoro-2-hydroxy-2-methylpropanamide, had comparable oral potency to mifepristone in rats and monkeys. The racemate ZM150271 was an effective abortifacient during early pregnancy in pigtailed monkeys (3 x 10 mg/kg) but less effective in cynomolgus monkeys. One of the most active progestins (Pn), ZM182345, N-(4-nitro-3-trifluoromethylphenyl)-4-phenyl-2-hydroxy-2-trifluoromet hyl-pentanamide, was at least as potent as P in rats and rabbits but also possessed A activity.

Receptor affinity and potency of non-steroidal antiandrogens: translation of preclinical findings into clinical activity.

The non-steroidal antiandrogens flutamide (Eulexin((R))), nilutamide (Anandron((R))) and bicalutamide (Casodex((R))) are widely used in the treatment of advanced prostate cancer, particularly in combination with castration. The naturally occurring ligand 5alpha-DHT has higher binding affinity at the androgen receptor than the non-steroidal antiandrogens. Bicalutamide has an affinity two to four times higher than 2-hydroxyflutamide, the active metabolite of flutamide, and around two times higher than nilutamide for wild-type rat and human prostate androgen receptors. Animal studies have indicated that bicalutamide also exhibits greater potency in reducing seminal vesicle and ventral prostate weights and inhibiting prostate tumour growth than flutamide. Although preclinical data can give an indication of the likely clinical activity, clinical studies are required to determine effective, well-tolerated dosing regimens. As components of combined androgen blockade (CAB), controlled studies have shown survival benefits of flutamide plus a luteinising hormone-releasing hormone analogue (LHRH-A) over LHRH-A alone, and for nilutamide plus orchiectomy over orchiectomy alone. Other studies have failed to show such survival benefits, including those comparing flutamide plus orchiectomy with orchiectomy alone, and nilutamide plus LHRH-A with LHRH-A alone. In a direct comparative study, bicalutamide (50 mg, once daily) was compared with flutamide (250 mg, three times daily), each in combination with an LHRH-A. Both therapies were well tolerated, although more patients could not tolerate flutamide therapy: 25 flutamide plus LHRH-A and 2 bicalutamide plus LHRH-A patients withdrew from therapy due to diarrhoea. There were no statistically significant differences for time to progression or survival between the two antiandrogens. This clinical trial of bicalutamide confirms the prediction from preclinical studies that a 50 mg dose of bicalutamide would be appropriate for use in patients with advanced prostate cancer, and demonstrates that this bicalutamide dose is clinically effective when administered as part of CAB.

Casodex (bicalutamide): overview of a new antiandrogen developed for the treatment of prostate cancer.

Casodex (bicalutamide, Zeneca Ltd), has been developed for prostate cancer therapy. Its preclinical, pharmacokinetic, pharmacodynamic, clinical efficacy and tolerability data are described. Casodex is a potent and specific non-steroidal antiandrogen. Clinical studies indicated that Casodex is orally bioavailable and well absorbed, with a plasma half-life of around 1 week. A Casodex dose of 50 mg daily decreased prostatic acid phosphatase comparable with castration. This dose was, therefore, evaluated initially as monotherapy and later as a component of maximal androgen blockade. Using prostate specific antigen as an end point, Casodex 150 mg daily was well-tolerated with demonstrable evidence of activity. Casodex 150 mg monotherapy was less effective than castration in terms of efficacy in patients with metastatic disease at entry. However, in patients non-metastatic at entry, Casodex 150 mg monotherapy appeared to be equivalent to castration in terms of time to death (data immature). Casodex was well-tolerated. In combination treatment, Casodex at 50 mg daily was at least as effective as 750 mg flutamide (Eulexin, Schering-Plough International) with respect to time to treatment failure, equivalent in terms of survival, and better tolerated with respect to diarrhoea. In conclusion, Casodex is a good option for the antiandrogen component of maximal androgen blockade.

The development of Casodex (bicalutamide): preclinical studies.

Casodex (bicalutamide, Zeneca Limited) was developed for the treatment of prostate cancer from a series of nonsteroidal compounds related to flutamide. Casodex is a selective antiandrogen that binds to rat, dog and human prostate androgen receptors, and has approximately a 4-fold higher affinity for the rat androgen receptor than hydroxyflutamide, the active metabolite of flutamide. Casodex also binds to androgen receptors found in the LNCaP human prostate tumour and the Shionogi S115 mouse mammary tumour cell line, as well as androgen receptors transfected into CV-1 and HeLa cells. In all cases, Casodex behaves as a 'pure' antiandrogen and inhibits gene expression and cell growth stimulated by androgens. Studies in vivo show that Casodex is a potent antiandrogen in the rat. In contrast to flutamide, which produces dose-related, marked increases in serum luteinising hormone (LH) and testosterone, Casodex has little effect on serum LH and testosterone; that is, it is peripherally selective. The peripheral selectivity of Casodex has now been shown to be due to poor penetration across the blood-brain barrier. In dogs, Casodex has exquisite potency and causes dose-related atrophy of the prostate gland and epididymis; with an oral ED50 of 0.1 mg/kg, it is about 50 times as potent as flutamide in this species. Casodex is also peripherally selective in the dog. In addition, magnetic resonance imaging studies have shown that Casodex is a potent antiandrogen in the monkey. Casodex, at a daily oral dose of 25 mg/kg effected a highly significant reduction in the growth of Dunning R3327H transplantable rat prostate tumours that was equivalent to that achieved by either surgical or medical castration with the LH-releasing hormone agonist Zoladex (goserelin). In a comparative study, flutamide was shown to be both less potent and less active than Casodex. In these preclinical studies, Casodex was well tolerated. The preclinical properties of Casodex give it advantages, with respect to potency, tolerability and the maintenance of effective antiandrogen serum concentrations, over other available antiandrogens. Moreover, it has a half-life that is compatible with once-daily administration.

The preclinical development of bicalutamide: pharmacodynamics and mechanism of action.

OBJECTIVES. To describe the preclinical development of bicalutamide and clarify its pharmacodynamics and mechanisms of action. Bicalutamide was developed from a series of nonsteroidal compounds related to flutamide that showed a range of pharmacologic activity from full androgen agonist to pure antiandrogen, including progestational and antiprogestational properties. METHODS AND RESULTS. Bicalutamide is a pure antiandrogen that binds to rat, dog, and human prostate; the affinity compared with the natural ligand 5 alpha-dihydrotestosterone is low, but bicalutamide has an affinity for the rat androgen receptor approximately four times higher than hydroxyflutamide, the active metabolite of flutamide. Bicalutamide also binds to androgen receptors found in the LNCaP human prostate tumor and the Shionogi S115 mouse mammary tumor cell line, as well as androgen receptors transfected into CV-1 and HeLa cells. In all cases, bicalutamide behaves as a pure antiandrogen and inhibits gene expression and cell growth stimulated by androgen. Studies with the LNCaP cell line are particularly interesting, as these cells contain a mutated androgen receptor (codon 868, Thr-->Ala), which behaves idiosyncratically with other antiandrogens (cyproterone acetate and flutamide): both these antiandrogens act as agonists in this cell line and stimulate proliferation. Studies in vivo show that bicalutamide is a potent antiandrogen in the rat. In immature, castrated male rats treated daily with testosterone propionate, bicalutamide produces a profound inhibition of accessory sex organ (ventral prostate and seminal vesicles) growth at oral doses as low as 0.25 mg/kg; it is more active in this test than flutamide or cyproterone acetate. In mature male rats, daily oral doses of bicalutamide produce a dose-related reduction in weights of the ventral prostate glands and seminal vesicles: in this test, bicalutamide is around five times as potent as flutamide. In contrast to flutamide, which produces dose-related, marked increases in serum luteinizing hormone (LH) and testosterone as a consequence of the central inhibition of the negative feedback effects of androgens on the hypothalamic-pituitary-tests axis, bicalutamide has little effect on serum LH and testosterone; i.e., it is peripherally selective. The peripheral selectivity of bicalutamide in the rat is not due to differences between the prostate versus hypothalamic or pituitary receptors, as bicalutamide reverses the suppressive effect of testosterone on luteinizing hormone-releasing hormone (LHRH) secretion from hypothalamic slices in vitro and is as effective as flutamide at sensitizing the pituitary gland to secrete LH in response to administered LHRH. The peripheral selectivity of bicalutamide has now been shown to be due to poor penetration across the blood-brain barrier: tissue distribution studies with [3H]bicalutamide show that although it is concentrated in the organs of metabolism and secretion as well as in the prostate, the pituitary glands, and the seminal vesicles, levels in the hypothalamus and the central nervous system (CNS) are much lower than in blood. Indeed, it is probable that levels found in the CNS reflect levels of blood contamination. In dogs, bicalutamide has exquisite potency and causes dose-related atrophy of the prostate gland and epididymides; with an oral ED50 of 0.1 mg/kg, it is around 50 times as potent as flutamide in this species and also more potent than the steroidal antiandrogen WIN49596 and the 5 alpha-reductase inhibitor MK-906. Even at substantial multiples of the active dose (up to 100 mg/kg orally), bicalutamide failed to increase serum testosterone, so it is also peripherally selective in the dog.

Effects of luteolytic doses of prostaglandin F2 alpha and cloprostenol on concentrations of progesterone, luteinizing hormone, follicle-stimulating hormone, glucose, insulin, growth hormone, thyroxine, prolactin and cortisol in jugular plasma of lactating dairy cows.

Three groups of five lactating dairy cows in the mid-luteal phases of oestrous cycles were given an injection (at time 0 h) of the naturally-occurring prostaglandin F2 alpha (PGF2 alpha) or cloprostenol (a synthetic analogue of PGE2 alpha) at doses recommended for inducing luteolysis, or injection vehicle. Concentrations of glucose and hormones in jugular plasma were measured from 26 h before to 12 h after the injections and the significance (P < 0.05) of the effects of the prostaglandins on these concentrations was determined. Both prostaglandins induced falls in progesterone concentration and rises in luteinizing hormone concentration; neither influenced follicle-stimulating hormone. PGF2 alpha increased glucose concentration; neither prostaglandin influenced insulin concentration. Both prostaglandins increased growth hormone concentration and resulted in declining thyroxine concentration. PGF2 alpha increased prolactin and cortisol concentration. There were, however, no significant differences between the effects of the two prostaglandins on any hormone (or glucose) concentration.

Effects of the gonadotrophin-releasing hormone agonist 'Zoladex' upon pituitary and gonadal function in hypogonadal (hpg) male mice: a comparison with normal male and testicular feminized (tfm) mice.

Hypogonadal (hpg) mutant mice, with a congenital deficiency of hypothalamic gonadotrophin-releasing hormone (GnRH), and testicular feminized (tfm) mice, which lack a functional androgen receptor, were used to study the effects of the potent GnRH agonist 'Zoladex' (ICI 118630; D-Ser (Bu(t))6, Azgly10-GnRH) on pituitary and gonadal function. Zoladex (0.5 mg) in a sustained-release lactide-glycolide copolymer depot was administered subcutaneously under anaesthesia and was left in place for 7 days, after which time the effects of the drug upon pituitary and serum gonadotrophin concentrations, glycoprotein hormone subunit mRNAs and testicular morphology were investigated. At the pituitary level, Zoladex treatment resulted in a substantial reduction in LH content in normal males, and LH content was depressed in hpg mice even below the basal levels normally found in these mutants. Pituitary LH content in the Zoladex-treated animals was depressed in the tfm groups, but not to the same levels as those found in the normal and castrated normal mice. Zoladex treatment at the time of castration prevented the post-operative elevation in serum LH associated with castration alone. In the androgen-deficient tfm mouse, Zoladex did not depress the normally elevated serum LH levels. Serum LH in the hpg animals was, in all cases, below the limit of detection of the assay. Pituitary FSH content was depressed into the hpg range in both the normal and castrated animals, but there was no further depression in the hpg mice. The pituitary content was reduced in the tfm mice, again the effects not being as dramatic as in the normal and castrated animals. Serum FSH content, as measured by radioimmunoassay, was depressed by 50% in normal mice; there was no reduction in the hpg mice, however. With regard to pituitary gonadotrophic hormone gene expression, Zoladex administration to normal mice caused a dramatic reduction in LH beta mRNA content, to a level approximating that found in untreated hpg mice. The drug also depressed LH beta mRNA in the castrated group to the hpg range when given at the time of castration, whereas in untreated castrated mice there was a significant increase in LH beta mRNA. In the tfm mouse, which can be considered as a model for long-term failure of androgen feedback, Zoladex again induced a fall in LH beta mRNA, but not to the same extent as in the normal and normal castrated group. Zoladex had no effect on the already low levels of LH beta mRNA found in hpg mice.(ABSTRACT TRUNCATED AT 400 WORDS)

Use of the nonsteroidal anti-androgen Casodex in advanced prostatic carcinoma.

Pure anti-androgens have advantages over steroidal anti-androgens of the cyproterone acetate type in the treatment of patients with advanced prostate cancer because they do not have steroidal side effects or such a marked inhibitory effect on libido. In addition, the long half-life of a pure anti-androgen such as Casodex results in maintenance of high serum anti-androgen concentrations, which allays concern over the clinical significance of any small rise in serum testosterone concentrations. The anti-androgen of choice for the treatment of androgen-responsive diseases has yet to be defined. However, this choice should be based on extensive clinical evaluations of a drug as monotherapy. As always, the clinical efficacy and tolerability of the drug will be important factors in determining the anti-androgen of choice; however, favorable pharmacokinetics should be emphasized in the treatment of a disease in which high and sustained concentrations of antagonist must be present to prevent androgenic stimulation. Casodex, a pure anti-androgen with a relatively long half-life, produces objective and subjective responses similar to those of surgical or pharmacologic castration and is well tolerated. Its profile makes it a strong candidate for consideration as the future anti-androgen of choice in the treatment of advanced prostate cancer.

A new extra long acting depot preparation of the LHRH analogue Zoladex. First endocrinological and pharmacokinetic data in patients with advanced prostate cancer.

A new depot formulation of the LHRH analogue Zoladex (goserelin acetate) has been developed which releases the drug over a period of at least 3 months as judged by measurement of drug content in depots at intervals after insertion in male rats and by the suppression of oestrogen secretion and oestrus in female rats. This formulation is based on the lactide/glycolide polymer system used for the standard 1-month Zoladex depot, but the dose has been increased to 10.8 mg and the characteristics have been modified to enable a longer release of drug to be achieved. Thirty-eight patients with histologically proven, locally advanced (stage T3 or T4) and/or metastatic prostate cancer were treated with this new longer acting LHRH analogue depot formulation containing 10.8 mg Zoladex. After initial increase of serum testosterone in the first week of therapy, castration levels were reached in all patients after 4 weeks and this was maintained for more than 14 weeks. At the time of depot exhaustion, when escape from castration levels of androgen occurred, all patients received a single injection of a standard 1-month depot containing 3.6 mg Zoladex which restored castration levels of androgen thus showing that the pituitary gland was again suppressed. The tolerance and acceptability of the longer-acting depot is high and comparable to the 1-month depot. Taking into account social and psychological factors, patients with advanced prostate carcinoma will soon be able to be treated with a longer acting LHRH depot formulation every 3 months an alternative of the 1-month depot now widely used clinically.

Protection of spermatogenesis in rats from the cytotoxic procarbazine by the depot formulation of Zoladex, a gonadotropin-releasing hormone agonist.

The hypothesis that adjuvant treatment designed to produce testicular atrophy would preserve fertility in males receiving cancer chemotherapy was examined in the rat. Testicular atrophy was induced by a depot formulation of Zoladex [D-Ser(Bu(t))6-Aza-Gly10-GnRH], a gonadotropin-releasing hormone (GnRH) analogue. The experiments were conducted in albino Wistar as well as in the piebald variegated rat. Rats received the depot Zoladex formulation 2 weeks before and immediately prior to being treated with four weekly doses of procarbazine (200 mg/kg). Testicular function was evaluated 50 and 90 days after the last procarbazine dose. Procarbazine induced testicular atrophy concomitant with marked germinal cell aplasia in both strains of rat. In the Wistar rat adjuvant treatment with Zoladex caused slight but not significant alleviation of the testicular toxicity of procarbazine. The testicular toxicity of procarbazine was more extensive in the piebald variegated rat, and 50 days after the last procarbazine treatment the testes were small, sperm were absent, and the stem cell index was close to zero. Serum luteinizing hormone (LH) concentrations were raised and testicular LH receptor binding was low in the presence of normal serum and testicular testosterone concentrations, indicating compensated Leydig cell failure. Testicular weight and sperm content, as well as LH receptor binding, were still decreased in rats which received both Zoladex and procarbazine, suggesting that the analogue offered no protection. However, the stem cell index of the seminiferous tubules in the procarbazine-Zoladex-treated rats was not significantly different from vehicle-treated rats, which suggested that recovery from the effects of procarbazine was in progress. Ninety days after the end of procarbazine treatment alone the testes of rats were still atrophied and there was little evidence of active spermatogenesis. Leydig cell failure appeared to have progressed as, in addition to the low testicular LH receptor content and raised serum LH concentration, the prostate and seminal vehicle weights were decreased. The combination of Zoladex treatment with procarbazine was successful in preserving testicular function in the piebald variegated rats as virtually all the functional and morphological parameters of both the seminiferous tubule and the Leydig cell were not significantly different from those of vehicle-treated rats. This study demonstrates for the first time that effective gonadal protection from the toxic effects of procarbazine chemotherapy can be achieved by administration of the depot formulation of the gonadotropin-releasing hormone analogue Zoladex. The results show clearly that complete suppression of spermatogenesis is not a prerequisite for the successful outcome of treatments designed to protect the gonad from cytotoxic chemotherapy.

A new longer-acting LHRH analog depot: preliminary results of a Dutch open phase II clinical study on a 10.8 mg Zoladex 3-monthly depot.

A new longer-acting depot formulation containing 10.8 mg Zoladex was administered subcutaneously without anesthetic to 35 patients with advanced carcinoma of the prostate. Pharmacodynamic and pharmacokinetic data show that following a transient elevation in serum LH and testosterone, the levels of both hormones decrease. Serum testosterone reaches the castrate range in all patients by week 4 and remains at this level for at least 12 weeks. The serum Zoladex profile shows that castrate serum testosterone values can be sustained by very low serum concentrations of the drug of around 0.05 ng/ml. In this preliminary report, the efficacy and safety of this new longer-acting 3-month depot formulation of 10.8 mg Zoladex has been shown to be comparable to the 1-month depot formulation of 3.6 mg Zoladex, in patients with advanced carcinoma of the prostate.

Casodex: preclinical studies.

Antiandrogens are effective drugs in the treatment of advanced prostatic cancer. The main problems associated with their use are their short half-lives, leading to fluctuating serum levels, and their non-selectivity, which leads to increases in serum LH and testosterone through centrally-mediated actions. Casodex is a pure, potent antiandrogen which, in pre-clinical studies, has been shown to have a long half-life and a high degree of peripheral selectivity. Casodex is as effective as surgical castration or medical castration with Zoladex in inhibiting the growth of a transplantable Dunning prostate tumor in rats. These properties suggest that Casodex, given once daily, would be an effective and well-tolerated monotherapy for advanced prostatic cancer.

Prolonged suppression of rat testis function by a depot formulation of Zoladex, a GnRH agonist.

A sustained-release formulation of a potent gonadotropin-releasing hormone (GnRH) agonist, Zoladex (D-Ser(But),6 Aza Gly10-GnRH; ICI 118,630; goserelin), was administered subcutaneously (3.6 mg/depot) to male rats once every 28 days for 2-24 wk to determine the extent to which pituitary-testis function could be suppressed and whether suppression was maintained throughout the period of treatment. Administration of Zoladex resulted in sustained decreases in weight of the testis, epididymis, seminal vesicles and prostate gland. The decreases were apparent within 2 wk of initiating treatment. Patchy degeneration of the seminiferous tubules and atrophy of the Leydig cells were observed, but did not progress beyond the degree observed after 1 month of treatment. Serum and testis testosterone were markedly depressed after 2 wk of treatment, as was testis [125I]hCG binding. Serum gonadotropins were also reduced by treatment. Serum androgen binding protein (ABP) was elevated, testis ABP content remained unchanged, and epididymal ABP content was reduced. The changes are consistent with the hypothesis that this compound affects both the anterior pituitary gland and the testis. These findings indicate that depot delivery systems are a convenient way to administer GnRH analogs for sustained treatment schedules.

A possible explanation for the peripheral selectivity of a novel non-steroidal pure antiandrogen, Casodex (ICI 176,334).

The in vivo antiandrogenicity of Casodex has been confirmed and characterised. Androgen receptor (AR) binding assays of rat ventral prostate gland cytosols revealed a relative binding affinity (RBA) for the AR of 0.267 and a k1 of 1.25 x 10(-7) M for Casodex. In addition, the peripheral selectivity of Casodex relative to other non-steroidal antiandrogens was confirmed in that daily treatment of non-castrated rats with Casodex (25 mg kg-1) did not elicit any changes in serum LH and testosterone concentrations relative to vehicle-treated controls, whereas elevated serum LH and testosterone were observed in rats treated with flutamide (25 mg kg-1). The peripheral selectivity of Casodex in the intact male rat was related to the distribution of radiolabelled antiandrogen following intravenous injection. All tissues with the exception of the hypothalamus and cerebral cortex (CC) sequestered radioactivity such that the tissue:serum ratio (TSR) for the drug was greater than unity. In the testis, the TSR was less than unity 1 h after injection but approached unity 5 h after injection and was greater than unity 10 h after injection. This may be explained by the presence of a blood-testis barrier for the drug, resulting in delayed equilibration between the blood and testis tissue. By comparison, an order of magnitude lower amounts of radioactivity in the hypothalamus and CC were maintained for the 10 h period after injection. These data, together with known physicochemical properties of Casodex suggest that a blood-brain barrier exists for the drug which results in exclusion of this antiandrogen from central sites of androgen negative feedback and that this accounts for its peripherally selective antihormonal profile.

"Casodex" (ICI 176,334)--a new, pure, peripherally-selective anti-androgen: preclinical studies.

The relative merits of the steroidal anti-androgen, cyproterone acetate, and the non-steroidal anti-androgens flutamide and nilutamide, are reviewed. It is concluded that pure anti-androgens offer some advantages over cyproterone acetate but that they each have some features which merit improvement. A new compound which was a pure anti-androgen, peripherally selective, well tolerated with a long half-life would have significant advantages. Preclinical studies in rats and dogs show that Casodex (ICI 176,334) is a potent pure anti-androgen which is well tolerated and has a long half-life. Casodex induces marked regression of the prostate yet fails to cause the substantial elevation in serum LH and testosterone seen with flutamide and nilutamide; it is thus peripherally selective. Casodex is as effective as surgical or medical castration with Zoladex in limiting the growth of the transplantable androgen-responsive Dunning rat prostate tumour. Such a profile makes Casodex a strong candidate as the future anti-androgen of choice for the treatment of prostate cancer and benign prostate hypertrophy.

Pharmacology of the luteinising hormone-releasing hormone (LHRH) analogue, Zoladex.

To prevent progression of sex hormone-responsive prostate and breast tumours, anti-androgens and anti-oestrogens are commonly used to induce androgen and oestrogen withdrawal. Zoladex is a potent luteinising hormone-releasing hormone agonist analogue, which has a selective effect on pituitary gonadotrophin release, and is highly effective at inducing regression of sex hormone-responsive prostate and breast tumours. Its depot formulation, active for at least 28 days, is convenient to administer and well tolerated and for the treatment of sex hormone-responsive tumours in men and women, Zoladex is an effective alternative to surgery.